User manual
INTRODUCTION
The ‘Encore’ Series amplifiers are second generation products designed for low cost
and high performance. They are designed for edgewise mounting and can operate
from power supplies ranging from 24V to 150V DC.
A wide range of inductive loads can be driven by the amplifiers. All models feature
fully differential inputs for the control, or reference, voltage. Enable inputs for the
control of outputs, and status signal and current monitor output are provided to ease
system interfacing.
The 22 KHz switching frequency eliminates audible noise from the motor windings,
and fast rise and fall times give high efficiency.
The amplifiers are protected against over temperature, over and under voltage, and
short circuits between outputs, and from outputs to ground.
They are typically used as voltage to current converters. A +/- 10V signal will drive
the amplifier’s peak rated current to the load in the ‘flat gain’ mode. If a tachometer is
used, the amplifier is still operated as a voltage to current converter, but DIP switch
settings are changed to increase the gain of the servo amplifier.
Voltage mode operation with IR compensation is also supported and is switch
selectable.
Loads driven are normally motors, but magnet coils, inductors or other non-motor
loads can also be driven using appropriate settings.
THEORY OF OPERATION
AC voltage from the transformer is rectified and filtered to provide the DC bus
voltage for the power stage. The power stage is a full bridge formed by power
MOSFETs, and is capable of allowing the motor to accelerate or brake in either
direction. The MOSFETs use separate floating power supplies for their gate drives,
which allow the drive to operate without any restriction on the duty cycle.
The innermost control loop in the drive is a current control loop, the heart of which is
a resistive feed-back element and the PWM control circuit. In the torque mode, the
input signal is fed directly to the current loop and so the motor current is made equal
to the input signal. The PWM circuit switches each leg of the bridge alternately to the
bus voltage and to ground, to maintain the motor current at the desired value.
In the velocity mode, an outer loop is formed by comparing the tachometer’s output
voltage and the input signal. Thus, the motor’s speed will equal the input signal. If the
motor’s speed varies due to load or voltage variations, the drive adjusts the motor
current till the preset speed is again achieved. In the velocity mode, the tach,
proportional , integral gains and integration time constant are all variable to allow
tuning of the drive to varying load and speed conditions.