Wiki source code of LX3V-4LTC

Version 7.1 by Devin Chen on 2024/10/09 11:36

version	line-number	content
1.1	1	= 1 Introduction =
	2
4.1	3	LX3V-4LTC is temperature control module. It has four temperature input ports and four transistor output ports (the collector is open). It reads data from thermocouple, and then output value with PID control.
1.1	4
	5	LX3V-4LTC needs to connect with LX3V series PLC
	6
	7	1. Four input ports could support type K, type J, type T, type E, type N, type B, type R and type S thermocouple.
	8	1. When it connects with LX3V PLC, PLC could read/write data by “FROM/TO” instruction. (LX3V-4LTC could execute PID control and output control, it does not need user to write PID ladder.)
	9	1. Proportion coefficient, integral time, differential time of LX3V-4LTC can be self-tuning/
	10	1. Each channel is isolation each other.
	11
	12	= 2 Dimensions =
	13
	14	(% style="text-align:center" %)
3.1	15	[[image:LX3V-4LTC_html_d0eefd90086ce676.png\|\|height="394" width="1000" class="img-thumbnail"]]
1.1	16
3.1	17	1. Extension cable and connector
	18	1. Com LED: Light when communicating
	19	1. Power LED: Light when connect to 24V
	20	1. State LED: Light when normal condition
	21	1. Module name
	22	1. Analog signal terminal
	23	1. Extension module interface
	24	1. DIN rail mounting slot
	25	1. DIN rail hook
	26	1. Mounting holes (φ4.5)
1.1	27
	28	Using crimp terminations
	29
	30	(((
	31	* Be sure to use the crimp-style terminals that satisfy the dimensional requirements shows in the left figure.
	32	* Apply 0.5 to 0.8 N.m (5 to 8 kgf.cm) torque to tighten the terminals to prevent abnormal operation.
	33	* Other terminals should be empty but only wiring terminals mention in this manual.
	34
	35	(% style="text-align:center" %)
3.1	36	[[image:LX3V-4LTC_html_67891e8f02a25438.png\|\|height="199" width="300" class="img-thumbnail"]]
1.1	37	)))
	38
	39	= 3 Wiring =
	40
	41	(((
3.1	42	The compensating cables that connect with thermocouples could be as follows:
1.1	43
3.1	44	* Type K: KX-G, KX-GS, KX-H, KX-HS, WX-G, WX-H, VX-G
	45	* Type J: JX-G, JX-H
	46	* Type K: SC-G, SC-H
	47	* Type N: NC-G, NC-H
	48	* Type E: EX-G, EX-H
	49	* Type T: TX-G, TX-H
	50	* Type B: BC-G, BC-H
	51	* Type R: RC-G, RC-H
1.1	52
	53	(% style="text-align:center" %)
3.1	54	[[image:LX3V-4LTC_html_1a21799ac3e4e881.png\|\|height="360" width="400" class="img-thumbnail"]]
1.1	55	)))
	56
	57	For every 10Ω of line resistance, the compensating cable will indicate a temperature 0.12°C higher than actual. Please check the line resistance before installation. Long compensating cables are more prone to noise interference, shorter (less than 100m) compensating cable is recommended.
	58
	59	1. Connect the ground terminals of the LX3V-4LTC unit with the main unit. And the main unit should be 3 grade grounding.
	60	1. The built-in 24V DC output of PLC main unit could be used as the power supply of LX3V-4LTC.
	61	1. FG1-FG4:GND connection of each channel.(generally it is not necessary to connect unless sensor signal is not stable)
	62
	63	Cautions
	64
	65	* Make sure all power be shut down before installation or wiring. Otherwise, it maybe cause electrical shock or components damaged.
	66	* It would be dangerous if system and loads outside starts simultaneously, please make sure both of them are interlocked each other by PLC ladder or other ways.
	67	* Please connect the PLC main unit and LX3V-4LTC with power supply properly; the main unit or LX3V-4LTC would be damaged if AC supply connects with DC I/O or DC power terminal.
	68	* Do not connect the empty terminals with outside wire, which could damage your devices.
	69
	70	= 4 Specifications =
	71
	72	General specification
	73
	74	(% class="table-bordered" %)
3.1	75	\|=(% scope="row" style="width: 326px;" %)Item\|=(% style="width: 749px;" %)Specification
	76	\|=(% style="width: 326px;" %)General specifications\|(% style="width:749px" %)Same as those for the main unit
	77	\|=(% style="width: 326px;" %)Dielectric withstand voltage\|(% style="width:749px" %)500V AC, 1min (between all terminals and ground)
1.1	78
	79	Power supply specification
	80
	81	(% class="table-bordered" %)
3.1	82	\|=(% scope="row" style="width: 323px;" %)Item\|=(% style="width: 752px;" %)Specification
	83	\|=(% style="width: 323px;" %)Analog circuits\|(% style="width:752px" %)24V DC ± 10%, 50mA
	84	\|=(% style="width: 323px;" %)Digital circuits\|(% style="width:752px" %)24V DC, 35mA (internal power supply from the main unit)
1.1	85
	86	Performance specification
	87
3.1	88	(% class="table-bordered" style="width:1117px" %)
	89	\|=(% rowspan="2" scope="row" style="width: 253px;" %)Item\|=(% colspan="2" style="width: 378px;" %)Centigrade (°C)\|=(% colspan="2" style="width: 445px;" %)Fahrenheit (°F)
	90	\|(% colspan="4" style="width:715px" %)Both °C and °F are available by reading the appropriate buffer memory (BFM).
5.1	91	\|(% style="width:253px" %)Input signal\|(% colspan="4" style="width:823px" %)Thermocouple: Type K, J, T, E, N, B, R, S (Each type can be used for each channel), 4 channels most.
3.1	92	\|(% rowspan="8" style="width:253px" %)(((
	93	Rated temperature range
	94	)))\|(% style="width:130px" %)Type K\|(% style="width:248px" %)-100 to +1,200\|(% style="width:147px" %)Type K\|(% style="width:298px" %)-148 to +2,192
	95	\|(% style="width:130px" %)Type J\|(% style="width:248px" %)-100 to +600\|(% style="width:147px" %)Type J\|(% style="width:298px" %)-148 to +1,112
	96	\|(% style="width:130px" %)Type T\|(% style="width:248px" %)-100 to +400\|(% style="width:147px" %)Type T\|(% style="width:298px" %)-148 to +752
	97	\|(% style="width:130px" %)Type E\|(% style="width:248px" %)-100 to +1,000\|(% style="width:147px" %)Type E\|(% style="width:298px" %)-148 to +1,832
	98	\|(% style="width:130px" %)Type N\|(% style="width:248px" %)-100 to +1,300\|(% style="width:147px" %)Type N\|(% style="width:298px" %)-148 to +2,372
	99	\|(% style="width:130px" %)Type B\|(% style="width:248px" %)+250 to +1,800\|(% style="width:147px" %)Type B\|(% style="width:298px" %)-482 to +3,272℉
	100	\|(% style="width:130px" %)Type R\|(% style="width:248px" %)-50 to +1,768\|(% style="width:147px" %)Type R\|(% style="width:298px" %)-58 to +3,214.4
	101	\|(% style="width:130px" %)Type S\|(% style="width:248px" %)-50 to +1,768\|(% style="width:147px" %)Type S\|(% style="width:298px" %)-58 to +3,214.4
	102	\|(% rowspan="9" style="width:253px" %)Digital output\|(% colspan="4" style="width:823px" %)12-bit conversion, saved in 16-bit binary complement form
	103	\|(% style="width:130px" %)Type K\|(% style="width:248px" %)-1,000 to +12,000\|(% style="width:147px" %)Type K\|(% style="width:298px" %)-1480 to +21,920
	104	\|(% style="width:130px" %)Type J\|(% style="width:248px" %)-1,000 to +6,000\|(% style="width:147px" %)Type J\|(% style="width:298px" %)-1480 to +11,120
	105	\|(% style="width:130px" %)Type T\|(% style="width:248px" %)-1,000 to +4,000\|(% style="width:147px" %)Type T\|(% style="width:298px" %)-1480 to +7,520
	106	\|(% style="width:130px" %)Type E\|(% style="width:248px" %)-1,000 to +10,000\|(% style="width:147px" %)Type E\|(% style="width:298px" %)-1480 to +18,320
	107	\|(% style="width:130px" %)Type N\|(% style="width:248px" %)-1,000 to +13,000\|(% style="width:147px" %)Type N\|(% style="width:298px" %)-1480 to +23,720
	108	\|(% style="width:130px" %)Type B\|(% style="width:248px" %)+2,500 to +18,000\|(% style="width:147px" %)Type B\|(% style="width:298px" %)-4820 to +32,720
	109	\|(% style="width:130px" %)Type R\|(% style="width:248px" %)-500 to +17,680\|(% style="width:147px" %)Type R\|(% style="width:298px" %)-580 to +32,144
	110	\|(% style="width:130px" %)Type S\|(% style="width:248px" %)-500 to +17,680\|(% style="width:147px" %)Type S\|(% style="width:298px" %)-580 to +32,144
	111	\|(% rowspan="8" style="width:253px" %)Resolution\|(% style="width:130px" %)Type K\|(% style="width:248px" %)0.4°C\|(% style="width:147px" %)Type K\|(% style="width:298px" %)0.72°F
	112	\|(% style="width:130px" %)Type J\|(% style="width:248px" %)0.3°C\|(% style="width:147px" %)Type J\|(% style="width:298px" %)0.54°F
	113	\|(% style="width:130px" %)Type T\|(% style="width:248px" %)0.4°C\|(% style="width:147px" %)Type T\|(% style="width:298px" %)0.72°F
	114	\|(% style="width:130px" %)Type E\|(% style="width:248px" %)0.25°C\|(% style="width:147px" %)Type E\|(% style="width:298px" %)0.45°F
	115	\|(% style="width:130px" %)Type N\|(% style="width:248px" %)0.52°C\|(% style="width:147px" %)Type N\|(% style="width:298px" %)0.936°F
	116	\|(% style="width:130px" %)Type B\|(% style="width:248px" %)(((
1.1	117	2.09°C
	118
	119	2.97°C (less than 1,000°C)
	120
	121	1.64°C (more than 1,000°C)
3.1	122	)))\|(% style="width:147px" %)Type B\|(% style="width:298px" %)(((
1.1	123	3.762°F
	124
	125	5.346°F (less than 1,832°F)
	126
	127	2.952°F (more than 1,832°F)
	128	)))
3.1	129	\|(% style="width:130px" %)Type R\|(% style="width:248px" %)(((
1.1	130	1.53°C
	131
	132	1.87°C (less than 800°C)
	133
	134	1.32°C (more than 800°C)
3.1	135	)))\|(% style="width:147px" %)Type R\|(% style="width:298px" %)(((
1.1	136	2.754°F
	137
	138	3.366°F (less than 1,472°F)
	139
	140	2.376°F (more than 1,472°F)
	141	)))
3.1	142	\|(% style="width:130px" %)Type S\|(% style="width:248px" %)(((
1.1	143	1.72°C
	144
	145	2.01°C (less than 800°C)
	146
	147	1.53°C (more than 800°C)
3.1	148	)))\|(% style="width:147px" %)Type S\|(% style="width:298px" %)(((
1.1	149	3.096°F
	150
	151	3.618°F (less than 1,472°F)
	152
	153	2.754°F (more than 1,472°F)
	154	)))
3.1	155	\|(% style="width:253px" %)(((
	156	Overall accuracy calibration point
	157	)))\|(% colspan="4" style="width:823px" %)(((
1.1	158	± (0.5% full scale +1°C)
	159
	160	Freezing point of pure water 0°C / 32°F
	161	)))
	162
3.1	163	(% class="box infomessage" %)
	164	(((
	165	✎Note:
1.1	166
3.1	167	* Earth-tipped thermocouples are not suitable for this unit.
	168	* Earth-tipped thermocouples are not suitable for this unit.
	169	)))
1.1	170
3.1	171
1.1	172	Analog Input
	173
	174	(% class="table-bordered" %)
3.1	175	\|=(% colspan="2" %)(((
1.1	176	Conversion Characteristics
	177
5.1	178	Readings given at calibration reference point 0°C/32°F (0/320) respectively. (Subject to the overall accuracy)
1.1	179	)))
	180	\|[[image:LX3V-4LTC_html_92edc788ec28d1cf.gif\|\|class="img-thumbnail"]]\|[[image:LX3V-4LTC_html_304483742690ee7c.gif\|\|class="img-thumbnail"]]
	181
	182	Miscellaneous
	183
	184	(% class="table-bordered" %)
3.1	185	\|=(% scope="row" style="width: 155px;" %)Item\|=(% style="width: 920px;" %)Specification
	186	\|=(% style="width: 155px;" %)Isolation\|(% style="width:920px" %)It has optical isolation between analog and digital circuits. DC/DC converter is applied to isolate between this device and MPU. It has signal isolation between each analog channel.
1.1	187
	188	= 5 Buffer Memory (BFM) =
	189
	190	Buffer memory list
	191
	192	(% class="table-bordered" %)
	193	\|(% colspan="4" style="width:310px" %)BFM No.\|(% rowspan="2" style="width:143px" %)Name\|(% rowspan="2" style="width:68px" %)Latched\|(% rowspan="2" style="width:77px" %)Operation\|(% rowspan="2" style="width:104px" %)Default value\|(% rowspan="2" style="width:348px" %)Contents
	194	\|(% style="width:55px" %)CH1\|(% style="width:12px" %)CH2\|(% style="width:52px" %)CH3\|(% style="width:65px" %)CH4
	195	\|(% colspan="4" style="width:310px" %)#0\|(% style="width:143px" %)Thermocouple types\|(% style="width:68px" %)0\|(% style="width:77px" %)W/R\|(% style="width:104px" %)H0000\|(% style="width:348px" %)(((
	196	Each number of 4 HEX corresponds to one channel, the highest bit is CH4, the lowest is CH1.
	197
3.1	198	* 0: Type K
	199	* 1: Type J
	200	* 2: Type T
1.1	201
	202	(((
	203	[[image:LX3V-4LTC_html_9936e798cd945c5e.gif]]
	204
	205	3: Type E
	206	)))
	207
	208	4: Type N
	209
	210	5: Type B
	211
	212	6: Type R
	213
	214	7: Type S
	215
	216	Others: not used.
	217	)))
	218	\|(% style="width:55px" %)#1\|(% style="width:12px" %)#2\|(% style="width:52px" %)#3\|(% style="width:65px" %)#4\|(% style="width:143px" %)Averaged constant of filter\|(% style="width:68px" %)0\|(% style="width:77px" %)W/R\|(% style="width:104px" %)8\|(% style="width:348px" %)Count of temperature sampling for averaging. Please set 1 for High-speed sampling. Only the range 1 to 256 is valid for the number of temperature readings to be averaged. If a value outside of this range is entered, a default value of 8 is used.
	219	\|(% style="width:55px" %)#5\|(% style="width:12px" %)#6\|(% style="width:52px" %)#7\|(% style="width:65px" %)#8\|(% style="width:143px" %)Averaged temp.°C\|(% style="width:68px" %)X\|(% style="width:77px" %)R\|(% style="width:104px" %)0\|(% style="width:348px" %)CH1 to CH4 Averaged temperature (unit is 0.1°C)
	220	\|(% style="width:55px" %)#9\|(% style="width:12px" %)#10\|(% style="width:52px" %)#11\|(% style="width:65px" %)#12\|(% style="width:143px" %)Present temp.°C\|(% style="width:68px" %)X\|(% style="width:77px" %)R\|(% style="width:104px" %)0\|(% style="width:348px" %)CH1 to CH4 Current temperature (unit is 0.1°C)
	221	\|(% style="width:55px" %)#13\|(% style="width:12px" %)#14\|(% style="width:52px" %)#15\|(% style="width:65px" %)#16\|(% style="width:143px" %)Averaged temp.°F\|(% style="width:68px" %)X\|(% style="width:77px" %)R\|(% style="width:104px" %)0\|(% style="width:348px" %)CH1 to CH4 Averaged temperature (unit is 0.1°C)
	222	\|(% style="width:55px" %)#17\|(% style="width:12px" %)#18\|(% style="width:52px" %)#19\|(% style="width:65px" %)#20\|(% style="width:143px" %)Present temp.°F\|(% style="width:68px" %)X\|(% style="width:77px" %)R\|(% style="width:104px" %)0\|(% style="width:348px" %)CH1 to CH4 Current temperature in (unit is 0.1°C)
	223	\|(% colspan="4" style="width:310px" %)#21~~#27\|(% style="width:143px" %)Reserved\|(% style="width:68px" %)X\|(% style="width:77px" %)R\|(% style="width:104px" %)-\|(% style="width:348px" %)-
	224	\|(% colspan="4" style="width:310px" %)*#28\|(% style="width:143px" %)Error latch\|(% style="width:68px" %)X\|(% style="width:77px" %)W/R\|(% style="width:104px" %)0\|(% style="width:348px" %)Digital range error latch
	225	\|(% colspan="4" style="width:310px" %)#29\|(% style="width:143px" %)Error status\|(% style="width:68px" %)X\|(% style="width:77px" %)R\|(% style="width:104px" %)-\|(% style="width:348px" %)(((
3.1	226	* B0: A/D conversion would be stopped when b2 or b3 is ON.
	227	* B1: Not used;
	228	* B2: power failed;
	229	* B3: Hardware failed;
	230	* B4~~B7: Not used;
	231	* B8: Values backup error;
	232	* B10: Digital output/analog input value is out of the specified range;
	233	* B11: Averaged value is out of the available range;
	234	* B13: backup error(during executing value backup(BFM42 is non-zero),and backup failed, this bit is ON.)
	235	* B14: It is in backup status(during executing value backup(BFM42 is non-zero),and backup failed, this bit is ON.)
	236	* B15: Initialization completion flag;(during initializing, (BFM42 is 1 or 2), when it finished, this bit is ON.)
1.1	237	)))
	238	\|(% colspan="4" style="width:310px" %)#30\|(% style="width:143px" %)Identification\|(% style="width:68px" %)-\|(% style="width:77px" %)R\|(% style="width:104px" %)-\|(% style="width:348px" %)Identification code: K2130
	239	\|(% colspan="4" style="width:310px" %)#31\|(% style="width:143px" %)Software version\|(% style="width:68px" %)-\|(% style="width:77px" %)R\|(% style="width:104px" %)-\|(% style="width:348px" %)Software version
	240	\|(% colspan="4" style="width:310px" %)#32~~#40\|(% style="width:143px" %)Reserved\|(% style="width:68px" %)-\|(% style="width:77px" %)-\|(% style="width:104px" %)-\|(% style="width:348px" %)Reserved
	241	\|(% colspan="4" style="width:310px" %)#41\|(% style="width:143px" %)Initialization command\|(% style="width:68px" %)X\|(% style="width:77px" %)W/R\|(% style="width:104px" %)0\|(% style="width:348px" %)(((
3.1	242	* 0: Performs nothing
	243	* 1: Initializes all data
	244	* 2: Initializes BFM #19 to BFM #174
	245	* 3: Initializes error
	246	* Others: No action
1.1	247	)))
	248	\|(% colspan="4" style="width:310px" %)#42\|(% style="width:143px" %)Backing up data to EEPROM\|(% style="width:68px" %)X\|(% style="width:77px" %)W/R\|(% style="width:104px" %)0\|(% style="width:348px" %)(((
3.1	249	* 0: Performs nothing
	250	* Other: Performs backups
1.1	251	)))
	252	\|(% style="width:55px" %)#43\|(% style="width:12px" %)#81\|(% style="width:52px" %)#119\|(% style="width:65px" %)#157\|(% style="width:143px" %)Error flag (Temperature control is stopped)\|(% style="width:68px" %)X\|(% style="width:77px" %)R\|(% style="width:104px" %)0\|(% style="width:348px" %)(((
3.1	253	* b0: Reserved;
	254	* b1: value range setting error;
	255	* b2: PID self-tuning error;
	256	* b3: The difference of setting value and offset value of PID self-tuning is too small;
	257	* b4~~b5: Reserved;
	258	* b6: Channel mode Error/ This channel is not enabled;
	259	* b7: PV exceeded;
	260	* b8: PID self-tuning parameters are changed in process;
1.1	261	)))
	262	\|(% style="width:55px" %)#44\|(% style="width:12px" %)#82\|(% style="width:52px" %)#120\|(% style="width:65px" %)#158\|(% style="width:143px" %)Event (PID continue)\|(% style="width:68px" %)X\|(% style="width:77px" %)-\|(% style="width:104px" %)0\|(% style="width:348px" %)(((
3.1	263	* b0 & b15: Reserved;
	264	* b4: Alarm 1 - When alarm 1 occurs, it is set ON;
	265	* b5: Alarm 2 - When alarm 2 occurs, it is set ON;
	266	* b6: Alarm 3 - When alarm 3 occurs, it is set ON;
	267	* b7: Alarm 4 - When alarm 4 occurs, it is set ON;
	268	* b8: Heating control;
	269	* b9: Cooling control;
	270	* b10: PID terminals output;
	271	* b11: PID control flag;
	272	* b12: Manual flag;
	273	* b13: Self-tuning;
	274	* b14: ON / OFF control;
1.1	275	)))
	276	\|(% style="width:55px" %)#45\|(% style="width:12px" %)#83\|(% style="width:52px" %)#121\|(% style="width:65px" %)#159\|(% style="width:143px" %)Current target temp. (PV)\|(% style="width:68px" %)X\|(% style="width:77px" %)R\|(% style="width:104px" %)0\|(% style="width:348px" %)(((
	277	Unit: 0.1 °C
	278
	279	Sampling temperature (from averaged value) during executing.
	280	)))
	281	\|(% style="width:55px" %)#46\|(% style="width:12px" %)#84\|(% style="width:52px" %)#122\|(% style="width:65px" %)#160\|(% style="width:143px" %)Control output value (MV)\|(% style="width:68px" %)X\|(% style="width:77px" %)R\|(% style="width:104px" %) \|(% style="width:348px" %)The output value of PID calculation, This value is equal with output value (BFM49) during manual control.
	282	\|(% style="width:55px" %)#47\|(% style="width:12px" %)#85\|(% style="width:52px" %)#123\|(% style="width:65px" %)#161\|(% style="width:143px" %)Control start/stop changeover\|(% style="width:68px" %)X\|(% style="width:77px" %)W/R\|(% style="width:104px" %)0\|(% style="width:348px" %)(((
3.1	283	* 0: Stops control;
	284	* Other: Starts control;
1.1	285	)))
	286	\|(% style="width:55px" %)#48\|(% style="width:12px" %)#86\|(% style="width:52px" %)#124\|(% style="width:65px" %)#162\|(% style="width:143px" %)Auto/manual mode changeover\|(% style="width:68px" %)0\|(% style="width:77px" %)W/R\|(% style="width:104px" %)0\|(% style="width:348px" %)(((
3.1	287	* 0: AUTO;
	288	* Other: MAN;
1.1	289	)))
	290	\|(% style="width:55px" %)#49\|(% style="width:12px" %)#87\|(% style="width:52px" %)#125\|(% style="width:65px" %)#163\|(% style="width:143px" %)Manual output set value\|(% style="width:68px" %)0\|(% style="width:77px" %)W/R\|(% style="width:104px" %)0\|(% style="width:348px" %)The value is equal to the value of control output in manual mode.
	291	\|(% style="width:55px" %)#50\|(% style="width:12px" %)#88\|(% style="width:52px" %)#126\|(% style="width:65px" %)#164\|(% style="width:143px" %)Self-tuning execution command\|(% style="width:68px" %)0\|(% style="width:77px" %)W/R\|(% style="width:104px" %)0\|(% style="width:348px" %)(((
3.1	292	* 0: Stops self-tuning;
	293	* Other : starts self-tuning;
1.1	294	)))
	295	\|(% style="width:55px" %)#51\|(% style="width:12px" %)#89\|(% style="width:52px" %)#127\|(% style="width:65px" %)#165\|(% style="width:143px" %)Heating / cooling control\|(% style="width:68px" %)0\|(% style="width:77px" %)W/R\|(% style="width:104px" %)0\|(% style="width:348px" %)(((
3.1	296	* 0: Heating control;
	297	* 1: Cooling control;
1.1	298	)))
	299	\|(% style="width:55px" %)#52\|(% style="width:12px" %)#90\|(% style="width:52px" %)#128\|(% style="width:65px" %)#166\|(% style="width:143px" %)Setting value (SV)\|(% style="width:68px" %)0\|(% style="width:77px" %)W/R\|(% style="width:104px" %)0\|(% style="width:348px" %)(((
	300	Unit: 0.1 °C
	301
	302	The target temperature of PID control
	303	)))
	304	\|(% style="width:55px" %)#53\|(% style="width:12px" %)#91\|(% style="width:52px" %)#129\|(% style="width:65px" %)#167\|(% style="width:143px" %)KP (Scaling coefficient)\|(% style="width:68px" %)0\|(% style="width:77px" %)W/R\|(% style="width:104px" %)3\|(% style="width:348px" %)(((
	305	KP = 0, ON / OFF control is executed.
	306
3.1	307	Range: 0 ~~ 32767.
1.1	308
3.1	309	(% class="box infomessage" %)
	310	(((
	311	✎Note: This value is magnified 256 times; the actual value is KP / 256.
1.1	312	)))
3.1	313	)))
	314	\|(% style="width:55px" %)#54\|(% style="width:12px" %)#92\|(% style="width:52px" %)#130\|(% style="width:65px" %)#168\|(% style="width:143px" %)TI (Integral coefficient)\|(% style="width:68px" %)0\|(% style="width:77px" %)W/R\|(% style="width:104px" %)2400\|(% style="width:348px" %)0 ~~ 32767
	315	\|(% style="width:55px" %)#55\|(% style="width:12px" %)#93\|(% style="width:52px" %)#131\|(% style="width:65px" %)#169\|(% style="width:143px" %)TD (Differential coefficient)\|(% style="width:68px" %)0\|(% style="width:77px" %)W/R\|(% style="width:104px" %)600\|(% style="width:348px" %)0 ~~ 32767
	316	\|(% style="width:55px" %)#56\|(% style="width:12px" %)#94\|(% style="width:52px" %)#132\|(% style="width:65px" %)#170\|(% style="width:143px" %)TS (Sampling cycle)\|(% style="width:68px" %)0\|(% style="width:77px" %)W/R\|(% style="width:104px" %)5\|(% style="width:348px" %)1~~100 (*500ms)
	317	\|(% style="width:55px" %)#57\|(% style="width:12px" %)#95\|(% style="width:52px" %)#133\|(% style="width:65px" %)#171\|(% style="width:143px" %)Filter coefficients\|(% style="width:68px" %)0\|(% style="width:77px" %)W/R\|(% style="width:104px" %)0\|(% style="width:348px" %)0~~1023
1.1	318	\|(% style="width:55px" %)#58\|(% style="width:12px" %)#96\|(% style="width:52px" %)#134\|(% style="width:65px" %)#172\|(% style="width:143px" %)DetaT\|(% style="width:68px" %)0\|(% style="width:77px" %)W/R\|(% style="width:104px" %)100\|(% style="width:348px" %)(((
	319	The maximum rate of rise: 0-320;
	320
	321	Range: 0-32000 (0-320);
	322	)))
	323	\|(% style="width:55px" %)#59\|(% style="width:12px" %)#97\|(% style="width:52px" %)#135\|(% style="width:65px" %)#173\|(% style="width:143px" %)Control cycle\|(% style="width:68px" %)0\|(% style="width:77px" %)W/R\|(% style="width:104px" %)20\|(% style="width:348px" %)(((
3.1	324	1~~100 (*500ms);
1.1	325
3.1	326	Range: 0.5s~~50s;
1.1	327	)))
	328	\|(% style="width:55px" %)#60\|(% style="width:12px" %)#98\|(% style="width:52px" %)#136\|(% style="width:65px" %)#174\|(% style="width:143px" %)Self-tuning bias\|(% style="width:68px" %)0\|(% style="width:77px" %)W/R\|(% style="width:104px" %)0\|(% style="width:348px" %)± Input range (Unit: 0.1 °C)
	329	\|(% style="width:55px" %)#61\|(% style="width:12px" %)#99\|(% style="width:52px" %)#137\|(% style="width:65px" %)#175\|(% style="width:143px" %)Reserved\|(% style="width:68px" %)-\|(% style="width:77px" %)-\|(% style="width:104px" %)-\|(% style="width:348px" %)Reserved
	330	\|(% style="width:55px" %)#62\|(% style="width:12px" %)#100\|(% style="width:52px" %)#138\|(% style="width:65px" %)#176\|(% style="width:143px" %)Dead zone setting\|(% style="width:68px" %)0\|(% style="width:77px" %)W/R\|(% style="width:104px" %)0\|(% style="width:348px" %)(((
	331	Dead zone is used for ON/OFF control mode
	332
3.1	333	Range: 0~~100 (Unit: 0.1%)
1.1	334	)))
	335	\|(% style="width:55px" %)#63\|(% style="width:12px" %)#101\|(% style="width:52px" %)#139\|(% style="width:65px" %)#177\|(% style="width:143px" %)PV upper limit\|(% style="width:68px" %)0\|(% style="width:77px" %)W/R\|(% style="width:104px" %)12000\|(% style="width:348px" %)(((
	336	Lower & upper threshold of input (Unit: 0.1 °C)
	337
	338	Remark: This BFM is used for the upper threshold of input value.
	339
	340	Range:
	341
3.1	342	* K type: -100°C ~~1200°C
	343	* J type: -100°C ~~ 600°C
1.1	344	)))
	345	\|(% style="width:55px" %)#64\|(% style="width:12px" %)#102\|(% style="width:52px" %)#140\|(% style="width:65px" %)#178\|(% style="width:143px" %)PV lower limit\|(% style="width:68px" %)0\|(% style="width:77px" %)W/R\|(% style="width:104px" %)-1000\|(% style="width:348px" %)(((
	346	Lower & upper threshold of input (Unit: 0.1 °C)
	347
	348	Remark: This BFM is used for setting lower threshold of input.
	349
	350	Range:
	351
3.1	352	* K type: -100°C~~1200°C
	353	* J type: -100°C~~600°C
1.1	354	)))
	355	\|(% style="width:55px" %)#65\|(% style="width:12px" %)#103\|(% style="width:52px" %)#141\|(% style="width:65px" %)#179\|(% style="width:143px" %)MV upper limit\|(% style="width:68px" %)0\|(% style="width:77px" %)W/R\|(% style="width:104px" %)100\|(% style="width:348px" %)(((
	356	This BFM is used for setting the upper threshold of output.
	357
3.1	358	Range: 0~~2000
1.1	359	)))
	360	\|(% style="width:55px" %)#66\|(% style="width:12px" %)#104\|(% style="width:52px" %)#142\|(% style="width:65px" %)#180\|(% style="width:143px" %)MV lower limit\|(% style="width:68px" %)0\|(% style="width:77px" %)W/R\|(% style="width:104px" %)0\|(% style="width:348px" %)(((
	361	This BFM is used for setting the lower threshold of output.
	362
3.1	363	Range: 0~~2000
1.1	364	)))
	365	\|(% style="width:55px" %)#67\|(% style="width:12px" %)#105\|(% style="width:52px" %)#143\|(% style="width:65px" %)#181\|(% style="width:143px" %)Reserved\|(% style="width:68px" %)-\|(% style="width:77px" %)-\|(% style="width:104px" %)-\|(% style="width:348px" %)Reserved
	366	\|(% style="width:55px" %)#68\|(% style="width:12px" %)#106\|(% style="width:52px" %)#144\|(% style="width:65px" %)#182\|(% style="width:143px" %)Alarm mode setting\|(% style="width:68px" %)0\|(% style="width:77px" %)W/R\|(% style="width:104px" %)0\|(% style="width:348px" %)(((
	367	It is used for alarm mode of four channels;
	368
	369	[[image:LX3V-4LTC_html_de0e4e05bfd9b167.gif]]
	370	)))
	371	\|(% style="width:55px" %)#69\|(% style="width:12px" %)#107\|(% style="width:52px" %)#145\|(% style="width:65px" %)#183\|(% style="width:143px" %)Alarm 1 set value\|(% style="width:68px" %)0\|(% style="width:77px" %)W/R\|(% style="width:104px" %)0\|(% rowspan="4" style="width:348px" %)(((
	372	Unit: °C
	373
	374	The alarm range, it depends on alarm mode.
	375	)))
	376	\|(% style="width:55px" %)#70\|(% style="width:12px" %)#108\|(% style="width:52px" %)#146\|(% style="width:65px" %)#184\|(% style="width:143px" %)Alarm 2 set value\|(% style="width:68px" %)0\|(% style="width:77px" %)W/R\|(% style="width:104px" %)0
	377	\|(% style="width:55px" %)#71\|(% style="width:12px" %)#109\|(% style="width:52px" %)#147\|(% style="width:65px" %)#185\|(% style="width:143px" %)Alarm 3 set value\|(% style="width:68px" %)0\|(% style="width:77px" %)W/R\|(% style="width:104px" %)0
	378	\|(% style="width:55px" %)#72\|(% style="width:12px" %)#110\|(% style="width:52px" %)#148\|(% style="width:65px" %)#186\|(% style="width:143px" %)Alarm 4 set value\|(% style="width:68px" %)0\|(% style="width:77px" %)W/R\|(% style="width:104px" %)0
	379	\|(% style="width:55px" %)#73\|(% style="width:12px" %)#111\|(% style="width:52px" %)#149\|(% style="width:65px" %)#187\|(% style="width:143px" %)Alarm dead zone setting\|(% style="width:68px" %)0\|(% style="width:77px" %)W/R\|(% style="width:104px" %)0\|(% style="width:348px" %)(((
	380	Calculation of dead zone
	381
3.1	382	* Bias: (SV+ bias)* dead zone
	383	* Upper & lower threshold mode: Alarm setting value* dead zone
1.1	384	)))
3.1	385	\|(% style="width:55px" %)#74\|(% style="width:12px" %)#112\|(% style="width:52px" %)#150\|(% style="width:65px" %)#188\|(% style="width:143px" %)Alarm delay times\|(% style="width:68px" %)0\|(% style="width:77px" %)W/R\|(% style="width:104px" %)0\|(% style="width:348px" %)Range: 0~~255
1.1	386	\|(% style="width:55px" %)#75\|(% style="width:12px" %)#113\|(% style="width:52px" %)#151\|(% style="width:65px" %)#189\|(% style="width:143px" %)Setting the wrong address\|(% style="width:68px" %)0\|(% style="width:77px" %)R\|(% style="width:104px" %)0\|(% style="width:348px" %)(((
3.1	387	* 0: Normal;
	388	* Others: Error in setting address
1.1	389	)))
	390	\|(% style="width:55px" %)#76~~#80\|(% style="width:12px" %)#114~~#118\|(% style="width:52px" %)#152~~#156\|(% style="width:65px" %)#190~~#193\|(% style="width:143px" %)Reserved\|(% style="width:68px" %)-\|(% style="width:77px" %)-\|(% style="width:104px" %)-\|(% style="width:348px" %)Reserved
	391
6.1	392	(% class="box infomessage" %)
	393	(((
1.1	394	✎Note:
	395
3.1	396	* 0: Retentive;
	397	* X: Non-retentive;
	398	* R: Only read is enabled;
	399	* R/W: Both read and write are enabled;
6.1	400	)))
1.1	401
	402	Details of buffer memories
	403
3.1	404	Buffer Memory BFM #0: Thermocouple Type K or J selection mode
1.1	405
	406	BFM #0 is used for selecting type K or J thermocouples for each channel. Each bit of a 4 digit hexadecimal number corresponds to one channel, the last digit is channel 1.
	407
	408	(% style="text-align:center" %)
3.1	409	[[image:LX3V-4LTC_html_9936e798cd945c5e.gif\|\|height="173" width="300" class="img-thumbnail"]]
1.1	410
	411	The time of A/D conversion is 240ms for each channel. When “3" (unused) is set for a channel, this channel would not have A/D conversion, therefore, the total time for conversion decreases. In the above example, the conversion time is as follows:
	412
	413	240ms (conversion time per channel) × 2channels (number of channels used) = 480ms (total conversion time)
	414
3.1	415	Buffer Memory BFMs #1 to #4: Number of temperature readings to be averaged
1.1	416
	417	When the value of averaged temperature is assigned to BFMs #1 to #4, the averaged data is stored in BFMs #5 to #8 (°C) and #13 to #16 (°F). Only the range 1 to 256 is valid for the number of averaged temperature. If a value out of this range, the default value is 8.
	418
3.1	419	Buffer Memory BFMs #9 to #12 and #17 to #20: Current temperature
1.1	420
	421	These BFMs store the current input value. This value is stored in units of 0.1°C or 0.1°F, but the resolution is only 0.4°C or 0.72°F for Type K and 0.3°C or 0.54°F for Type J.
	422
3.1	423	Buffer Memory BFM #28: Digital range error latch
1.1	424
3.1	425	* BFM #29 b10(digital range error) is used for confirm if the measured temperature is in the range of this unit.
	426	* BFM #28 latches the error status of each channel and can be used to check for thermocouple disconnection.
1.1	427
	428	(((
	429	(% class="table-bordered" %)
3.1	430	\|=(% scope="row" %)b15 ~~ b8\|=b7\|=b6\|=b5\|=b4\|=b3\|=b2\|=b1\|=b0
1.1	431	\|(% rowspan="2" %)Not used\|High\|Low\|High\|Low\|High\|Low\|High\|Low
	432	\|(% colspan="2" %)CH4\|(% colspan="2" %)CH3\|(% colspan="2" %)CH2\|(% colspan="2" %)CH1
	433	)))
	434
3.1	435	* Low: Latches ON when the measured temperature drops down and less than the lowest temperature threshold.
	436	* High: Turns ON when measured temperature rises up and more than the highest temperature threshold, or the thermocouple was disconnected.
1.1	437
	438	When an error occur the temperature data before the error is latched. If the measured value returns to normal threshold, all data return to run properly again. (Note: The error remains latched in (BFM #28))
	439
	440	An error can be cleared by writing K0 to BFM #28 using the TO instruction or turning off the power.
	441
3.1	442	Buffer Memory BFM #29: Error status
1.1	443
	444	(((
	445	(% class="table-bordered" %)
3.1	446	\|=(% scope="row" %)Bit devices of BFM #29\|=Error information
	447	\|=b0\|Error, when either b1~~ b3 is ON, A/D conversion is stopped.
	448	\|=b1, b4~~b7\|Not used;
	449	\|=b2\|24V DC power supply failed;
	450	\|=b3\|Hardware failed;
	451	\|=b8\|Backup error of set value.
	452	\|=b10\|Digital output/analog input value is out of the specified range;
	453	\|=b11\|The value of averaged results is out of the available range;
	454	\|=b13\|Backup error, during executing of backup,(BFM42 is non-zero) , and backup failed, this bit sets to ON;
	455	\|=b14\|It is in backup status, this bit sets to ON;
	456	\|=b15\|Initialization completion flag;
1.1	457	)))
	458
3.1	459	ID Code Buffer Memory BFM #30
1.1	460
	461	The identification code or ID number for this Special Block is read from buffer memory BFM #30 by FROM instruction. This number for the LX3V-4LTC unit is K2130. The PLC can use this ID in program to identify the special block before commencing data transfer to and from the special block.
	462
7.1	463	Power-down retention flag BFM#42
	464
	465	First, configure the parameters to be saved, and then set the power-down retention flag BFM#42 to 1. This enables power-down retention for the configured parameters.
	466
	467	The operation steps are illustrated as follows:
	468
	469	1. Set the power-down retention register to a value of 100 (e.g., BFM#52 is set to 100).
	470	1. Set the power-down retention flag BFM#42 to 1 (data is saved at this point, and BFM#42 will automatically reset to zero upon completion).
	471	1. Change the data of the power-down retention register to 1000 (e.g., BFM#52 is set to 1000).
	472	1. Power off and then power on again. At this point, check the value of the power-down retention register, which should be 100 (e.g., BFM#52 shows a value of 100)."
	473
3.1	474	Error flag BFM #43, BFM#81, BFM#119, BFM#157 (Temperature control is stopped)
1.1	475
	476	(((
	477	(% class="table-bordered" %)
3.1	478	\|=(% scope="row" style="width: 134px;" %)Error flag\|=(% style="width: 383px;" %)Content\|=(% style="width: 559px;" %)Remark
	479	\|=(% style="width: 134px;" %)b0, b4, b5\|(% style="width:383px" %)Not used;\|(% style="width:559px" %)-
	480	\|=(% style="width: 134px;" %)b1\|(% style="width:383px" %)Error in setting value range.\|(% style="width:559px" %)When set value is out of the specified range, this bit sets to ON. The error addresses will be showed in BFM#75, BFM#113, BFM#151, BFM#189
	481	\|=(% style="width: 134px;" %)b2\|(% style="width:383px" %)PID self-tuning error;\|(% style="width:559px" %)When either b3 or b8 is ON, this bit set ON
	482	\|=(% style="width: 134px;" %)b3\|(% style="width:383px" %)The difference of set value and offset are too small.\|(% style="width:559px" %)The difference between measured temperature (PV) and SV + DIFF less than 100 in self-tuning mode, or SV+DIFF exceeded PV’s range. This bit sets to ON
	483	\|=(% style="width: 134px;" %)b6\|(% style="width:383px" %)Channel mode Error/ This channel is disable;\|(% style="width:559px" %)When the channel is disabled by BFM#0, this bit sets to ON.
	484	\|=(% style="width: 134px;" %)b7\|(% style="width:383px" %)PV exceeded;\|(% style="width:559px" %)When measured temperature exceeded PV’s range, this bit sets to ON.
	485	\|=(% style="width: 134px;" %)b8\|(% style="width:383px" %)PID self-tuning parameters are changed in process;\|(% style="width:559px" %)When one of upper & lower threshold, set value, bias changes, this bit sets to ON.
1.1	486	)))
	487
3.1	488	BFM #48 (CH1), BFM #86 (CH2), BFM#124(CH3), BFM#162(CH4) : Auto/manual mode changeover
1.1	489
	490	BFM #48 is used for changing the mode of CH1. BFM #86 is used for changing the mode of CH2. BFM #124 is used for changing the mode of CH3. BFM #162 is used for the mode of CH4.
	491
3.1	492	* When BFM #48/#86/#124/#162 is set to "K0 (initialized value)", the auto mode is selected.
	493	* When BFM #48/#86/#124/#162 is set to "K1", the manual mode is selected.
1.1	494
	495	Auto mode:
	496
	497	The measured value (PV) is compared with the set value (SV), PID arithmetic operation is performed, then output the control value (MV).
	498
	499	In the auto mode, the manual output set value (CH1: BFM #48, CH2: BFM #86, CH3: BFM#124, CH4:BFM#162) is always equival with the control output value.
	500
	501	Manual mode:
	502
	503	The control output (MV) value is fixed to the manual output set value (CH1: BFM #48, CH2: BFM #86, CH3: BFM#124, CH4:BFM#162).
	504
	505	The manual output set value can be changed while b13 of the event (CH1: BFM #48, CH2: BFM #86, CH3: BFM#124, CH4:BFM#162) is ON even if operation is performed in the manual mode.
	506
	507	The temperature alarm function is effective even in the manual mode.
	508
3.1	509	Self-tuning function
1.1	510
	511	The self-tuning function automatically measures, calculates and sets the most optimal PID constants in accordance with the set temperature.
	512
	513	When the self-tuning execution command (CH1: BFM #48, CH2: BFM #86, CH3: BFM#124, CH4: BFM#162) is set to "1", self-tuning is performed. (Self-tuning can start from an arbitrary status at any time immediately after the power is turned ON, while the temperature is rising or while control is stable.)
	514
	515	When self-tuning starts, two-position control is performed using the set value (SV). By two-position control, the output is forcedly hunted and its amplitude and oscillation cycle are measured. PID constants are calculated based on the measured values, and stored in each parameter. When self-tuning normally finishes, control continues with new calculated PID constants.
	516
	517	While self-tuning is performed, b14 of the event (CH1: BFM #48, CH2: BFM #86, CH3: BFM#124, CH4: BFM#162) is set to "1".
	518
	519	(In order to calculate proper PID constants by self-tuning, set the upper limit of the output limiter to 2000, the lower limit of the output limiter to 0.)
	520
	521	Self-tuning can be started with the following conditions:
	522
	523	* The control start/stop changeover set to "1: Starts control".
	524	* The operation mode sets to "2: Monitor + Temperature alarm + Control".
	525	* The auto/manual mode is "0: AUTO".
	526	* The measured value PV is normal.
	527	* The upper threshold and lower threshold for output should be different.
	528
	529	Self-tuning would be canceled with one of the following conditions:
	530
	531	(% style="text-align:center" %)
3.1	532	[[image:LX3V-4LTC_html_98e0b421b7f760bb.png\|\|height="217" width="500" class="img-thumbnail"]]
1.1	533
	534	* SV value has been changed.
	535	* The control has been stopped, the operation mode is "0: Stops control".
	536	* The auto/manual mode is set to "1: MAN".
	537	* The PV bias has been changed.
	538	* The upper and lower threshold for output has been changed.
	539	* The self-tuning executed command is set to "0: Stops auto tuning".
	540	* Power failed
	541
	542	Self-tuning bias
	543
	544	If the self-tuning bias has been used for auto-tuning, The measured value (PV) should not exceed the set value (SV). The self-tuning makes the measured value vibrating and SV switching ON/OFF, then calculates and sets each PID constant. However, for some control targets, overshoot by vibration is not permitted, Set the self-tuning bias is necessary for this case. The set value(SV) could be changed when self-tuning bias is set.
	545
	546	(% style="text-align:center" %)
3.1	547	[[image:LX3V-4LTC_html_797cdf2f2cae01b5.png\|\|height="197" width="500" class="img-thumbnail"]]
1.1	548
	549	Dead zone (adjustment sensitivity) setting
	550
	551	BFM #62 is used for dead zone of CH1. BFM #100 is used for the dead zone of CH2. BFM #138 is used for the dead zone of CH3.BFM #176 is used for the dead zone of CH4.
	552
	553	When system has been turning ON/OFF operations, if the adjustment sensitivity has been configured, it could avoid temperature value (SV) show ON/OFF changes nearby.
	554
	555	The value set to BFM #62/#100/#138/#176 is equally to the value of the upper and the lower area of the temperature set value (BFM #52/#90/#128/#166).
	556
	557	For example, if the sensitive value sets to "10%", 5% above and 5% below of the set value would be treated as the dead zone (width of 10% in total).
	558
	559	Example
	560
3.1	561	Conditions:
1.1	562
3.1	563	* When BFM #41/#60 is set to "10.0%" in the range span of 400°C; 400°C x 10.0% / 100 = 40°C
	564	* When the temperature set value is 200°C, the range from 180 to 220°C is treated as the dead zone.
	565	* When the dead zone sets to a large value, vertical fluctuation would be larger. But if dead zone is too small, small oscillations of the measured value may cause vibration.
1.1	566
	567	(% style="text-align:center" %)
3.1	568	[[image:LX3V-4LTC_html_f8ae0c0b5cfc3817.png\|\|height="226" width="600" class="img-thumbnail"]]
1.1	569
3.1	570	Output(MV) upper threshold: BFM #65/#103/#141/#179
1.1	571
	572	Output(MV) lower threshold: BFM #66/#104/#142/#180
	573
3.1	574	* BFM #65/#103/#141/#179 are used for output upper threshold of CH1/CH2/CH3/CH4.
	575	* BFM #66/#104/#142/#180 are used for output lower threshold of CH1/CH2/CH3/CH4.
1.1	576
	577	These BFMs could be used for setting the upper threshold and the lower threshold of the control output value (MV) (BFM #46/#84/#122/#160). The range of the upper threshold is from the lower threshold of the output limiter to 2000. The range of the upper threshold is from 0 to the upper threshold of the output limiter.
	578
	579	(% style="text-align:center" %)
3.1	580	[[image:LX3V-4LTC_html_39b35ec1eae61e45.png\|\|height="222" width="400" class="img-thumbnail"]]
1.1	581
	582	1. Proper PID constants could not be obtained during self-tuning while the output limiter is active. So it is not recommended not to use the output limiter when self-tuning is active.
	583	1. The output limiter would not be active when two-position control is active,.
3.1	584	1. If lower threshold and self-tuning is active, please set the upper and lower threshold for PV, otherwise the temperature may continue to rise, and out of system control
1.1	585
3.1	586	Alarm mode setting: BFM#68/ BFM#106/ BFM#144/ BFM#182
1.1	587
	588	LX3V-4LTC has 12 alarm modes. Four of them most could be used meanwhile. BFM #68 is used for CH1 alarm mode, BFM#106 is used for CH2 alarm mode, BFM#144 is used for CH3 mode, BFM#182 is used for CH4 alarm mode.
	589
	590	Each channel could have four alarm modes.
	591
	592	(% style="text-align:center" %)
3.1	593	[[image:LX3V-4LTC_html_de0e4e05bfd9b167.gif\|\|height="166" width="500" class="img-thumbnail"]]
1.1	594
	595	Example: BFM#68=H0021 means CH1 has the following four type alarm modes: the first is upper threshold alarm, second is lower threshold, third is close alarm, and fourth is close alarm.
	596
	597	For detailed please refer to the following table
	598
	599	(((
	600	(% class="table-bordered" %)
3.1	601	\|(% style="width:88px" %)Alarm No.\|(% style="width:238px" %)Alarm mode\|(% style="width:608px" %)Description\|(% style="width:141px" %)Set range
	602	\|(% style="width:88px" %)0\|(% style="width:238px" %)Alarm is disabled\|(% style="width:608px" %)Alarm function is disabled.\|(% style="width:141px" %)~-~--
	603	\|(% style="width:88px" %)1\|(% style="width:238px" %)Alarm for Upper threshold of input value\|(% style="width:608px" %)Alarms if measured value (PV) is more than value of alarm.\|(% style="width:141px" %)Input range
	604	\|(% style="width:88px" %)2\|(% style="width:238px" %)Alarm for lower threshold of input value\|(% style="width:608px" %)Alarms if measured value (PV) is less than value of alarm.\|(% style="width:141px" %)Input range
	605	\|(% style="width:88px" %)3\|(% style="width:238px" %)Alarm for upper threshold deviation\|(% style="width:608px" %)Alarms if deviation (= Measured value (PV) – Set value (SV)) is more than value of alarm.\|(% style="width:141px" %)±Input width
	606	\|(% style="width:88px" %)4\|(% style="width:238px" %)Alarm for lower threshold deviation\|(% style="width:608px" %)Alarms if deviation (= Measured value (PV) – Set value (SV)) is less than value of alarm.\|(% style="width:141px" %)±Input width
	607	\|(% style="width:88px" %)5\|(% style="width:238px" %)Alarm for Upper/lower limit deviation\|(% style="width:608px" %)Alarms if absolute deviation (= Measured value (PV) – Set value (SV)) is less than value of alarm.\|(% style="width:141px" %)+Input width
	608	\|(% style="width:88px" %)6\|(% style="width:238px" %)Range alarm\|(% style="width:608px" %)Alarms if absolute deviation (= Measured value (PV) – Set value (SV)) is less than value of alarm.\|(% style="width:141px" %)+Input width
	609	\|(% style="width:88px" %)7\|(% style="width:238px" %)Alarm for upper threshold input value alarm with wait\|(% style="width:608px" %)Alarms if measured value (PV) is more than set value, However, measured value is ignored at the start of system.\|(% style="width:141px" %)Input range
	610	\|(% style="width:88px" %)8\|(% style="width:238px" %)Alarm for lower threshold input value alarm with wait\|(% style="width:608px" %)Alarms if measured value (PV) is less than set value, However, measured value are ignored at the start of system.\|(% style="width:141px" %)Input range
	611	\|(% style="width:88px" %)9\|(% style="width:238px" %)Alarm for upper threshold deviation with wait\|(% style="width:608px" %)Alarms if deviation (= Measured value (PV) – Set value (SV)) is more than value of alarm. However, measured value is ignored at the start of system.\|(% style="width:141px" %)±Input width
	612	\|(% style="width:88px" %)10\|(% style="width:238px" %)Alarm for lower threshold deviation with wait\|(% style="width:608px" %)Alarms if deviation (= Measured value (PV) – Set value (SV)) is less than value of alarm. However, measured value is ignored at the start of system.\|(% style="width:141px" %)±Input width
	613	\|(% style="width:88px" %)11\|(% style="width:238px" %)Alarm for Upper/lower limit deviation with wait\|(% style="width:608px" %)Alarms if absolute deviation (= Measured value (PV) – Set value (SV)) is less than value of alarm. However, measured value is ignored at the start of system.\|(% style="width:141px" %)+Input width
1.1	614	)))
	615
6.1	616	(% class="box infomessage" %)
	617	(((
1.1	618	✎Note:
	619
	620	* Input range: it is from the lower threshold to the upper threshold of input value
	621	* Input width: Width from the lower threshold to the upper threshold of input value (Input width = Upper threshold value - Lower threshold value).
	622	* ±Input width: it could be positive and negative.
	623	* + Input width: it could be positive only.
6.1	624	)))
1.1	625
3.1	626	Alarm dead zone setting
1.1	627
	628	BFM #73 is used for the dead zone of alarms 1 to 4 for CH1. BFM #111 is used for the dead zone of alarms 1 to 4 for CH2. BFM #149 is used for the dead zone of alarms 1 to 4 for CH3. BFM #187 is used for the dead zone of alarms 1 to 4 for CH4. When the measured value (PV) is near the alarm set value, the alarm status and the non-alarm status may be repeated by fluctuation in input area. In this case, setting the alarm dead zone could avoid the repeating of the alarm status and the non-alarm status.
	629
	630	The allowable set range is the input range (from 0.0 to 10.0 %.)
	631
	632	Calculation of dead zone
	633
	634	In deviation mode: dead zone =(SV+ deviation)*dead zone
	635
	636	In upper/lower threshold mode: dead zone=alarm setting value*dead zone
	637
3.1	638	* Upper threshold input alarm and upper threshold deviation alarm
1.1	639
	640	(% style="text-align:center" %)
3.1	641	[[image:LX3V-4LTC_html_5d9062fb0bab5b33.png\|\|height="198" width="600" class="img-thumbnail"]]
1.1	642
3.1	643	* Lower threshold input alarm and lower threshold deviation alarm
1.1	644
	645	(% style="text-align:center" %)
3.1	646	[[image:LX3V-4LTC_html_89ce396354c991f8.png\|\|height="190" width="600" class="img-thumbnail"]]
1.1	647
3.1	648	* Upper/lower threshold deviation alarm
1.1	649
	650	(% style="text-align:center" %)
3.1	651	[[image:LX3V-4LTC_html_6f9dd5f8d717395.png\|\|height="241" width="600" class="img-thumbnail"]]
1.1	652
3.1	653	Number of times of alarm delay
1.1	654
	655	BFM #74/#112/#150/#188 are used for the number of alarm delays of CH1/CH2/CH3/CH4 respectively. This setting is active for all alarms 1 to 4.
	656
	657	The alarm delay function keeps non-alarm status until the number of input samples exceeds the number of alarm delays, after the deviation between the measured value (PV) and the set value (SV) reaches the alarm set value. If the deviation is in the alarm range, the Alarm happens when the deviation remains in the alarm range until the number of input samples exceeds the number of alarm delays
	658
	659	Example: the number of alarm delay sets to 5 times
	660
	661	(% style="text-align:center" %)
3.1	662	[[image:LX3V-4LTC_html_1094d322a8c61ac3.png\|\|height="346" width="600" class="img-thumbnail"]]
1.1	663
3.1	664	Address of value range error
1.1	665
	666	When there has an out-of-range error occurs in the set value, BFM #75/#113/#151/#189 will show the error address,
	667
	668	BFM #75/#113/#151/#189 sets to "0" when no error happens.
	669
	670	When an error occurs, the value of BFM #75/#113/#151/#189 is the address of BFM has errors, please check the range, and give a normal value for this BFM, please clear the error after that (BFM#41).
	671
3.1	672	Output cycle control
1.1	673
	674	BFM #59 is used for the control output cycle of CH1. BFM #97 is used for the control output cycle of CH2. BFM #135 is used for control output cycle of CH3. BFM #173 is used for the control output cycle of CH4. Control cycle is longer than sampling cycle, the sampling cycle is equal with control output cycle when control cycle is less than sampling cycle.
	675
	676	This value multiplies by the control output value and divided by 2000 is treated as the ON time. This value multiplies by "2000 - Control cycle value ~(%)/2000" is the OFF time.
	677
	678	The allowable range of this value is from 1 to 100 sec.
	679
	680	(% style="text-align:center" %)
3.1	681	[[image:LX3V-4LTC_html_79f827d969cd03f8.png\|\|height="102" width="500" class="img-thumbnail"]]
1.1	682
	683	= 6 Program Example =
	684
3.1	685	Keep doing nothing while the power is supplied.
1.1	686
	687	If you touch a terminal while the power is supplied, you may get electrical shock or the unit may malfunction.
	688
3.1	689	Make sure the power be OFF before cleaning the unit or tightening the terminals.
1.1	690
	691	If you clean the unit or tighten the terminals while the power is supplied, you may get electrical shock.
	692
3.1	693	To run temperature control module in safe, please read this manual carefully firstly.
1.1	694
	695	Damages or accidents would happen if the operations is not right.
	696
3.1	697	Never disassemble or modify the unit. Disassembly or modification may cause failure, malfunction amd fire.
1.1	698
	699	~* For repair, contact WECON Technology Co., Ltd.
	700
3.1	701	Make sure power is off before wiring.
1.1	702
	703	Failure or malfunction maybe happen because of wiring during power is on.
	704
	705	Simple example
	706
	707	In this example, LX3V-4LTC module occupies the position of No.2 special module (This is the 3rd model connects with CPU). CH1 connects with K type thermocouple, CH2 connects with J type thermocouple, CH3 and CH4 connects with E type thermocouple, the average is 4. The value of CH1~~CH4 are written to D0~~D3.
	708
	709	(% style="text-align:center" %)
3.1	710	[[image:LX3V-4LTC_html_aebb33707de8c24a.png\|\|height="116" width="600" class="img-thumbnail"]]
1.1	711
	712	Initialization to check if the No.2 special module is LX3V-4LTC. The ID code should be as K2130 (BFM#30).
	713
	714	Program example
	715
3.1	716	* Input range: K type ~-~- 100.0 to 400.0 °C
	717	* PID values: it is determined by auto-tuning
	718	* Alarm: Upper threshold alarm is 820 and lower threshold alarm is 780
	719	* Heater/cooling control: Heater (Initialization)
1.1	720
3.1	721	Device assignment:
1.1	722
3.1	723	* X000: initialization
	724	* X001: Reset the flag of error bit.
	725	* X002: Control starts (ON)/stop (OFF);
	726	* X003: self-tuning beginning when it changes from 0 to 1.
	727	* M0~~M15: Flags of error
	728	* M20~~M35: Flags of events
	729	* D0~~D199: Read value from BFM
	730	* D200~~D399: Write set value(SV) into BFM
1.1	731
3.1	732	Project:
1.1	733
	734	(% style="text-align:center" %)
3.1	735	[[image:LX3V-4LTC_html_c23b907303de1a1d.png\|\|height="770" width="700" class="img-thumbnail"]]
1.1	736
	737	= 7 Diagnostic =
	738
	739	Basic check
	740
	741	* Check whether the input/output wiring and/or extension cables are properly connected with LX3V-4LTC analog special function block
	742	* All configurations should follow the rule of LX3V configuration. The number of special function blocks does not exceed 16 and the total number of PLC system should exceed 256.
	743	* Ensure that all operating ranges is normal.
	744	* Ensure there is no power overload in either the 5V or 24V power supplies, Warning: the load for LX3V MPU or other powered extension unit is variable with the number of modules or special modules .
	745	* The main processing unit (MPU) is in RUN status.
	746
	747	Error checking
	748
	749	If LX3V-4LTC cannot run properly, please check the following items.
	750
	751	* Check the status of the POWER LED.
	752
	753	Lit: The extension cable is connected properly.
	754
	755	Otherwise: Check the connection of the extension cable.
	756
	757	* Check the external wiring.
	758	* Check the status of the “24V” LED (top right corner of the LX3V-4LTC).
	759
	760	Lit:LX3V-4LTC is ON, 24V DC power source is ON.
	761
	762	Otherwise: Possible 24VDC power failure, if ON possible LX3V-4LTC failure.
	763
	764	* Check the status of the “A/D” LED (top right corner of the LX3V-4LTC).
	765
	766	Lit: A/D conversion is proceeding normally.
	767
	768	Otherwise :Check buffer memory #29 (error status). If any bits (b0, b2, b3) are ON, then this is why the A/D LED is OFF.

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