Date Published:Aug. 03. 2020

Advancements in Servomotor Coupling Technology

Advancements in Servomotor Coupling Technology

 Flexible couplings are machine elements that fasten drive shafts and transmit torque while allowing for multiple forms of misalignment such as lateral, angular, and axial. Various flexible coupling types have been developed based on application demands.
 Couplings used in servo systems with specific feedback mechanisms are often selected due to their static torsional stiffness and backlash-free features which are integral requirements for high precision and high-speed applications. Typically, users are accustomed to utilizing the disk coupling with static torsional stiffness capability (Pic.1*).
 Recent technological improvements in servomotors have led to dramatic improvement in speed response frequency. Vibration (aka “hunting”) occurrence tends to arise as when increased gain settings are applied to servo systems using high static torsional stiffness coupling such as the disk or bellows type (Pic.2**).
 A potential solution to resolve hunting while operating servo system at high gain settings involves equipping the coupling with vibration damping technology. Further discussion will analyze the extent of the high-gain rubber type coupling’s features as a solution for high response mandatory servo systems designed for the semiconductor manufacturing equipment as well as many other automation fields.

*Pic. 1 Disk type 

**Pic. 2 Bellows type

***Pic. 3 High-gain rubber type

Stabilization Time’s Effect on Productivity

 Integrated damping technology has the ability to greatly reduce stabilization time for speed purposes, but increase productivity as whole.
 The interplay between a feed screw machine with a ball screw and servomotor system illustrates a potential operation issue. For feed screw related applications which utilize both servomotors and ball screws, the ideal scenario dictates that operation proceeds in exact accordance with the servomotor's commands; however, real life scenarios may experience a situation where executed commands are delayed. Delayed response is a factor in errant positioning, and this delayed response is known as stabilization time (See Fig. 1).

 

●Fig. 1 Stabilization time

 Higher servomotor gain and high-response operation are required for reduced stabilization time (Fig. 2), but substantial gain increases are likely to lead to the counterproductive hunting phenomena. Hunting, in effect, will distort the application’s operating equilibrium and disable servo-motor control. Increasing the gain while suppressing hunting requires systematic adjustments to the servomotor parameters such as reviewing the coupling’s mechanical characteristics.
 Tests have shown that when a servomotor contains a disk or bellows couplings that raising the gain tends to cause hunting occurrence much more readily. When hunting occurs, conventional wisdom proposes switching to a coupling with higher torsional stiffness to increase the rigidity of the entire rotating system. However, the torsional rigidity of the entire system is dependent on the torsional rigidity of the ball screw.


●Fig. 2 Change in stabilization time due to gain

 Table 1 shows the calculated values of the torsional rigidity of the entire system utilizing different couplings. The torsional rigidity value of the disk coupling is 450 N.m/rad compared to the highgain rubber type coupling value of 240 N.m/rad. Strictly examining the values, one would conclude that the disk coupling has 1.9 times higher torsional stiffness values. Further examination reveals that the torsional rigidity of the entire system with a disk coupling is 79 N.m/rad for the former and 68 N.m/rad for the latter, making the actual difference about 1.2 times. In other words, the torsional rigidity of the ball screw is the greater determining factor for the torsional rigidity of the entire system, not the coupling. Simply changing the coupling with inherent higher torsional stiffness values may not sufficiently improve the torsional rigidity of the entire system nor provide protection against hunting occurrence. 

 

●Table 1 Torsional rigidity of the entire system

  Values (Units)  Disk type   High-gain rubber type 
Torsional rigidity of coupling: Kc (N.m/rad)
 450  240
 Ball screw groove diameter (mm)
 7.8  7.8
 Support bearing - Nut distance (mm)  300  300
 Torsional rigidity of ball screw: Kbs (N.m/rad)  96  96
 Torsional rigidity of entire system*: K (N.m/rad)  79  68
*Torsional rigidity of the entire system: 1/K = 1/Kc + 1/Kbs
 

Technical advancements in servomotors especially in speed response frequency (Fig. 3) have made the need for increased vibration damping capability even more pronounced to avoid hunting. Ultimately, vibration damping along with adequate statistic torsional stiffness allows for accurate repeat position repeatability to ensure positioning accuracy.


●Fig. 3 Industry changes in servomotor speed response frequency*
(Note: Based on servomotor speed response frequency manufactures’ catalog values)

1.Purpose

Testing was conducted to see the relationship between a coupling's static torsional stiffness and positioning repeatability on an actuator.
 

2.Testing equipment

 Equipment  Part numbers  Notes
 Actuator  KR30H  Positioningrepeatability:±0.005(mm)
 Position accuracy:±0.1(mm)
 Motor  HF-KP013  
 Couplings

XGT-25C-6-8

(High-gain rubber type)

 Static Torsional Stiffness: 170(Nm/rad) 

XBW-25C2-6-8

(Disk type)

 Static Torsional Stiffness: 850(Nm/rad) 

MJT-20C-RD-6-8

(Jaw Type)

 Static Torsional Stiffness: 55(Nm/rad)
 Laser Displacement Sensor   XL-80  

3. Method

Testing methodology adheres to JIS B 6192 (Japanese Industrial Standards) protocols and the testing equipment used the high-gain rubber type, disk type and jaw type couplings where the accuracy of stop position accuracy was measured 7 times.  The gap of Max. and Min. values was calculated and respective values were compared (See test results).  The origin of position is set at both the center and edge for the max range liner stroke. Max value as testing parameter was written in ± (plus minus) with its half value as below. 

4. Testing Conditions

 Motor speed   3000 [min-1]
 Acceleration/deceleration time   50 [ms]
 Positioning location   20 [mm], 170 [mm], 350 [mm]
 Loaded object   3 [kg]

5. Testing Results

   Unit
 High-gain rubber type  Disk type  Jaw type
 Positioning location

[mm]

 20  170  350  20  170  350 20   170  350
 1st  [mm]
 19.9983  170.0387  350.0446  19.9989  170.0382  350.0413  20  170.358  350.0456
 2nd  [mm]
 19.9983
 170.0394  350.0456  19.9988  170.0387  350.042  20  170.363  350.0459
 3rd  [mm]
 19.9983
 170.0385  350.0456  19.9987  170.0375  350.0436  20  170.366  350.0459
 4th  [mm]
 19.9983
 170.0391  350.0452  19.9988  170.0371  350.0433  20  170.357  350.0475
 5th  [mm]
 19.9983
 170.0396  350.0439  19.9989  170.0376  350.0433  20  170.356  350.0466
 6th  [mm]
 19.9984
 170.0387  350.0449  19.9989  170.0371  350.0432  20  170.359  350.0474
 7th  [mm]
 19.9983
 170.0394  350.0469  19.9988  170.0367  350.0426  20  170.368  350.0481
 Max.  [mm]
 19.9984
 170.0396  350.0469  19.9989  170.0387  350.0436  20  170.368  350.0481
 Min.  [mm]
 19.9983
 170.0385  350.0439  19.9987  1703071  350.0413  20  170.356  350.0456
 Gap  [mm]
 1E-04  0.0011  0.003  0.0002  0.0016  0.0023  7E-04  0.0012  0.0025
 Positioning repeatability  [mm]
 0.0015  0.0012  0.0012

 

6. Conclusion

Static Torsional Stiffness does not gravely impact positioning repeatability on actuators.Sub-micron value variations referenced above are likely due to the precision performance of the actuator. 

High-Gain Rubber Coupling’s Unique Construction

The high-gain rubber type coupling has a completely integrated structure in which aluminum hubs on both sides are molded with a vibration-reduction rubber that prevents backlash yet remains flexible. As seen in picture and figure 4, the internal claw-like structure lined with rubber allows for optimal torsional rigidity and damping. 

 

●Pic.4 Structure of high-gain rubber type

 

●Fig. 4 Coupling damping performance comparison

  The Bode plot (Fig. 5)  brilliantly illustrates why the high-gain rubber type coupling has the advantage for increased servomotor gain well beyond the capacity of the disk coupling with higher torsional stiffness values. Gain width between 0 dB and the point where there is a phase delay in the Bode plot is -180° and this is known as the gain margin. General guidelines for servo systems stipulate for setting the gain margin between 10 and 20 dB. As the servomotor gain is increased, the gain margin decreases. When the gain margin falls below 10 dB, hunting tends to occur.
  Comparing the limit gain (servo gain at which hunting occurs) of the disk type to the gain margin of the high-gain rubber type, the high gain rubber type at 17.40 dB surpasses the disk type's 9.90 dB value. Since the gain margin is above 10 dB, the servomotor gain of the high-gain rubber type can be increased beyond that of the disk type thus reducing the stabilization time to allow for increased productivity.


●Fig. 5 Bode plot

Table 2 shows the difference in stabilization time according to the difference in coupling types and servomotor gain. If the servomotor gain is the same, there is no difference in the stabilization time due to the difference in couplings. However, when comparing the servomotor limit gain, the stabilization time is 12 ms for the disk type limit gain (25) and 3 ms for the high-gain rubber type limit gain (32). The high-gain rubber type which suppresses hunting and improves servomotor gain can more effectively reduce the stabilization time.
  

●Table 2 Difference in stabilization time according to coupling type and servomotor gain

Servomotor gain*    Disk type  High-gain rubber type 
 25  12ms  12 ms
 32   Occurrence of hunting   3 ms
* Values with all gains, such as position control gain and speed control gain, adjusted. Additional testing results in an actual system were completed and are shown below as an example.

<Test Devices>
Ball screw shaft diameter: φ15
Servomotor: 100 W
 
<Test Conditions>
Motor revolution: 3,000 min-1
Acceleration/deceleration time: 50 ms
Workpiece load: 3.0 kg
Ratio of moment of inertia of load: 3.5

Rubber Durability

Rubber is used as a component to impart damping properties and data on the durability has been accumulated since the advent of high-gain couplings in 2007.
Fig. 6 shows that even after 100 million drive tests, there is no drop in performance due to rubber deterioration.


●Fig. 6 Results of 100 million drive tests

Future Issues

Servomotors are expected to display even higher frequency response in the future paired with demands for higher precision and higher speed. Couplings technology will continue to require a meld of high torsional rigidity and high-level damping properties to help maintain peek servo system performance.

Recommended product

High-Gain Rubber Couplings  XGT2

Flexible Couplings - The Vibration-Absorption Capable Disk Type  XGHW


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