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Changes for page 07 Adjustments

Last modified by Iris on 2025/07/24 11:03
From version 14.13
edited by Stone Wu
on 2022/07/06 15:34
Change comment: (Autosaved)
To version 14.7
edited by Stone Wu
on 2022/07/06 15:14
Change comment: There is no comment for this version

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137 137  
138 138  When debugging with the host computer debugging software, automatic rigidity level measurement can be carried out, which is used to select a set of appropriate rigidity grades as operating parameters. The operation steps are as follows:
139 139  
140 -* Step1 Confirm that the servo is in the ready state, the panel displays “rdy”, and the communication line is connected;
141 -* Step2 Open the host computer debugging software, enter the trial run interface, set the corresponding parameters, and click "Servo on";
142 -* Step3 Click the "forward rotation" or "reverse rotation" button to confirm the travel range of the servo operation;
143 -* Step4 After the "start recognition" of inertia recognition lights up, click "start recognition" to perform inertia recognition, and the load inertia can be measured.
144 -* Step5 After the inertia recognition test is completed, click "Save Inertia Value";
145 -* Step6 Click "Next" at the bottom right to go to the parameter adjustment interface, and click "Parameter measurement" to start parameter measurement.
146 -* Step7 After the parameter measurement is completed, the host computer debugging software will pop up a confirmation window for parameter writing and saving.
140 +Step1 Confirm that the servo is in the ready state, the panel displays “rdy”, and the communication line is connected;
147 147  
142 +Step2 Open the host computer debugging software, enter the trial run interface, set the corresponding parameters, and click "Servo on";
143 +
144 +Step3 Click the "forward rotation" or "reverse rotation" button to confirm the travel range of the servo operation;
145 +
146 +Step4 After the "start recognition" of inertia recognition lights up, click "start recognition" to perform inertia recognition, and the load inertia can be measured.
147 +
148 +Step5 After the inertia recognition test is completed, click "Save Inertia Value";
149 +
150 +Step6 Click "Next" at the bottom right to go to the parameter adjustment interface, and click "Parameter measurement" to start parameter measurement.
151 +
152 +Step7 After the parameter measurement is completed, the host computer debugging software will pop up a confirmation window for parameter writing and saving.
153 +
148 148  (% class="table-bordered" %)
149 149  |(% style="text-align:center; vertical-align:middle" %)[[image:image-20220611152634-2.png]]
150 150  |(((
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223 223  
224 224  Table 7-5 Speed loop gain parameters
225 225  
226 -(% style="text-align:center" %)
227 -[[image:image-20220706152743-1.jpeg]]
228 -
229 -Figure 7-3 Speed loop gain effect illustration
230 -
231 231  **(2) Speed loop integral time constant**
232 232  
233 233  The speed loop integral time constant is used to eliminate the speed loop deviation. Decreasing the integral time constant of the speed loop can increase the speed of the speed following. If the set value is too small, is will easily cause speed overshoot or vibration. When the time constant is set too large, the integral action will be weakened, resulting in a deviation of the speed loop. Related function codes are shown as below.
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263 263  
264 264  Table 7-6 Speed loop integral time constant parameters
265 265  
266 -(% style="text-align:center" %)
267 -[[image:image-20220706153140-2.jpeg]]
268 -
269 -Figure 7-4 Speed loop integral time constant effect illustration
270 -
271 271  **(3) Position loop gain**
272 272  
273 273  Determine the highest frequency of the position instruction that the position loop can follow the change. Increasing this parameter can speed up the positioning time and improve the ability of the motor to resist external disturbances when the motor is stationary. However, if the setting value is too large, the system may be unstable and oscillate. The related function codes are shown as below.
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