Step Motors
NEMA Size 8
Step Size 1.8°
NEMA Size 11
Step Size 1.8°
NEMA Size 14
Step Size 0.9°
Step Size 1.8°
NEMA Size 17
Step Size 0.9°
Step Size 1.8°
NEMA Size 23
Step Size 0.45°
Step Size 0.9°
Step Size 1.8°
NEMA Size 34
Step Size 1.8°
Integrated Motors
NEMA Size 17 - 1.8°
SilverPak 17C
SilverPak 17CE
SilverPak 17D
SilverPak 17DE
SilverPak 17T
NEMA Size 23 - 1.8°
SilverPak 23C
SilverPak 23CE
SilverPak 23D
SilverPak 23DE
BLDC Motors
NEMA Size 23
BL24A
BL25A
NEMA Size 17
BL17A
Drivers / Controllers
Drivers
R208
R701/R710°
R325
Drivers + Controllers
R256
R356
R364
Trinamic-Microchips
Trinamic - Microchips
Power Supplies
PW-100 Series
PW-150 Series
Optical Encoders
E2 Encoder
E3 Encoder
E4 Encoder
E5 Encoder
Planetary Gears
PM Planetary
CGI Planetary
Accessories
RS485 to RS232 Converter
USB485 Converter
Configuration Module
Nema17 Damper
Nema23 Damper
Additional Info
Custom Designs
Wiring Connections
Motor Operating Specifications
Application Data Sheet
Motor Numbering System
Linear Actuators
Maximizing Torque
 
 
 

Stepper motors have a natural tendency to want to move towards their full step ON position. This magnetic pull is called the detent torque of the motor, which causes a jerking motion as the motor nears these positions. In a bipolar stepper motor, one phase will have 100% current and the other phase will have 0% current (this is what we’ll call the zero crossing point). Phases A and B are 90° offset and both have a sinusoidal current waveforms.




Engineers in the Motion Control Industry have gone through the trial and error process, tweaking the current sine waves in order to alleviate the “jerk” that the motor makes as it is forcefully pulled towards the zero crossing spots. However, these zero crossing spots are sensitive to the minimal amount of change so altering the waveform can greatly affect other areas of the driver’s performance.


The R325 Driver and SilverPak 23D Integrated Step Motor + Driver output the right amount of both holding and running current into the motor to overcome the motor’s detent torque. The following graphs use the same step motor to run the step-to-step tests. The R325 and a comparable driver were both set to 64 microstepping, the shaft of the motor was aligned to an encoder which graphed the position of the motor over time.

dline

Figure 1.2 Comparative Driver with Spike

As shown in the above graph, the spikes occur because of the step motor’s poles, forcefully being pulled towards each other. These uneven steps translate into a negative affective on the step motor’s accuracy and smooth motion.


dline

Figure 1.2 R325 Driver with Pole Damping Technology

Pole Damping Technology, dampens each step as it nears the full step positions where the poles are the strongest. When using a product with PDT, the spikes are eliminated resulting in smoother motion and higher accuracy.

dline
Pole Damping Technology™ Benefits Applications that Require:
BETTER ACCURACY - SMOOTHER MOTION - HIGHER PRECISION
DEMO VIDEO
 
744
BG PRODUCTS THAT CURRENTLY UTILIZE PDT:
 
SilverPak 23D
• NEMA Size 23, 2 Phase, 1.8° Bipolar Step Motor
w/Built-In Microstepping Driver
• Up to 294 oz-in of holding torque
• Operates from +15 to 48 VDC
• Phase currents from 0.3 to 3.0 Amps Peak
• Step Resolutions from Half Step to 256x Microstepping
• Four Selectable Damping Modes
R325
• Operates from +15 to 48 VDC
• Phase current from 0.3 to 3.0 Amps Peak
• Step Resolutions from Full to 256x Microstepping
• Hold current reduction capability with
adjustable current and timeout settings
Also available with Indexer and Static Encoder Feedback Options
Click Here
Click Here