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Wiki source code of 8 Function parameter details

Version 10.1 by Theodore Xu on 2023/07/11 16:30
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1 = 1 F0 group basic parameters =
2
3 (% class="table-bordered" %)
4 |(% rowspan="3" %)**F0.00**|(% colspan="2" %)Motor control mode|Default|0
5 |(% rowspan="2" %)Setting Range|0|(% colspan="2" %)Sensorless vector control(SVC)
6 |1|(% colspan="2" %)V/F Control
7
8 0: Sensorless vector control(SVC)
9
10 Refers to the open loop vector. It is suitable for general high-performance control occasions, one AC drive can only drive one motor. Such as machine tools, centrifuges, wire drawing machines, injection molding machines and other loads.
11
12 1: V/F Control
13
14 It is suitable for occasions where the load requirements are not high or one AC drive drives multiple motors, such as fans and pumps.
15
16 **✎Note**: The motor parameter identification process must be carried out when selecting the SVC mode. Only accurate motor parameters can give full play to the advantages of it
17
18 (% class="table-bordered" %)
19 |(% rowspan="4" %)**F0.01**|(% colspan="2" %)Command source selection|Default|0
20 |(% rowspan="3" %)Setting Range|0|(% colspan="2" %)Keypad control
21 |1|(% colspan="2" %)Terminal control
22 |2|(% colspan="2" %)Communication control
23
24 Select the source of AC drive control command.
25
26 AC drive commands include: start, stop, forward, reverse, jog, etc.
27
28 0: Keypad control(“LOCAL/REMOT”LED off);
29
30 Command control is performed by the RUN and STOP/RESET keys on the Keypad.
31
32 1: Terminal control(“LOCAL/REMOT”LED on);
33
34 Command control is carried out by multi-function input terminals FWD, REV, FJOG, RJOG, etc.
35
36 2: Communication control(“LOCAL/REMOT”Led blinking)
37
38 Command control is given by the upper machine through communication.
39
40 (% class="table-bordered" %)
41 |(% rowspan="3" %)**F0.02**|(% colspan="2" %)UP/DOWN standard|Default|0
42 |(% rowspan="2" %)Setting Range|0|(% colspan="2" %)Running frequency
43 |1|(% colspan="2" %)Set frequency
44
45 This function is only valid for the digital setting of the frequency source. It is used to determine whether the set frequency is the current operating frequency or the current target frequency in UP/DOWN. .
46
47 (% class="table-bordered" %)
48 |(% rowspan="11" %)**F0.03**|(% colspan="2" %)Setting main frequency source X|Default|1
49 |(% rowspan="10" %)Setting Range|0|(% colspan="2" %)Digital setting (non-retentive at power failure)
50 |1|(% colspan="2" %)Digital setting (retentive at power failure)
51 |2|(% colspan="2" %)AI1
52 |3|(% colspan="2" %)AI2
53 |4|(% colspan="2" %)Reserved
54 |5|(% colspan="2" %)PULSE setting(Reserved)
55 |6|(% colspan="2" %)Multi-stage speed setting
56 |7|(% colspan="2" %)Simple PLC
57 |8|(% colspan="2" %)PID
58 |9|(% colspan="2" %)Communication setting
59
60 Select the main source of the AC drive’s input frequency. There are 10 main frequency sources:
61
62 **0:** Digital setting (non-retentive at power failure)
63
64 The initial value is 0. The frequency can be increased or decreased by the pulse knob, and the set frequency value of the inverter can be changed by the ▲/▼ keys of the keyboard (or UP and DOWN of the multi-function input terminals).
65
66 Non-retentive means that after the AC drive is powered off, the set frequency value will be restored to 0; it will be cleared after switching as the frequency source, so this parameter should not be the object of frequency source switching.
67
68 **1: **Digital setting (retentive at power failure)
69
70 The initial value is the value of F0.08 "Keypad setting frequency".
71
72 The set frequency value of the inverter can be changed by the ▲/▼ keys of the keyboard (or UP and DOWN of the multi-function input terminals).
73
74 Retentive means that when the AC drive is powered on again after power failure, the set frequency is the value before the last power failure (note that it is used in conjunction with F0.23).
75
76 **2: **AI1
77
78 **3:** AI2
79
80 Means that the frequency is determined by the analog input terminal. The standard unit provides 2 analog input terminals (AI1, AI2), among which AI1 is 0V~~10V voltage input, AI2 can be 0V~~10V voltage input, or 4mA~~20mA current input, Selected by jumper J8 on the control board.
81
82 **5: **PULSE setting(Reserved)
83
84 The set frequency is given by the terminal pulse.
85
86 Pulse given signal specifications: voltage range 9V~~30V, frequency range 0kHz~~100kHz.
87
88 Note: Pulse reference can only be input from the multi-function input terminal, __**requires custom control board development.**__
89
90 **6: **Multi-stage speed
91
92 Select multi-stage speed operation mode. Need to set the F5 group "input terminals" and FD group "multi-stage speed and PLC" parameters to determine the corresponding relationship between the given signal and the given frequency.
93
94 **7: **Simple PLC
95
96 Select simple PLC mode. When the frequency source is simple PLC, you need to set the FD group "multi-speed and PLC" parameters to determine the set frequency.
97
98 **8: **PID
99
100 Select process PID control. At this time, you need to set the F9 group "PID function of process control ". The running frequency of the inverter is the frequency value after PID action. For the meaning of PID given source, given amount, feedback source, etc., please refer to the introduction of "PID Function of process control" in F9 group.
101
102 **9: **Communication setting
103
104 Means that the main frequency source is given by the upper machine through communication.
105
106 (% class="table-bordered" %)
107 |(% rowspan="11" %)**F0.04**|(% colspan="2" %)Setting auxiliary frequency source Y|Default|0
108 |(% rowspan="10" %)Setting Range|0|(% colspan="2" %)Digital setting (non-retentive at power failure)
109 |1|(% colspan="2" %)Digital setting (retentive at power failure)
110 |2|(% colspan="2" %)AI1
111 |3|(% colspan="2" %)AI2
112 |4|(% colspan="2" %)Reserved
113 |5|(% colspan="2" %)Reserved
114 |6|(% colspan="2" %)Multi-stage speed setting
115 |7|(% colspan="2" %)Simple PLC
116 |8|(% colspan="2" %)PID
117 |9|(% colspan="2" %)Communication setting
118
119 When the auxiliary frequency source is used as an independent frequency given channel (that is, the frequency source is selected to switch from X to Y), its usage is the same as that of the main frequency source X.
120
121 When the auxiliary frequency source is used as a superimposed reference (that is, the frequency source is selected as X+Y, X to X+Y switching or Y to X+Y switching), there are the following special features:
122
123 ~1. When the auxiliary frequency source is digital setting or pulse knob setting, the preset frequency (F0.08) does not work. You can use the ▲/▼ keys of the keyboard (or UP, DOWN of the multi-function input terminal) to adjust up and down based on the given frequency.
124
125 2. When the auxiliary frequency source is analog input setting (AI1, AI2) or pulse input setting, 100% of the input setting corresponds to the auxiliary frequency source range (see the description of F0.05 and F0.06). If you need to adjust up and down on the basis of the main set frequency, please set the corresponding setting range of the analog input to .n%~~+n%.
126
127 3. When the frequency source is pulse input setting, it is similar to analog input setting.
128
129 Tip: The selection of auxiliary frequency source Y and the main frequency source X cannot be the same, that is, the main and auxiliary frequency sources cannot use the same frequency given channel.
130
131 (% class="table-bordered" %)
132 |(% rowspan="3" %)**F0.05**|(% colspan="2" %)Range of auxiliary frequency source Y|Default|0
133 |(% rowspan="2" %)Setting Range|0|(% colspan="2" %)Relative to the maximum frequency
134 |1|(% colspan="2" %)Relative to the frequency source X
135 |(% rowspan="2" %)**F0.06**|(% colspan="2" %)Percentage range of auxiliary frequency source Y|Default|0
136 |(% colspan="2" %)Setting Range|(% colspan="2" %)0%~~150%
137
138 When the frequency source is selected as the frequency superposition setting (F0.07 is set to 1, 3 or 4), it is used to determine the adjustment range of the auxiliary frequency source. F0.05 is used to determine the relative object of the range. If it is relative to the maximum frequency (F0.10), its range is a fixed value; if it is relative to the main frequency source X, its range will follow the change of main frequency source X.
139
140 (% class="table-bordered" %)
141 |(% rowspan="13" %)**F0.07**|(% colspan="2" %)Frequency reference selection|Default|0
142 |(% rowspan="12" %)Setting Range|One’s digit|(% colspan="2" %)Selection of frequency source
143 |0|(% colspan="2" %)main frequency source X
144 |1|(% colspan="2" %)main and auxiliary calculation results(The calculation relationship is determined by the ten’s digits)
145 |2|(% colspan="2" %)Switchover between X and Y
146 |3|(% colspan="2" %)Switchover between X and main (X) & auxiliary(Y) calculation
147 |4|(% colspan="2" %)Switchover between Y and main (X) & auxiliary(Y) calculation
148 |Ten’s digit|(% colspan="2" %)X and Y calculation relationship
149 |0|(% colspan="2" %)X+Y
150 |1|(% colspan="2" %)X-Y
151 |2|(% colspan="2" %)MAX(X, Y)
152 |3|(% colspan="2" %)MIN(X, Y)
153 |4|(% colspan="2" %)X* Y
154
155 Use this parameter to select the frequency given channel. The frequency setting is realized by the combination of the main frequency source X and the auxiliary frequency source Y.
156
157 One’s digit:Selection of frequency source
158
159 0:main frequency source X
160
161 The main frequency X is used as the target frequency.
162
163 1: main and auxiliary calculation results
164
165 The main and auxiliary calculation result is used as the target frequency (The calculation relationship is determined by the ten’s digits).
166
167 2: Switchover between X and Y
168
169 When the multi-function input terminal 18: frequency source switching is invalid, the main frequency source X is taken as the target frequency.
170
171 When the multi-function input terminal 18: frequency source switching is valid, the auxiliary frequency source Y is taken as the target frequency.
172
173 3: Switchover between X and main (X) & auxiliary(Y) calculation
174
175 When the multi-function input terminal 18: frequency source switching is invalid, the main frequency source X is taken as the target frequency.
176
177 When the multi-function input terminal 18: frequency source switching is valid, the main and auxiliary calculation result is taken as the target frequency.
178
179 4: Switchover between Y and main (X) & auxiliary(Y) calculation
180
181 When the multi-function input terminal 18: frequency source switching is invalid, the auxiliary frequency source Y is taken as the target frequency.
182
183 When the multi-function input terminal 18: frequency source switching is valid, the main and auxiliary calculation result is taken as the target frequency.
184
185 Ten’s digit:X and Y calculation relationship:
186
187 0: X+Y
188
189 The sum of the main frequency source X and the auxiliary frequency source Y serves as the target frequency. Realize frequency superposition given function.
190
191 1: X-Y
192
193 The difference between the main frequency source X and the auxiliary frequency source Y serves as the target frequency.
194
195 2: MAX(X, Y)
196
197 Take the main frequency source X and auxiliary frequency source Y with the largest absolute value as the target frequency.
198
199 3: MIN(X, Y)
200
201 Take the main frequency source X and the auxiliary frequency source Y with the smallest absolute value as the target frequency.
202
203 4: X * Y
204
205 The result of multiplying the main frequency source X by the auxiliary frequency source Y is used as the target frequency.
206
207 (% class="table-bordered" %)
208 |(% rowspan="2" %)**F0.08**|Keypad setting frequency|Default|50.00Hz
209 |Setting Range|(% colspan="2" %)0.00~~Maximum frequency F0.10 (valid for digital setting for frequency source selection)
210
211 When the frequency source is selected as "digital setting" or "terminal UP/DOWN", the function code value is the initial value of the frequency digital setting of the inverter.
212
213 (% class="table-bordered" %)
214 |(% rowspan="3" %)**F0.09**|(% colspan="2" %)Running direction selection|Default|0
215 |(% rowspan="2" %)Setting Range|0|(% colspan="2" %)Forward direction
216 |1|(% colspan="2" %)Reverse direction
217
218 By changing this parameter, the rotation direction of the motor can be changed without changing any other parameters. Its function is equivalent to realizing the conversion of the rotation direction of the motor by adjusting any two cables of the motor (U, V, W).
219
220 Tip: After the parameters are initialized, the motor running direction will return to the original state. Use it with caution when it is forbidden to change the rotation of the motor after the system is debugged.
221
222 (% class="table-bordered" %)
223 |(% rowspan="2" %)**F0.10**|(% colspan="2" %)Maximum Frequency|Default|50.00 Hz
224 |(% colspan="2" %)Setting Range|(% colspan="2" %)50.00Hz~~500.00Hz
225 |(% rowspan="7" %)**F0.11**|(% colspan="2" %)Source of frequency upper limit|Default|0
226 |(% rowspan="6" %)Setting Range|0|(% colspan="2" %)Set by F0.12
227 |1|(% colspan="2" %)AI1
228 |2|(% colspan="2" %)AI2
229 |3|(% colspan="2" %)Reserved
230 |4|(% colspan="2" %)Reserved
231 |5|(% colspan="2" %)Communication setting
232
233 Define the source of the upper limit frequency. The upper limit frequency can come from the digital setting (F0.12) or the analog input channel. When using the analog input to set the upper limit frequency, 100% of the analog input setting corresponds to F0.12.
234
235 For example, in torque control, speed control is invalid. In order to avoid "overspeeding" due to material disconnection, the upper limit frequency can be set by analog. When the inverter runs to the upper limit frequency value, the torque control is invalid and the inverter continues to run at the upper limit frequency.
236
237 (% class="table-bordered" %)
238 |(% rowspan="2" %)**F0.12**|Frequency upper limit|Default|50.00Hz
239 |Setting Range|(% colspan="2" %)Frequency lower limit (F0.14)~~F0.10
240 |(% rowspan="2" %)**F0.13**|Upper limit frequency offset|Default|0.00Hz
241 |Setting Range|(% colspan="2" %)0.00Hz ~~F0.10
242
243 When the upper limit frequency is given by the analog input, this parameter is used as the offset of the upper limit frequency calculation, and this upper limit frequency offset is added to the set value of the analog upper limit frequency as the final upper limit frequency setting value.
244
245 (% class="table-bordered" %)
246 |(% rowspan="2" %)**F0.14**|Frequency lower limit|Default|0.00Hz
247 |Setting Range|(% colspan="2" %)0.00Hz~~F0.12
248
249 When the inverter starts to run, it starts from the starting frequency. If the given frequency is less than the lower limit frequency during operation, the inverter will run at the lower limit frequency, stop or run at zero speed. You can set which operating mode to use through F0.15.
250
251 (% class="table-bordered" %)
252 |(% rowspan="4" %)**F0.15**|(% colspan="2" %)The function of frequency lower limit|Default|0
253 |(% rowspan="3" %)Setting Range|0|(% colspan="2" %)Running at frequency lower limit
254 |1|(% colspan="2" %)Stop
255 |2|(% colspan="2" %)Standby(Running at 0 Hz)
256
257 Select the running state of the AC drive when the set frequency is lower than the lower limit frequency. In order to prevent the motor from running at low speed for a long time, this function can be used to choose to stop.
258
259 (% class="table-bordered" %)
260 |(% rowspan="2" %)** F0.16**|Carrier Frequency|Default|Model Dependent
261 |Setting Range|(% colspan="2" %)0.5kHz~~16.0kHz
262
263 = Carrier Frequency: =
264
265 This function adjusts the carrier frequency of the AC drive. By adjusting the carrier frequency, the motor noise can be reduced, the resonance point of the mechanical system can be avoided, the leakage current of the line to the ground and the interference caused by the inverter can be reduced.
266
267 When the carrier frequency is low, the higher harmonic components of the output current increase, the motor loss increases, and the motor temperature rise increases.
268
269 When the carrier frequency is high, the motor loss will decrease and the motor temperature rise will decrease, but the AC drive loss will increase, the AC drive temperature rise will increase, and the interference will increase.
270
271 The effect of adjusting the carrier frequency on the following performance:
272
273 (% class="table-bordered" %)
274 |Carrier Frequency|Low  → High
275 |Motor Noise|Much → Little
276 |Output Current Waveform|Bad  → Good
277 |Motor Temperature Rise|High  →  Low
278 |AC Drive Temperature Rise|Low  → High
279 |Leakage Current|Low  → High
280 |External Radiation Interference|Low  → High
281
282 (% class="table-bordered" %)
283 |(% rowspan="2" %) **F0.17**|PWM Output Method Selection|Default|0
284 |Setting Range|(% colspan="2" %)(((
285 0:5/7-stage automatic switching
286
287 1:7-stage
288 )))
289
290 Method selection of PWM Output Method
291
292 (% class="table-bordered" %)
293 |(% rowspan="2" %)**F0.18**|Acceleration Time 1|Default|Model Dependent
294 |Setting Range|(% colspan="2" %)0.0s~~6500.0s
295 |(% rowspan="2" %)**F0.19**|Deceleration Time 1|Default|Model Dependent
296 |Setting Range|(% colspan="2" %)0.0s~~6500.0s
297
298 The acceleration time refers to the time required to accelerate from zero frequency to the acceleration/deceleration base frequency (determined by F0.24), see t1 in Figure 6-1-1.
299
300 The deceleration time refers to the time required to decelerate from the acceleration/deceleration base frequency (determined by F0.24) to zero frequency, see t2 in Figure 6-1-1.
301
302
303 (% style="text-align:center" %)
304 [[image:CHAPTER 7 FUNCTIONAL PARAMETER DETAILS_html_a0c9063bc45a4ec4.png]]
305
306 Figure 6-1-1 Schematic diagram of acceleration and deceleration time
307
308 Pay attention to the difference between actual acceleration and deceleration time and set acceleration and deceleration time.
309
310 There are 4 groups of acceleration and deceleration time options
311
312 Group 1: F0.18. F0.19;
313
314 Group 2: F8.03. F8.04;
315
316 Group 3: F8.05. F8.06;
317
318 Group 4: F8.07. F8.08.
319
320 The acceleration and deceleration time can be selected through the multi-function digital input terminals (F5.00~~F5.05).
321
322 (% class="table-bordered" %)
323 |(% rowspan="4" %)**F0.20**|(% colspan="2" %)Default setting restoring|Default|0
324 |(% rowspan="3" %)Setting Range|0|(% colspan="2" %)No operation
325 |1|(% colspan="2" %)Restore to factory default setting (not including motor parameters )
326 |2|(% colspan="2" %)clear fault record 
327
328 After changing this parameter to 1 or 2, all parameters will be initialized, and then this parameter will be reset to 0 automatically.
329
330 1: Restoring default settings,not including the F2 group parameters and error records.
331
332 2: Cleaning error records.
333
334 Cleaning error records. accumulative running time(F7.09). accumulative power-on time(F7.13). accumulative power consumption(F7.14).
335
336 (% class="table-bordered" %)
337 |(% rowspan="3" %)**F0.21**|(% colspan="2" %)Function code modification attribute|Default|0
338 |(% rowspan="2" %)Setting range|0|(% colspan="2" %)Modifiable
339 |1|(% colspan="2" %)Non-modifiable
340
341 Function code modification attribute,After locking, it can prevent the parameter value from being changed by mistake
342
343 0:All parameters can be changed
344
345 1:All parameters can only be viewed,but not changed,except F0.21
346
347 (% class="table-bordered" %)
348 |(% rowspan="3" %)**F0.22**|(% colspan="2" %)Digital setting frequency shutdown memory selection|Default|1
349 |(% rowspan="2" %)Setting range|0|(% colspan="2" %)Non-retentive
350 |1|(% colspan="2" %)Retentive
351
352 This function is only valid when frequency source is digital setting
353
354 0: Non-retentive, Refers to the digital set frequency value restored to the set value of F0.08 after the AC drive stops.
355
356 1: Retentive, Refers to the digital set frequency value restored to the set frequency after the AC drive stops.
357
358 (% class="table-bordered" %)
359 |(% rowspan="4" %)**F0.23**|(% colspan="2" %)Acceleration & deceleration time unit|Default|1
360 |(% rowspan="3" %)Setting range|0|(% colspan="2" %)1s
361 |1|(% colspan="2" %)0.1s
362 |2|(% colspan="2" %)0.01s
363
364 This function is used to determine all acceleration and deceleration time units. Note that when the value is modified, the actual acceleration/deceleration time will also change accordingly (the position of the decimal point changes, and the actual display digits remain unchanged), so it is necessary to readjust the size of various acceleration/deceleration settings according to the situation. Pay attention to the following function codes: F0.18, F0.19, F8.01, F8.02, F8.03, F8.04, F8.05, F8.06, F8.07, F8.08.
365
366 (% class="table-bordered" %)
367 |(% rowspan="4" %)**F0.24**|(% colspan="2" %)Base Frequency of Acceleration & Deceleration Time|Default|0
368 |(% rowspan="3" %)Setting range|0|(% colspan="2" %)Maximum frequency(F0.10)
369 |1|(% colspan="2" %)Set Frequency
370 |2|(% colspan="2" %)100Hz
371
372 Define the frequency range corresponding to the acceleration and deceleration time. See Figure 6.1 Acceleration and deceleration time diagram
373
374 (% class="table-bordered" %)
375 |(% rowspan="3" %)**F0.25**|(% colspan="2" %)Cooling Fan Running Option|Default|0
376 |(% rowspan="2" %)Setting range|0|(% colspan="2" %)Automatic running
377 |1|(% colspan="2" %)Keep running when power on
378
379 This function is used to set the operating mode of the cooling fan. This setting can be adjusted according to changes in operating conditions to achieve a balance between maintaining continuous maximum heat dissipation and extending fan life.
380
381 0: Automatic running.When the motor is running, the fan runs; when the motor stops, the fan stops running after a delay of 30 seconds. When the temperature of the AC drive module exceeds 50 degrees, the fan also starts to run.
382
383 1: Keep running .The fan will keep running after AC drive is powered on
384
385 (% class="table-bordered" %)
386 |(% rowspan="3" %)**F0.26**|(% colspan="2" %)Frequency Command Decimal Point|Default|2
387 |(% rowspan="2" %)Setting range|1|(% colspan="2" %)One Decimal Place
388 |2|(% colspan="2" %)Two Decimal Place
389
390 The decimal place of the control frequency related instruction, the default is 2 decimal places. After the parameter is set, the decimal place of the parameter associated with the frequency is automatically adjusted. This parameter is not affected by F0.20.
391
392 = 2 F1 group start & stop control =
393
394 (% class="table-bordered" %)
395 |(% rowspan="4" %)**F1.00**|(% colspan="2" %)Starting mode|Default|0
396 |(% rowspan="3" %)Setting range|0|(% colspan="2" %)Start directly(When the starting DC braking time is not 0, the DC braking will be performed first)
397 |1|(% colspan="2" %)Speed tracing and start
398 |2|(% colspan="2" %)Pre-excitation start(When the pre-excitation time is not 0, first pre-excitation and then start)
399
400 0: Start directly
401
402 if F1.06 startup DC braking/pre-excitation time, when it is set to 0, start from the startup frequency. When the setting is not 0, implement DC braking first and then start, which can solve the problem of reverse rotation when starting with small inertia load.
403
404 1: Speed tracing and start
405
406 The AC drive first detects the rotation and speed of the motor, and then starts according to the real-time speed. It is suitable for restarting after instantaneous power failure with large inertial loads or for smooth restarting of rotating equipment. Set accurate F2 group motor parameters to obtain better speed tracking and restart performance.
407
408 2: Pre-excitation start(Asynchronous motor)
409
410 Pre-excitation current and time share function codes with DC braking current and time.
411
412 If F1.06 startup DC braking/pre-excitation time, when it is set to 0, start from the starting frequency. When the setting is not 0, the pre-excitation is performed first and then the start is performed to improve the dynamic response speed.
413
414 (% class="table-bordered" %)
415 |(% rowspan="5" %)**F1.01**|(% colspan="2" %)Speed tracking mode|Default|0
416 |(% rowspan="4" %)Setting Range|0|(% colspan="2" %)Start with the frequency of input power failure
417 |1|(% colspan="2" %)Start at zero speed
418 |2|(% colspan="2" %)Start at the maximum frequency F0.10
419 |3|(% colspan="2" %)Excitation search
420
421 Provide 4 speed tracking methods:
422
423 0: Tracking down from the frequency during a power outage, this method is usually used.
424
425 1: Start tracking upwards from 0 frequency, use in the case of a longer power outage and restart
426
427 2: Track down from the maximum frequency, generally used for generating loads
428
429 3: Output the excitation current to estimate the current frequency of the motor. After the estimation is successful, the inverter will start at the estimated frequency
430
431 (% class="table-bordered" %)
432 |(% rowspan="2" %)**F1.02**|Speed tracking coefficient|Default|20
433 |Setting Range|(% colspan="2" %)1~~100
434
435 In speed tracking restart mode, set the speed of speed tracking. The larger the parameter setting, the faster the tracking speed. But too large may cause unreliable tracking.
436
437 (% class="table-bordered" %)
438 |(% rowspan="2" %)**F1.03**|Starting frequency|Default|0.00Hz
439 |Setting Range|(% colspan="2" %)0.00Hz~~10.00Hz
440 |(% rowspan="2" %)**F1.04**|Hold time of starting frequency|Default|0.0s
441 |Setting Range|(% colspan="2" %)0.0s~~100.0s
442
443 To ensure the torque at startup, please set an appropriate startup frequency. In addition, in order to wait for the magnetic flux to be established when the motor starts, the starting frequency is maintained for a certain period of time and then the acceleration starts. The starting frequency value F1.03 is not limited by the lower limit frequency. If the given frequency (frequency source) is less than the starting frequency, the inverter cannot be started and is in the standby state. When switching between forward and reverse, the start frequency holding time has no effect. The hold time is not included in the acceleration time, but is included in the running time of the simple PLC.
444
445 (% class="table-bordered" %)
446 |(% rowspan="2" %)**F1.05**|DC braking current at start-up/Pre-excitation current|Default|0%
447 |Setting Range|(% colspan="2" %)0%~~100%
448 |(% rowspan="2" %)**F1.06**|DC braking time at start-up/Pre-excitation time|Default|0.0s
449 |Setting Range|(% colspan="2" %)0.0s~~100.0s
450
451 Starting DC braking is generally used to completely stop the motor before starting. Pre-excitation is generally used to establish a magnetic field before starting the motor to improve response speed.
452
453 If the start mode is direct start, the AC drive will first perform DC braking according to the set start DC braking current when starting, and then start running after the set start DC braking time. If the DC braking time is set to 0, it will start directly without DC braking. The greater the DC braking current, the greater the braking force. If the start mode is asynchronous motor pre-excitation start, the AC drive will first establish the magnetic field according to the set start pre-excitation current when starting, and then start running after the set start pre-excitation time. If the pre-excitation time is set to 0, it will start directly without pre-excitation. Start DC braking/pre-excitation current refers to the percentage relative to the AC drive rated current.
454
455 (% class="table-bordered" %)
456 |(% rowspan="4" %)**F1.07**|(% colspan="2" %)Acceleration & deceleration method|Default|0
457 |(% rowspan="3" %)Setting Range|0|(% colspan="2" %)Linear acceleration/deceleration
458 |1|(% colspan="2" %)S-curve acceleration/deceleration A
459 |2|(% colspan="2" %)S-curve acceleration/deceleration B
460
461 Select the frequency change mode of the AC drive during the start and stop process.
462
463 0:Linear acceleration/deceleration
464
465 The output frequency increases or decreases linearly. The acceleration/deceleration time changes according to the set acceleration/deceleration time. VB series AC drive provides 4 kinds of acceleration and deceleration time. The acceleration and deceleration time can be selected through the multi-function digital input terminals (F5.00~~F5.05).
466
467 1: S-curve acceleration/deceleration A
468
469 The output frequency increases or decreases according to the S curve. S curve is generally used in places where the start and stop process is relatively gentle, such as elevators and conveyor belts. Function codes F1.08 and F1.09 respectively define the time proportions of the start and end segments of S curve acceleration and deceleration
470
471 2: S-curve acceleration/deceleration B
472
473 In this acceleration and deceleration curve, the rated motor frequency fb is always the inflection point of the S curve. As shown in Figure 6-3. Generally used in the high-speed area above the rated frequency, where short-term acceleration and deceleration are required.
474
475 When the set frequency is above the rated frequency, the acceleration and deceleration time is:
476
477 [[image:CHAPTER 7 FUNCTIONAL PARAMETER DETAILS_html_840ad38ebbb1d9bd.gif]]
478
479 Among them, f is the set frequency; fb is the rated frequency of the motor;
480
481 T is the time to accelerate from 0 frequency to rated frequency fb.
482
483 (% class="table-bordered" %)
484 |(% rowspan="2" %)**F1.08**|Time proportion of S-curve start segment|Default|30.0%
485 |Setting Range|(% colspan="2" %)0.0%~~70.0%
486 |(% rowspan="2" %)**F1.09**|Time proportion of S-curve end segment|Default|30.0%
487 |Setting Range|(% colspan="2" %)0.0%~~70.0%
488
489 The function codes F1.08 and F1.09 respectively define the time proportions of the start section and the end section of S-curve acceleration/deceleration A, and both meet: F1.08 + F1.09 ≤ 100.0%.
490
491 In Figure 6.2-1, t1 is the parameter defined by parameter F1.08. During this period of time, the slope of the output frequency change gradually increases. t2 is the time defined by parameter F1.09, during which the slope of the output frequency change gradually changes to 0. During the time between t1 and t2, the slope of the output frequency change is fixed.
492
493 (% style="text-align:center" %)
494 [[image:图片1.png]]
495
496 Figure 6-2-1 S Schematic diagram of curve acceleration and deceleration A
497
498 (% style="text-align:center" %)
499 [[image:图片2.png]]
500
501 Figure 6-2-2 S Schematic diagram of curve acceleration and deceleration B
502
503 (% class="table-bordered" %)
504 |(% rowspan="3" %)**F1.10**|Stop mode|Default|0
505 |(% rowspan="2" %)Setting Range|0|Decelerate to stop 
506 |1|Free stopping
507
508 0: Decelerate to stop 
509
510 After the stop command is valid, the AC drive will reduce the output frequency according to the deceleration mode and the defined acceleration/deceleration time, and stop after the frequency drops to 0.
511
512 1: Free stopping
513
514 After the stop command is valid, the AC drive immediately terminates the output. The load stops freely according to mechanical inertia.
515
516 (% class="table-bordered" %)
517 |(% rowspan="2" %)**F1.11**|Trigging frequency of DC braking at stop|Default|0.00Hz
518 |Setting Range|(% colspan="2" %)0.00Hz~~max.frequency 
519 |(% rowspan="2" %)**F1.12**|Waiting time of DC braking at stop|Default|0.0s
520 |Setting Range|(% colspan="2" %)0.0s~~36.0s
521 |(% rowspan="2" %)**F1.13**|The current of DC braking at stop|Default|0%
522 |Setting Range|(% colspan="2" %)0%~~100%
523 |(% rowspan="2" %)**F1.14**|The time of DC braking at stop|Default|0.0s
524 |Setting Range|(% colspan="2" %)0.0s~~36.0s
525
526 Trigging frequency of DC braking at stop: During deceleration to stop, when the output frequency is less than this frequency, the DC braking process at stop will start.
527
528 Waiting time of DC braking at stop: When the output frequency is reduced to the start frequency of F1.11 stop DC braking during stop, the AC drive will stop output and start timing. After the delay time set by F1.12, DC will start again brake. It is used to prevent over-current faults caused by DC braking when the speed is high.
529
530 The current of DC braking at stop: refers to the added DC braking amount. The larger the value, the stronger the DC braking effect.
531
532 The time of DC braking at stop: the time added by the DC braking amount. When this value is 0, it means that there is no DC braking process and the AC drive will stop according to the set deceleration stop process.
533
534 (% style="text-align:center" %)
535 [[image:CHAPTER 7 FUNCTIONAL PARAMETER DETAILS_html_fcb1f31274fca2cb.png]]
536
537 Figure 6-2-3 Schematic diagram of DC braking at stop
538
539 (% class="table-bordered" %)
540 |(% rowspan="2" %)**F1.15**|Brake use rate|Default|100%
541 |Setting Range|(% colspan="2" %)0%~~100%
542
543 It is valid for inverters with built-in braking unit. The braking effect of the dynamic braking function can be adjusted.
544
545 (% class="table-bordered" %)
546 |(% rowspan="3" %)**F1.16**|Zero frequency output selection|Default|1
547 |(% rowspan="2" %)Setting Range|0|Open
548 |1|Closed
549
550 Setting whether the AC drive has output when running frequency is 0
551
552 = 3 F2 group motor parameters =
553
554 (% class="table-bordered" %)
555 |(% rowspan="5" %)**F2.00**|(% colspan="2" %)Motor type selection|Default|0
556 |(% rowspan="4" %)Setting Range|0|(% colspan="2" %)Ordinary asynchronous motor
557 |1|(% colspan="2" %)Variable frequency asynchronous motor
558 |2|(% colspan="2" %)Permanent magnet synchronous motor
559 |3|(% colspan="2" %)Single-phase asynchronous motor
560 |(% rowspan="2" %)**F2.01**|(% colspan="2" %)Motor rated power|Default|Model Dependent
561 |(% colspan="2" %)Setting Range|(% colspan="2" %)0.1kW~~400.0kW
562 |(% rowspan="2" %)**F2.02**|(% colspan="2" %)Motor rated Voltage|Default|Model Dependent
563 |(% colspan="2" %)Setting Range|(% colspan="2" %)0V~~440V
564 |(% rowspan="2" %)**F2.03**|(% colspan="2" %)Motor rated current|Default|Model Dependent
565 |(% colspan="2" %)Setting Range|(% colspan="2" %)(((
566 0.01A~~655.35A(AC drive<=55kW)
567
568 0.1A~~6553.5A(AC drive >55kW)
569 )))
570 |(% rowspan="2" %)**F2.04**|(% colspan="2" %)Motor rated frequency|Default|Model Dependent
571 |(% colspan="2" %)Setting Range|(% colspan="2" %)0.00Hz~~Maximum frequency F0.10
572 |(% rowspan="2" %)**F2.05**|(% colspan="2" %)Motor rated speed|Default|Model Dependent
573 |(% colspan="2" %)Setting Range|(% colspan="2" %)0rpm~~36000rpm
574
575 |** Caution**
576 |(((
577 ~1. Please set according to the nameplate parameters of the motor.
578
579 2. The excellent control performance of vector control requires accurate motor parameters, and accurate parameter identification comes from the correct setting of motor rated parameters.
580
581 3. In order to ensure the control performance, please configure the motor according to the standard adapted motor of the AC drive. If the power of the motor is too far from the standard adapted motor, the control performance of the inverter will be significantly reduced.
582 )))
583
584 (% class="table-bordered" %)
585 |(% rowspan="2" %)**F2.06**|Asynchronous motor stator resistance|Default|Model Dependent
586 |Setting Range|(% colspan="2" %)(((
587 0.001Ω~~65.535Ω(AC drive<=55kW)
588
589 0.0001Ω~~6.5535Ω(AC drive >55kW)
590 )))
591 |(% rowspan="2" %)**F2.07**|Asynchronous motor rotator resistance|Default|Model Dependent
592 |Setting Range|(% colspan="2" %)(((
593 0.001Ω~~65.535Ω(AC drive<=55kW)
594
595 0.0001Ω~~6.5535Ω(AC drive >55kW)
596 )))
597 |(% rowspan="2" %)**F2.08**|Asynchronous motor leakage inductance|Default|Model Dependent
598 |Setting Range|(% colspan="2" %)(((
599 0.01mH~~655.35mH(AC drive<=55kW)
600
601 0.001mH~~65.535mH(AC drive >55kW)
602 )))
603 |(% rowspan="2" %)**F2.09**|Asynchronous motor mutual inductance|Default|Model Dependent
604 |Setting Range|(% colspan="2" %)(((
605 0.1mH~~6553.5mH(AC drive<=55kW)
606
607 0.01mH~~655.35mH(AC drive >55kW)
608 )))
609 |(% rowspan="2" %)**F2.10**|Asynchronous motor no-load current|Default|Model Dependent
610 |Setting Range|(% colspan="2" %)(((
611 0.01A~~F2.03(AC drive<=55kW)
612
613 0.1A~~F2.03(AC drive >55kW)
614 )))
615
616 After the automatic tuning ends normally, the setting values of the asynchronous motor parameters (F2.06~~F2.10) are automatically updated.
617
618 After changing the motor rated power F2.01 each time, the AC drive will automatically restore the default standard motor parameters from F2.06 to F2.10. (Four-pole Y series asynchronous motor)
619
620 If it is impossible to tune the asynchronous motor in the site, you can manually input it with reference to the known parameters of similar motors.
621
622 (% class="table-bordered" %)
623 |(% rowspan="4" %)**F2.11**|(% colspan="2" %)Tuning selection|Default|0
624 |(% rowspan="3" %)Setting Range|0|(% colspan="2" %)0:No operation
625 |1|(% colspan="2" %)1:The asynchronous machine static tuning.
626 |2|(% colspan="2" %)2:The asynchronous machine is fully tuned
627
628 **✎Note**: Before tuning, you must set the correct motor type and rated parameters (F2.00-F2.05)
629
630 0: No operation, that is, tuning is prohibited.
631
632 1: The asynchronous motor is statically tuned, which is suitable for occasions where the motor and the load are not easily disconnected and cannot be rotated and tuned.
633
634 Action description: After setting the function code to 1, and pressing the RUN key to confirm, the AC drive will perform static tuning.
635
636 2: Complete tuning of asynchronous motor. In order to ensure the dynamic control performance of the AC drive, please select complete tuning, the motor must be disconnected from the load (no load) during rotary tuning.
637
638 After the complete tuning is selected, the AC drive will perform static tuning first. After the static tuning, the motor will accelerate to 80% of the rated frequency of the motor according to the acceleration time set by F0.18, and hold for a period of time, and then follow the deceleration time set by F0.19 Decelerate to zero speed and end the rotation tuning.
639
640 Action description: After setting the function code to 2, and pressing the RUN key to confirm, the AC drive will perform rotary tuning.
641
642 **Tuning instructions:**
643
644 When F2.11 is set to 1 or 2 and then press the ENT key, "TUNE" is displayed and flashes at this time, and then press the RUN key to start parameter tuning, and the displayed "TUNE" stops flashing at this time. When the tuning is over, the display returns to the stop state interface. During the tuning process, you can press the STOP button to stop tuning. When the tuning is completed, the value of F2.11 automatically returns to 0.
645
646 **✎Note: Tuning can only be effective in keyboard control mode, and the factory default value of acceleration and deceleration time is recommended.**
647
648 (% class="table-bordered" %)
649 |(% rowspan="3" %)**F2.12**|(% colspan="2" %)G/P type selection|Default|Model dependent
650 |(% rowspan="2" %)Setting Range|1|(% colspan="2" %)General model (G) (constant torque load model)
651 |2|(% colspan="2" %)Pump model (P) (draught fan, water pump type load model)
652
653 This parameter is only for users to view the factory model and cannot be changed.
654
655 1: Suitable for constant torque load with specified rated parameters
656
657 2: Suitable for variable torque loads with specified rated parameters (fans, water pump loads)
658
659 (% class="table-bordered" %)
660 |(% rowspan="2" %)**F2.13**|Single-phase motor turns ratio|Default|140
661 |Setting Range|(% colspan="2" %)50~~200
662
663 The main and auxiliary winding currents can be changed by adjusting the single-phase motor turns ratio. Generally, reducing the single-phase motor turns ratio can increase the main winding current, reduce the auxiliary winding current, and reduce the motor heating (only effective when F2.00 = 3) .
664
665 = 4 F3 group vector control parameters =
666
667 F3 group function codes are only valid in vector control mode, that is, it is valid when F0.00=0, and it is invalid when F0.00=1.
668
669 (% class="table-bordered" %)
670 |(% rowspan="2" %)**F3.00**|Speed loop proportional gain 1|Default|30
671 |Setting range|(% colspan="2" %)1~~100
672 |(% rowspan="2" %)**F3.01**|Speed loop integral time 1|Default|0.50s
673 |Setting range|(% colspan="2" %)0.01s~~10.00s
674 |(% rowspan="2" %)**F3.02**|Switchover frequency 1|Default|5.00Hz
675 |Setting range|(% colspan="2" %)0.00~~F3.05
676 |(% rowspan="2" %)**F3.03**|Speed loop proportional gain 2|Default|20
677 |Setting range|(% colspan="2" %)0~~100
678 |(% rowspan="2" %)**F3.04**|Speed loop integral time 2|Default|1.00s
679 |Setting range|(% colspan="2" %)0.01s~~10.00s  
680 |(% rowspan="2" %)**F3.05**|Switchover frequency 2|Default|10.00Hz
681 |Setting range|(% colspan="2" %)F3.02~~Maximum frequency F0.10
682
683 F3.00 and F3.01 are PI adjustment parameters when the running frequency is lower than switchover frequency 1 (F3.02).
684
685 F3.03 and F4.04 are PI adjustment parameters for the frequency band between the operating frequency greater than the switchover frequency 2.
686
687 The PI parameters in the frequency band between switchover frequency 1 and switchover frequency 2 are linear switching of two sets of PI parameters, as shown in the following figure:
688
689 (% style="text-align:center" %)
690 [[image:CHAPTER 7 FUNCTIONAL PARAMETER DETAILS_html_3a0fe23ce96d4424.png]]
691
692 Figure 6-4-1 Schematic diagram of PI parameters
693
694 By setting the proportional coefficient and integral time of the speed regulator, the speed dynamic response characteristics of the vector control can be adjusted. Increasing the proportional gain and reducing the integral time can speed up the dynamic response of the speed loop. If the proportional gain is too large or the integral time is too small, the system may oscillate.
695
696 Suggested adjustment method:
697
698 If the factory parameters cannot meet the requirements, fine-tune the parameters based on the factory value: first increase the proportional gain to ensure that the system does not oscillate; then reduce the integration time to make the system have faster response characteristics and smaller overshoot.
699
700 Note: Improper setting of PI parameters may result in excessive speed overshoot. Even when the overshoot falls back, an overvoltage fault occurs.
701
702 (% class="table-bordered" %)
703 |(% rowspan="2" %)**F3.06**|Slip compensation coefficient of vector control|Default|100%
704 |Setting range|(% colspan="2" %)50%~~200%
705
706 In the speed sensorless vector control mode, this parameter is used to adjust the speed stability accuracy of the motor. When the speed of the motor is heavy, increase this parameter, otherwise decrease this parameter.
707
708 (% class="table-bordered" %)
709 |(% rowspan="2" %)**F3.07**|Speed loop filter time constant.|Default|0.000s
710 |Setting range|(% colspan="2" %)0.000s~~0.100s  
711
712 In vector control mode, the output of the speed loop regulator is the torque current command, and this parameter is used to filter the torque command. Generally, this parameter does not need to be adjusted. When the speed fluctuates greatly, the filter time can be appropriately increased; if the motor oscillates, the parameter should be appropriately reduced.
713
714 The speed loop filter time constant is small, the output torque of the AC drive may vary greatly, but the response is fast.
715
716 (% class="table-bordered" %)
717 |(% rowspan="2" %)**F3.08**|Speed control torque upper limit|Default|150.0%
718 |Setting range|(% colspan="2" %)0.0%~~200.0% 
719
720 In speed control mode, the maximum output torque of the inverter is controlled by F3.08.
721
722 (% class="table-bordered" %)
723 |(% rowspan="3" %)**F3.09**|(% colspan="2" %)Speed/torque control|Default|0
724 |(% rowspan="2" %)Setting range|0|(% colspan="2" %)Speed Control
725 |1|(% colspan="2" %)Torque Control
726
727 To select whether the AC drive control mode is speed control or torque control, this function code needs to be judged together with terminal function 29: torque control prohibition and 46: speed control/torque control switching.
728
729 When the torque control prohibition is valid, the AC drive is speed control.
730
731 When the torque control prohibition is invalid, if the speed control/torque control switch is invalid, the control mode is determined by F3.09; if the speed control/torque control switch is valid, the value of F3.09 is reversed.
732
733 When it is torque control, the AC drive running frequency is given by F3.12, F3.13, and the acceleration/deceleration time is given by F3.14, F3.15.
734
735 (% class="table-bordered" %)
736 |(% rowspan="10" %)**F3.10**|(% colspan="2" %)Torque upper limit source in torque control|Default|0
737 |(% rowspan="9" %)Setting range|0|(% colspan="2" %)Digital setting(F3.11)
738 |1|(% colspan="2" %)AI1
739 |2|(% colspan="2" %)AI2
740 |3|(% colspan="2" %)Reserved
741 |4|(% colspan="2" %)Reserved
742 |5|(% colspan="2" %)Communication setting
743 |6|(% colspan="2" %)MIN(AI1,AI2)
744 |7|(% colspan="2" %)MAX(AI1,AI2)
745 |(% colspan="3" %)The full scale of options 1~~7 corresponds to F3.11
746 |(% rowspan="2" %)**F3.11**|(% colspan="2" %)Digital setting of torque upper limit in torque control|Default|150.0%
747 |(% colspan="2" %)Setting range|(% colspan="2" %)-200.0%~~200.0%
748
749 F3.10 is used to select the torque upper limit setting source in the torque control mode. When setting by analog, 100% of analog input setting corresponds to F3.11, and 100% of setting corresponds to AC drive matching motor rated torque.
750
751 (% class="table-bordered" %)
752 |(% rowspan="2" %)**F3.12**|Forward maximum frequency of torque control|Default|50.00Hz
753 |Setting range|(% colspan="2" %)0.00Hz~~Maximum Frequency(F0.10)
754 |(% rowspan="2" %)**F3.13**|Reverse maximum frequency of torque control|Default|50.00Hz
755 |Setting range|(% colspan="2" %)0.00Hz~~Maximum Frequency(F0.10) 
756
757 Set the maximum forward or reverse running frequency of the AC drive in torque control mode.
758
759 (% class="table-bordered" %)
760 |(% rowspan="2" %)**F3.14**|Acceleration time of torque control|Default|0.00s
761 |Setting range|(% colspan="2" %)0.00s~~65000s
762 |(% rowspan="2" %)**F3.15**|Deceleration time of torque control|Default|0.00s
763 |Setting range|(% colspan="2" %)0.00s~~65000s 
764
765 Set the frequency acceleration/deceleration time of the AC drive in torque control mode.
766
767 (% class="table-bordered" %)
768 |(% rowspan="2" %)**F3.16**|Torque stiffness coefficient|Default|100.00%
769 |Setting range|(% colspan="2" %)10.0%~~120.0% 
770
771 In the torque control mode, when the set torque is small, this coefficient can be appropriately reduced to obtain a stable control effect, otherwise, the coefficient can be appropriately increased to obtain a stable control effect.
772
773 (% class="table-bordered" %)
774 |(% rowspan="2" %)**F3.17**|M axis current loop proportional gain|Default|2000
775 |Setting range|(% colspan="2" %)0~~60000 
776 |(% rowspan="2" %)**F3.18**|M axis current loop integral gain|Default|1300
777 |Setting range|(% colspan="2" %)0~~60000 
778 |(% rowspan="2" %)**F3.19**|T axis current loop proportional gain|Default|2000
779 |Setting range|(% colspan="2" %)0~~60000  
780 |(% rowspan="2" %)**F3.20**|T axis current loop integral gain|Default|1300
781 |Setting range|(% colspan="2" %)0~~60000  
782
783 The current loop control parameters in the MT coordinate system and the synchronous motor dq coordinate system will be automatically identified after complete parameter identification, and generally do not need to be modified.
784
785 The bandwidth of the current loop directly determines the response speed of the electromagnetic torque. If the adjustment parameters are too strong, the current loop will be out of adjustment, causing the entire control loop to oscillate; when the current oscillates and torque fluctuations are large, you can manually adjust this group of parameters to improve the effect .
786
787 (% class="table-bordered" %)
788 |(% rowspan="3" %)**F3.21**|(% colspan="2" %)The speed loop integral separation|Default|0
789 |(% rowspan="2" %)Setting range|0|(% colspan="2" %)Invalid
790 |1|(% colspan="2" %)Valid
791
792 (% class="table-bordered" %)
793 |(% rowspan="2" %)**F3.24**|Torque control static friction compensation coefficient|Default|100
794 |Setting range|(% colspan="2" %)100~~300
795
796 (% class="table-bordered" %)
797 |(% rowspan="2" %)**F3.25**|Torque mode friction compensation time|Default|0
798 |Setting range|(% colspan="2" %)0~~100s
799
800 During startup, torque command 1 = F3.11 * F3.24 / 100; after maintaining time F3.25 seconds, it will be restored to torque command 2 = F3.11; torque command 1/2 switching requires torque acceleration and deceleration time F3.14/F3.15.
801
802 = 5 F4 group v/f control parameters =
803
804 This group of function codes is only valid for V/F control (F0.00=1), and invalid for vector control.
805
806 V/F control is suitable for general loads such as fans and water pumps, or applications where one AC drive has multiple motors, or the power of the AC drive is one level lower or two levels higher than the motor power.
807
808 (% class="table-bordered" %)
809 |(% rowspan="7" %)**F4.00**|(% colspan="2" %)V/F curve setting|Default|0
810 |(% rowspan="6" %)Setting Range|0|(% colspan="2" %)Linear V/F
811 |1|(% colspan="2" %)Multi-point V/F
812 |2|(% colspan="2" %)Square V/F
813 |3~~9|(% colspan="2" %)Reserved
814 |10|(% colspan="2" %)V/F complete separation
815 |11|(% colspan="2" %)V/F half separation
816
817 For fans and pumps, you can choose square V/F control.
818
819 Common VF control method
820
821 0: Straight line V/F curve. Suitable for ordinary constant torque load.
822
823 1: Multi-point V/F curve. Suitable for special loads such as dehydrators and centrifuges.
824
825 2: Square V/F curve. Suitable for centrifugal loads such as fans and pumps.
826
827 VF separation control method
828
829 10: VF complete separation mode. At this time, the output voltage is set separately according to the setting mode of F4.13 (VF separation voltage source).
830
831 11: VF semi-separated mode.
832
833 In this case, V and F are proportional, and the voltage source is only used to adjust the slope of V/F. At this time, the relationship between V and F is related to the rated voltage and rated frequency of the motor set in group F2. If the voltage source input is X (X is a value of 0~~100%), then: V/F=2 * X * (motor rated voltage)/(motor rated frequency)
834
835 (% class="table-bordered" %)
836 |(% rowspan="2" %)**F4.01**|Torque boost|Default|Model dependent
837 |Setting Range|(% colspan="2" %)0.0%~~30%  
838 |(% rowspan="2" %)**F4.02**|Cut-off frequency of torque boost|Default|50.00Hz
839 |Setting Range|(% colspan="2" %)0.00Hz~~Maximum frequencyF0.10
840
841 In order to compensate the low-frequency torque characteristics of V/F control, some boost compensation is made for the AC drive output voltage at low frequency.
842
843 If the torque boost is set too large, the motor will easily overheat and the AC drive will easily overcurrent. Generally, the torque boost should not exceed 8.0%. Effective adjustment of this parameter can effectively avoid overcurrent during starting. For larger loads, it is recommended to increase this parameter, and reduce this parameter setting when the load is lighter. When the torque boost is set to 0.0, the AC drive is automatic torque boost. Torque boost torque cut-off frequency: below this frequency, the torque boost torque is valid, if the set frequency is exceeded, the torque boost is invalid, as shown in Figure 6.6.
844
845 (((
846 Output frequency
847
848 (% style="text-align:center" %)
849 [[image:CHAPTER 7 FUNCTIONAL PARAMETER DETAILS_html_9a72975cd3987dca.png]]
850 )))
851
852 Figure 6-5-1 Schematic diagram of manual torque boost
853
854 (% class="table-bordered" %)
855 |(% rowspan="2" %)**F4.03**|Multipoint V/F frequency 1|Default|3.00Hz
856 |Setting Range|(% colspan="2" %)0.00Hz~~F4.05 
857 |(% rowspan="2" %)**F4.04**|Multipoint V/F voltage 1|Default|10.0%
858 |Setting Range|(% colspan="2" %)0.0%~~100.0%
859 |(% rowspan="2" %)**F4.05**|Multipoint V/F frequency 2|Default|5.00Hz
860 |Setting Range|(% colspan="2" %)F4.03~~F4.07 
861 |(% rowspan="2" %)**F4.06**|Multipoint V/F voltage 2|Default|15.0%
862 |Setting Range|(% colspan="2" %)0.0%~~100.0%
863 |(% rowspan="2" %)**F4.07**|Multipoint V/F frequency 3|Default|8.00Hz
864 |Setting Range|(% colspan="2" %)F4.05~~Motor rated frequency(F2.04)
865 |(% rowspan="2" %)**F4.08**|Multipoint V/F voltage 3|Default|22.0%
866 |Setting Range|(% colspan="2" %)0.0%~~100.0%
867
868 Six parameters F4.03~~F4.08 define multi-segment V/F curve. The set value of the V/F curve is usually set according to the load characteristics of the motor. Note: V1<V2<V3, F1<F2<F3. Setting the voltage too high at low frequency may cause the motor to overheat or even burn, and the AC drive may over-current stall or over-current
869
870 protection.
871
872 (% style="text-align:center" %)
873 [[image:CHAPTER 7 FUNCTIONAL PARAMETER DETAILS_html_f550fcd15ecbb3b8.png]]
874
875 Figure 6-5-2 Schematic diagram of V/F curve setting
876
877 (% class="table-bordered" %)
878 |(% rowspan="2" %)**F4.09**|V/F slip compensation|Default|0.0%
879 |Setting Range|(% colspan="2" %)0%~~200.0%
880
881 Effective for V/F control. Setting this parameter can compensate for the slip caused by the load during V/F control, and reduce the change in motor speed with load changes during V/F control. Generally 100% corresponds to the rated slip when the motor is loaded with rated load. The slip coefficient can be adjusted according to the following principles: when the load is rated load and the slip compensation coefficient is set to 100%, the speed of the motor with the inverter is basically close to the given speed.
882
883 (% class="table-bordered" %)
884 |(% rowspan="2" %)**F4.10**|V/F over-excitation gain|Default|0
885 |Setting Range|(% colspan="2" %)0~~200
886
887 The function of the VF overexcitation gain function is to suppress the rise of the bus voltage during the deceleration of the AC drive, and to prevent the bus voltage from exceeding the overvoltage protection limit value and causing an overvoltage fault. The greater the overexcitation gain, the stronger the suppression effect. The setting instructions are as follows:
888
889 ~1. Generally, the overexcitation gain should be set to 0 when the inertia is small, and the overexcitation gain should be appropriately increased when the inertia is large.
890
891 2. If there is a braking resistor, please set the overexcitation gain to 0
892
893 (% class="table-bordered" %)
894 |(% rowspan="2" %)**F4.11**|V/F oscillation suppression gain|Default|Model dependent
895 |Setting Range|(% colspan="2" %)0~~100
896
897 Please select this gain as 0 when the motor has no oscillation. Only when the motor obviously oscillates and cannot run normally, increase the gain appropriately. The larger the gain, the more obvious the suppression of oscillation. When using the oscillation suppression function, it is required that the motor rated current and no-load current parameter settings have little deviation from the actual values. The method of selecting the gain is to choose as small as possible under the premise of effectively suppressing the oscillation, so as not to have too much influence on the VF operation.
898
899 (% class="table-bordered" %)
900 |(% rowspan="11" %)**F4.12**|(% colspan="2" %)Voltage source for V/F separation|Default|0
901 |(% rowspan="10" %)Setting Range|0|(% colspan="2" %)Digital setting(F4.14) 
902 |1|(% colspan="2" %)AI1
903 |2|(% colspan="2" %)AI2
904 |3|(% colspan="2" %)Reserved
905 |4|(% colspan="2" %)Reserved
906 |5|(% colspan="2" %)Multi-speed instructions
907 |6|(% colspan="2" %)Simple PLC
908 |7|(% colspan="2" %)PID
909 |8|(% colspan="2" %)Communication setting
910 |(% colspan="3" %)(100% corresponds to the rated motor voltage)
911
912 Define the voltage source for VF separation. The output voltage can come from digital setting (F4.13), or from analog input channel, multi-speed command, PLC, PID or communication setting. When using non-digital setting of output voltage, 100% of the input setting corresponds to the rated voltage of the motor, and the absolute value of the input setting is taken as the effective setting value.
913
914 0: Digital setting (F4.13); The voltage is directly set through F4.13.
915
916 1: AI1 2: AI2 voltage is determined by analog input terminal, AI input 0~~100% corresponds to output voltage 0V~~rated voltage of motor.
917
918 4: Reserved
919
920 5: Multi-speed instructions
921
922 When the voltage source is multi-speed, you need to set the F4 group "input terminal" and FC group "multi-speed and PLC" parameters to determine the corresponding relationship between the given signal and the given voltage (100% corresponds to the rated motor voltage).
923
924 6: Simple PLC
925
926 When the voltage source is a simple PLC, you need to set the FC group "multi-speed and PLC" parameters to determine the given output voltage (100% corresponds to the rated voltage of the motor).
927
928 7: PID
929
930 Generate output voltage according to PID closed loop. For details, please refer to the introduction of FA group PID.
931
932 8: Communication setting
933
934 Refers to the voltage given by the host computer through communication (100% corresponds to the rated voltage of the motor).
935
936 (% class="table-bordered" %)
937 |(% rowspan="2" %)**F4.13**|Voltage digital setting for V/F separation|Default|0V
938 |Setting Range|(% colspan="2" %)0V~~F2.02
939
940 When the voltage source is digital setting, this value is directly used as the target value of the output voltage.
941
942 (% class="table-bordered" %)
943 |(% rowspan="2" %)**F4.14**|Voltage rise time of separation|Default|0.0s
944 |Setting Range|(% colspan="2" %)0.0s~~1000.0s
945
946 VF separation rise time refers to the time required for the output voltage to change from 0V to the rated voltage of the motor.
947
948 As Figure 6-5-3:
949
950 (((
951 (% style="text-align:center" %)
952 [[image:CHAPTER 7 FUNCTIONAL PARAMETER DETAILS_html_d312ba31a6b637aa.png]]
953 )))
954
955 Figure 6-5-3 Schematic diagram of V/F separation
956
957 (% class="table-bordered" %)
958 |(% rowspan="2" %)**F4.16**|Auto voltage regulation (AVR)|Default|1
959 |Setting Range|(% colspan="2" %)(((
960 0:Invalid
961
962 1:Only valid during deceleration
963
964 2:Only valid during acceleration
965
966 3:Valid
967 )))
968
969 According to the actual use, select the situation where the AVR function is enabled.
970
971 = 6 F5 group input terminals =
972
973 The standard unit of the VB series inverter has 6 multi-function digital input terminals and 2 analog input terminals.
974
975 (% class="table-bordered" %)
976 |**F5.00**|DI1 terminal function selection|Default|1(Forward Running)
977 |**F5.01**|DI2 terminal function selection|Default|2(Reverse Running)
978 |**F5.02**|DI3 terminal function selection|Default|9(Reset Faults)
979 |**F5.03**|DI4 terminal function selection|Default|12(Multi-speed instruction terminal 1)
980 |**F5.04**|DI5 terminal function selection|Default|13(Multi-speed instruction terminal 2)
981 |**F5.05**|DI6 terminal function selection|Default|0
982 |**F5.06~~F5.09**|(% colspan="3" %)Reserved
983 |**F5.10**|VDI terminal function selection|Default|0
984
985 These parameters are used to set the corresponding function of the digital multi-function input terminals
986
987 (% class="table-bordered" %)
988 |(% style="width:121px" %)**Set Value**|(% style="width:540px" %)**Function**|(% style="width:829px" %)**Description**
989 |(% style="width:121px" %)0|(% style="width:540px" %)No function|(% style="width:829px" %)The AC drive will not operate even if a signal is input. The unused terminals can be set to have no function to prevent malfunction.
990 |(% style="width:121px" %)1|(% style="width:540px" %)Forward Running(FWD)|(% rowspan="2" style="width:829px" %)Control the forward and reverse rotation of the inverter through external terminals.
991 |(% style="width:121px" %)2|(% style="width:540px" %)Reverse Running(REV)
992 |(% style="width:121px" %)3|(% style="width:540px" %)Three-wire operation control|(% style="width:829px" %)Use this terminal to determine that the inverter operating mode is three-wire control mode. For details, please refer to F5.16 three-wire control mode function code introduction.
993 |(% style="width:121px" %)4|(% style="width:540px" %)Forward point movement (FJOG)|(% rowspan="2" style="width:829px" %)FJOG is jog forward running, RJOG is jog reverse running. Refer to the detailed description of F8.00, F8.01, F8.02 function codes for frequency and jog acceleration/deceleration time during jog operation.
994 |(% style="width:121px" %)5|(% style="width:540px" %)Reverse point movement(RJOG)
995 |(% style="width:121px" %)6|(% style="width:540px" %)Terminal UP|(% rowspan="2" style="width:829px" %)When the frequency is given by the external terminal, modify the frequency increase command and decrease command. When the frequency source is set to digital setting, the set frequency can be adjusted up and down.
996 |(% style="width:121px" %)7|(% style="width:540px" %)Terminal DOWN
997 |(% style="width:121px" %)8|(% style="width:540px" %)Free stopping|(% style="width:829px" %)(((
998 The inverter blocks the output, and the motor stopping process is not controlled by the inverter. For large inertia loads and when there is no requirement for stopping time, the method is often adopted.
999
1000 This method has the same meaning as the free stop described in F1.10.
1001 )))
1002 |(% style="width:121px" %)9|(% style="width:540px" %)Reset Faults|(% style="width:829px" %)External fault reset function. It has the same function as the RESET key on the keyboard. Use this function to realize remote fault reset.
1003 |(% style="width:121px" %)10|(% style="width:540px" %)Run pause|(% style="width:829px" %)The inverter decelerates to stop, but all operating parameters are in the memory state. Such as PLC parameters, swing frequency parameters, PID parameters. After this signal disappears, the inverter will resume running to the state before stopping.
1004 |(% style="width:121px" %)11|(% style="width:540px" %)External faults normally open input|(% style="width:829px" %)After the external fault signal is sent to the inverter, the inverter reports a fault and handles it according to the fault protection action mode (FA.13~~FA.16).
1005 |(% style="width:121px" %)12|(% style="width:540px" %)Multi-speed instruction terminal 1|(% rowspan="4" style="width:829px" %)(((
1006 A total of 16-speed settings can be achieved through the digital state combination of these four terminals.
1007
1008 See attached sheet 1 for detailed combination.
1009 )))
1010 |(% style="width:121px" %)13|(% style="width:540px" %)Multi-speed instruction terminal 2
1011 |(% style="width:121px" %)14|(% style="width:540px" %)Multi-speed instruction terminal 3
1012 |(% style="width:121px" %)15|(% style="width:540px" %)Multi-speed instruction terminal 4
1013 |(% style="width:121px" %)16|(% style="width:540px" %)Terminal 1 for acceleration/deceleration time selection|(% rowspan="2" style="width:829px" %)Four types of acceleration and deceleration time can be selected through the combination of the digital states of these two terminals. See attached sheet 2 for detailed combination.
1014 |(% style="width:121px" %)17|(% style="width:540px" %)Terminal 2 for acceleration/deceleration time selection
1015 |(% style="width:121px" %)18|(% style="width:540px" %)Frequency source switchover(terminal and keypad)|(% style="width:829px" %)(((
1016 When the frequency source selection (F0.07 ones place) is set to 2, the main frequency source X and auxiliary frequency source Y are switched through this terminal.
1017
1018 When the frequency source selection (F0.07 ones place) is set to 3, this terminal is used to switch between the main frequency source X and the main and auxiliary calculation results.
1019
1020 When the frequency source selection (F0.07 ones place) is set to 4, use this terminal to switch between the auxiliary frequency source Y and the main and auxiliary calculation results
1021 )))
1022 |(% style="width:121px" %)19|(% style="width:540px" %)UP/DOWN setting clear(terminal and keypad)|(% style="width:829px" %)When the frequency source is a digital frequency setting, this terminal can be used to clear the frequency value changed by UP/DOWN and restore the reference frequency to the value set by F0.08.
1023 |(% style="width:121px" %)20|(% style="width:540px" %)Command source switchover terminal|(% style="width:829px" %)(((
1024 When the command source (F0.01) is set to 1, this terminal can be used to switch between terminal control and keyboard control.
1025
1026 When the command source (F0.01) is set to 2, the communication control and keyboard control can be switched through this terminal.
1027 )))
1028 |(% style="width:121px" %)21|(% style="width:540px" %)Acceleration/deceleration prohibited|(% style="width:829px" %)Ensure that the inverter is not affected by external signals (except for the stop command) and maintain the current output frequency.
1029 |(% style="width:121px" %)22|(% style="width:540px" %)PID pause|(% style="width:829px" %)PID is temporarily invalid and the inverter maintains the current frequency output.
1030 |(% style="width:121px" %)23|(% style="width:540px" %)PLC status reset|(% style="width:829px" %)The PLC pauses during execution, and can be restored to the initial state of the simple PLC through this terminal when it is running again.
1031 |(% style="width:121px" %)24|(% style="width:540px" %)Swing pause|(% style="width:829px" %)The inverter outputs at the central frequency. The swing frequency is paused.
1032 |(% style="width:121px" %)25|(% style="width:540px" %)Counter input|(% style="width:829px" %)The input terminal for counting pulses.
1033 |(% style="width:121px" %)26|(% style="width:540px" %)Counter reset|(% style="width:829px" %)Clear the counter status.
1034 |(% style="width:121px" %)27|(% style="width:540px" %)Length count input|(% style="width:829px" %)The input terminal for length count.
1035 |(% style="width:121px" %)28|(% style="width:540px" %)Length reset|(% style="width:829px" %)Clear the length.
1036 |(% style="width:121px" %)29|(% style="width:540px" %)Torque control prohibited|(% style="width:829px" %)The inverter is prohibited from torque control mode.
1037 |(% style="width:121px" %)30|(% style="width:540px" %)Reserved|(% style="width:829px" %)Reserved
1038 |(% style="width:121px" %)31|(% style="width:540px" %)Reserved|(% style="width:829px" %)
1039 |(% style="width:121px" %)32|(% style="width:540px" %)Immediate DC braking|(% style="width:829px" %)When this terminal is valid, the inverter directly switches to the DC braking state
1040 |(% style="width:121px" %)33|(% style="width:540px" %)External faults normally closed input|(% style="width:829px" %)When the external fault signal is sent to the inverter, the inverter reports a fault and stops.
1041 |(% style="width:121px" %)34|(% style="width:540px" %)Frequency setting effect terminal|(% style="width:829px" %)If the function of this terminal is set, when the frequency is modified, the effective time of the modification is controlled by this terminal
1042 |(% style="width:121px" %)35|(% style="width:540px" %)Reverse PID action direction|(% style="width:829px" %)If this terminal is valid, the PID action direction is opposite to the direction set by F9.03
1043 |(% style="width:121px" %)36|(% style="width:540px" %)External stop terminal 1|(% style="width:829px" %)During keyboard control, this terminal can be used to stop, which is equivalent to the STOP key on the keypad
1044 |(% style="width:121px" %)37|(% style="width:540px" %)Command source switchover terminal 1|(% style="width:829px" %)Used to switch between terminal control and communication control. When this terminal is valid if F0.02 is set to terminal control, it will switch to communication control; if F0.02 is set to communication control, it will switch to terminal control.
1045 |(% style="width:121px" %)38|(% style="width:540px" %)PID integral pause|(% style="width:829px" %)If this terminal is valid, the PID integral function is suspended, but the proportional regulation and differential regulation still function.
1046 |(% style="width:121px" %)39|(% style="width:540px" %)Frequency source X and preset frequency switchover terminals|(% style="width:829px" %)If this terminal is valid, the frequency source X is replaced by the preset frequency (F0.08)
1047 |(% style="width:121px" %)40|(% style="width:540px" %)Frequency source Y and preset frequency switchover terminals|(% style="width:829px" %)If this terminal is valid, the frequency source Y is replaced by the preset frequency (F0.08)
1048 |(% style="width:121px" %)41|(% style="width:540px" %)Reserved|(% style="width:829px" %)
1049 |(% style="width:121px" %)42|(% style="width:540px" %)Reserved|(% style="width:829px" %)
1050 |(% style="width:121px" %)43|(% style="width:540px" %)PID parameter switchover terminal|(% style="width:829px" %)When F9.18 (PID parameter switching condition) is DI terminal, when this terminal is valid, PID uses F9.15~~F9.17 parameters. When the terminal is invalid, use F9.05~~F9.07 parameters
1051 |(% style="width:121px" %)44|(% style="width:540px" %)User-defined fault 1|(% style="width:829px" %)After the external fault signal is sent to the inverter, the inverter reports a fault and handles it according to the fault protection action mode (FA.13~~FA.16).
1052 |(% style="width:121px" %)45|(% style="width:540px" %)User-defined fault 2|(% style="width:829px" %)After the external fault signal is sent to the inverter, the inverter reports a fault and handles it according to the fault protection action mode (FA.13~~FA.16).
1053 |(% style="width:121px" %)46|(% style="width:540px" %)Speed control/torque control switchover|(% style="width:829px" %)Switch the inverter to run in torque control or speed control mode. If this terminal is invalid, it runs in the mode defined by F3.09 (speed/torque control mode), and if it is valid, it switches to the other mode.
1054 |(% style="width:121px" %)47|(% style="width:540px" %)Emergency stop|(% style="width:829px" %)If this terminal is valid, the inverter will stop at the fastest speed
1055 |(% style="width:121px" %)48|(% style="width:540px" %)External stopping terminal 22|(% style="width:829px" %)Under any control mode, this terminal can be used to stop, and stop according to deceleration time 4
1056 |(% style="width:121px" %)49|(% style="width:540px" %)Deceleration DC braking|(% style="width:829px" %)If this terminal is valid, the inverter will first decelerate to the start frequency of stop DC braking and then switch to DC braking state
1057 |(% style="width:121px" %)50|(% style="width:540px" %)Clear the current running time|(% style="width:829px" %)If this terminal is valid, the inverter's current running timing time will be cleared, and this function will be used for timing running (F8.42).
1058
1059 Attached sheet: Multi-speed function description
1060
1061 (% class="table-bordered" %)
1062 |**K4**|**K3**|**K2**|**K1**|**Set Frequency**|**Related Parameter**
1063 |OFF|OFF|OFF|OFF|Multistage Speed0|FD.00
1064 |OFF|OFF|OFF|ON|Multistage Speed1|FD.01
1065 |OFF|OFF|ON|OFF|Multistage Speed2|FD.02
1066 |OFF|OFF|ON|ON|Multistage Speed3|FD.03
1067 |OFF|ON|OFF|OFF|Multistage Speed4|FD.04
1068 |OFF|ON|OFF|ON|Multistage Speed5|FD.05
1069 |OFF|ON|ON|OFF|Multistage Speed6|FD.06
1070 |OFF|ON|ON|ON|Multistage Speed7|FD.07
1071 |ON|OFF|OFF|OFF|Multistage Speed8|FD.08
1072 |ON|OFF|OFF|ON|Multistage Speed9|FD.09
1073 |ON|OFF|ON|OFF|Multistage Speed10|FD.10
1074 |ON|OFF|ON|ON|Multistage Speed11|FD.11
1075 |ON|ON|OFF|OFF|Multistage Speed12|FD.12
1076 |ON|ON|OFF|ON|Multistage Speed13|FD.13
1077 |ON|ON|ON|OFF|Multistage Speed14|FD.14
1078 |ON|ON|ON|ON|Multistage Speed15|FD.15
1079
1080 Attached sheet: description of acceleration and deceleration time selection
1081
1082 (% class="table-bordered" %)
1083 |**Terminal 2**|**Terminal 1**|**Selection of acceleration/deceleration time**|**Related Parameter**
1084 |OFF|OFF|Acceleration/Deceleration Time1|F0.18. F0.19
1085 |OFF|ON|Acceleration/Deceleration Time2|F8.03. F8.04
1086 |ON|OFF|Acceleration/Deceleration Time3|F8.05. F8.06
1087 |ON|ON|Acceleration/Deceleration Time4|F8.07. F8.08
1088
1089 (% class="table-bordered" %)
1090 |(% rowspan="2" %)**F5.15**|DI filter time|Default|0.010s
1091 |Setting range|(% colspan="2" %)0.000s~~1.000s 
1092
1093 Set the sensitivity of the DI terminal. If the digital input terminal is susceptible to interference and cause malfunction, you can increase this parameter to increase the anti-interference ability, but cause the sensitivity of the DI terminal to decrease.
1094
1095 (% class="table-bordered" %)
1096 |(% rowspan="5" %)**F5.16**|(% colspan="2" %)Terminal command mode|Default|0
1097 |(% rowspan="4" %)Setting range|0|(% colspan="2" %)Two-line mode 1
1098 |1|(% colspan="2" %)Two-line mode 2
1099 |2|(% colspan="2" %)Three-line mode 1
1100 |3|(% colspan="2" %)Three-line mode 2
1101
1102 This parameter defines four different ways to control the operation of the inverter through external terminals.
1103
1104 0: Two-line mode 1: This mode is the most commonly used two-line mode. The FWD and REV terminal commands determine the forward and reverse of the motor.
1105
1106 [[image:1681697850903-377.png||height="282" width="633"]]
1107
1108 1: Two-wire mode 2: FWD is the enable terminal when using this mode. The direction is determined by the state of the REV.
1109
1110 [[image:1681697969422-504.png]]
1111
1112 2: Three-line mode 1: This mode Din(function code 3) is the enable terminal, and the direction is controlled by FWD and REV respectively.
1113
1114 DIN is pulse effective, user need to disconnect the Din terminal signal when stop.
1115
1116 Din is the multifunctional input terminal of DI1~~DI6. At this time, the corresponding terminal function should be defined as the No. 3 function "three-wire operation control".
1117
1118 [[image:1681698530367-261.png||height="298" width="628"]]
1119
1120 3: Three-line mode 2: The enable terminal of this mode is Din, the running command is given by FWD, and the direction is determined by the state of REV. The stop command is completed by disconnecting the Din signal.
1121
1122 Din is the multi-function input terminal of DI1~~DI6. At this time, the corresponding terminal function should be defined as the No. 3 function "three-wire operation control".
1123
1124 [[image:1681698557086-403.png||height="267" width="625"]]
1125
1126
1127 (% class="table-bordered" %)
1128 |(% rowspan="2" %)**F5.17**|UP/DOWN change rate range|Default|0.50Hz
1129 |Setting range|(% colspan="2" %)0.01Hz~~65.535Hz
1130
1131 Frequency change rate while using terminal UP/DOWN function
1132
1133 (% class="table-bordered" %)
1134 |(% rowspan="2" %)**F5.18**|AI1 minimum input|Default|0.00V
1135 |Setting range|(% colspan="2" %)0.00V~~F5.15  
1136 |(% rowspan="2" %)**F5.19**|Percentage rate of AI1 minimum input|Default|0.0%
1137 |Setting range|(% colspan="2" %)-100.00%~~100.0%
1138 |(% rowspan="2" %)**F5.20**|AI1 maximum input|Default|10.00V
1139 |Setting range|(% colspan="2" %)F5.18~~10.00V  
1140 |(% rowspan="2" %)**F5.21**|Percentage rate of AI1 maximum input|Default|100.0%
1141 |Setting range|(% colspan="2" %)-100.00%~~100.0%
1142 |(% rowspan="2" %)**F5.22**|AI1 filter time|Default|0.10s
1143 |Setting range|(% colspan="2" %)0.00s~~10.00s
1144
1145 The above function code defines the relationship between the analog input voltage and the set value represented by the analog input. When the analog input voltage exceeds the set maximum input range, the other part will be calculated as the maximum input. When the analog input voltage exceeds the set minimum input The range, the outside part will be calculated based on the AI minimum input.
1146
1147 When analog input is current input, 1mA current is equivalent to 0.5V voltage. In different applications, the nominal value corresponding to 100% of the analog setting is different. For details, please refer to the description of each application part.
1148
1149 The following figures illustrate several settings:
1150
1151 (% style="text-align:center" %)
1152 [[image:CHAPTER 7 FUNCTIONAL PARAMETER DETAILS_html_18e4cbe6e1292696.png]]
1153
1154 Figure 6-6-1 Correspondence between analog reference and setting
1155
1156 (% class="table-bordered" %)
1157 |(% rowspan="2" %)**F5.23**|AI2 minimum input|Default|0.00V
1158 |Setting range|(% colspan="2" %)0.00V~~F5.25  
1159 |(% rowspan="2" %)**F5.24**|Percentage rate of AI2 minimum input|Default|0.0%
1160 |Setting range|(% colspan="2" %)-100.00%~~100.0%
1161 |(% rowspan="2" %)**F5.25**|AI2 maximum input|Default|10.00V
1162 |Setting range|(% colspan="2" %)F5.23~~10.00V  
1163 |(% rowspan="2" %)**F5.26**|Percentage rate of AI2 maximum input|Default|100.0%
1164 |Setting range|(% colspan="2" %)-100.00%~~100.0%
1165 |(% rowspan="2" %)**F5.27**|AI2 filter time|Default|0.10s
1166 |Setting range|(% colspan="2" %)0.00s~~10.00s
1167
1168 The function of AI2 is similar to the setting method of AI1.
1169
1170 (% class="table-bordered" %)
1171 |(% rowspan="2" %)**F5.33**|DI1 enable delay time|Default|0.0s
1172 |Setting range|(% colspan="2" %)0.0s~~3600.0s
1173 |(% rowspan="2" %)**F5.34**|DI1 disable delay time|Default|0.0s
1174 |Setting range|(% colspan="2" %)0.0s~~3600.0s
1175 |(% rowspan="2" %)**F5.35**|DI2 enable delay time|Default|0.0s
1176 |Setting range|(% colspan="2" %)0.0s~~3600.0s
1177 |(% rowspan="2" %)**F5.36**|DI2 disable delay time|Default|0.0s
1178 |Setting range|(% colspan="2" %)0.0s~~3600.0s
1179
1180 Set the delay time from DI terminal status change to inverter response.
1181
1182 Currently only DI1\DI2 has the function of setting the delay time.
1183
1184 (% class="table-bordered" %)
1185 |(% rowspan="8" %)**F5.37**|(% colspan="2" %)DI valid mode selection 1|Default|00000
1186 |(% rowspan="7" %)Setting range|Ones Place|(% colspan="2" %)DI1 terminal valid state setting
1187 |0|(% colspan="2" %)High level
1188 |1|(% colspan="2" %)Low Level
1189 |Tens Place|(% colspan="2" %)DI2 terminal valid state setting(0~~1,as above)
1190 |Hundreds Place|(% colspan="2" %)DI3 terminal valid state setting(0~~1,as above)
1191 |Thousands Place|(% colspan="2" %)DI4 terminal valid state setting(0~~1,as above)
1192 |Ten Thousands Place|(% colspan="2" %)DI5 terminal valid state setting(0~~1,as above)
1193 |(% rowspan="8" %)**F5.38**|(% colspan="2" %)DI valid mode selection 2|Default|00000
1194 |(% rowspan="7" %)Setting range|Ones Place|(% colspan="2" %)DI6 terminal valid state setting
1195 |0|(% colspan="2" %)High level
1196 |1|(% colspan="2" %)Low Level
1197 |Tens Place|(% colspan="2" %)Reserved
1198 |Hundreds Place|(% colspan="2" %)Reserved
1199 |Thousands Place|(% colspan="2" %)Reserved
1200 |Ten Thousands Place|(% colspan="2" %)Reserved
1201
1202 Define the effective state setting of the input terminal.
1203
1204 High level:The connection between DI terminal and COM is valid, while disconnection is invalid.
1205
1206 Low Level:The connection between DI terminal and COM is invalid, while disconnection is valid.
1207
1208 = 7 F6 group output terminals =
1209
1210 The standard unit of VB series inverter has 2 multi-function relay output terminals, 1 FM terminal and 2 multi-function analog output terminals.
1211
1212 (% class="table-bordered" %)
1213 |(% rowspan="3" %)**F6.00**|(% colspan="2" %)FM terminal output mode|Default|1
1214 |(% rowspan="2" %)Setting range|0|(% colspan="2" %)Pulse Output(FMP)(Reserved)  
1215 |1|(% colspan="2" %)Open-collector output(FMR)  
1216
1217 The FM terminal is a programmable multiplexing terminal. It can be used as an open collector output terminal (FMR). Refer to F6.01 for FMR function.
1218
1219 FMP function needs hardware support
1220
1221 (% class="table-bordered" %)
1222 |**F6.01**|FMR function|Default|0
1223 |**F6.02**|Relay 1 function|Default|2
1224 |**F6.03**|Relay 2 function|Default|1
1225 |**F6.06**|VDO Output Selection|Default|0
1226
1227 **The functions of the multi-function output terminals are as follows:**
1228
1229 (% class="table-bordered" %)
1230 |(% style="width:108px" %)**Set Value**|(% style="width:469px" %)**Function**|(% style="width:912px" %)**Description**
1231 |(% style="width:108px" %)0|(% style="width:469px" %)No output|(% style="width:912px" %)The output terminal has no function  
1232 |(% style="width:108px" %)1|(% style="width:469px" %)AC Drive running|(% style="width:912px" %)It means that the inverter is running and there is an output frequency (it can be zero) and the ON signal is output at this time.
1233 |(% style="width:108px" %)2|(% style="width:469px" %)Fault output(stop)|(% style="width:912px" %)When the inverter fails and it stops, it outputs ON signal.
1234 |(% style="width:108px" %)3|(% style="width:469px" %)Frequency level detection FDT1 output|(% style="width:912px" %)Please refer to the detailed description of function codes F8.08 and F8.09.
1235 |(% style="width:108px" %)4|(% style="width:469px" %)Frequency reached|(% style="width:912px" %)Please refer to the detailed description of function codes F8.21
1236 |(% style="width:108px" %)5|(% style="width:469px" %)Zero-speed running(no output at stop)|(% style="width:912px" %)The inverter runs and the output frequency is 0, and the ON signal is output.
1237 |(% style="width:108px" %)6|(% style="width:469px" %)Motor overload pre-warning|(% style="width:912px" %)Before the motor electronic thermal protection acts, it is judged according to the overload forecast value, and the ON signal is output after the forecast value is exceeded. Motor overload parameters are set in FA.00~~FA.02.
1238 |(% style="width:108px" %)7|(% style="width:469px" %)AC Drive overload pre-warning|(% style="width:912px" %)After checking that the inverter is overloaded, advance 10s before the protection occurs. Output ON signal.
1239 |(% style="width:108px" %)8|(% style="width:469px" %)Set count value reached|(% style="width:912px" %)When the count value reaches the value set by FB.08, the ON signal is output.
1240 |(% style="width:108px" %)9|(% style="width:469px" %)Designated count value reached|(% style="width:912px" %)When the count value reaches the value set by FB.09, the ON signal is output. Refer to the function description of FB group for counting function
1241 |(% style="width:108px" %)10|(% style="width:469px" %)Length reached|(% style="width:912px" %)When the actual length detected exceeds the length set by FB.05, the ON signal is output.
1242 |(% style="width:108px" %)11|(% style="width:469px" %)PLC cycle complete|(% style="width:912px" %)When the simple PLC runs a cycle, it outputs a pulse signal with a width of 250ms.
1243 |(% style="width:108px" %)12|(% style="width:469px" %)Accumulative running time reached|(% style="width:912px" %)When the accumulative running time of the inverter exceeds the time set by F8.17, it outputs ON signal.
1244 |(% style="width:108px" %)13|(% style="width:469px" %)Frequency limited|(% style="width:912px" %)When the set frequency exceeds the upper and lower frequency limits and the inverter output frequency reaches the upper and lower frequency limits, the ON signal is output.
1245 |(% style="width:108px" %)14|(% style="width:469px" %)Torque limited|(% style="width:912px" %)When the torque limit function is activated, the stall protection function automatically activates, automatically changes the output frequency, and outputs an ON signal to indicate that the output torque is limited. This output signal can be used to reduce the load or display an overload status signal on the monitoring device.
1246 |(% style="width:108px" %)15|(% style="width:469px" %)Ready for running|(% style="width:912px" %)The power supply of the main circuit and control circuit is established, the protection function of the inverter does not operate, and the inverter outputs ON signal when it is in an operational state.
1247 |(% style="width:108px" %)16|(% style="width:469px" %)AI1 larger than AI2|(% style="width:912px" %)When the value of analog input AI1 is greater than the other input AI2, the ON signal is output.
1248 |(% style="width:108px" %)17|(% style="width:469px" %)Frequency upper limit reached|(% style="width:912px" %)When the operating frequency reaches the upper limit frequency, the ON signal is output.
1249 |(% style="width:108px" %)18|(% style="width:469px" %)Frequency lower limit reached|(% style="width:912px" %)When the operating frequency reaches the lower limit frequency, the ON signal is output.
1250 |(% style="width:108px" %)19|(% style="width:469px" %)Undervoltage state output|(% style="width:912px" %)When the inverter is under voltage, it outputs ON signal.
1251 |(% style="width:108px" %)20|(% style="width:469px" %)Communication setting|(% style="width:912px" %)See the relevant description in the communication protocol.
1252 |(% style="width:108px" %)21|(% style="width:469px" %)Positioning completed (Reserved)|(% style="width:912px" %)Reserved
1253 |(% style="width:108px" %)22|(% style="width:469px" %)Positioning close (Reserved)|(% style="width:912px" %)Reserved
1254 |(% style="width:108px" %)23|(% style="width:469px" %)Zero-speed running 2(having output at stop)|(% style="width:912px" %)When the output frequency of the inverter is 0, the ON signal is output (also output when stopping).
1255 |(% style="width:108px" %)24|(% style="width:469px" %)Accumulative power-on time reached|(% style="width:912px" %)When F7.13 (accumulated power-on time of the inverter) exceeds the time set by F8.16, the ON signal is output.
1256 |(% style="width:108px" %)25|(% style="width:469px" %)Frequency level detection FDT2|(% style="width:912px" %)Please refer to the detailed description of function codes F8.28 and F8.39.
1257 |(% style="width:108px" %)26|(% style="width:469px" %)Frequency 1 reached|(% style="width:912px" %)Please refer to the detailed description of function codes F8.30 and F8.31.
1258 |(% style="width:108px" %)27|(% style="width:469px" %)Frequency 2 reached|(% style="width:912px" %)Please refer to the detailed description of function codes F8.32 and F8.33.
1259 |(% style="width:108px" %)28|(% style="width:469px" %)Current 1 reached|(% style="width:912px" %)Please refer to the detailed description of function codes F8.38 and F8.30.
1260 |(% style="width:108px" %)29|(% style="width:469px" %)Current 2 reached|(% style="width:912px" %)Please refer to the detailed description of function codes F8.40 and F8.41.
1261 |(% style="width:108px" %)30|(% style="width:469px" %)Timing reached|(% style="width:912px" %)When F8.42 (timing function selection) is valid, the inverter will output ON signal when the current running time reaches the set timing time.
1262 |(% style="width:108px" %)31|(% style="width:469px" %)AI1 input limit exceeded|(% style="width:912px" %)When the value of analog input AI1 is greater than F8.46 (AI1 input protection upper limit) or less than F8.45 (AI1 input protection lower limit), FM (FMR) outputs ON signal.
1263 |(% style="width:108px" %)32|(% style="width:469px" %)Offload|(% style="width:912px" %)Output ON signal when the inverter is in the off-load state
1264 |(% style="width:108px" %)33|(% style="width:469px" %)Running direction|(% style="width:912px" %)Output ON signal when inverter is running in reverse
1265 |(% style="width:108px" %)34|(% style="width:469px" %)Zero current detection|(% style="width:912px" %)Please refer to the detailed description of function codes F8.34 and F8.35.
1266 |(% style="width:108px" %)35|(% style="width:469px" %)Module temperature reached|(% style="width:912px" %)When F7.07 (IGBT module heatsink temperature) reaches the value of F8.47 (module temperature reached), output ON signal
1267 |(% style="width:108px" %)36|(% style="width:469px" %)Software overcurrent output|(% style="width:912px" %)Please refer to the detailed description of function codes F8.36 and F8.37.
1268 |(% style="width:108px" %)37|(% style="width:469px" %)Lower limit frequency reached (non-operational)|(% style="width:912px" %)When the running frequency reaches the lower limit frequency, the ON signal is output (also output when stopping).
1269 |(% style="width:108px" %)38|(% style="width:469px" %)Fault output (continue operation)|(% style="width:912px" %)When the inverter fails, output ON signal
1270 |(% style="width:108px" %)39|(% style="width:469px" %)Reserved|(% style="width:912px" %)
1271 |(% style="width:108px" %)40|(% style="width:469px" %)This running time arrive|(% style="width:912px" %)
1272 |(% style="width:108px" %)41|(% style="width:469px" %)User-defined output 1|(% style="width:912px" %)The user can define the conditions for the output terminal to output, see F6.28~~F6.32 for details.
1273 |(% style="width:108px" %)42|(% style="width:469px" %)User-defined output 2|(% style="width:912px" %)The user can define the conditions for the output terminal to output, see F6.23~~F6.37 for details.
1274 |(% style="width:108px" %)43|(% style="width:469px" %)(((
1275 Timer output
1276 )))|(% style="width:912px" %)(((
1277 If the timer arrives, the VFD outputs ON signal
1278 )))
1279 |(% style="width:108px" %)44|(% style="width:469px" %)(((
1280 Forward running status
1281 )))|(% style="width:912px" %)(((
1282 If the VFD is running forward, output ON signal
1283 )))
1284 |(% style="width:108px" %)45|(% style="width:469px" %)(((
1285 Reverse running status
1286 )))|(% style="width:912px" %)(((
1287 If the VFD is running reverse, output ON signal
1288 )))
1289
1290 (% class="table-bordered" %)
1291 |F6.11|FMP(Pulse output terminal)output selection(Reserved)|Default|0
1292 |F6.12|AO1 function|Default|0
1293 |F6.13|AO2 function|Default|1
1294
1295 The standard output of analog output (zero offset is 0, gain is 1) is 0mA~~20mA (or 0V~~10V), and the FMP output range is from 0Hz to the setting of function code F5.09.
1296
1297 The range of the corresponding amount expressed is shown in the following Sheet:
1298
1299 (% class="table-bordered" %)
1300 |**Set value**|**Function**|**Range**
1301 |0|Running frequency|0~~Maximum output power
1302 |1|Set frequency|0~~Maximum output frequency
1303 |2|Output current|0~~2 times motor rated current
1304 |3|Output torque|0~~2 times motor rated torque
1305 |4|Output power|0~~2 times motor rated power
1306 |5|Output voltage|0~~1.2 times AC drive rated voltage
1307 |6|PULSE input|0.01kHz~~100.00kHz
1308 |7|AI1|0V~~10V
1309 |8|AI2|0V~~10V/0~~20mA
1310 |10|Length|0~~Maximum set length
1311 |11|Count value|0~~Maximum count value
1312 |12|Communication setting|-10000~~10000
1313 |13|Motor Speed|0~~Rotation speed corresponding to maximum output frequency
1314 |14|Output Current|0-1000A,as 0-10V
1315 0-1000V,as 0-10V
1316 |15|Output Voltage|0.0V~~1000.0V
1317
1318 (% class="table-bordered" %)
1319 |(% rowspan="2" %)**F6.14**|FMP output maximum frequency|Default|50.00kHz   
1320 |Setting range|(% colspan="2" %)0.01kHz~~100.00kHz   
1321
1322 When the FM terminal is selected as pulse output, the maximum frequency value of the pulse can be output.
1323
1324 (% class="table-bordered" %)
1325 |(% rowspan="2" %)**F6.15**|AO1 offset coefficient|Default|0.0%   
1326 |Setting range|(% colspan="2" %)-100.0%~~100.0%
1327 |(% rowspan="2" %)**F6.16**|AO1 gain|Default|1.00   
1328 |Setting range|(% colspan="2" %)-10.00~~10.00
1329 |(% rowspan="2" %)**F6.17**|AO2 offset coefficient|Default|0.00%   
1330 |Setting range|(% colspan="2" %)-100.0%~~100.0%
1331 |(% rowspan="2" %)**F6.18**|AO2 gain|Default|1.00   
1332 |Setting range|(% colspan="2" %)-10.00~~10.00
1333
1334 If the zero offset is represented by "b", the gain is represented by k, the actual output is represented by Y, and the standard output is represented by X, the actual output is Y=kX+b; AO1, A02 zero offset coefficient 100% corresponds to 10V (20mA). Standard output refers to the output 0V~~10V (20mA) corresponding to the analog output representing 0~~max. Generally used to correct the zero drift of analog output and the deviation of output amplitude. It can also be customized to any desired output curve: For example: if the analog output content is the operating frequency, and hope to output 8V (16mA) when the frequency is 0, and 3V (6mA) when the frequency is the maximum frequency, the gain should be set to " .0.50", the zero offset should be set to "80%".
1335
1336 (% class="table-bordered" %)
1337 |(% rowspan="2" %)**F6.19**|FMR connecting delay time|Default|0.0s
1338 |Setting range|(% colspan="2" %)0.0s~~3600.0s
1339 |(% rowspan="2" %)**F6.20**|RELAY1 connecting delay time|Default|0.0s
1340 |Setting range|(% colspan="2" %)0.0s~~3600.0s
1341 |(% rowspan="2" %)**F6.21**|RELAY2 connecting delay time|Default|0.0s
1342 |Setting range|(% colspan="2" %)0.0s~~3600.0s
1343 |(% rowspan="2" %)**F6.22**|VDO connecting delay time|Default|0.0s
1344 |Setting range|(% colspan="2" %)0.0s~~3600.0s
1345 |(% rowspan="2" %)**F6.23**|FMR disconnecting delay time|Default|0.0s
1346 |Setting range|(% colspan="2" %)0.0s~~3600.0s
1347 |(% rowspan="2" %)**F6.24**|RELAY1 disconnecting delay time|Default|0.0s
1348 |Setting range|(% colspan="2" %)0.0s~~3600.0s
1349 |(% rowspan="2" %)**F6.25**|RELAY2 disconnecting delay time|Default|0.0s
1350 |Setting range|(% colspan="2" %)0.0s~~3600.0s
1351 |(% rowspan="2" %)**F6.26**|VDO disconnecting delay time|Default|0.0s
1352 |Setting range|(% colspan="2" %)0.0s~~3600.0s
1353
1354 Set the delay time from the state change of the output terminal FMR, relay 1, relay 2, VDO to the output change.
1355
1356 (% class="table-bordered" %)
1357 |(% rowspan="8" %)**F6.27**|(% colspan="2" %)Output terminal valid state selection|Default|00000
1358 |(% rowspan="7" %)Setting range|Ones Place|(% colspan="2" %)FMR valid state selection
1359 |0|(% colspan="2" %)Positive Logic
1360 |1|(% colspan="2" %)Negative Logic
1361 |Tens Place|(% colspan="2" %)RELAY1 valid state selection(0~~1,as above)
1362 |Hundreds Place|(% colspan="2" %)RELAY2 valid state selection(0~~1,as above)
1363 |Thousands Place|(% colspan="2" %)Reserved
1364 |Ten Thousands Place|(% colspan="2" %)Reserved
1365
1366 Define the positive and negative logic of output terminal FMR, relay 1, and relay 2.
1367
1368 Positive logic: the digital output terminal is valid when connected to the corresponding common terminal, but invalid when disconnected;
1369
1370 Inverse logic: the connection between the digital output terminal and the corresponding common terminal is invalid, and the disconnection is valid;
1371
1372 (% class="table-bordered" %)
1373 |(% rowspan="2" %)**F6.28**|(((
1374 User defined output
1375
1376 variability selection (EX)1
1377 )))|Default|00
1378 |Setting range|(% colspan="2" %)0~~49
1379
1380 This parameter is used to select the reference variable for custom output. Use the selected variable EX as the comparison object
1381
1382 (% class="table-bordered" %)
1383 |(% rowspan="2" %)**F6.29**|User defined comparison method 1|Default|00
1384 |Setting range|(% colspan="2" %)0~~14
1385
1386 The ones place selection comparison test mode, the variable selected by F6.28 is used as the comparison test object, and the comparison and test values are set by F6.31~~F6.32.
1387
1388 Tens place selects the output mode. False value output means output if the condition is not met, and no output if the condition is met; true value output means output if the condition is met, and no output if the condition is not met.
1389
1390 (% class="table-bordered" %)
1391 |(% rowspan="2" %)**F6.30**|User defined output dead zone 1|Default|0
1392 |Setting range|(% colspan="2" %)0~~65535
1393
1394 When the comparison test mode of F6.29 is set to be greater than or equal to or less than or equal to, F6.30 is used to define the processing dead zone value centered on the comparison value X1, and the processing dead zone is only for 1 and 2 of the F6.29 comparison test mode It has an effect, but no effect on 0, 3, and 4. For example, when F6.29 is set to 11, when EX increases from 0 upwards, the output is valid after increasing to greater than or equal to X1+F6.30; when EX decreases downward, after decreasing to less than or equal to X1.F6.30, The output is invalid.
1395
1396 (% class="table-bordered" %)
1397 |(% rowspan="2" %)**F6.31**|(((
1398 User-defined 1 output
1399
1400 comparison value X1
1401 )))|Default|0
1402 |Setting range|(% colspan="2" %)0~~65535
1403 |(% rowspan="2" %)**F6.32**|(((
1404 User-defined 1 output
1405
1406 comparison value X2
1407 )))|Default|0
1408 |Setting range|(% colspan="2" %)0~~65535
1409
1410 These two parameters are used to set the comparison value of the custom output.
1411
1412 The following is an example of using custom output:
1413
1414 When the set frequency is greater than or equal to 20.00HZ, the relay is closed;
1415
1416 The setting parameters are as follows: F6.02 = 41, F6.28 = 1, F6.29 = 11, F6.30 = 0, F6.31 = 2000;
1417
1418 2. The relay is required to close when the bus voltage is less than or equal to 500.0V; in order to avoid frequent relay actions when the detection voltage is 5.0V up and down from 500.0V, it is required to be treated as a dead zone in the range of (500.0-5.0) ~~ (500.0+5.0) .
1419
1420 The setting parameters are as follows: F6.02 = 41, F6.28 = 2, F6.29 = 01, F6.30 = 50, F6.31 = 5000;
1421
1422 When the inverter is required to reverse, the relay is closed:
1423
1424 The setting parameters are as follows: F6.02 = 41, F6.28 = 5, F6.29 = 14, F6.31 = 8, F6.32 = 8;
1425
1426 When AI1 input is required to be greater than 3.00V and less than or equal to 6.00V, the relay is closed:
1427
1428 The setting parameters are as follows: F6.02 = 41, F6.28 = 13, F6.29 = 13, F6.31 = 300, F6.32 = 600;
1429
1430 (% class="table-bordered" %)
1431 |(% rowspan="2" %)**F6.33**|(((
1432 User defined output
1433
1434 variability selection (EX)2
1435 )))|Default|00
1436 |Setting range|(% colspan="2" %)0~~49
1437
1438 (% class="table-bordered" %)
1439 |(% rowspan="2" %)**F6.34**|User defined comparison method 2|Default|00
1440 |Setting range|(% colspan="2" %)0~~14
1441
1442 (% class="table-bordered" %)
1443 |(% rowspan="2" %)**F6.35**|User defined output dead zone 1|Default|0
1444 |Setting range|(% colspan="2" %)0~~65535
1445
1446 (% class="table-bordered" %)
1447 |(% rowspan="2" %)**F6.36**|(((
1448 User-defined 2 output
1449
1450 comparison value X1
1451 )))|Default|0
1452 |Setting range|(% colspan="2" %)0~~65535
1453 |(% rowspan="2" %)**F6.37**|(((
1454 User-defined 2output
1455
1456 comparison value X2
1457 )))|Default|0
1458 |Setting range|(% colspan="2" %)0~~65535
1459
1460 For the second output, the parameter setting method is the same as F6.28~~F6.32.
1461
1462 (% class="table-bordered" %)
1463 |(% rowspan="2" %)**F6.38**|The setting time of timer|Default|0
1464 |Setting range|(% colspan="3" %)0.00s~~100.0s
1465
1466 Set the timer setting time
1467
1468 = 8 F7 group keypad display =
1469
1470 (% class="table-bordered" %)
1471 |(% rowspan="4" %)**F7.00**|(% colspan="2" %)LCD keypad parameter copy|Default|0
1472 |(% rowspan="3" %)Setting range|0|(% colspan="2" %)No operation
1473 |1|(% colspan="2" %)Upload local functional parameters to LCD keypad
1474 |2|(% colspan="2" %)Download functional parameters from LCD keypad to AC drive
1475
1476 Note: This function only supports LCD keyboard
1477
1478 (% class="table-bordered" %)
1479 |(% rowspan="7" %)**F7.01**|(% colspan="2" %)MF.K key function selection|Default|0
1480 |(% rowspan="6" %)Setting range|0|(% colspan="2" %)MF.K disabled
1481 |1|(% colspan="2" %)Switchover between keypad control and remote command control(terminal or communication)
1482 |2|(% colspan="2" %)Switchover between forward rotation and reverse rotation
1483 |3|(% colspan="2" %)Forward JOG
1484 |4|(% colspan="2" %)Reverse JOG
1485 |5|(% colspan="2" %)Menu mode switching
1486
1487 The MF.K key is the multi-function key. The function of the keyboard MF.K key can be defined through parameter settings. This key can be used to switch during stop and running.
1488
1489 0: When set to 0, this key has no function.
1490
1491 1: Switchover between keypad control and remote command control(terminal or communication). Refers to the switch of the command source, from the current command source to keyboard control (local operation). If the current command source is keyboard control, this command has no effect.
1492
1493 2: Switchover between forward rotation and reverse rotation
1494
1495 Switch the direction of the frequency command through the keyboard MF.K key. It is valid only in the operation panel command channel.
1496
1497 3: Forward jog
1498
1499 Realize forward jog (FJOG) by keyboard MF.K key.
1500
1501 4: Reverse jog
1502
1503 Reverse jog (RJOG) can be realized by keyboard MF.K key.
1504
1505 5: Menu mode switching
1506
1507 The menu mode switch is realized through the keyboard MF.K key.
1508
1509 (% class="table-bordered" %)
1510 |(% rowspan="3" %)**F7.02**|(% colspan="4" %)STOP/RESET key function|(% colspan="2" %)Default|(% colspan="2" %)1
1511 |(% colspan="3" rowspan="2" %)Setting range|0|(% colspan="4" %)STOP/RESET key enabled only in keypad control
1512 |1|(% colspan="4" %)STOP/RESET key enabled in any operation mode
1513 |(% rowspan="2" %)**F7.03**|(% colspan="5" %)LED display parameters 1 while running|(% colspan="2" %)Default|17
1514 |Setting range|(((
1515 0000
1516
1517 ~~FFFF
1518 )))|(% colspan="6" %)(((
1519 Bit00: Running frequency (Hz)
1520
1521 Bit01: Set frequency (Hz)
1522
1523 Bit02: DC bus voltage (V)
1524
1525 Bit03: Output voltage (V)
1526
1527 Bit04: Output current (A)
1528
1529 Bit05: Output power (kW)
1530
1531 Bit06: Output torque ~(%)
1532
1533 Bit07: DI input status
1534
1535 Bit08: DO output status
1536
1537 Bit09: AI1 power (V)
1538
1539 Bit10: AI2 power (V)
1540
1541 Bit11: Reserved
1542
1543 Bit12: Count value
1544
1545 Bit13: Length value
1546
1547 Bit14: Load speed display
1548
1549 Bit15: PID set value
1550
1551 If you need to display the above parameters while running, set the corresponding digit to 1, convert this binary number to hexadecimal and set it to F7.03.
1552 )))
1553 |(% rowspan="2" %)**F7.04**|(% colspan="5" %)LED display parameters 2 while running|(% colspan="2" %)Default|0
1554 |Setting range|(((
1555 0000
1556
1557 ~~FFFF
1558 )))|(% colspan="6" %)(((
1559 Bit00: PID feedback
1560
1561 Bit01: PLC stage
1562
1563 Bit02: Feedback speed (0.1Hz)
1564
1565 Bit03: Reserved
1566
1567 Bit04: Remaining running time
1568
1569 Bit05: AI1 voltage before correction
1570
1571 Bit06: AI2 voltage before correction
1572
1573 Bit07: Reserved
1574
1575 Bit08: Linear speed
1576
1577 Bit09: Current power-on time
1578
1579 Bit10: Current running time
1580
1581 Bit11: Reserved
1582
1583 Bit12: Communication setting
1584
1585 Bit13: Reserved
1586
1587 Bit14: Main frequency X display
1588
1589 Bit15: Auxiliary frequency Y display
1590
1591 If you need to display the above parameters while running, set the corresponding digit to 1, convert this binary number to hexadecimal and set it to F7.04
1592 )))
1593
1594 The running display parameters are used to set the status parameters that can be viewed when the inverter is running. Up to 32 state parameters can be viewed. Select the state parameters to be displayed according to the digits of the parameter values of F7.03 and F7.04, and the display sequence starts from the lowest bit of F7.03.
1595
1596 (% class="table-bordered" %)
1597 |(% rowspan="2" %)**F7.05**|(% colspan="5" %)LED display parameters while stopping|(% colspan="2" %)Default|33
1598 |(% colspan="2" %)Setting range|(((
1599 0000
1600
1601 ~~FFFF
1602 )))|(% colspan="5" %)(((
1603 Bit00: Set frequency (Hz)
1604 Bit01: DC bus voltage(V)
1605 Bit02: DI input status
1606 Bit03: DO output status
1607 Bit04: AI1 voltage (V)
1608 Bit05: AI2 voltage (V)
1609 Bit06: Reserved
1610 Bit07: Count value
1611 Bit08: Length value
1612 Bit09: PLC stage
1613 Bit10: Load speed display
1614 Bit11: PID set value
1615 Bit12: Reserved
1616
1617 Bit13: PID feedback value
1618
1619 If you need to display the above parameters while stopping, set the corresponding digit to 1, convert this binary number to hexadecimal and set it to F7.05
1620 )))
1621 |(% colspan="2" rowspan="2" %)**F7.06**|(% colspan="3" %)Load speed display coefficien|(% colspan="2" %)Default|(% colspan="2" %)1.0000
1622 |(% colspan="3" %)Setting range|(% colspan="4" %)0.0001~~6.5000
1623
1624 Correspond the output frequency of the inverter to the load speed through this parameter. Set when you need to display the load speed.
1625
1626 The specific calculation method is described in F7.12.
1627
1628 (% class="table-bordered" %)
1629 |(% rowspan="2" %)**F7.07**|Heatsink temperature of IGBT|Default|0
1630 |Setting range|(% colspan="2" %)0.0℃~~100.0℃
1631
1632 Displays the temperature of the IGBT module. The over-temperature protection value of IGBT module of different models may be different.
1633
1634 (% class="table-bordered" %)
1635 |(% rowspan="2" %)**F7.08**|Heatsink temperature of rectifier bridge|Default|0
1636 |Setting range|(% colspan="2" %)0.0℃~~100.0℃
1637
1638 Displays the temperature of the rectifier bridge. The over-temperature protection value of rectifier bridge of different models may be different.
1639
1640 (% class="table-bordered" %)
1641 |(% rowspan="2" %)**F7.09**|Accumulative running time|Default|0h
1642 |Setting range|(% colspan="2" %)0h~~65535h
1643
1644 Display the cumulative running time of the inverter so far. When this time reaches the set running time (F8.17), the multi-function digital output (12) of the inverter will act.
1645
1646 (% class="table-bordered" %)
1647 |(% rowspan="2" %)**F7.10**|(% colspan="2" %)Product Number|Default|-
1648 |(% colspan="2" %)Setting range|(% colspan="2" %)Product Number of AC Drive
1649 |(% rowspan="2" %)**F7.11**|(% colspan="2" %)Software Version|Default|
1650 |(% colspan="2" %)Setting range|(% colspan="2" %)Software Version of Control Board
1651 |(% rowspan="5" %)**F7.12**|(% colspan="2" %)Number of decimal places for load speed display|Default|0
1652 |(% rowspan="4" %)Setting range|0|(% colspan="2" %)0 decimal places
1653 |1|(% colspan="2" %)1 decimal places
1654 |2|(% colspan="2" %)2 decimal places
1655 |3|(% colspan="2" %)3 decimal places
1656
1657 The load speed calculation method is: if the load speed display coefficient is 2.000, the load speed decimal point position is 2: 2 decimal points.
1658
1659 When the inverter is running: if the running frequency is 40.00 Hz, 4000*2.000 = 8000, and 2 decimal points display, the load speed is 80.00.
1660
1661 When the inverter is stopped: If the set frequency is 50.00 Hz, 5000*2.000 = 10000, and the load speed is 100.00 when displayed with 2 decimal points.
1662
1663 (% class="table-bordered" %)
1664 |(% rowspan="2" %)**F7.13**|Accumulative power-on time|Default|0h
1665 |Setting range|(% colspan="2" %)0h~~65535h
1666
1667 Display the cumulative power-on time of the inverter so far. When this time reaches the set power-on time (F8.17), the inverter's multi-function digital output (24) will act.
1668
1669 (% class="table-bordered" %)
1670 |(% rowspan="2" %)**F7.14**|Accumulative power consumption|Default|0
1671 |Setting range|(% colspan="2" %)0~~65535
1672
1673 Displays the cumulative power consumption of the inverter so far.
1674
1675 (% class="table-bordered" %)
1676 |(% rowspan="2" %)**F7.15**|Performance software version|Default|-
1677 |Setting range|(% colspan="2" %)-
1678
1679 = 9 F8 group auxiliary functions =
1680
1681 (% class="table-bordered" %)
1682 |(% rowspan="2" %)**F8.00**|JOG running frequency|Default|2.00Hz
1683 |Setting range|(% colspan="2" %)0.00Hz~~F0.10
1684 |(% rowspan="2" %)**F8.01**|JOG acceleration time|Default|20.0s
1685 |Setting range|(% colspan="2" %)0.0s~~6500.0s
1686 |(% rowspan="2" %)**F8.02**|JOG deceleration time|Default|20.0s  
1687 |Setting range|(% colspan="2" %)0.0s~~6500.0s
1688
1689 Define the given frequency and acceleration/deceleration time of the inverter during jog. The jog process starts and stops according to start mode 0 (F1.00, direct start) and stop mode 0 (F1.10, decelerate to stop).
1690
1691 Jog acceleration time refers to the time required for the inverter to accelerate from 0Hz to the maximum output frequency (F0.10).
1692
1693 Jog deceleration time refers to the time required for the inverter to decelerate from the maximum output frequency (F0.10) to 0Hz.
1694
1695 (% class="table-bordered" %)
1696 |(% rowspan="2" %)**F8.03**|Acceleration time2|Default|Model dependent
1697 |Setting range|(% colspan="2" %)0. 0s~~6500.0s
1698 |(% rowspan="2" %)**F8.04**|Deceleration time2|Default|Model dependent
1699 |Setting range|(% colspan="2" %)0. 0s~~6500.0s
1700 |(% rowspan="2" %)**F8.05**|Acceleration time3|Default|Model dependent
1701 |Setting range|(% colspan="2" %)0. 0s~~6500.0s
1702 |(% rowspan="2" %)**F8.06**|Deceleration time3|Default|Model dependent
1703 |Setting range|(% colspan="2" %)0. 0s~~6500.0s
1704 |(% rowspan="2" %)**F8.07**|Acceleration time4|Default|Model dependent
1705 |Setting range|(% colspan="2" %)0. 0s~~6500.0s
1706 |(% rowspan="2" %)**F8.08**|Deceleration time4|Default|Model dependent
1707 |Setting range|(% colspan="2" %)0. 0s~~6500.0s
1708
1709 The acceleration and deceleration time can be selected from F0.18 and F0.19 and the above three types of acceleration and deceleration time. The meanings are the same, please refer to the relevant description of F0.18 and F0.19. The acceleration and deceleration time 1~~4 during the operation of the inverter can be selected through different combinations of the multifunctional digital input terminal DI. Please refer to the function codes F5.01~~F5.05.
1710
1711 (% class="table-bordered" %)
1712 |(% rowspan="2" %)**F8.09**|Jump frequency 1|Default|0.00Hz
1713 |Setting range|(% colspan="2" %)0.00Hz~~F0.10
1714 |(% rowspan="2" %)**F8.10**|Jump frequency 2|Default|0.00Hz
1715 |Setting range|(% colspan="2" %)0.00 Hz~~F0.10
1716 |(% rowspan="2" %)**F8.11**|Frequency jump amplitude|Default|0.01Hz
1717 |Setting range|(% colspan="2" %)0.00~~F0.10
1718
1719 When the set frequency is within the jump frequency range, the actual running frequency will run at the jump frequency boundary close to the set frequency. By setting the jump frequency, the inverter can avoid the mechanical resonance point of the load. This inverter can set two jumping frequency points. If both skip frequencies are set to 0, this function will not work.
1720
1721 (% style="text-align:center" %)
1722 [[image:CHAPTER 7 FUNCTIONAL PARAMETER DETAILS_html_9a49731ff18de325.png]]
1723
1724 Figure 6-9-1 Schematic diagram of hopping frequency
1725
1726 (% class="table-bordered" %)
1727 |(% rowspan="2" %)**F8.12**|Forward/Reverse rotation dead-zone time|Default|0.0s
1728 |Setting range|(% colspan="2" %)0.00s~~3000.0s
1729
1730 Set the transition time at the output zero frequency during the forward and reverse transition of the inverter, as shown in the figure below:
1731
1732 (((
1733 (% style="text-align:center" %)
1734 [[image:CHAPTER 7 FUNCTIONAL PARAMETER DETAILS_html_d8f000d30762f35.png]]
1735 )))
1736
1737 Figure 6-9-2 Schematic diagram of forward and reverse dead zone time
1738
1739 (% class="table-bordered" %)
1740 |(% rowspan="3" %)**F8.13**|(% colspan="2" %)Reverse control|Default|0
1741 |(% rowspan="2" %)Setting range|0|(% colspan="2" %)Enabled
1742 |1|(% colspan="2" %)Disabled
1743
1744 When this parameter is 0: it can be reverse controlled by keyboard, terminal or communication.
1745
1746 When this parameter is 1: the reverse control function is valid regardless of the command source selection, that is, the reverse control function is invalid under keyboard, terminal, and communication control.
1747
1748 (% class="table-bordered" %)
1749 |(% rowspan="3" %)**F8.14**|(% colspan="2" %)The carrier frequency is adjusted with temperature|Default|1
1750 |(% rowspan="2" %)Setting range|0|(% colspan="2" %)No
1751 |1|(% colspan="2" %)Yes
1752
1753 Provide fixed and random PWM carrier frequency adjustment methods. Random PWM motor noise has a wide frequency domain, and fixed PWM motor noise frequency is fixed.
1754
1755 The carrier frequency temperature adjustment is effective, which means that the inverter can automatically adjust the carrier frequency according to its own temperature. Selecting this function can reduce the chance of inverter overheating alarm.
1756
1757 (% class="table-bordered" %)
1758 |(% rowspan="2" %)**F8.15**|Droop control|Default|0.00Hz
1759 |Setting range|(% colspan="2" %)0.00Hz~~10.00Hz
1760
1761 When multiple inverters drive the same load, the load distribution is unbalanced due to different speeds, which makes the inverter with higher speed bear heavier load. The droop control characteristic is that the speed droops as the load increases, which can make the load balanced.
1762
1763 This parameter adjusts the frequency change of the inverter with drooping speed.
1764
1765 (% class="table-bordered" %)
1766 |(% rowspan="2" %)**F8.16**|Setting of accumulated power-on arrive time|Default|0h
1767 |Setting range|(% colspan="2" %)0h~~65000h
1768
1769 Preset the power-on time of the inverter. When the accumulated power-on time (F7.13) reaches this set power-on time, the inverter's multi-function digital DO outputs a running time arrival signal.
1770
1771 (% class="table-bordered" %)
1772 |(% rowspan="2" %)**F8.17**|Setting of accumulated running arrive time|Default|0h
1773 |Setting range|(% colspan="2" %)0h~~65000h
1774
1775 Pre-set the running time of the inverter. When the accumulated running time (F7.09) reaches this set running time, the inverter's multi-function digital DO outputs a running time arrival signal.
1776
1777 (% class="table-bordered" %)
1778 |(% rowspan="3" %)**F8.18**|(% colspan="2" %)Startup protection|Default|0
1779 |(% rowspan="2" %)Setting range|0|(% colspan="2" %)Invalid
1780 |1|(% colspan="2" %)Valid
1781
1782 This function code is used to improve the safety protection coefficient. If it is set to 1, it has two effects: one is that if the running command exists when the inverter is powered on, the running command must be removed to eliminate the running protection status. The second is that if the running command still exists when the inverter fault is reset, the running command must be removed first to eliminate the running protection state. This can prevent the motor from running automatically without knowing it, causing danger.
1783
1784 (% class="table-bordered" %)
1785 |(% rowspan="2" %)**F8.19**|Frequency detection value (FDT1)|Default|50.00Hz
1786 |Setting range|(% colspan="2" %)0.00Hz~~F0.10
1787 |(% rowspan="2" %)**F8.20**|Frequency detection hysteresis (FDT1)|Default|5.0%
1788 |Setting range|(% colspan="2" %)0.0%~~100.0%(FDT1)
1789
1790 Set the detection value of the output frequency and the hysteresis value of the output operation release.
1791
1792 (% style="text-align:center" %)
1793 [[image:CHAPTER 7 FUNCTIONAL PARAMETER DETAILS_html_a185f8b9d5aa6fa7.png]]
1794
1795 Figure 6-9-3 FDT1 level diagram
1796
1797 (% class="table-bordered" %)
1798 |(% rowspan="2" %)**F8.21**|Detection amplitude of frequency reached|Default|0.0%
1799 |Setting range|(% colspan="2" %)0.00~~100%*F0.10
1800
1801 When the output frequency of the inverter reaches the set frequency value, this function can adjust its detection amplitude. As shown below:
1802
1803 (((
1804 (% style="text-align:center" %)
1805 [[image:CHAPTER 7 FUNCTIONAL PARAMETER DETAILS_html_5226db5d1f9834fd.png]]
1806 )))
1807
1808 Figure 6-9-4 Schematic diagram of frequency arrival detection amplitude
1809
1810 (% class="table-bordered" %)
1811 |(% rowspan="2" %)**F8.22**|(% colspan="2" %)Jump frequency during acceleration/deceleration|Default|0
1812 |Setting range|(% colspan="3" %)(((
1813 0:Disabled
1814
1815 1:Enabled
1816 )))
1817
1818 This function code is set to be valid. When the running frequency is within the jump frequency range, the actual running frequency will directly skip the set jump frequency boundary.
1819
1820 (% style="text-align:center" %)
1821 [[image:CHAPTER 7 FUNCTIONAL PARAMETER DETAILS_html_43540e37b92098da.png]]
1822
1823 Figure 6-9-5 Schematic diagram of effective jumping frequency during acceleration and deceleration
1824
1825 (% class="table-bordered" %)
1826 |(% rowspan="2" %)**F8.23**|(% colspan="2" %)Accumulated running time arrive selection|Default|0
1827 |Setting range|(% colspan="3" %)0:Keep running
1828 1:Fault warning
1829 |(% rowspan="2" %)**F8.24**|(% colspan="2" %)Accumulated power-on time arrive action selection|Default|0
1830 |Setting range|(% colspan="3" %)0:Keep running
1831 1:Fault warning
1832
1833 Set to 1: When the fault prompts, if the running time or power-on time arrives, according to the FA group fault protection action selection, the inverter will stop freely, decelerate to stop or continue to run (please refer to the function code FA.13~~FA.16 for detailed description).
1834
1835 (% class="table-bordered" %)
1836 |(% rowspan="2" %)**F8.25**|Acceleration time 1/2 switching frequency point|Default|0.00Hz
1837 |Setting range|(% colspan="2" %)0.00Hz~~F0.10
1838 |(% rowspan="2" %)**F8.26**|Deceleration time 1/2 switching frequency point|Default|0.00Hz
1839 |Setting range|(% colspan="2" %)0.00Hz~~F0.10
1840
1841 (% style="text-align:center" %)
1842 [[image:CHAPTER 7 FUNCTIONAL PARAMETER DETAILS_html_2b2ceaa98c745458.png]]
1843
1844 Figure 6-9-6 Schematic diagram of acceleration and deceleration time switching
1845
1846 ~1. Switchover selection during acceleration time
1847
1848 During acceleration, if the running frequency is less than F8.25 (acceleration time 1/2 switching frequency point), acceleration time 2 is selected, otherwise, acceleration time 1 is selected.
1849
1850 2. Switchover selection during deceleration time
1851
1852 During deceleration, if the running frequency is less than F8.26 (deceleration time 1/2 switching frequency point), deceleration time 2 is selected, otherwise, deceleration time 1 is selected.
1853
1854 (% class="table-bordered" %)
1855 |(% rowspan="2" %)**F8.27**|Terminal JOG preferred|Default|1
1856 |Setting range|(% colspan="2" %)(((
1857 0:Disabled
1858
1859 1:Enabled
1860 )))
1861
1862 This parameter is used to set the priority of terminal jog. When this parameter is set to be valid, once DI terminal receives the jog control command, the inverter will switch from other running states to terminal jog running state.
1863
1864 (% class="table-bordered" %)
1865 |(% rowspan="2" %)**F8.28**|Frequency detection value (FDT2)|Default|50.00Hz
1866 |Setting range|(% colspan="2" %)0.00Hz~~F0.10
1867 |(% rowspan="2" %)**F8.29**|Frequency detection hysteresis (FDT2)|Default|5.0%
1868 |Setting range|(% colspan="2" %)0.0%~~100.0%(FDT2)
1869
1870 The function of FDT2 is similar to the setting method of FDT1 (F8.19, F8.20).
1871
1872 (% style="text-align:center" %)
1873 [[image:CHAPTER 7 FUNCTIONAL PARAMETER DETAILS_html_9a49acf9634cd985.png]]
1874
1875 Figure 6-9-7 FDT2 level diagram
1876
1877 (% class="table-bordered" %)
1878 |(% rowspan="2" %)**F8.30**|Arbitrary frequency reaching detection value 1|Default|50.00Hz
1879 |Setting range|(% colspan="2" %)0.00Hz~~F0.10
1880 |(% rowspan="2" %)**F8.31**|Arbitrary frequency reaching detection amplitude 1|Default|0.0%
1881 |Setting range|(% colspan="2" %)0.0%~~100.0%(F0.10)
1882 |(% rowspan="2" %)**F8.32**|Arbitrary frequency reaching detection value 2|Default|50.00Hz
1883 |Setting range|(% colspan="2" %)0.00Hz~~F0.10
1884 |(% rowspan="2" %)**F8.33**|Arbitrary frequency reaching detection amplitude 2|Default|0.0%
1885 |Setting range|(% colspan="2" %)0.0%~~100.0%(F0.10)
1886
1887 When the output frequency of the inverter is within the positive or negative detection range of the arbitrary arrival frequency detection value 1, 2, output pulse signal. As shown below:
1888
1889
1890 (((
1891 (% style="text-align:center" %)
1892 [[image:CHAPTER 7 FUNCTIONAL PARAMETER DETAILS_html_3aef8d5790f3423f.png]]
1893 )))
1894
1895 Figure 6-9-8 Schematic diagram of arbitrary reaching frequency detection
1896
1897 (% class="table-bordered" %)
1898 |(% rowspan="2" %)**F8.34**|Zero current detection level|Default|5.0%
1899 |Setting range|(% colspan="2" %)0.0%~~300.0%(Motor rated current)
1900 |(% rowspan="2" %)**F8.35**|Zero current detection delay time|Default|0.10s
1901 |Setting range|(% colspan="2" %)0.00s~~600.00s
1902
1903 When the output current of the inverter is less than or equal to the zero current detection level and the duration exceeds the zero current detection delay time, a pulse signal is output. As shown below:
1904
1905 (% style="text-align:center" %)
1906 [[image:CHAPTER 7 FUNCTIONAL PARAMETER DETAILS_html_c93b84a4c5da944b.png]]
1907
1908 Figure 6-9-9 Schematic diagram of zero current detection
1909
1910 (% class="table-bordered" %)
1911 |(% rowspan="2" %)**F8.36**|Software overcurrent point|Default|200.0%
1912 |Setting range|(% colspan="2" %)0.0%(Invalid) ; 0.1%~~300.0%(Motor rated current)
1913 |(% rowspan="2" %)**F8.37**|Software overcurrent detection delay time|Default|0.00s
1914 |Setting range|(% colspan="2" %)0.00s~~600.00s
1915
1916 (((
1917 When the output current of the inverter is greater than or equal to the software overcurrent point and the duration exceeds the software overcurrent point detection delay time, a pulse signal is output. As shown below:
1918 )))
1919
1920 (% style="text-align:center" %)
1921 [[image:CHAPTER 7 FUNCTIONAL PARAMETER DETAILS_html_879549a41172d673.png]]
1922
1923 Figure 6-9-10 Schematic diagram of software overcurrent point detection
1924
1925 (% class="table-bordered" %)
1926 |(% rowspan="2" %)**F8.38**|Arbitrary reaching current 1|Default|100.0%
1927 |Setting range|(% colspan="2" %)0.0%~~300.0%(Motor rated current)
1928 |(% rowspan="2" %)**F8.39**|Arbitrary reaching current amplitude 1|Default|0.0%
1929 |Setting range|(% colspan="2" %)0.0%~~300.0%(Motor rated current)
1930 |(% rowspan="2" %)**F8.40**|Arbitrary reaching current 2|Default|100.0%
1931 |Setting range|(% colspan="2" %)0.0%~~300.0%(Motor rated current)
1932 |(% rowspan="2" %)**F8.41**|Arbitrary reaching current amplitude 2|Default|0.0%
1933 |Setting range|(% colspan="2" %)0.0%~~300.0%(Motor rated current)
1934
1935 When the output current of the inverter is within the detection amplitude of the positive and negative currents 1 and 2, it outputs a pulse signal. As shown below:
1936
1937 (% style="text-align:center" %)
1938 [[image:CHAPTER 7 FUNCTIONAL PARAMETER DETAILS_html_9c74ba626be55d06.png]]
1939
1940 Figure 6-9-11 Schematic diagram of arbitrary reaching frequency detection
1941
1942 (% class="table-bordered" %)
1943 |(% rowspan="3" %)**F8.42**|(% colspan="2" %)Timing function|Default|0
1944 |(% rowspan="2" %)Setting range|0|(% colspan="2" %)Disabled
1945 |1|(% colspan="2" %)Enabled
1946 |(% rowspan="5" %)**F8.43**|(% colspan="2" %)Timing duration source|Default|0
1947 |(% rowspan="4" %)Setting range|0|(% colspan="2" %)F8.44 setting
1948 |1|(% colspan="2" %)AI1
1949 |2|(% colspan="2" %)AI2
1950 |3|(% colspan="2" %)Reserved
1951 |(% rowspan="2" %)**F8.44**|(% colspan="2" %)Timing duration|Default|0.0Min
1952 |Setting range|(% colspan="3" %)0.0Min~~6500.0Min
1953
1954 This function is used to complete the timing operation of the inverter. When the F8.42 timing function selection is valid, the inverter is running timing. When the set timing running time is reached, the inverter stops and outputs pulse signals. The timer will be cleared next time it runs. The timing remaining running time can be viewed through D0.20.
1955
1956 The set timing running time is determined by F8.43 and F8.44.
1957
1958 (% class="table-bordered" %)
1959 |(% rowspan="2" %)**F8.45**|(% colspan="2" %)AI1 input voltage lower limit|Default|3.10V
1960 |Setting range|(% colspan="3" %)0.00V~~F8.46
1961 |(% rowspan="2" %)**F8.46**|(% colspan="2" %)AI1 input voltage upper limit|Default|6.80V
1962 |Setting range|(% colspan="3" %)F8.45~~10.00V
1963
1964 When the value of analog input AI1 is greater than F8.46 (AI1 input protection upper limit) or less than F8.47 (AI1 input protection lower limit), FM (FMR) outputs a pulse signal.
1965
1966 (% class="table-bordered" %)
1967 |(% rowspan="2" %)**F8.47**|(% colspan="2" %)IGBT temperature threshold|Default|75℃
1968 |Setting range|(% colspan="3" %)0.00V~~F8.46
1969
1970 When F7.07 (IGBT module radiator temperature) reaches this value, output pulse signal
1971
1972 (% class="table-bordered" %)
1973 |(% rowspan="3" %)**F8.48**|(% colspan="2" %)Fast current limiting|Default|1
1974 |(% rowspan="2" %)Setting range|0|(% colspan="2" %)Disabled
1975 |1|(% colspan="2" %)Enabled
1976
1977 Enabling the fast current limiting function can minimize the inverter's overcurrent fault and protect the inverter from uninterrupted operation. After entering the fast current-limiting state for a period of time, a fast current-limiting fault (Err40) will be reported, indicating that the inverter is overloaded. Please refer to the handling of Err10.
1978
1979 = 10 F9 group pid function of process control =
1980
1981 PID control is a common method used in process control. It adjusts the output frequency of the inverter by performing proportional, integral, and differential calculations on the difference between the feedback signal of the controlled quantity and the target quantity signal to form a negative feedback system. The controlled amount is stable at the target amount. It is suitable for process control such as flow control, pressure control and temperature control. The basic control block diagram is as follows:
1982
1983 (% style="text-align:center" %)
1984 [[image:CHAPTER 7 FUNCTIONAL PARAMETER DETAILS_html_972dcbcc01a1c9f6.png]]
1985
1986 Figure 6-10-1 Block diagram of process PID principle
1987
1988 (% class="table-bordered" %)
1989 |(% rowspan="8" %)**F9.00**|(% colspan="3" %)PID setting source|Default|0
1990 |(% rowspan="7" %)PID setting source|0|(% colspan="3" %)F9.01
1991 |1|(% colspan="3" %)AI1
1992 |2|(% colspan="3" %)AI2
1993 |3|(% colspan="3" %)Reserved
1994 |4|(% colspan="3" %)(((
1995 Reserved
1996 )))
1997 |5|(% colspan="3" %)Communication setting
1998 |6|(% colspan="3" %)Multi-speed instructions
1999
2000 When the frequency source selects PID, that is, if F0.03 or F0.04 is selected as 8, this group of functions will work. (Please refer to function code F0.03-F0.04). This parameter determines the target quantity given channel of the process PID. The set target value of the process PID is a relative value, and the set 100% corresponds to 100% of the feedback signal of the controlled system; the PID range (F9.04) is not necessary, because no matter how much the range is set, the system will It is calculated by relative value (0~~100%). However, if the PID range is set, the actual value of the signal corresponding to the PID setting and feedback can be visually observed through the keyboard display parameters.
2001
2002 (% class="table-bordered" %)
2003 |(% rowspan="2" %)**F9.01**|(% colspan="2" %)PID digital setting|Default|50.0%
2004 |Setting range|(% colspan="3" %)0.0%~~100.0%
2005
2006 When F9.00=0 is selected, the target source is keyboard setting. This parameter needs to be set. The reference value of this parameter is the feedback amount of the system.
2007
2008 (% class="table-bordered" %)
2009 |(% rowspan="10" %)**F9.02**|(% colspan="2" %)PID feedback source|Default|0
2010 |(% rowspan="9" %)Setting range|0|(% colspan="2" %)AI1
2011 |1|(% colspan="2" %)AI2
2012 |2|(% colspan="2" %)Reserved
2013 |3|(% colspan="2" %)AI1-AI2
2014 |4|(% colspan="2" %)PULSE setting(DI6)
2015 |5|(% colspan="2" %)Communication setting
2016 |6|(% colspan="2" %)AI1+AI2
2017 |7|(% colspan="2" %)MAX(~|AI1~|,~|AI2~|)
2018 |8|(% colspan="2" %)MIN (~|AI1~|,~|AI2~|)
2019
2020 Use this parameter to select the PID feedback channel.
2021
2022 (% class="table-bordered" %)
2023 |(% rowspan="3" %)**F9.03**|(% colspan="2" %)PID controlling direction|Default|0
2024 |(% rowspan="2" %)Setting range|0|(% colspan="2" %)Positive
2025 |1|(% colspan="2" %)Negative
2026
2027 Positive effect: When the feedback signal is less than the PID setting, the inverter output frequency is required to increase in order to make the PID balance. Such as the tension PID control of winding.
2028
2029 Reverse effect: When the feedback signal is greater than the PID setting, the output frequency of the inverter is required to decrease in order to balance the PID. Such as unwinding tension PID control.
2030
2031 The effect of this function is affected by terminal function 35: PID direction.
2032
2033 (% class="table-bordered" %)
2034 |(% rowspan="2" %)**F9.04**|(% colspan="2" %)PID setting feedback range|Default|1000
2035 |Setting range|0~~65535|(% colspan="2" %)PID given feedback range is a dimensionless unit. Used as the display of PID given and feedback.
2036 |(% rowspan="2" %)**F9.05**|(% colspan="2" %)Proportional gain P1|Default|20.0
2037 |Setting range|(% colspan="3" %)0.0~~100.0
2038 |(% rowspan="2" %)**F9.06**|(% colspan="2" %)Integral time I1|Default|2.00s
2039 |Setting range|(% colspan="3" %)0.01s~~10.00s
2040 |(% rowspan="2" %)**F9.07**|(% colspan="2" %)Differential time D1|Default|0.000s
2041 |Setting range|(% colspan="3" %)0.00~~10.000
2042
2043 Proportional gain P: determines the adjustment intensity of the entire PID regulator, the greater the P, the greater the adjustment intensity. The parameter of 100 means that when the deviation between the PID feedback amount and the given amount is 100%, the adjustment range of the PID regulator to the output frequency command is the maximum frequency (ignoring the integral effect and the derivative effect).
2044
2045 Integral time I: Decide how fast the PID regulator performs integral adjustment on the deviation between the PID feedback amount and the given amount. Integral time means that when the deviation between PID feedback quantity and given quantity is 100%, the integral regulator (ignoring proportional action and differential action) is continuously adjusted after this time, and the adjustment quantity reaches the maximum frequency (F0.09). The shorter the integration time, the greater the adjustment intensity.
2046
2047 Differential time D: determines the intensity of the PID regulator to adjust the rate of change of the deviation between the PID feedback quantity and the given quantity. Differential time means that if the feedback amount changes 100% within this time, the adjustment amount of the differential regulator is the maximum frequency (F0.09) (ignoring proportional action and integral action). The longer the derivative time, the greater the adjustment intensity.
2048
2049 (% class="table-bordered" %)
2050 |(% rowspan="2" %)**F9.08**|(% colspan="2" %)PID reverse cut-off frequency|Default|0.00Hz
2051 |Setting range|(% colspan="3" %)0.00~~F0.10
2052 |(% rowspan="2" %)**F9.09**|(% colspan="2" %)PID deviation limit|Default|0.01%
2053 |(% colspan="2" %)Setting range|(% colspan="2" %)0. 0%~~100.0%
2054
2055 Deviation limit: When the PID feedback deviation is within this range, PID stops adjusting;
2056
2057 (% class="table-bordered" %)
2058 |(% rowspan="2" %)**F9.10**|PID differential limit range|Default|0.10%
2059 |Setting range|(% colspan="2" %)0.00%~~100.00%
2060 |(% rowspan="2" %)**F9.11**|PID setting change time|Default|0.00s
2061 |Setting range|(% colspan="2" %)0.00s~~650.00s
2062
2063 PID given change time refers to the time required for the actual value of PID to change from 0.0% to 100.0%.
2064
2065 When the PID setting changes, the actual value of the PID setting will not respond immediately. Moreover, it changes linearly according to the given change time to prevent the given mutation from occurring.
2066
2067 (% class="table-bordered" %)
2068 |(% rowspan="2" %)**F9.12**|PID feedback filtering time|Default|0.00s
2069 |Setting range|(% colspan="2" %)0.00s~~60.00s
2070 |(% rowspan="2" %)**F9.13**|PID output filtering time|Default|0.00s
2071 |Setting range|(% colspan="2" %)0.00s~~60.00s
2072
2073 Filter the PID feedback and output value to eliminate sudden changes.
2074
2075 (% class="table-bordered" %)
2076 |(% rowspan="2" %)**F9.14**|(% colspan="2" %)Proportional gain P2|Default|20.0
2077 |Setting range|(% colspan="3" %)0.0~~100.0
2078 |(% rowspan="2" %)**F9.15**|(% colspan="2" %)Integral time I2|Default|2.00s
2079 |Setting range|(% colspan="3" %)0.01s~~10.00s
2080 |(% rowspan="2" %)**F9.16**|(% colspan="2" %)Differential time D2|Default|0.000s
2081 |Setting range|(% colspan="3" %)0.00~~10.000
2082
2083 The setting method is similar to F9.05, F9.06, F9.07. It is used in situations where PID parameter changes are required, see F9.18 introduction.
2084
2085 (% class="table-bordered" %)
2086 |(% rowspan="4" %)**F9.17**|(% colspan="3" %)PID parameter switchover condition|Default|0
2087 |(% rowspan="3" %)Setting range|0|(% colspan="3" %)No switchover
2088 |1|(% colspan="3" %)DI terminal
2089 |2|(% colspan="3" %)Automatic switchover based on deviation
2090 |(% rowspan="2" %)**F9.18**|(% colspan="3" %)PID parameter switchover deviation 1|Default|20.0%
2091 |Setting range|(% colspan="4" %)0.0%~~F9.20
2092 |(% rowspan="2" %)**F9.19**|(% colspan="3" %)PID parameter switchover deviation 2|Default|80.0%
2093 |Setting range|(% colspan="4" %)F9.19~~100.0%
2094
2095 In some applications, a set of PID parameters may not satisfy the entire running process. At this time, multiple groups of PID parameters may need to be switched.
2096
2097 When not switching, the PID parameter is constant as parameter group 1.
2098
2099 When the DI terminal is switched, the multi-function terminal function selection is 43: When the PID parameter switching terminal and the terminal is valid, the parameter group 2 is selected, otherwise, the parameter group 1 is selected.
2100
2101 To switch automatically according to the deviation, when the deviation between the reference and the feedback is less than the PID parameter switching deviation 1 (F9.19), use F9.05, F9.06, F9.07 as the PID adjustment parameters, and the deviation between the reference and the feedback When it is greater than PID switching deviation 2 (F9.20), use F9.15, F9.16, and F9.17 as PID adjustment parameters. The PID parameters of the deviation segment between the switching deviation 1 and the switching deviation 2 are two sets of PID parameters linear switching.
2102
2103 (% class="table-bordered" %)
2104 |(% rowspan="2" %)**F9.20**|(% colspan="2" %)PID initial value|Default|0.0%
2105 |Setting range|(% colspan="3" %)0.0%~~100.0%
2106 |(% rowspan="2" %)**F9.21**|(% colspan="2" %)PID initial value holding time|Default|0.00s
2107 |Setting range|(% colspan="3" %)0.00s~~650.00s
2108
2109 When PID is running, the inverter will first run with PID initial value (F9.21) given output and the duration is F9.22 (PID initial value holding time), and then start normal PID adjustment.
2110
2111 (% class="table-bordered" %)
2112 |(% rowspan="2" %)**F9.22**|(% colspan="2" %)Two output deviation forward maximum value|Default|1.00%.
2113 |Setting range|(% colspan="3" %)0.00%~~100.00%
2114 |(% rowspan="2" %)**F9.23**|(% colspan="2" %)Two output deviation reverse maximum value|Default|1.00%
2115 |Setting range|(% colspan="3" %)0.00%~~100.00%
2116
2117 This function code is used to limit the difference between the two beats (2ms/beat) of the PID output, so as to prevent the PID output from changing too fast. F9.23 and F9.24 respectively correspond to the maximum output deviation during forward and reverse rotation.
2118
2119 (% class="table-bordered" %)
2120 |(% rowspan="7" %)**F9.24**|(% colspan="3" %)PID integral property|Default|00
2121 |(% rowspan="6" %)Setting range|Ones Place|(% colspan="3" %)Integration separation
2122 |0|(% colspan="3" %)Disabled
2123 |1|(% colspan="3" %)Enabled
2124 |Tens Place|(% colspan="3" %)Output to limit value
2125 |0|(% colspan="3" %)Continue the integral
2126 |1|(% colspan="3" %)Stop the integral
2127
2128 Integration separation
2129
2130 When it is valid, if terminal function 22: integral pause is valid, the PID integral operation will stop. Only proportional and derivative are calculated.
2131
2132 Output to limit value
2133
2134 If it is to stop integration, when the PID output value reaches the maximum or minimum value, the PID integration stops calculating.
2135
2136 If it is continuous integration, the PID integration will be calculated at any time
2137
2138 (% class="table-bordered" %)
2139 |(% rowspan="2" %)**F9.25**|(% colspan="2" %)Detection value of PID feedback loss|Default|0.0%
2140 |Setting range|(% colspan="3" %)(((
2141 0.0%:No judging feedback loss
2142
2143 0.1%~~100.0%
2144 )))
2145 |(% rowspan="2" %)**F9.26**|(% colspan="2" %)Detection time of PID feedback loss|Default|0.0s
2146 |Setting range|(% colspan="3" %)0.0s~~20.0s
2147
2148 This function code is used to judge whether PID feedback is lost. When the PID feedback is less than the feedback loss detection value (F9.26) and the duration reaches F9.27 (feedback loss detection time), the inverter reports a fault and runs according to the fault handling method.
2149
2150 (% class="table-bordered" %)
2151 |(% rowspan="3" %)**F9.27**|(% colspan="3" %)PID operation at stop|Default|0
2152 |(% rowspan="2" %)Setting range|0|(% colspan="3" %)No PID operation at stop
2153 |1|(% colspan="3" %)PID operation at stop
2154
2155 (% class="table-bordered" %)
2156 |(% rowspan="3" %)**F9.28**|(% colspan="2" %)PID function selection|Default|0
2157 |(% rowspan="2" %)Setting range|0|(% colspan="2" %)Normal PID
2158 |1|(% colspan="2" %)Sleep PID
2159
2160 0: The inverter runs under normal PID control and the sleep function is invalid.
2161
2162 1: The inverter runs under sleep PID control, and the sleep function is enabled.
2163
2164 (% class="table-bordered" %)
2165 |(% rowspan="2" %)**F9.29**|PID sleep threshold|Default|60.0%
2166 |Setting range|(% colspan="2" %)0.0%~~100.0%
2167 |(% rowspan="2" %)**F9.30**|PID sleep delay|Default|3.0s
2168 |Setting range|(% colspan="2" %)0.0~~3600s
2169 |(% rowspan="2" %)**F9.31**|PID wake-up threshold|Default|20.0%
2170 |Setting range|(% colspan="2" %)0.0%~~100.0%
2171 |(% rowspan="2" %)**F9.32**|PID wake-up time delay|Default|3.0s
2172 |PID wake-up time delay|(% colspan="2" %)0.0~~3600s
2173
2174 When the sleep PID is selected, if the feedback is higher than the setting of F9.29 sleep threshold, the inverter will start the sleep timer. After the sleep delay time set by F9.30, if the feedback amount is still higher than the setting of F9.29 If the feedback is lower than the setting of the wake-up threshold of F9.31, the inverter will start the wake-up timer. After the time set by F9.32 wake-up delay, if the feedback If it is still lower than the set value of F9.31 wake-up threshold, the wake-up is successful and PID control is performed. Refer to Figure 6-22 below to understand the relationship between the above parameters.
2175
2176 (% style="text-align:center" %)
2177 [[image:CHAPTER 7 FUNCTIONAL PARAMETER DETAILS_html_229dff56f8f13b95.png]]
2178
2179 Figure 6-10-2 PID sleep and wake-up timing diagram
2180
2181 = 11 FA group faults & protection =
2182
2183 (% class="table-bordered" %)
2184 |(% rowspan="3" %)**FA.00**|Motor overload protection selection|Default|1
2185 |(% rowspan="2" %)Setting range|0|Disabled
2186 |1|Enabled
2187
2188 Choose 0: The inverter has no overload protection for the load motor, at this time the thermal relay shall be added in front of the motor;
2189
2190 Choose 1: At this time, the inverter has overload protection function for the motor. See FA.01 for protection value.
2191
2192 (% class="table-bordered" %)
2193 |(% rowspan="2" %)**FA.01**|Motor overload protection gain|Default|1.00
2194 |Setting range|(% colspan="2" %)0.20~~10.00
2195
2196 Motor overload protection is an inverse time curve; 220%×(FA.01)×motor rated current for 1 minute, 150%×(FA.01)×motor rated current for 60 minutes.
2197
2198 (% class="table-bordered" %)
2199 |(% rowspan="2" %)**FA.02**|Motor overload warning coefficient|Default|80%
2200 |Setting range|(% colspan="2" %)50%~~100%
2201
2202 The reference value of this value is the motor overload current. When the inverter detects that the output current reaches (FA.02) × motor overload current and continues for the specified time on the inverse time curve, it outputs a pre-alarm signal from DO or relay.
2203
2204 (% class="table-bordered" %)
2205 |(% rowspan="2" %)**FA.03**|Overvoltage stall gain|Default|10
2206 |Setting range|(% colspan="2" %)0 (Invalid)~~100
2207
2208 Adjust the inverter's ability to suppress overvoltage stall. The larger the value, the stronger the ability to suppress overvoltage.
2209
2210 For loads with small inertia, this value should be small, otherwise the dynamic response of the system will slow down.
2211
2212 For loads with large inertia, this value should be large, otherwise the suppression effect is not good, and overvoltage faults may occur.
2213
2214 (% class="table-bordered" %)
2215 |(% rowspan="2" %)**FA.04**|Overvoltage stall protective voltage|Default|130%
2216 |Setting range|(% colspan="2" %)120%~~150%(3 phase)
2217
2218 Select the protection point of the overvoltage stall function. When this value is exceeded, the inverter starts to perform the over-voltage stall protection function.
2219
2220 (% class="table-bordered" %)
2221 |(% rowspan="2" %)**FA.05**|Overcurrent stall gain|Default|Model dependent
2222 |Setting range|0~~100|
2223
2224 Adjust the inverter's ability to suppress excessive stall speed. The larger the value, the stronger the ability to suppress overcurrent.
2225
2226 For loads with small inertia, this value should be small, otherwise the dynamic response of the system will slow down.
2227
2228 For loads with large inertia, this value should be large, otherwise the suppression effect is not good, and overcurrent faults may occur.
2229
2230 (% class="table-bordered" %)
2231 |(% rowspan="2" %)**FA.06**|Overvoltage stall protective current|Default|150%
2232 |Setting range|(% colspan="2" %)100%~~200%
2233
2234 Select the current protection point for the over-current stall function. When this value is exceeded, the inverter starts to perform the overcurrent stall protection function.
2235
2236 (% class="table-bordered" %)
2237 |(% rowspan="3" %)**FA.07**|(% colspan="2" %)Short-circuit to ground upon power-on|Default|1
2238 |(% rowspan="2" %)Setting range|0|(% colspan="2" %)Disabled
2239 |1|(% colspan="2" %)Enabled
2240
2241 The inverter can be selected to detect whether the motor has a ground protection short-circuit fault when the inverter is powered on. If this function is valid, the inverter will output for a short time at the moment of power-on.
2242
2243 (% class="table-bordered" %)
2244 |(% rowspan="2" %)**FA.08**|Fault auto reset times|Default|0
2245 |Setting range|(% colspan="2" %)0~~5
2246
2247 When the inverter selects automatic fault reset, it is used to set the number of times that can be reset automatically. If the value exceeds this value, the inverter will be on standby and waiting for repair.
2248
2249 (% class="table-bordered" %)
2250 |(% rowspan="2" %)**FA.09**|Relay action during fault auto reset|Default|0
2251 |Setting range|(% colspan="2" %)0:Disabled; 1:Enabled
2252
2253 After selecting the inverter fault automatic reset function, during the execution of the fault reset, through this parameter setting, you can decide whether the fault relay is required to act, so as to shield the fault alarm caused by this and make the equipment continue to run.
2254
2255 (% class="table-bordered" %)
2256 |(% rowspan="2" %)**FA.10**|(% colspan="2" %)Time interval of fault auto reset|Default|1.0s
2257 |Setting range|(% colspan="3" %)0.1s~~100.0s
2258
2259 The waiting time for the inverter from the fault alarm to the automatic reset of the fault.
2260
2261 (% class="table-bordered" %)
2262 |(% rowspan="2" %)**FA.11**|(% colspan="2" %)Input phase loss protection|Default|Model dependent
2263 |Setting range|(% colspan="3" %)(((
2264 0:Disabled
2265
2266 1:Enabled
2267 )))
2268
2269 Choose whether to protect the input phase loss.
2270
2271 (% class="table-bordered" %)
2272 |(% rowspan="2" %)**FA.12**|(% colspan="2" %)Output phase loss protection|Default|1
2273 |Setting range|(% colspan="3" %)(((
2274 0:Disabled
2275
2276 1:Enabled
2277 )))
2278
2279 Choose whether to protect the output phase loss.
2280
2281 (% class="table-bordered" %)
2282 |(% rowspan="9" %)**FA.13**|(% colspan="2" style="width:442px" %)Fault protection action selection 1|(% style="width:451px" %)Default|(% colspan="2" %)00000
2283 |(% rowspan="8" %)Setting range|(% style="width:316px" %)Ones Place|(% colspan="3" style="width:978px" %)Motor Overload(Err11)
2284 |(% style="width:316px" %)0|(% colspan="3" style="width:978px" %)Free stopping
2285 |(% style="width:316px" %)1|(% colspan="3" style="width:978px" %)Stop according to the stop mode
2286 |(% style="width:316px" %)2|(% colspan="3" style="width:978px" %)Continue to run
2287 |(% style="width:316px" %)Tens Place|(% colspan="3" style="width:978px" %)Input Phase Loss(Err12) (0~~2,as ones place)
2288 |(% style="width:316px" %)Hundr-eds Place|(% colspan="3" style="width:978px" %)Output Phase Loss (Err13) (0~~2,as ones place)
2289 |(% style="width:316px" %)Thous-ands Place|(% colspan="3" style="width:978px" %)External Fault(Err15) (0~~2,as ones place)
2290 |(% style="width:316px" %)Ten thous-ands Place|(% colspan="3" style="width:978px" %)Communication Fault(Err16) (0~~2,as ones place)
2291 |(% rowspan="11" %)**FA.14**|(% colspan="2" style="width:442px" %)Reserved|(% style="width:451px" %)Default|(% colspan="2" %)
2292 |(% rowspan="10" %)Setting range|(% style="width:316px" %)Ones Place|(% colspan="3" style="width:978px" %)Reserved
2293 |(% style="width:316px" %)0|(% colspan="3" style="width:978px" %)Reserved
2294 |(% style="width:316px" %)1|(% colspan="3" style="width:978px" %)Reserved
2295 |(% style="width:316px" %)2|(% colspan="3" style="width:978px" %)Reserved
2296 |(% style="width:316px" %)Tens Place|(% colspan="3" style="width:978px" %)Reserved
2297 |(% style="width:316px" %)0|(% colspan="3" style="width:978px" %)Reserved
2298 |(% style="width:316px" %)1|(% colspan="3" style="width:978px" %)Reserved
2299 |(% style="width:316px" %)Hundr-eds Place|(% colspan="3" style="width:978px" %)Reserved
2300 |(% style="width:316px" %)Thous-ands Place|(% colspan="3" style="width:978px" %)Reserved
2301 |(% style="width:316px" %)Ten thous-ands Place|(% colspan="3" style="width:978px" %)Reserved
2302 |(% rowspan="9" %)**FA.15**|(% colspan="2" style="width:442px" %)Fault protection action selection 3|(% style="width:451px" %)Default|(% colspan="2" %)00000
2303 |(% rowspan="7" %)Setting range|(% style="width:316px" %)Ones Place|(% colspan="3" style="width:978px" %)User-defined fault 1(Err27) (0~~2,as ones place of FA.13)
2304 |(% style="width:316px" %)Tens Place|(% colspan="3" style="width:978px" %)User-defined fault 2(Err28) (0~~2,as ones place of FA.13)
2305 |(% style="width:316px" %)Hundr-eds Place|(% colspan="3" style="width:978px" %)Powering on time reached(Err29) (0~~2,as ones place of FA.13)
2306 |(% style="width:316px" %)Thous-ands Place|(% colspan="3" style="width:978px" %)Load loss(Err30)
2307 |(% style="width:316px" %)0|(% colspan="3" style="width:978px" %)Free stopping
2308 |(% style="width:316px" %)1|(% colspan="3" style="width:978px" %)Stop according to the stop mode
2309 |(% style="width:316px" %)2|(% colspan="3" style="width:978px" %)Decelerate to 7% of the rated frequency of the motor and continue to run, and automatically return to the set frequency if the load is not lost
2310 | |(% style="width:316px" %)Ten thous-ands Place|(% colspan="3" style="width:978px" %)(((
2311 PID feedback loss during
2312
2313 Running (Err31) (0~~2,as ones place of FA.13)
2314 )))
2315 |(% rowspan="6" %)**FA.16**|(% colspan="2" style="width:442px" %)(((
2316 Overcurrent stall Integral coefficient
2317 )))|(% colspan="2" style="width:451px" %)Default|500
2318 |(% rowspan="5" %)Setting range|(% colspan="4" rowspan="5" %)1~~2000
2319
2320 set overcurrent stall Integral coefficient rate.
2321
2322 When “free stop” is selected: the inverter prompts Err~*~* and stops directly.
2323
2324 When "Stop according to stop mode" is selected: the inverter prompts A~*~* and stops according to the stop mode, and prompts ErrXX after stopping.
2325
2326 When “continue running” is selected: the inverter continues to run and prompts A~*~*. For the running frequency, refer to the description of FA.20 and FA.21.
2327
2328 (% class="table-bordered" %)
2329 |(% rowspan="2" %)(((
2330 FA.17
2331 )))|(((
2332 Undervoltage setting
2333 )))|(((
2334 Default
2335 )))|(((
2336 100.0%
2337 )))
2338 |(((
2339 Setting range
2340 )))|(% colspan="2" rowspan="1" %)(((
2341 60.0%~~140.0%
2342 )))
2343
2344 Instantaneous power failure mode selection
2345
2346 (% class="table-bordered" %)
2347 |(% rowspan="2" %)**FA.18**|Undervoltage setting|Default|100.0%
2348 |Setting range|(% colspan="2" %)60.0%~~140.0%
2349
2350 Adjusting this parameter can adjust the voltage point at which the inverter reports undervoltage fault (Err09), and 100.0% corresponds to 350V.
2351
2352 (% class="table-bordered" %)
2353 |(% rowspan="2" %)**FA.19**|Overvoltage setting|Default|810.0V
2354 |Setting range|(% colspan="2" %)200.0V ~~ 2500.0V
2355
2356 Generally, this parameter is not adjusted after the inverter leaves the factory. If there is frequent overvoltage during operation, please consult the manufacturer's customer service department before making adjustments.
2357
2358 (% class="table-bordered" %)
2359 |(% rowspan="6" %)**FA.20**|(% colspan="2" %)Continue running frequency selection during failure|Default|0
2360 |(% rowspan="5" %)Setting range|0|(% colspan="2" %)Run with the current run frequency
2361 |1|(% colspan="2" %)Run with the setting frequency
2362 |2|(% colspan="2" %)Run with the upper limit frequency
2363 |3|(% colspan="2" %)Run with lower limit frequency.
2364 |4|(% colspan="2" %)(((
2365 Run with standby frequency when abnormal
2366
2367 (FA.21)
2368 )))
2369 |(% rowspan="2" %)**FA.21**|(% colspan="2" %)Abnormal standby frequency setting|Default|100.0%(Current set frequency)
2370 |(% colspan="2" %)Setting range|(% colspan="2" %)60.0%~~100.0%
2371
2372 When a fault occurs during the operation of the inverter and the fault handling method is keep running, the inverter prompts A~*~* and runs at the set frequency determined by this function.
2373
2374 (% class="table-bordered" %)
2375 |(% rowspan="4" %)**FA.22**|(% colspan="2" %)Action selection at instantaneous power failure|Default|0
2376 |(% rowspan="3" %)Setting range|0|(% colspan="2" %)Invalid
2377 |1|(% colspan="2" %)Stop as Deceleration time 1
2378 |2|(% colspan="2" %)Stop as Deceleration time 2
2379 |(% rowspan="2" %)**FA.23**|(% colspan="2" %)Action pause judging voltage at instantaneous power failure|Default|90.0%
2380 |(% colspan="2" %)Setting range|(% colspan="2" %)80.0%~~100.0%(Standard Bus Voltage)
2381 |(% rowspan="2" %)**FA.24**|(% colspan="2" %)Voltage rally judging time at instantaneous power failure|Default|0.50s
2382 |(% colspan="2" %)Setting range|(% colspan="2" %)0.00s~~100.00s
2383 |(% rowspan="2" %)**FA.25**|(% colspan="2" %)Action judging voltage at instantaneous power failure|Default|80.0%
2384 |(% colspan="2" %)Setting range|(% colspan="2" %)60.0%~~100.0%( Standard Bus Voltage)
2385
2386 This function means that the inverter will not stop when the power is cut instantaneously. In the case of an instantaneous power failure or a sudden voltage drop, the inverter will reduce its output speed, and compensate for the voltage drop by feeding back energy through the load to keep the inverter running in a short time.
2387
2388 If the instantaneous stop non-stop function selection is valid, when the bus voltage is lower than the voltage indicated by the instantaneous stop non-stop action judgment voltage (FA.25), the inverter will decelerate according to the instantaneous stop action selection. When the stop action judgment voltage (FA.25) represents the voltage, and the duration is maintained for the momentary stop and non-stop voltage rise judgment time (FA.24), the inverter resumes the set frequency operation; otherwise the inverter will continue to reduce the operating frequency to Stop at 0 o'clock. Instantaneous stop non-stop function if shown.
2389
2390 The deceleration time of instantaneous power failure is too long, the load feedback energy is small, and the low voltage can not be effectively compensated; the deceleration time is too short, the load feedback energy is large, which will cause overvoltage protection. Please adjust the deceleration time appropriately according to the load inertia and the weight of the load.
2391
2392 (% class="table-bordered" %)
2393 |(% rowspan="3" %)**FA.26**|(% colspan="2" %)Loss of loads protection options|Default|0
2394 |(% rowspan="2" %)Setting range|0|(% colspan="2" %)Disabled
2395 |1|(% colspan="2" %)Enabled
2396 |(% rowspan="2" %)**FA.27**|(% colspan="2" %)Loss of loads detection level|Default|10.0%
2397 |(% colspan="2" %)Setting range|(% colspan="2" %)0.0%~~100.0%(Motor rated current)
2398 |(% rowspan="2" %)**FA.28**|(% colspan="2" %)Loss of loads detection time|Default|1.0s
2399 |(% colspan="2" %)Setting range|(% colspan="2" %)0.0s~~60.0s
2400
2401 If this function is valid, when the inverter loses load, the inverter reports Err30 fault, and the output frequency is 7% of the rated frequency; if the load is restored, it will run at the set frequency. The off-load detection level and detection time can be set.
2402
2403 (% class="table-bordered" %)
2404 |(% rowspan="6" %)**FA.29**|(% colspan="2" %)The decimal point of the frequency in failure state|Default|222
2405 |(% rowspan="5" %)Setting range|Ones Place|(% colspan="2" %)The third fault frequency decimal point
2406 |1|(% colspan="2" %)1 decimal point
2407 |2|(% colspan="2" %)2 decimal point
2408 |Tens Place|(% colspan="2" %)The second fault frequency decimal point (1~~2,as ones place)
2409 |Hundreds Place|(% colspan="2" %)The first fault frequency decimal point (1~~2,as ones place)
2410
2411 Since the frequency decimal point can be set, this function code is used to record the position of the decimal point of the frequency at the time of failure (for frequency display during failure).
2412
2413 Note: The function code display data is H.xxx, where H. means hexadecimal data.
2414
2415 = 12 FB group frequency swing, length fixing and counting =
2416
2417 The swing frequency function is suitable for textile, chemical fiber and other industries and occasions that require traverse and winding functions.
2418
2419 Swing frequency function means that the output frequency of the inverter swings up and down around the set frequency (frequency command is selected by F0.07). The trajectory of the running frequency on the time axis is shown in the figure below, where the swing amplitude is determined by FB.00 and FB. 01 setting, when FB.01 is set to 0, that is, the swing amplitude is 0, and the swing frequency has no effect.
2420
2421 (% style="text-align:center" %)
2422 [[image:CHAPTER 7 FUNCTIONAL PARAMETER DETAILS_html_1c70827204f62468.png]]
2423
2424 Figure 6-12-1 Schematic diagram of swing frequency work
2425
2426 (% class="table-bordered" %)
2427 |(% rowspan="3" %)**FB.00**|(% colspan="2" %)Swing frequency setting mode|Default|0
2428 |(% rowspan="2" %)Setting range|0|(% colspan="2" %)Relative to the central frequency
2429 |1|(% colspan="2" %)Relative to the maximum frequency
2430
2431 Use this parameter to determine the reference amount of swing.
2432
2433 0: Relative to the center frequency (F0.07 frequency source selection), a variable swing amplitude system. The swing amplitude changes with the center frequency (set frequency).
2434
2435 1: Relative to the maximum frequency (F0.10 maximum output frequency), it is a fixed swing amplitude system.
2436
2437 (% class="table-bordered" %)
2438 |(% rowspan="2" %)**FB.01**|(% colspan="2" %)Swing frequency amplitude|Default|0.0%
2439 |Setting range|(% colspan="3" %)0.0%~~100.0%
2440 |(% rowspan="2" %)**FB.02**|(% colspan="2" %)Jump frequency amplitude|Default|0.0%
2441 |Setting range|(% colspan="3" %)0.0%~~50.0%
2442
2443 Use this parameter to determine the swing amplitude and kick frequency. The swing frequency operation frequency is restricted by the upper and lower limit frequencies.
2444
2445 The swing amplitude is relative to the center frequency (variable swing amplitude, select FB.00=0): swing amplitude AW = frequency source F0.07 × swing amplitude FB.01.
2446
2447 The swing amplitude is relative to the maximum frequency (fixed swing amplitude, select FB.00=1): swing amplitude AW = maximum frequency F0.10× swing amplitude FB.01.
2448
2449 Kick frequency = swing amplitude AW × sudden jump frequency amplitude FB.02. That is, when the swing frequency is running, the value of the kick frequency relative to the swing amplitude.
2450
2451 If the swing amplitude is relative to the center frequency (variable swing amplitude, select FB.00=0), the kick frequency is the variable value.
2452
2453 If the swing amplitude is relative to the maximum frequency (fixed swing amplitude, select FB.00=1), the kick frequency is a fixed value.
2454
2455 (% class="table-bordered" %)
2456 |(% rowspan="2" %)**FB.03**|(% colspan="2" %)Swing frequency cycle|Default|10.0s
2457 |Setting range|(% colspan="3" %)0.0s~~3000.0s
2458 |(% rowspan="2" %)**FB.04**|(% colspan="2" %)Triangular wave rising time coefficient|Default|50.0%
2459 |Setting range|(% colspan="3" %)0.0%~~100.0%
2460
2461 Swing frequency cycle: the time value of a complete swing frequency cycle. FB.04 triangle wave rise time coefficient is relative to FB.03 swing frequency period.
2462
2463 Triangular wave rise time = swing frequency period FB.03 × triangular wave rise time coefficient FB.04 (unit: s)
2464
2465 Triangular wave falling time = swing frequency period FB.03 × (1-triangular wave rising time coefficient FB.04) (unit: s)
2466
2467 (% class="table-bordered" %)
2468 |(% rowspan="2" %)**FB.05**|Setting length|Default|1000m
2469 |Setting range|(% colspan="2" %)0m~~65535m
2470 |(% rowspan="2" %)**FB.06**|Actual length|Default|0m
2471 |Setting range|(% colspan="2" %)0m~~65535m
2472 |(% rowspan="2" %)**FB.07**|Number of pulses per meter|Default|100.0
2473 |Setting range|(% colspan="2" %)0.1~~6553.5
2474
2475 The three function codes of set length, actual length and number of pulses per m are mainly used for fixed length control. The length is calculated by the pulse signal input from the digital input terminal, and the corresponding input terminal needs to be set as the length counting input terminal. Generally, when the pulse frequency is high, DI5 input is required.
2476
2477 Actual length = length count input pulse number / pulse number per m
2478
2479 When the actual length FB.06 exceeds the set length FB.05, the multi-function digital output terminal "length reach terminal" will output ON signal (please refer to F1.04 function code)
2480
2481 (% class="table-bordered" %)
2482 |(% rowspan="2" %)**FB.08**|(% colspan="2" %)Set count value|Default|1000
2483 |Setting range|(% colspan="3" %)1~~65535
2484 |(% rowspan="2" %)**FB.09**|(% colspan="2" %)Designated count value|Default|1000
2485 |Setting range|(% colspan="3" %)1~~65535
2486
2487 The count value is counted by inputting the pulse signal from the counter input terminal in the multi-function switch input terminal.
2488
2489 When the count value reaches the set count value, the switch output terminal outputs a signal that the set count value has reached. The counter stops counting.
2490
2491 When the count value reaches the designated count value, the switch output terminal outputs a signal that the designated count value has reached. The counter continues to count and stops at the "set count value".
2492
2493 The designated count value FB.09 should not be greater than the set count value FB.08.
2494
2495 This function is as below:
2496
2497 (% style="text-align:center" %)
2498 [[image:CHAPTER 7 FUNCTIONAL PARAMETER DETAILS_html_3afe609068e8ab4b.png]]
2499
2500 Figure 6-12-2 Schematic diagram of set count value given and designated count value given
2501
2502 = 13 FC group communication parameters =
2503
2504 (% class="table-bordered" %)
2505 |(% rowspan="2" %)**FC.00**|Local address|Default|1
2506 |Setting range|(% colspan="2" %)00~~247
2507
2508 When the local address is set to 0, it is the broadcast address, which realizes the broadcast function of the host computer. The address of this machine is unique (except the broadcast address), which is the basis for the point-to-point communication between the host computer and the inverter.
2509
2510 (% class="table-bordered" %)
2511 |(% rowspan="9" %)**FC.01**|Baud Rate|(% colspan="2" %)Default|5
2512 |(% rowspan="8" %)Setting range|0|(% colspan="2" %)300 bps
2513 |1|(% colspan="2" %)600 bps
2514 |2|(% colspan="2" %)1200 bps
2515 |3|(% colspan="2" %)2400 bps
2516 |4|(% colspan="2" %)4800 bps
2517 |5|(% colspan="2" %)9600 bps
2518 |6|(% colspan="2" %)19200 bps
2519 |7|(% colspan="2" %)38400 bps
2520
2521 This parameter is used to set the data transmission rate between the host computer and the inverter. Note that the baud rate set by the host computer and the inverter must be consistent, otherwise, the communication cannot be carried out. The greater the baud rate, the faster the communication speed.
2522
2523 (% class="table-bordered" %)
2524 |(% rowspan="5" %)**FC.02**|Data format|Default|3
2525 |(% rowspan="4" %)Setting range|0|No check, data format <8,N,2>
2526 |1|Even parity check, data format <8,E,1>
2527 |2|Odd Parity check, data format <8,0,1>
2528 |3|No check, data format <8,N,1>
2529
2530 The data format set by the host computer and the inverter must be same, otherwise, the communication cannot be carried out.
2531
2532 (% class="table-bordered" %)
2533 |(% rowspan="2" %)**FC.03**|Response delay|Default|2ms
2534 |Setting range|(% colspan="2" %)0~~20ms
2535
2536 Response delay: refers to the intermediate time between the end of the inverter data receiving and the sending of data to the upper computer. If the response delay is less than the system processing time, the response delay is based on the system processing time. If the response delay is longer than the system processing time, the system will wait after processing the data until the response delay time expires before going to the upper computer. send data.
2537
2538 (% class="table-bordered" %)
2539 |(% rowspan="2" %)**FC.04**|Communication timeout|Default|0.0 s
2540 |Setting range|(% colspan="2" %)0.0 s(Invalid),0.1~~60.0s
2541
2542 When the function code is set to 0.0 s, the communication timeout time parameter is invalid.
2543
2544 When the function code is set to a valid value, if the interval between one communication and the next communication exceeds the communication timeout time, the system will report a communication failure error (Err16). Under normal circumstances, it is set to invalid. If you set the secondary parameters in a continuous communication system, you can monitor the communication status.
2545
2546 (% class="table-bordered" %)
2547 |(% rowspan="3" %)**FC.05**|Communication reading current resolution|Default|0
2548 |(% rowspan="2" %)Setting range|0|0.01A
2549 |1|0.1A
2550
2551 Used to determine the output unit of the current value when the communication reads the output current.
2552
2553 = 14 FD group muti-stage speed and simple plc functions =
2554
2555 The simple PLC function is that the inverter has a programmable controller (PLC) built in to complete automatic control of multi-segment frequency logic. The running time, running direction and running frequency can be set to meet the technological requirements. This series of inverters can realize 16-speed change control, and there are 4 kinds of acceleration and deceleration time for selection. When the set PLC completes a cycle, an ON signal can be output from the multifunctional digital output terminals DO1 and DO2 or multifunctional relay 1 and relay 2. See F1.02~~F1.05 for details. When the frequency source selection F0.07, F0.03, F0.04 is determined as the multi-speed operation mode, it is necessary to set FD.00~~FD.15 to determine its characteristics.
2556
2557 (% class="table-bordered" %)
2558 |(% rowspan="2" %)**FD.00**|Multistage Speed0|Default|0.0%
2559 |Setting range|(% colspan="2" %)-100.0%~~100.0%; 100.0% for maximum frequency (F0.10)
2560 |(% rowspan="2" %)**FD.01**|Multistage Speed1|Default|0.0%
2561 |Setting range|(% colspan="2" %)-100.0%~~100.0%
2562 |(% rowspan="2" %)**FD.02**|Multistage Speed2|Default|0.0%
2563 |Setting range|(% colspan="2" %)-100.0%~~100.0%
2564 |(% rowspan="2" %)**FD.03**|Multistage Speed3|Default|0.0%
2565 |Setting range|(% colspan="2" %)-100.0%~~100.0%
2566 |(% rowspan="2" %)**FD.04**|Multistage Speed4|Default|0.0%
2567 |Setting range|(% colspan="2" %)-100.0%~~100.0%
2568 |(% rowspan="2" %)**FD.05**|Multistage Speed5|Default|0.0%
2569 |Setting range|(% colspan="2" %)-100.0%~~100.0%
2570 |(% rowspan="2" %)**FD.06**|Multistage Speed6|Default|0.0%
2571 |Setting range|(% colspan="2" %)-100.0%~~100.0%
2572 |(% rowspan="2" %)**FD.07**|Multistage Speed7|Default|0.0%
2573 |Setting range|(% colspan="2" %)-100.0%~~100.0%
2574 |(% rowspan="2" %)**FD.08**|Multistage Speed8|Default|0.0%
2575 |Setting range|(% colspan="2" %)-100.0%~~100.0%
2576 |(% rowspan="2" %)**FD.09**|Multistage Speed9|Default|0.0%
2577 |Setting range|(% colspan="2" %)-100.0%~~100.0%
2578 |(% rowspan="2" %)**FD.10**|Multistage Speed10|Default|0.0Hz
2579 |Setting range|(% colspan="2" %)-100.0%~~100.0%
2580 |(% rowspan="2" %)**FD.11**|Multistage Speed11|Default|0.0%
2581 |Setting range|(% colspan="2" %)-100.0%~~100.0%
2582 |(% rowspan="2" %)**FD.12**|Multistage Speed12|Default|0.0%
2583 |Setting range|(% colspan="2" %)-100.0%~~100.0%
2584 |(% rowspan="2" %)**FD.13**|Multistage Speed13|Default|0.0%
2585 |Setting range|(% colspan="2" %)-100.0%~~100.0%
2586 |(% rowspan="2" %)**FD.14**|Multistage Speed14|Default|0.0%
2587 |Setting range|(% colspan="2" %)-100.0%~~100.0%
2588 |(% rowspan="2" %)**FD.15**|Multistage Speed15|Default|0.0%
2589 |Setting range|(% colspan="2" %)-100.0%~~100.0%
2590
2591 When the frequency source parameters F0.07, F0.03, F0.04 are determined to be the PLC operation mode, you need to set FD.00 ~~ FD.15, FD.16, FD.17, FD.18 ~~ FD.49 to determine them. characteristic.
2592
2593 Note: The symbols of FD.00~~FD.15 determine the running direction of the simple PLC. If it is negative, it means running in the reverse direction.
2594
2595 Simple PLC schematic diagram:
2596
2597 (% class="table-bordered" %)
2598 |(% rowspan="4" %)**FD.16**|(% colspan="2" %)Simple PLC running mode|Default|0
2599 |(% rowspan="3" %)Setting range|0|(% colspan="2" %)Stop after the AC Drive runs one cycle
2600 |1|(% colspan="2" %)Keep final values after the AC Drive runs one cycle(running frequency)
2601 |2|(% colspan="2" %)Repeat after the AC Drive runs one cycle
2602 |(% rowspan="7" %)**FD.17**|(% colspan="2" %)Simple PLC retentive selection|Default|00
2603 |(% rowspan="6" %)Setting range|Ones place|(% colspan="2" %)(Retentive upon power failure)
2604 |0|(% colspan="2" %)No
2605 |1|(% colspan="2" %)Yes
2606 |Tens place|(% colspan="2" %)(Retentive upon stop)
2607 |0|(% colspan="2" %)No
2608 |1|(% colspan="2" %)Yes
2609
2610 PLC operation mode
2611
2612 **0: Stop after the AC Drive runs one cycle**
2613
2614 After the inverter completes a single cycle, it stops automatically, and it needs to be given a run command again to start.
2615
2616 **1: Keep final values after the AC Drive runs one cycle(running frequency)**
2617
2618 After the inverter completes a single cycle, it automatically maintains the operating frequency and direction of the last segment.
2619
2620 **2: Repeat after the AC Drive runs one cycle**
2621
2622 After the inverter completes one cycle, it will automatically start the next cycle until the system stops when there is a stop command.
2623
2624 **3: Retentive upon power failure**
2625
2626 PLC power-down memory refers to memorizing the operation stage and frequency of PLC before power-off.
2627
2628 **4: Retentive upon stop**
2629
2630 PLC stop memory is to record the previous PLC running stage and running frequency when stopping.
2631
2632 (% class="table-bordered" %)
2633 |(% rowspan="2" %)**FD.18**|(% colspan="2" %)Running time of simple PLC reference 0|Default|0.0s(h)
2634 |(% colspan="2" %)Setting range|(% colspan="2" %)0.0s(h)~~6553.5s(h)
2635 |(% rowspan="2" %)**FD.19**|(% colspan="2" %)Acceleration/deceleration time of simple PLC reference 0|Default|0
2636 |(% colspan="2" %)Setting range|(% colspan="2" %)0~~3
2637 |(% rowspan="2" %)**FD.20**|(% colspan="2" %)Running time of simple PLC reference 1|Default|0.0s(h)
2638 |(% colspan="2" %)Setting range|(% colspan="2" %)0.0s(h)~~6553.5s(h)
2639 |(% rowspan="2" %)**FD.21**|(% colspan="2" %)Acceleration/deceleration time of simple PLC reference 1|Default|0
2640 |(% colspan="2" %)Setting range|(% colspan="2" %)0~~3
2641 |(% rowspan="2" %)**FD.22**|(% colspan="2" %)Running time of simple PLC reference 2|Default|0.0s(h)
2642 |(% colspan="2" %)Setting range|(% colspan="2" %)0.0s(h)~~6553.5s(h)
2643 |(% rowspan="2" %)**FD.23**|(% colspan="2" %)Acceleration/deceleration time of simple PLC reference 2|Default|0
2644 |(% colspan="2" %)Setting range|(% colspan="2" %)0~~3
2645 |(% rowspan="2" %)**FD.24**|(% colspan="2" %)Running time of simple PLC reference 3|Default|0.0s(h)
2646 |(% colspan="2" %)Setting range|(% colspan="2" %)0.0s(h)~~6553.5s(h)
2647 |(% rowspan="2" %)**FD.25**|(% colspan="2" %)Acceleration/deceleration time of simple PLC reference 3|Default|0
2648 |(% colspan="2" %)Setting range|(% colspan="2" %)0~~3
2649 |(% rowspan="2" %)**FD.26**|(% colspan="2" %)Running time of simple PLC reference 4|Default|0.0s(h)
2650 |(% colspan="2" %)Setting range|(% colspan="2" %)0.0s(h)~~6553.5s(h)
2651 |(% rowspan="2" %)**FD.27**|(% colspan="2" %)Acceleration/deceleration time of simple PLC reference 4|Default|0
2652 |(% colspan="2" %)Setting range|(% colspan="2" %)0~~3
2653 |(% rowspan="2" %)**FD.28**|(% colspan="2" %)Running time of simple PLC reference 5|Default|0.0s(h)
2654 |(% colspan="2" %)Setting range|(% colspan="2" %)0.0s(h)~~6553.5s(h)
2655 |(% rowspan="2" %)**FD.29**|(% colspan="2" %)Acceleration/deceleration time of simple PLC reference 5|Default|0
2656 |(% colspan="2" %)Setting range|(% colspan="2" %)0~~3
2657 |(% rowspan="2" %)**FD.30**|(% colspan="2" %)Running time of simple PLC reference 6|Default|0.0s(h)
2658 |(% colspan="2" %)Setting range|(% colspan="2" %)0.0s(h)~~6553.5s(h)
2659 |(% rowspan="2" %)**FD.31**|(% colspan="2" %)Acceleration/deceleration time of simple PLC reference 6|Default|0
2660 |(% colspan="2" %)Setting range|(% colspan="2" %)0~~3
2661 |(% rowspan="2" %)**FD.32**|(% colspan="2" %)Running time of simple PLC reference 7|Default|0.0s(h)
2662 |(% colspan="2" %)Setting range|(% colspan="2" %)0.0s(h)~~6553.5s(h)
2663 |(% rowspan="2" %)**FD.33**|(% colspan="2" %)Acceleration/deceleration time of simple PLC reference 7|Default|0
2664 |(% colspan="2" %)Setting range|(% colspan="2" %)0~~3
2665 |(% rowspan="2" %)**FD.34**|(% colspan="2" %)Running time of simple PLC reference 8|Default|0.0s(h)
2666 |(% colspan="2" %)Setting range|(% colspan="2" %)0.0s(h)~~6553.5s(h)
2667 |(% rowspan="2" %)**FD.35**|(% colspan="2" %)Acceleration/deceleration time of simple PLC reference 8|Default|0
2668 |(% colspan="2" %)Setting range|(% colspan="2" %)0~~3
2669 |(% rowspan="2" %)**FD.36**|(% colspan="2" %)Running time of simple PLC reference 9|Default|0.0s(h)
2670 |(% colspan="2" %)Setting range|(% colspan="2" %)0.0s(h)~~6553.5s(h)
2671 |(% rowspan="2" %)**FD.37**|(% colspan="2" %)Acceleration/deceleration time of simple PLC reference 9|Default|0
2672 |(% colspan="2" %)Setting range|(% colspan="2" %)0~~3
2673 |(% rowspan="2" %)**FD.38**|(% colspan="2" %)Running time of simple PLC reference 10|Default|0.0s(h)
2674 |(% colspan="2" %)Setting range|(% colspan="2" %)0.0 s(h)~~6553.5s(h)
2675 |(% rowspan="2" %)**FD.39**|(% colspan="2" %)Acceleration/deceleration time of simple PLC reference 10|Default|0
2676 |(% colspan="2" %)Setting range|(% colspan="2" %)0~~3
2677 |(% rowspan="2" %)**FD.40**|(% colspan="2" %)Running time of simple PLC reference 11|Default|0.0s(h)
2678 |(% colspan="2" %)Setting range|(% colspan="2" %)0.0s(h)~~6553.5s(h)
2679 |(% rowspan="2" %)**FD.41**|(% colspan="2" %)Acceleration/deceleration time of simple PLC reference 11|Default|0
2680 |(% colspan="2" %)Setting range|(% colspan="2" %)0~~3
2681 |(% rowspan="2" %)**FD.42**|(% colspan="2" %)Running time of simple PLC reference 12|Default|0.0s(h)
2682 |(% colspan="2" %)Setting range|(% colspan="2" %)0.0s(h)~~6553.5s(h)
2683 |(% rowspan="2" %)**FD.43**|(% colspan="2" %)Acceleration/deceleration time of simple PLC reference 12|Default|0
2684 |(% colspan="2" %)Setting range|(% colspan="2" %)0~~3
2685 |(% rowspan="2" %)**FD.44**|(% colspan="2" %)Running time of simple PLC reference 13|Default|0.0s(h)
2686 |(% colspan="2" %)Setting range|(% colspan="2" %)0.0s(h)~~6553.5s(h)
2687 |(% rowspan="2" %)**FD.45**|(% colspan="2" %)Acceleration/deceleration time of simple PLC reference 13|Default|0
2688 |(% colspan="2" %)Setting range|(% colspan="2" %)0~~3
2689 |(% rowspan="2" %)**FD.46**|(% colspan="2" %)Running time of simple PLC reference 14|Default|0.0s(h)
2690 |(% colspan="2" %)Setting range|(% colspan="2" %)0.0s(h)~~6553.5s(h)
2691 |(% rowspan="2" %)**FD.47**|(% colspan="2" %)Acceleration/deceleration time of simple PLC reference 14|Default|0
2692 |(% colspan="2" %)Setting range|(% colspan="2" %)0~~3
2693 |(% rowspan="2" %)**FD.48**|(% colspan="2" %)Running time of simple PLC reference 15|Default|0.0s(h)
2694 |(% colspan="2" %)Setting range|(% colspan="2" %)0.0s(h)~~6553.5s(h)
2695 |(% rowspan="2" %)**FD.49**|(% colspan="2" %)Acceleration/deceleration time of simple PLC reference 15|Default|0
2696 |(% colspan="2" %)Setting range|(% colspan="2" %)0~~3
2697 |(% rowspan="4" %)**FD.50**|(% colspan="2" %)Time unit of simple PLC running|Default|0
2698 |(% rowspan="3" %)Setting range|0|(% colspan="2" %)s:second
2699 |1|(% colspan="2" %)h:hour
2700 |2|(% colspan="2" %)min:minute
2701 |(% rowspan="8" %)**FD.51**|(% colspan="2" %)The source of multistage speed 0|Default|0
2702 |(% rowspan="7" %)Setting range|0|(% colspan="2" %)Set by FD.00
2703 |1|(% colspan="2" %)AI1
2704 |2|(% colspan="2" %)AI2
2705 |3|(% colspan="2" %)Reserved
2706 |4|(% colspan="2" %)Reserved
2707 |5|(% colspan="2" %)PID
2708 |6|(% colspan="2" %)Set by preset frequency (F0.08)
2709
2710 This parameter determines the target quantity given channel of multi-speed 0.
2711
2712 = 15 FE group user password management =
2713
2714 (% class="table-bordered" %)
2715 |(% rowspan="2" %)**FE.00**|User password|Default|0
2716 |Setting range|(% colspan="2" %)0~~65535
2717
2718 Set to any non-zero number, the password protection function will take effect.
2719
2720 00000: Clear the previously set user password value and disable the password protection function.
2721
2722 When the user password is set and effective, when entering the parameter setting state again, if the user password is incorrect, you can only view the parameters, but
2723
2724 cannot modify the parameters. Please keep in mind the user password. If you accidentally set it by mistake or forget it, please contact the manufacturer.
2725
2726 (% class="table-bordered" %)
2727 |(% rowspan="2" %)**FE.01**|Fault record display times|Default|5
2728 |Setting range|(% colspan="2" %)0~~15
2729
2730 This function code is used to set the number of displaying fault records.