Rockwell Automation 20G PowerFlex 750-Series AC Drives User Manual

Rockwell Automation Publication 750-RM002B-EN-P - September 2013

205

Motor Control

Chapter 4

3.

The motor inertia and load inertia in kilogram-meters2, or lb•ft

2

.

4.

The gear ratio, if a gear is present between the motor and load, GR.

5.

Review the Speed, Torque Power profile of the application.

Equations used for calculating Dynamic Braking values use the following
variables.

ω

(t) = The motor shaft speed in Radians/second, or

N

(t)

= The motor shaft speed in Revolutions Per Minute, or RPM

T

(t)

= The motor shaft torque in Newton-meters, 1.01 lb•ft - 1.355818N•m

P

(t)

= The motor shaft power in Watts, 1.0HP = 746 Watts

-P

b

= The motor shaft peak regenerative power in Watts

Step 1 – Determine the Total Inertia

J

T

= J

m

+ GR

2

x J

L

J

T

= Total inertia reflected to the motor shaft, kilogram-meters

2

, kg•m

2

, or

pound-feet

2

, lb•ft

2

J

m

= Motor inertia, kilogram-meters2, kg•m

2

, or pound-feet2, lb•ft

2

GR = The gear ratio for any gear between motor and load, dimentionless

J

L

= Load inertia, kilogram-meters2, kg•m

2

, or pound-feet2, lb•ft

2

– 1 lb•ft

2

=

0.04214011 kg•m

2

Step 2 – Calculate the Peak Braking Power

J

T

= Total inertia reflected to the motor shaft, kg•m

2

ω

= rated angular rotational speed,

N = Rated motor speed, RPM

ωRad s

⁄

2

πN

60

----------RPM

=

P

b

J

T

ω

2

×

t

3

t

2

–

-----------------

=

Rad s

⁄

2

πN

60

----------

=