Mechanical Characteristics Next, we will apply Newton's law to write the differential equations that model the mechanical portion of the DC motor. Write here the diff eqs. of the mechanical portion: Write here Newton's law (sum of the torques of the motor must equal zero): Write here the diff eqs. of the mechanical portion: Note that the electromagnetic torque is proportional to the current through the armature winding and can be written as the product of the velocity constant (K₁)times the current. The torque constant K depends on the flux density of the fixed magnets.

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Please answer questions using the figure
Mechanical Characteristics
Next, we will apply Newton's law to write the differential equations
that model the mechanical portion of the DC motor. Write here the
diff eqs. of the mechanical portion:
Write here Newton's law (sum of the torques of the motor must
equal zero):
Write here the diff eqs. of the mechanical portion:
Note that the electromagnetic torque is proportional to the current
through the armature winding and can be written the product of
the velocity constant (K₂)times the current. The torque constant K
depends on the flux density of the fixed magnets.
Transcribed Image Text:Mechanical Characteristics Next, we will apply Newton's law to write the differential equations that model the mechanical portion of the DC motor. Write here the diff eqs. of the mechanical portion: Write here Newton's law (sum of the torques of the motor must equal zero): Write here the diff eqs. of the mechanical portion: Note that the electromagnetic torque is proportional to the current through the armature winding and can be written the product of the velocity constant (K₂)times the current. The torque constant K depends on the flux density of the fixed magnets.
The electric circuit of the armature and the free-body diagram of
the rotor are shown in the following figure.
R
ww
Armature
circuit
L
30
be
Rotor
Fig. 1- Dynamic Model of a DC Motor
i
Fixed field
or permanent
magnet
Transcribed Image Text:The electric circuit of the armature and the free-body diagram of the rotor are shown in the following figure. R ww Armature circuit L 30 be Rotor Fig. 1- Dynamic Model of a DC Motor i Fixed field or permanent magnet
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