Changes for page 06 Operation

Summary

• Page properties (2 modified, 0 added, 0 removed)

Details

Page properties

Author

...	...	@@ -1,1 +1,1 @@
1		-XWiki.Stone
	1	+XWiki.Jim

Content

...	...	@@ -1724,7 +1724,7 @@
1724	1724	)))|=(((
1725	1725	**Effective time**
1726	1726	)))|=**Default value**|=**Range**|=**Definition**|=**Unit**
1727		-|=P01-08|Torque instruction source|(((
	1727	+|=P01-07|Torque instruction source|(((
1728	1728	Shutdown setting
1729	1729	)))|(((
1730	1730	Effective immediately
...	...	@@ -1953,7 +1953,7 @@
1953	1953
1954	1954	✎**Note:** Function codes P01-17 and P01-18 are only effective in limiting motor speed under the torque mode. The speed limit value is set according to load requirements. To set speed limit in speed mode or position mode, please refer to __[[6.3.3 Speed instruction limit>>https://docs.we-con.com.cn/bin/view/Servo/Manual/02%20VD2%20SA%20Series/06%20Operation/#HSpeedinstructionlimit]]__.
1955	1955
1956		-== **Torque-related DO output functions** ==
	1956	+== Torque-related DO output functions ==
1957	1957
1958	1958	The feedback value of torque instruction is compared with different thresholds, and could output the DO signal for the host computer use. The DO terminal of the servo drive is assigned to different functions and determine the logic to be valid.
1959	1959
...	...	@@ -1962,26 +1962,27 @@
1962	1962	The torque arrival function is used to determine whether the actual torque instruction reaches the set interval. When the actual torque instruction reaches the torque instruction threshold, the servo drive outputs a torque arrival signal (T-COIN) for the host computer use.
1963	1963
1964	1964	(% style="text-align:center" %)
1965		-[[image:image-20220608173541-42.png]]
	1965	+(((
	1966	+(% class="wikigeneratedid" style="display:inline-block" %)
	1967	+[[**Figure 6-47 Torque arrival output diagram**>>image:image-20220608173541-42.png||id="Iimage-20220608173541-42.png"]]
	1968	+)))
1966	1966
1967		-Figure 6-47 Torque arrival output diagram
	1970	+To use the torque arrival function, a DO terminal of the servo drive should be assigned to function 138 (T-COIN, torque arrival). The function code parameters and related DO function codes are shown in __Table 6-49__ and __Table 6-50__.
1968	1968
1969		-To use the torque arrival function, a DO terminal of the servo drive should be assigned to function 138 (T-COIN, torque arrival). The function code parameters and related DO function codes are shown in __[[Table 6-49>>https://docs.we-con.com.cn/bin/view/Servo/2.%20User%20Manual/06%20VD2%20SA%20Series%20Servo%20Drives%20Manual%20%28Full%20V1.1%29/06%20Operation/#HTorque-relatedDOoutputfunctions]]__ and __[[Table 6-50>>https://docs.we-con.com.cn/bin/view/Servo/2.%20User%20Manual/06%20VD2%20SA%20Series%20Servo%20Drives%20Manual%20%28Full%20V1.1%29/06%20Operation/#HTorque-relatedDOoutputfunctions]]__.
1970		-
1971		-|**Function code**|**Name**|(((
	1972	+|=(% scope="row" %)**Function code**|=(% style="width: 113px;" %)**Name**|=(% style="width: 100px;" %)(((
1972	1972	**Setting method**
1973		-)))|(((
	1974	+)))|=(% style="width: 124px;" %)(((
1974	1974	**Effective time**
1975		-)))|**Default value**|**Range**|**Definition**|**Unit**
1976		-|P05-20|(((
	1976	+)))|=(% style="width: 83px;" %)**Default value**|=(% style="width: 94px;" %)**Range**|=(% style="width: 421px;" %)**Definition**|=**Unit**
	1977	+|=P05-20|(% style="width:113px" %)(((
1977	1977	Torque arrival
1978	1978
1979	1979	threshold
1980		-)))|(((
	1981	+)))|(% style="width:100px" %)(((
1981	1981	Operation setting
1982		-)))|(((
	1983	+)))|(% style="width:124px" %)(((
1983	1983	Effective immediately
1984		-)))|100|0 to 300|(((
	1985	+)))|(% style="width:83px" %)100|(% style="width:94px" %)0 to 300|(% style="width:421px" %)(((
1985	1985	The torque arrival threshold must be used with “Torque arrival hysteresis value”:
1986	1986
1987	1987	When the actual torque reaches Torque arrival threshold + Torque arrival hysteresis Value, the torque arrival DO is valid;
...	...	@@ -1988,21 +1988,20 @@
1988	1988
1989	1989	When the actual torque decreases below torque arrival threshold-torque arrival hysteresis value, the torque arrival DO is invalid
1990	1990	)))|%
1991		-|P05-21|(((
	1992	+|=P05-21|(% style="width:113px" %)(((
1992	1992	Torque arrival
1993	1993
1994	1994	hysteresis
1995		-)))|(((
	1996	+)))|(% style="width:100px" %)(((
1996	1996	Operation setting
1997		-)))|(((
	1998	+)))|(% style="width:124px" %)(((
1998	1998	Effective immediately
1999		-)))|10|0 to 20|Torque arrival the hysteresis value must be used with Torque arrival threshold|%
	2000	+)))|(% style="width:83px" %)10|(% style="width:94px" %)0 to 20|(% style="width:421px" %)Torque arrival the hysteresis value must be used with Torque arrival threshold|%
2000	2000
2001	2001	Table 6-49 Torque arrival parameters
2002	2002
2003		-
2004		-|**DO function code**|**Function name**|**Function**
2005		-|138|(((
	2004	+|=(% scope="row" %)**DO function code**|=**Function name**|=**Function**
	2005	+|=138|(((
2006	2006	T-COIN torque arrival
2007	2007	)))|Used to determine whether the actual torque instruction has reached the set range
2008	2008
...	...	@@ -2012,35 +2012,28 @@
2012	2012
2013	2013	Mixed control mode means that when the servo enable is ON and the status of the servo drive is "run", the mode of the servo drive could be switched between different modes. The VD2 series servo drives have the following 3 mixed control modes:
2014	2014
2015		-Position mode⇔ Speed mode
	2015	+* Position mode⇔ Speed mode
	2016	+* Position mode ⇔Torque mode
	2017	+* Speed mode ⇔Torque mode
2016	2016
2017		-Position mode ⇔Torque mode
2018		-
2019		-Speed mode ⇔Torque mode
2020		-
2021	2021	Set the function code P00-01 through the software of Wecon “SCTool” or servo drive panel, and the servo drive will run in mixed mode.
2022	2022
2023		-|**Function code**|**Name**|(((
	2021	+|=(% scope="row" %)**Function code**|=**Name**|=(((
2024	2024	**Setting method**
2025		-)))|(((
	2023	+)))|=(((
2026	2026	**Effective time**
2027		-)))|**Default value**|**Range**|**Definition**|**Unit**
2028		-|P00-01|Control mode|(((
	2025	+)))|=**Default value**|=(% style="width: 90px;" %)**Range**|=(% style="width: 273px;" %)**Definition**|=**Unit**
	2026	+|=P00-01|Control mode|(((
2029	2029	Shutdown setting
2030	2030	)))|(((
2031	2031	Shutdown setting
2032		-)))|1|1 to 6|(((
2033		-1: Position control
2034		-
2035		-2: Speed control
2036		-
2037		-3: Torque control
2038		-
2039		-4: Position/speed mixed control
2040		-
2041		-5: Position/torque mixed control
2042		-
2043		-6: Speed/torque mixed control
	2030	+)))|1|(% style="width:90px" %)1 to 6|(% style="width:273px" %)(((
	2031	+* 1: Position control
	2032	+* 2: Speed control
	2033	+* 3: Torque control
	2034	+* 4: Position/speed mixed control
	2035	+* 5: Position/torque mixed control
	2036	+* 6: Speed/torque mixed control
2044	2044	)))|-
2045	2045
2046	2046	Table 6-51 Mixed control mode parameters
...	...	@@ -2047,35 +2047,38 @@
2047	2047
2048	2048	Please set the servo drive parameters in different control modes according to the mechanical structure and indicators. The setting method refer to [[__“Parameters”__>>https://docs.we-con.com.cn/bin/view/Servo/2.%20User%20Manual/06%20VD2%20SA%20Series%20Servo%20Drives%20Manual%20%28Full%20V1.1%29/09%20Parameters/]]. When function code P00-01=4/5/6 (that is, in mixed mode), a DI terminal of the servo drive needs to be assigned to function 17 (MixModeSel, mixed mode selection), and the DI terminal logic is determined to be valid.
2049	2049
2050		-|**DI function code**|**Name**|**Function name**|**Function**
2051		-|17|MixModeSel|Mixed mode selection|Used in mixed control mode, when the servo status is "run", set the current control mode of the servo drive(((
2052		-|**P00-01**|**MixModeSel terminal logic**|**Control mode**
2053		-|(% rowspan="2" %)4|Valid|Speed mode
2054		-|invalid|Position mode
2055		-|(% rowspan="2" %)5|Valid|Torque mode
2056		-|invalid|Position mode
2057		-|(% rowspan="2" %)6|Valid|Torque mode
2058		-|invalid|Speed mode
	2043	+|=(% scope="row" %)**DI function code**|=**Name**|=(% style="width: 187px;" %)**Function name**|=(% style="width: 662px;" %)**Function**
	2044	+|=17|MixModeSel|(% style="width:187px" %)Mixed mode selection|(% style="width:662px" %)Used in mixed control mode, when the servo status is "run", set the current control mode of the servo drive(((
	2045	+(% style="margin-left:auto; margin-right:auto; width:585px" %)
	2046	+|=**P00-01**|=(% style="width: 243px;" %)**MixModeSel terminal logic**|=(% style="width: 220px;" %)**Control mode**
	2047	+|(% rowspan="2" %)4|(% style="width:243px" %)Valid|(% style="width:220px" %)Speed mode
	2048	+|(% style="width:243px" %)invalid|(% style="width:220px" %)Position mode
	2049	+|(% rowspan="2" %)5|(% style="width:243px" %)Valid|(% style="width:220px" %)Torque mode
	2050	+|(% style="width:243px" %)invalid|(% style="width:220px" %)Position mode
	2051	+|(% rowspan="2" %)6|(% style="width:243px" %)Valid|(% style="width:220px" %)Torque mode
	2052	+|(% style="width:243px" %)invalid|(% style="width:220px" %)Speed mode
2059	2059	)))
2060	2060
2061	2061	Table 6-52 Description of DI function codes in control mode
2062	2062
	2057	+(% class="box infomessage" %)
	2058	+(((
2063	2063	✎**Note:** In mixed control mode, it is recommended to switch the mode at zero speed or low speed, and the switching process will be smoother.
	2060	+)))
2064	2064
2065	2065	= **Absolute system** =
2066	2066
2067		-== **Overview** ==
	2064	+== Overview ==
2068	2068
2069	2069	Absolute encoder could detect the position of the servo motor within one turn, and could count the number of turns of the motor. This series of servo drives are equipped with a maximum of 23-bit encoders and could memorize 16-bit multi-turn data, and position, speed, torque control modes could be used. Especially in position control, the absolute value encoder does not need to count, could achieve direct internal high-speed reading and external output, and could significantly reduce the subsequent calculation tasks of the receiving device controller. When the drive is powered off, the encoder uses battery backup data. After power on, the drive uses the encoder's absolute position to calculate the absolute mechanical position, eliminating the need for repeated mechanical origin reset operations.
2070	2070
2071	2071	The absolute value encoder is determined by the mechanical position of the photoelectric code disc, and is not affected by power failure or interference. Each position of the absolute encoder determined by the mechanical position is unique, and no external sensor is required to assist in memorizing position.
2072	2072
2073		-== **Single-turn absolute value system** ==
	2070	+== Single-turn absolute value system ==
2074	2074
2075	2075	The single-turn absolute value system is applicable for the equipment load stroke within the single-turn range of the encoder. At this time, the absolute encoder is only as a single-turn system function and does not need to be connected to the battery. The types and information of encoders adapted to VD2 series servo drives are shown as below.
2076	2076
2077		-
2078		-|**Encoder type**|**Encoder resolution (bits)**|**Data range**
	2074	+|=**Encoder type**|=**Encoder resolution (bits)**|=**Data range**
2079	2079	|A1 (single-turn magnetic encoder)|17|0 to 131071
2080	2080
2081	2081	Table 6-53 Single-turn absolute encoder information
...	...	@@ -2083,17 +2083,18 @@
2083	2083	The relationship between encoder feedback position and rotating load position is shown in the figure below. (take a 17-bit encoder as an example).
2084	2084
2085	2085	(% style="text-align:center" %)
2086		-[[image:image-20220608173618-43.png]]
	2082	+(((
	2083	+(% class="wikigeneratedid" style="display:inline-block" %)
	2084	+[[**Figure 6-48 Diagram of relationship between encoder feedback position and rotating load position**>>image:image-20220608173618-43.png||id="Iimage-20220608173618-43.png"]]
	2085	+)))
2087	2087
2088		-Figure 6-48 Diagram of relationship between encoder feedback position and rotating load position
	2087	+== Multi-turn absolute value system ==
2089	2089
2090		-== **Multi-turn absolute value system** ==
2091		-
2092	2092	The encoder adapted to the multi-turn absolute value system is equipped with 16-bit RAM memory. Compared with the single-turn absolute value, it can additionally memorize the number of turns of the 16-bit encoder. The multi-turn absolute encoder is equipped with a battery (the battery is installed on the encoder cable with a battery unit), which can achieve direct internal high-speed readings and external output without the need for external sensors to assist memory positions. The types and information of encoders adapted to VD2 series servo drives are shown as below.
2093	2093
2094		-|**Encoder type**|**Encoder resolution (bits)**|**Data range**
2095		-|C1 (multi-turn magnetic encoder)|17|0 to 131071
2096		-|D2 (multi-turn Optical encoder)|23|0 to 8388607
	2091	+|=(% scope="row" %)**Encoder type**|=**Encoder resolution (bits)**|=**Data range**
	2092	+|=C1 (multi-turn magnetic encoder)|17|0 to 131071
	2093	+|=D2 (multi-turn Optical encoder)|23|0 to 8388607
2097	2097
2098	2098	Table 6-54 Multi-turn absolute encoder information
2099	2099
...	...	@@ -2100,20 +2100,21 @@
2100	2100	The relationship between encoder feedback position and rotating load multi-turn is shown in the figure below (take a 23-bit encoder as an example).
2101	2101
2102	2102	(% style="text-align:center" %)
2103		-[[image:image-20220608173701-44.png]]
	2100	+(((
	2101	+(% class="wikigeneratedid" style="display:inline-block" %)
	2102	+[[**Figure 6-49 The relationship between encoder feedback position and rotating load position**>>image:image-20220608173701-44.png||id="Iimage-20220608173701-44.png"]]
	2103	+)))
2104	2104
2105		-Figure 6-49 The relationship between encoder feedback position and rotating load position
	2105	+== Related functions and parameters ==
2106	2106
2107		-== **Related functions and parameters** ==
2108		-
2109	2109	**Encoder feedback data**
2110	2110
2111	2111	The feedback data of the absolute value encoder can be divided into the position within 1 turn of the absolute value encoder and the number of rotations of the absolute value encoder. The related information of the two feedback data is shown in the table below.
2112	2112
2113		-|**Monitoring number**|**Category**|**Name**|**Unit**|**Data type**
2114		-|U0-54|Universal|Absolute encoder position within 1 turn|Encoder unit|32-bit
2115		-|U0-55|Universal|Rotations number of absolute encoder|circle|16-bit
2116		-|U0-56|Universal|Multi-turn absolute value encoder current position|Instruction unit|32-bit
	2111	+|=(% scope="row" %)**Monitoring number**|=**Category**|=**Name**|=**Unit**|=**Data type**
	2112	+|=U0-54|Universal|Absolute encoder position within 1 turn|Encoder unit|32-bit
	2113	+|=U0-55|Universal|Rotations number of absolute encoder|circle|16-bit
	2114	+|=U0-56|Universal|Multi-turn absolute value encoder current position|Instruction unit|32-bit
2117	2117
2118	2118	Table 6-55 Encoder feedback data
2119	2119
...	...	@@ -2121,26 +2121,28 @@
2121	2121
2122	2122	The VD2 series absolute value servo drive provides shielded multi-turn absolute encoder battery fault function to shield under voltage and low-voltage fault. You could set by setting the function code P00-30.
2123	2123
2124		-|**Function code**|**Name**|(((
	2122	+|=(% scope="row" %)**Function code**|=**Name**|=(((
2125	2125	**Setting**
2126	2126
2127	2127	**method**
2128		-)))|(((
	2126	+)))|=(((
2129	2129	**Effective**
2130	2130
2131	2131	**time**
2132		-)))|**Default value**|**Range**|**Definition**|**Unit**
2133		-|P00-30|Shield multi-turn absolute encoder battery fault|Operation setting|Power on again|0|0 to 1|(((
2134		-0：Detect multi-turn absolute encoder battery under voltage, and battery low voltage fault
2135		-
2136		-1: (Not recommended) Shield multi-turn absolute motor battery failure alarm. Multi-turn absolute application may cause mechanical fault, only multi-turn absolute encoder motors is used as single-turn absolute
	2130	+)))|=**Default value**|=**Range**|=**Definition**|=**Unit**
	2131	+|=P00-30|Shield multi-turn absolute encoder battery fault|Operation setting|Power on again|0|0 to 1|(((
	2132	+* 0：Detect multi-turn absolute encoder battery under voltage, and battery low voltage fault
	2133	+* 1: (Not recommended) Shield multi-turn absolute motor battery failure alarm. Multi-turn absolute application may cause mechanical fault, only multi-turn absolute encoder motors is used as single-turn absolute
2137	2137	)))|-
2138	2138
2139	2139	This function is permitted when a multi-turn absolute encoder motor is used as a single-turn absolute and when it is confirmed that no mechanical failure will occur.
2140	2140
	2138	+(% class="box infomessage" %)
	2139	+(((
2141	2141	**✎Note: **Be sure to use the shield multi-turn absolute encoder battery fault function carefully, otherwise it may cause data loss, mechanical failure, or even personal injury or death.
	2141	+)))
2142	2142
2143		-== **Absolute value system encoder battery box use precautions**. ==
	2143	+== Absolute value system encoder battery box use precautions. ==
2144	2144
2145	2145	**Cautions**
2146	2146
...	...	@@ -2147,10 +2147,11 @@
2147	2147	Er.40 (Encoder battery failure) will occur when the battery is turned on for the first time, and the function code P10-03 must be set to 1 to clear the encoder fault to operate the absolute value system again.
2148	2148
2149	2149	(% style="text-align:center" %)
2150		-[[image:image-20220707111333-28.png]]
	2150	+(((
	2151	+(% class="wikigeneratedid" style="display:inline-block" %)
	2152	+[[**Figure 6-50 the encoder battery box**>>image:image-20220707111333-28.png||id="Iimage-20220707111333-28.png"]]
	2153	+)))
2151	2151
2152		-Figure 6-50 the encoder battery box
2153		-
2154	2154	When it is detected that the battery voltage is less than 3.1V, A-92 (Encoder battery low voltage warning) will occur. Please replace the battery in time.
2155	2155
2156	2156	**Replace the battery**
...	...	@@ -2166,20 +2166,19 @@
2166	2166
2167	2167	When the servo drive is powered off, if the battery is replaced and powered on again, Er.40 (encoder battery failure) will occur, and the multi-turn data will change suddenly. Please set the function code P10-03 or P10-06 to 1 to clear the encoder fault alarms and perform the origin return function operation again.
2168	2168
2169		-|**Function code**|**Name**|(((
	2170	+|=(% scope="row" %)**Function code**|=**Name**|=(((
2170	2170	**Setting method**
2171		-)))|(((
	2172	+)))|=(((
2172	2172	**Effective time**
2173		-)))|**Default value**|**Range**|**Definition**|**Unit**
2174		-|P10-06|Multi-turn absolute encoder reset|(((
	2174	+)))|=**Default value**|=**Range**|=**Definition**|=**Unit**
	2175	+|=P10-06|Multi-turn absolute encoder reset|(((
2175	2175	Shutdown setting
2176	2176	)))|(((
2177	2177	Effective immediately
2178	2178	)))|0|0 to 1|(((
2179		-0: No operation
	2180	+* 0: No operation
	2181	+* 1: Clear rotation number of multi-turn absolute encoder, multi-turn absolute encoder current position and encoder fault alarms.
2180	2180
2181		-1: Clear rotation number of multi-turn absolute encoder, multi-turn absolute encoder current position and encoder fault alarms.
2182		-
2183	2183	✎**Note: **After resetting the multi-turn data of the encoder, the encoder absolute position will change suddenly, and the mechanical origin return operation is required.
2184	2184	)))|-
2185	2185
...	...	@@ -2187,7 +2187,7 @@
2187	2187
2188	2188	**Battery selection**
2189	2189
2190		-|(% style="width:361px" %)**Battery selection specification**|(% style="width:496px" %)**Item**|(% style="width:219px" %)**Value**
	2190	+|=(% scope="row" style="width: 361px;" %)**Battery selection specification**|=(% style="width: 496px;" %)**Item**|=(% style="width: 219px;" %)**Value**
2191	2191	|(% rowspan="4" style="width:361px" %)(((
2192	2192	Nominal Voltage: 3.6V
2193	2193
...	...	@@ -2215,111 +2215,108 @@
2215	2215
2216	2216	= **Other functions** =
2217	2217
2218		-== **VDI** ==
	2218	+== VDI ==
2219	2219
2220	2220	VDI (Virtual Digital Signal Input Port) is similar to hardware DI terminal. The DI function could also be assigned for use.
2221	2221
	2222	+(% class="box infomessage" %)
	2223	+(((
2222	2222	✎**Note: **If multiple VDI terminals are configured with the same non-zero DI function, servo drive will occur an error “A-89” (DI port configuration is duplicate).
	2225	+)))
2223	2223
2224	2224	Take the VDI_1 terminal assignment forward drive prohibition (03-POT) as an example, and the use steps of VDI are as the figure below.
2225	2225
2226		-
2227	2227	(% style="text-align:center" %)
2228		-[[image:image-20220608173804-46.png]]
	2230	+(((
	2231	+(% class="wikigeneratedid" style="display:inline-block" %)
	2232	+[[**Figure 6-51 VDI_1 setting steps**>>image:image-20220608173804-46.png||id="Iimage-20220608173804-46.png"]]
	2233	+)))
2229	2229
2230		-Figure 6-51 VDI_1 setting steps
2231		-
2232		-|**Function code**|**Name**|(((
	2235	+|=(% scope="row" %)**Function code**|=**Name**|=(((
2233	2233	**Setting method**
2234		-)))|(((
	2237	+)))|=(((
2235	2235	**Effective time**
2236		-)))|**Default value**|**Range**|**Definition**|**Unit**
2237		-|P13-1|Virtual VDI_1 input value|Operation setting|Effective immediately|0|0 to 1|(((
	2239	+)))|=**Default value**|=**Range**|=**Definition**|=**Unit**
	2240	+|=P13-1|Virtual VDI_1 input value|Operation setting|Effective immediately|0|0 to 1|(((
2238	2238	When P06-04 is set to 1, DI_1 channel logic is control by this function code.
2239	2239
2240	2240	VDI_1 input level:
2241	2241
2242		-0: low level
2243		-
2244		-1: high level
	2245	+* 0: low level
	2246	+* 1: high level
2245	2245	)))|-
2246		-|P13-2|Virtual VDI_2 input value|Operation setting|Effective immediately|0|0 to 1|(((
	2248	+|=P13-2|Virtual VDI_2 input value|Operation setting|Effective immediately|0|0 to 1|(((
2247	2247	When P06-07 is set to 1, DI_2 channel logic is control by this function code.
2248	2248
2249	2249	VDI_2 input level:
2250	2250
2251		-0: low level
2252		-
2253		-1: high level
	2253	+* 0: low level
	2254	+* 1: high level
2254	2254	)))|-
2255		-|P13-3|Virtual VDI_3 input value|Operation setting|Effective immediately|0|0 to 1|(((
	2256	+|=P13-3|Virtual VDI_3 input value|Operation setting|Effective immediately|0|0 to 1|(((
2256	2256	When P06-10 is set to 1, DI_3 channel logic is control by this function code.
2257	2257
2258	2258	VDI_3 input level:
2259	2259
2260		-0: low level
2261		-
2262		-1: high level
	2261	+* 0: low level
	2262	+* 1: high level
2263	2263	)))|-
2264		-|P13-4|Virtual VDI_4 input value|Operation setting|Effective immediately|0|0 to 1|(((
	2264	+|=P13-4|Virtual VDI_4 input value|Operation setting|Effective immediately|0|0 to 1|(((
2265	2265	When P06-13 is set to 1, DI_4 channel logic is control by this function code.
2266	2266
2267	2267	VDI_4 input level:
2268	2268
2269		-0: low level
2270		-
2271		-1: high level
	2269	+* 0: low level
	2270	+* 1: high level
2272	2272	)))|-
2273		-|P13-05☆|Virtual VDI_5 input value|Operation setting|Effective immediately|0|0 to 1|(((
	2272	+|=P13-05☆|Virtual VDI_5 input value|Operation setting|Effective immediately|0|0 to 1|(((
2274	2274	When P06-16 is set to 1, DI_5 channel logic is control by this function code.
2275	2275
2276	2276	VDI_5 input level:
2277	2277
2278		-0: low level
2279		-
2280		-1: high level
	2277	+* 0: low level
	2278	+* 1: high level
2281	2281	)))|-
2282		-|P13-06☆|Virtual VDI_6 input value|Operation setting|Effective immediately|0|0 to 1|(((
	2280	+|=P13-06☆|Virtual VDI_6 input value|Operation setting|Effective immediately|0|0 to 1|(((
2283	2283	When P06-19 is set to 1, DI_6 channel logic is control by this function code.
2284	2284
2285	2285	VDI_6 input level:
2286	2286
2287		-0: low level
2288		-
2289		-1: high level
	2285	+* 0: low level
	2286	+* 1: high level
2290	2290	)))|-
2291		-|P13-07☆|Virtual VDI_7 input value|Operation setting|Effective immediately|0|0 to 1|(((
	2288	+|=P13-07☆|Virtual VDI_7 input value|Operation setting|Effective immediately|0|0 to 1|(((
2292	2292	When P06-22 is set to 1, DI_7 channel logic is control by this function code.
2293	2293
2294	2294	VDI_7 input level:
2295	2295
2296		-0: low level
2297		-
2298		-1: high level
	2293	+* 0: low level
	2294	+* 1: high level
2299	2299	)))|-
2300		-|P13-08☆|Virtual VDI_8 input value|Operation setting|Effective immediately|0|0 to 1|(((
	2296	+|=P13-08☆|Virtual VDI_8 input value|Operation setting|Effective immediately|0|0 to 1|(((
2301	2301	When P06-25 is set to 1, DI_8 channel logic is control by this function code.
2302	2302
2303	2303	VDI_8 input level:
2304	2304
2305		-0: low level
2306		-
2307		-1: high level
	2301	+* 0: low level
	2302	+* 1: high level
2308	2308	)))|-
2309	2309
2310	2310	Table 6-57 Virtual VDI parameters
2311	2311
	2307	+(% class="box infomessage" %)
	2308	+(((
2312	2312	✎**Note: **“☆” means VD2F servo drive does not support the function code .
	2310	+)))
2313	2313
2314		-== **Port filtering time** ==
	2312	+== Port filtering time ==
2315	2315
2316	2316	VD2A and VD2B servo drives have 8 hardware DI terminals (DI_1 to DI_8) , and VD2F servo drive has 4 hardware DI terminals (DI_1 to DI_4) . All the DI terminals are normal terminals.
2317	2317
	2316	+|=(% scope="row" style="width: 204px;" %)**Setting value**|=(% style="width: 235px;" %)**DI channel logic selection**|=(% style="width: 637px;" %)**Illustration**
	2317	+|=(% style="width: 204px;" %)0|(% style="width:235px" %)Active high level|(% style="width:637px" %)[[image:image-20220707113050-31.jpeg]]
	2318	+|=(% style="width: 204px;" %)1|(% style="width:235px" %)Active low level|(% style="width:637px" %)[[image:image-20220707113205-33.jpeg||height="166" width="526"]]
2318	2318
2319		-|(% style="width:204px" %)**Setting value**|(% style="width:235px" %)**DI channel logic selection**|(% style="width:637px" %)**Illustration**
2320		-|(% style="width:204px" %)0|(% style="width:235px" %)Active high level|(% style="width:637px" %)[[image:image-20220707113050-31.jpeg]]
2321		-|(% style="width:204px" %)1|(% style="width:235px" %)Active low level|(% style="width:637px" %)[[image:image-20220707113205-33.jpeg||height="166" width="526"]]
2322		-
2323	2323	Table 6-58 DI terminal channel logic selection
2324	2324
2325	2325	== **VDO** ==
...	...	@@ -2329,51 +2329,49 @@
2329	2329	Take the DO_2 terminal as communication VDO, and the use steps of VDI are as the figure below.
2330	2330
2331	2331	(% style="text-align:center" %)
2332		-[[image:image-20220608173957-48.png]]
	2329	+(((
	2330	+(% class="wikigeneratedid" style="display:inline-block" %)
	2331	+[[**Figure 6-52 VDO_2 setting steps**>>image:image-20220608173957-48.png||id="Iimage-20220608173957-48.png"]]
	2332	+)))
2333	2333
2334		-Figure 6-52 VDO_2 setting steps
2335	2335
2336		-|**Function code**|**Name**|(((
	2335	+|=(% scope="row" %)**Function code**|=**Name**|=(((
2337	2337	**Setting method**
2338		-)))|(((
	2337	+)))|=(((
2339	2339	**Effective time**
2340		-)))|**Default value**|**Range**|**Definition**|**Unit**
2341		-|P13-11|Communication VDO_1 output value|Operation setting|Effective immediately|0|0 to 1|(((
	2339	+)))|=**Default value**|=**Range**|=**Definition**|=**Unit**
	2340	+|=P13-11|Communication VDO_1 output value|Operation setting|Effective immediately|0|0 to 1|(((
2342	2342	VDO_1 output level：
2343	2343
2344		-0: low level
2345		-
2346		-1: high level
	2343	+* 0: low level
	2344	+* 1: high level
2347	2347	)))|-
2348		-|P13-12|Communication VDO_2 output value|Operation setting|Effective immediately|0|0 to 1|(((
	2346	+|=P13-12|Communication VDO_2 output value|Operation setting|Effective immediately|0|0 to 1|(((
2349	2349	VDO_2 output level：
2350	2350
2351		-0: low level
2352		-
2353		-1: high level
	2349	+* 0: low level
	2350	+* 1: high level
2354	2354	)))|-
2355		-|P13-13|Communication VDO_3 output value|Operation setting|Effective immediately|0|0 to 1|(((
	2352	+|=P13-13|Communication VDO_3 output value|Operation setting|Effective immediately|0|0 to 1|(((
2356	2356	VDO_3 output level：
2357	2357
2358		-0: low level
2359		-
2360		-1: high level
	2355	+* 0: low level
	2356	+* 1: high level
2361	2361	)))|-
2362		-|P13-14|Communication VDO_4 output value|Operation setting|Effective immediately|0|0 to 1|(((
	2358	+|=P13-14|Communication VDO_4 output value|Operation setting|Effective immediately|0|0 to 1|(((
2363	2363	VDO_4 output level：
2364	2364
2365		-0: low level
2366		-
2367		-1: high level
	2361	+* 0: low level
	2362	+* 1: high level
2368	2368	)))|-
2369	2369
2370	2370	Table 6-59 Communication control DO function parameters
2371	2371
2372		-|**DO function number**|**Function name**|**Function**
2373		-|145|COM_VDO1 communication VDO1 output|Use communication VDO
2374		-|146|COM_VDO1 communication VDO2 output|Use communication VDO
2375		-|147|COM_VDO1 communication VDO3 output|Use communication VDO
2376		-|148|COM_VDO1 communication VDO4output|Use communication VDO
	2367	+|=(% scope="row" %)**DO function number**|=**Function name**|=**Function**
	2368	+|=145|COM_VDO1 communication VDO1 output|Use communication VDO
	2369	+|=146|COM_VDO1 communication VDO2 output|Use communication VDO
	2370	+|=147|COM_VDO1 communication VDO3 output|Use communication VDO
	2371	+|=148|COM_VDO1 communication VDO4output|Use communication VDO
2377	2377
2378	2378	Table 6-60 VDO function number
2379	2379
...	...	@@ -2381,16 +2381,16 @@
2381	2381
2382	2382	If multiple DO terminals are configured with the same non-128 DI function, servo drive will occur an error “A-90” (DO port configuration is duplicate).
2383	2383
2384		-== **Motor overload protection** ==
	2379	+== Motor overload protection ==
2385	2385
2386	2386	VD2 Series absolute encoder (VD2SA) servo drive provides motor overload protection to prevent motor burning due to high temperature. By setting function code P10-04 to modify motor overload alarm (A-82) and motor overload protection fault time (Er.34). The default value of P10-04 is 100%.
2387	2387
2388		-|**Function code**|**Name**|(((
	2383	+|=(% scope="row" %)**Function code**|=**Name**|=(((
2389	2389	**Setting method**
2390		-)))|(((
	2385	+)))|=(((
2391	2391	**Effective time**
2392		-)))|**Default value**|**Range**|**Definition**|**Unit**
2393		-|P10-04|motor overload protection time coefficient|Operation setting|Effective immediately|100|0 to 800|(((
	2387	+)))|=**Default value**|=**Range**|=**Definition**|=**Unit**
	2388	+|=P10-04|motor overload protection time coefficient|Operation setting|Effective immediately|100|0 to 800|(((
2394	2394	According to the heating condition of the motor, the value could be modified to make the overload protection time float up and down in the reference value.
2395	2395
2396	2396	50 corresponds to 50%, that is, the time is reduced by half. 300 corresponds to 300%, that is, the time extended to 3 times. When the value is set to 0, the overload protection fault detection function is disabled