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Changes for page 02 Devices

Last modified by Mora Zhou on 2023/11/22 14:13
From version 12.1
edited by Jim
on 2022/09/13 10:14
Change comment: There is no comment for this version
To version 3.2
edited by Stone Wu
on 2022/07/13 20:33
Change comment: Update document after refactoring.

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1 -PLC Editor2.WebHome
1 +PLC Editor2.1 User manual.2\.1 LX5V user manual.WebHome
Author
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1 -XWiki.Jim
1 +XWiki.Stone
Content
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1 -= Registers list =
1 +**Device list**
2 2  
3 -
4 -|**Classification**|**Length**|**Description**|**Register**|**Range**|**Number**
5 -|(% rowspan="10" %)User registers|Bit|Input|X|0 to 1777|Octal number
3 +(% class="table-bordered" %)
4 +|**Classification**|**Type**|**Device name**|**Sign**|**Range**|**Mark**
5 +|(% rowspan="10" %)User device|Bit|Input|X|0 to 1777|Octal number
6 6  |Bit|Output|Y|0 to 1777|Octal number
7 7  |Bit|Internal relay|M|0 to 7999|Decimal number
8 8  |Bit|Step relay|S|0 to 4095|Decimal number
... ... @@ -12,9 +12,9 @@
12 12  |Bit/double word|High-speed counter|HSC|0 to 15|Decimal number
13 13  |Word|Data Register|D|0 to 7999|Decimal number
14 14  |Word|Data Register|R|0 to 29999|Decimal number
15 -|(% rowspan="2" %)System registers|Bit|Special|SM|0 to 4095|Decimal number
15 +|(% rowspan="2" %)System software|Bit|Special|SM|0 to 4095|Decimal number
16 16  |Word|Special register|SD|0 to 4095|Decimal number
17 -|(% rowspan="3" %)Index registers|Word|Index register|[D]|0 to 7999|Decimal number
17 +|(% rowspan="3" %)Index register|Word|Index register|[D]|0 to 7999|Decimal number
18 18  |Word|Index register|V|0 to 7|Decimal number
19 19  |Double word|Long index register|Z|0 to 7|Decimal number
20 20  |Nested|Bit|Nested|N|0 to 7|Decimal number
... ... @@ -23,9 +23,9 @@
23 23  |-|Hexadecimal constant|H|-|Hexadecimal number
24 24  |Single precision floating point|Real constant|E|-|-
25 25  
26 -= User registers =
26 += **User device** =
27 27  
28 -== Input relay (X) ==
28 +== {{id name="_Toc10233"/}}**{{id name="_Toc9353"/}}{{id name="_Toc1366"/}}{{id name="_Toc17120"/}}Input relay (X)** ==
29 29  
30 30  The input relay represents the original PLC external input signal status, and the external signal status is detected through the input X port. 0 represents the external signal is open, and 1 represents the external signal is closed.
31 31  
... ... @@ -35,7 +35,7 @@
35 35  
36 36  When an expansion module is connected, the extended X point will also use the X point as the component of the input signal state, and the occupied X point is the starting position of the X point used by the PLC with 0 as the end of the X point, such as PLC Occupy 17 to 24 X points (X0 to X21, X0 to X27), at this time the X points of the expansion module will be stored starting from X30.
37 37  
38 -== Output relay (Y) ==
38 +== {{id name="_Toc2094"/}}**Output relay (Y)** ==
39 39  
40 40  The output relay is a Devices directly connected to the hardware port of the external user control device, and logically corresponds to the physical output port of the PLC. After the PLC scans the user program each time, the component status of the Y relay will be transmitted to the hardware port of the PLC. 0 means the output port is open; 1 means the output port is closed.
41 41  
... ... @@ -43,17 +43,17 @@
43 43  
44 44  In terms of hardware, according to the different output components, it can be divided into relay type, transistor type, solid state relay type, etc. If there are output expansion module ports, they are numbered in sequence starting from the main module.
45 45  
46 -== Internal relay (M) ==
46 +== {{id name="_Toc10273"/}}**Internal relay (M)** ==
47 47  
48 48  The auxiliary relay M element is used as an intermediate variable in the execution of the user program, just like the auxiliary relay in the actual electronic control system, used for the transmission of status information, and multiple M variables can also be combined into word variables. M variables and external ports There is no direct connection, but you can copy X to M through program statements, or copy M to Y to connect with the outside world. An M variable can be used unlimited times.
49 49  
50 50  The auxiliary relay M is identified by Signs such as M0, M1........., M7999, and its serial number is numbered in decimal system.
51 51  
52 -== Status relay (S) ==
52 +== **Status relay (S)** ==
53 53  
54 54  The state relay S is used for the design and execution of the step program. The STL step instruction is used to control the transfer of the step state S, simplifying the programming design. If STL programming is not used, S can be used as an M variable. State S variables are identified by Signs such as S0, S1...S4095, and their serial numbers are numbered in decimal system.
55 55  
56 -== Timer (T) ==
56 +== **Timer (T)** ==
57 57  
58 58  The timer T is equivalent to the time relay in the relay system and is used to complete the timing function. The timer is an addition expression. When the timer expires, the current value and the set value are the same value.
59 59  
... ... @@ -63,18 +63,15 @@
63 63  
64 64  When the timer coil (OUT T instruction) is executed, the timer coil is turned on/off, the current value is updated, and the contact is turned on/off.
65 65  
66 +(% class="table-bordered" %)
67 +|**Device number**|(% style="width:582px" %)**Timer**|(% style="width:162px" %)**Device number**|(% style="width:210px" %)**Timer**
68 +|T0 to T191|(% style="width:582px" %)100ms timer|(% style="width:162px" %)T246 to T249|(% style="width:210px" %)1ms accumulative timer
69 +|(% rowspan="2" %)T192 to T199|(% rowspan="2" style="width:582px" %)100ms subroutine timer (used in the subroutine, even if the subroutine is not called, it will still be updated)|(% style="width:162px" %)T250 to T255|(% style="width:210px" %)10ms cumulative timer
70 +|(% style="width:162px" %)T256 to T383|(% style="width:210px" %)1ms timer
71 +|T200 to T245|(% style="width:582px" %)10ms timer|(% style="width:162px" %)T384 to T511|(% style="width:210px" %)0.1ms timer
66 66  
67 -|=Registers|=Timer
68 -|=T0 to T191|100ms timer
69 -|=T192 to T199|100ms subroutine timer (used in the subroutine, even if the subroutine is not called, it will still be updated)
70 -|=T200 to T245|10ms timer
71 -|=T246 to T249|1ms accumulative timer
72 -|=T250 to T255|10ms cumulative timer
73 -|=T256 to T383|1ms timer
74 -|=T384 to T511|0.1ms timer
73 +**(1) General-purpose timer (T0 to T245)**{{id name="OLE_LINK328"/}}
75 75  
76 -**(1) General-purpose timer (T0 to T245)**
77 -
78 78  (% style="text-align:center" %)
79 79  [[image:02(1)_html_b1b48247f79e373c.gif||height="214" width="800" class="img-thumbnail"]]
80 80  
... ... @@ -96,7 +96,7 @@
96 96  
97 97  After PLC is powered on, multiplication is performed, D3=D0*2. Use the data of D3 as the timing time value of T10.
98 98  
99 -== Counter (C) ==
96 +== {{id name="_Toc21206"/}}**{{id name="_Toc31862"/}}{{id name="_Toc26590"/}}{{id name="_Toc29366"/}}Counter (C)** ==
100 100  
101 101  The counter is used to complete the counting function. Each counter contains a coil, a contact, and a timer value register. Whenever the driving signal of the counter coil changes from OFF to ON, the counter reading value increases by 1, if the timer value reaches the preset time value, Its contact action, a contact (NO contact) is closed, b contact (NC contact) is opened; if the timing value is cleared, the output a contact will be opened, and b contact (NC contact) will be closed. Some timers have features such as power-down retention, accumulation, etc., and maintain the value before power-down after power-on again.
102 102  
... ... @@ -109,13 +109,13 @@
109 109  
110 110  The setting value of the 16-bit up counter is 1 to 32767. As shown in the working process of the up counter in Figure c, after the normally open contact of X1 in the figure is turned on, C0 is reset, its corresponding bit storage unit is set to 0, the normally open contact of C0 is disconnected, and the normally closed contact Point is turned on, and its current counter value is set to 0 at the same time. X2 provides a counting input signal. When the reset input circuit of the counter is disconnected and the counting input circuit changes from disconnected to connected (that is, the rising edge of the counting pulse), the current value of counter C0 is increased by 1. After 10 count pulses, the current value of C0 is equal to the set value of 10, and its corresponding bit storage unit is set to 1, and the Y0 contact is turned on at this time. When counting pulses again, the current value does not change until the reset input signal is turned on, and the current value of the counter is set to 0.
111 111  
112 -== Long Counter (LC) ==
109 +== {{id name="_Toc30139"/}}**{{id name="_Toc23467"/}}{{id name="_Toc16112"/}}{{id name="_Toc2290"/}}Long Counter (LC)** ==
113 113  
114 114  The long counter (LC) is basically the same as the counter (C), but compared to the counter (C), the long counter (LC) is a 32-bit register, and the range of values that can be counted is larger.
115 115  
116 116  The long counter is identified by LC0, LC1,...,LC255, and the sequence is numbered in decimal.
117 117  
118 -== High-speed counter (HSC) ==
115 +== {{id name="_Toc27105"/}}**{{id name="_Toc1133"/}}{{id name="_Toc1198"/}}{{id name="_Toc19952"/}}High-speed counter (HSC)** ==
119 119  
120 120   High-speed counter (HSC) is a device used for counting through external input of high-speed pulse signals. HSC is a 32-bit register.
121 121  
... ... @@ -129,7 +129,7 @@
129 129  
130 130  
131 131  
132 -== Data Register (D&R) ==
129 +== **Data Register (D & R)** ==
133 133  
134 134  Registers are used for data calculation and storage, such as the calculation and calculation of timers, counters, and analog parameters. The width of each register is 16 bits. If 32bit instructions are used, the adjacent registers are automatically formed into 32bit registers for use, the lower address is the low byte, and the higher address is the high byte.
135 135  
... ... @@ -139,23 +139,23 @@
139 139  
140 140  When 32-bit data needs to be processed, the two adjacent D registers can be formed into a 32-bit double word. For example, when accessing D100 in 32-bit format, use the high address D101 register as the high word and the high byte bit 15 as The sign bit of a double word can handle values from -2147483648 to 2 147483647.
141 141  
142 -= System device =
139 += {{id name="_Toc24649"/}}**System device** =
143 143  
144 -== Special Relay (SM) ==
141 +== {{id name="_Toc26153"/}}**{{id name="_Toc29513"/}}{{id name="_Toc18631"/}}{{id name="_Toc28930"/}}Special Relay (SM)** ==
145 145  
146 146  The special relay SM is an internal relay with a certain specification inside the programmable controller, so it cannot be used in the program like ordinary internal relays. It can be turned ON/OFF as needed to control the PLC.
147 147  
148 -For details, please refer to [[(% class="wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink" %)__Special relays (SM) list__>>path:https://docs.we-con.com.cn/bin/view/PLC%20Editor2/15/#HAppendix1SpecialRelay28SM29]](%%).
145 +{{id name="OLE_LINK152"/}}For details, please refer to [[(% class="wikiinternallink wikiinternallink wikiinternallink" %)__Special relays (SM) list__>>path:#_Attachment 1 Special Relay (SM)]](%%).
149 149  
150 -== Special Register (SD) ==
147 +== {{id name="_Toc7566"/}}**{{id name="_Toc3384"/}}{{id name="_Toc32434"/}}{{id name="_Toc20897"/}}Special Register (SD)** ==
151 151  
152 152  The special register SD is an internal register whose specifications are determined within the programmable controller, so it cannot be used in the program like a normal internal register, and the corresponding data can be written as needed to control the PLC.
153 153  
154 -For details, please refer to [[(% class="wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink" %)__Special register (SD) list__>>path:https://docs.we-con.com.cn/bin/view/PLC%20Editor2/15/#HAppendix2SpecialRegister28SD29]](%%).
151 +For details, please refer to [[(% class="wikiinternallink wikiinternallink wikiinternallink" %)__Special register (SD) list__>>path:#_Appendix 2 Special Register (SD)]](%%).
155 155  
156 -= Index Register =
153 += {{id name="_Toc18802"/}}**Index Register** =
157 157  
158 -== Index register ([D]) ==
155 +== {{id name="_Toc2075"/}}**{{id name="_Toc5787"/}}{{id name="_Toc5824"/}}{{id name="_Toc2076"/}}Index register ([D])** ==
159 159  
160 160  The index register is used to modify the index of the Devices. [D] The index register is actually the same as the data register D, ranging from D0 to D7999. The input method is as follows, just add [D] directly after the Devices:
161 161  
... ... @@ -176,9 +176,9 @@
176 176  
177 177  Whether the index modification can be used depends on whether each instruction supports the format, you can check the "offset modification" in the description of the available device for each instruction.
178 178  
179 -= Nesting =
176 += {{id name="_Toc29907"/}}**{{id name="_Toc2190"/}}{{id name="_Toc18837"/}}Nesting** =
180 180  
181 -== Nesting (N) ==
178 +== {{id name="_Toc10381"/}}**{{id name="_Toc9090"/}}{{id name="_Toc18834"/}}{{id name="_Toc11480"/}}Nesting (N)** ==
182 182  
183 183  Nesting is a device used in master station control instructions (MC/MCR instructions)*1 to program operating conditions through a nested structure. Specify with a small number (order from N0 to N7) from the outside of the nested structure.
184 184  
... ... @@ -187,27 +187,27 @@
187 187  
188 188  *1 is an instruction used to create an efficient ladder switching program by opening and closing the common bus of the Circuit program.
189 189  
190 -= pointer =
187 += {{id name="_Toc31133"/}}**pointer** =
191 191  
192 -== Pointer (P) ==
189 +== {{id name="_Toc9036"/}}**{{id name="_Toc12926"/}}{{id name="_Toc20167"/}}{{id name="_Toc17677"/}}Pointer (P)** ==
193 193  
194 194  The pointer is the device used in the jump instruction (CJ instruction).
195 195  
196 196  At present, the CALL instruction directly uses the subroutine name to call, and no longer uses the P pointer.
197 197  
198 -= Constant =
195 += {{id name="_Toc3845"/}}**Constant** =
199 199  
200 200  The constants are explained below.
201 201  
202 -== Decimal constant (K) ==
199 +== {{id name="_Toc24739"/}}**{{id name="_Toc31877"/}}{{id name="_Toc5216"/}}{{id name="_Toc13896"/}}Decimal constant (K)** ==
203 203  
204 204  “K” is a Sign that represents a decimal integer and is specified by K£ (for example: K123). It is mainly used to designate the set value of a timer or counter or the value in the operand of an application instruction. In 16bit instructions, the value range of constant K is -32768 to 32767; in 32bit instructions, the value range of constant K is -247483648 to 2147483647.
205 205  
206 -== Hexadecimal constant (H) ==
203 +== {{id name="_Toc23697"/}}**{{id name="_Toc8455"/}}{{id name="_Toc19156"/}}{{id name="_Toc18932"/}}Hexadecimal constant (H)** ==
207 207  
208 208  “H” is the Sign of hexadecimal number, specified by H□ (example: H123), mainly used to designate the value of the operand of the application instruction. The value range of the constant H is 0000 to FFFF; in the 32-bit instruction, the value range of the constant K is 0000, 0000 to FFFF, FFFF.
209 209  
210 -== Real number constant (E) ==
207 +== {{id name="_Toc9652"/}}**{{id name="_Toc27560"/}}{{id name="_Toc27972"/}}{{id name="_Toc17774"/}}Real number constant (E)** ==
211 211  
212 212  “E” is the single-precision floating-point number representation Sign, specified by E□ (example: E1.23), mainly used to specify the value of the operand of the application instruction, the value range of the single-precision floating-point number E is ±1.175495*10 -38 to ±3.402823*10+38 (±1.175495 E-38 to ±3.402823 E+38) and 0 (7 effective digits).
213 213  
... ... @@ -216,7 +216,7 @@
216 216  
217 217   (The address occupies D1 and D0)
218 218  
219 -== String constant ==
216 +== {{id name="_Toc20728"/}}**{{id name="_Toc22438"/}}{{id name="_Toc27030"/}}{{id name="_Toc32625"/}}String constant** ==
220 220  
221 221  The character string constant is the device that specifies the character string, and only supports the ASCII code character set, and any character string ends with a NULL character (00H). To use string devices, you must use double eye marks to modify the characters, as follows to convert the string to ASCII characters and fill in the device starting with D0:
222 222  
... ... @@ -223,7 +223,7 @@
223 223  (% style="text-align:center" %)
224 224  [[image:02(1)_html_61bdd1807e91322f.png||class="img-thumbnail"]]
225 225  
226 -= Power-down retention setting =
223 += {{id name="_Toc15009"/}}**Power-down retention setting** =
227 227  
228 228  The user can freely configure the power-off storage range within the range of the Devices. The constant configuration is located in: “Project Management”→”Parameters”→”PLC Parameters”→”Device Latch”.
229 229  
... ... @@ -230,9 +230,9 @@
230 230  (% style="text-align:center" %)
231 231  [[image:02(1)_html_6ba62f454f76a539.png||class="img-thumbnail"]]
232 232  
233 -**✎Note: **The X and Y registers do not support the power-down save function.
230 +**{{id name="OLE_LINK153"/}}✎Note: **The X and Y registers do not support the power-down save function.
234 234  
235 -= Special use of device =
232 += {{id name="_Toc8668"/}}**Special use of device** =
236 236  
237 237  **(1) Use bits to form words**
238 238