2 drive function description – Lenze MCH Series User Manual

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“Variable torque” refers to the fact that the torque required varies with the square of

the speed. Also, the horsepower required varies with the cube of the speed, resulting

in a large reduction in horsepower for even a small reduction in speed. It is easily seen

that substantial energy savings can be achieved by reducing the speed of a fan or

pump. For example, reducing the speed to 50% results in a 50 HP motor having to

produce only 12.5% of rated horsepower, or 6.25 HP. Variable torque drives usually

have a low overload capacity (110% - 120% for 60 seconds) because variable torque

applications rarely experience overload conditions. To optimize efficiency and energy

savings, variable torque drives are usually programmed to follow a variable V/Hz ratio.
The term “constant torque” is not entirely accurate in terms of the actual torque required

for an application. Many constant torque applications have reciprocating loads, such

as vibrating conveyors and punch presses, where the rotational motion of the motor is

being converted to a linear motion. In such cases, the torque required can vary greatly

at different points in the cycle. For constant torque loads, this fluctuation in torque is not

a direct function of speed as it is with a variable torque load. As a result, constant torque

drives typically have a high overload rating (150% for 60 seconds) in order to handle

the higher peak torque demands. To achieve maximum torque, constant torque drives

follow a constant V/Hz ratio.
The MCH Series has an overload capacity of 120% for one minute, indicating that it is

meant for variable torque loads.

6.2

DRIVE FUNCTION DESCRIPTION

The MC Series is a microprocessor based, keypad programmable, variable speed AC

motor drive. There are four major sections: an input diode bridge and filter, a power

board, a control board and an output intelligent power module.

6.2.1

DRIVE OPERATION

Incoming AC line voltage is converted to a pulsating DC voltage by the input diode

bridge. The DC voltage is supplied to the bus filter capacitors through a charge circuit

that limits inrush current to the capacitors during power-up. The pulsating DC voltage

is filtered by the bus capacitors which reduces the ripple level. The filtered DC voltage

enters the inverter section of the drive, composed of six output intelligent insulated gate

bi-polar transistors (IGBTs) that make up the three output legs of the drive. Each leg

has one intelligent IGBT connected to the positive bus voltage and one connected to the

negative bus voltage. Alternately switching on each leg, the intelligent IGBT produces

an alternating voltage on each of the corresponding motor windings. By switching each

output intelligent IGBT at a very high frequency (known as the carrier frequency) for

varying time intervals, the inverter is able to produce a smooth, three phase, sinusoidal

output current wave which optimizes motor performance.

6.2.2

CIRCUIT DESCRIPTION

The control section consists of a control board with a microprocessor, keypad and

display. Drive programming is accomplished via the keypad or the serial communications

port. During operation the drive can be controlled via the keypad, by control devices

wired to the control terminal strip, or by the the serial communications port. The Power

Board contains the control and protection circuits which govern the six output IGBTs.

The Power Board also contains a charging circuit for the bus filter capacitors, a motor

current feedback circuit, a voltage feedback circuit, and a fault signal circuit. The drive

has several built in protection circuits. These include phase-to-phase and phase-to-

ground short circuit protection, high and low line voltage protection, protection against

excessive ambient temperature, and protection against continuous excessive output

current. Activation of any of these circuits will cause the drive to shut down in a fault

condition.