Control Techniques 0453-0016-06 Installation Manual Download Page 12

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M’Ax Installation Guide

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Issue Number: 6

The drive can supply the rated maximum continuous output current
(FLC) as follows...

Models M’Ax 403 and M’Ax 406: Up to an ambient temperature of
55°C (131°F)
Models M’Ax 409 and M’Ax 412: Up to an ambient temperature of
45°C (113°F); from 45°C to 55°C (131°F), the maximum permissible
continuous output current is reduced to 8.5A and 10.5A respectively.

If the drive is to be used at an altitude in excess of 2000m (6600ft), de-
rating for altitude must be applied to the output current; see Altitude on
page 26.

Make a note of the following values for the model to be used; you will
need to know these later:

•

Maximum intended ambient temperature (T

AMB

max) (required for

calculating the enclosure size later in this chapter)

•

Maximum continuous output current (if this needs to be a de-rated
value)

•

Maximum heat dissipated into the enclosure

Current de-rating
If this precaution is not taken, the output current of the
drive can exceed the maximum permissible value. This
may result in loss of motor control due to excessive
heatsink temperature causing the drive to trip.

2.12

Thermal protection

The power output stage (IGBT bridge) of the drive is protected as
follows:

•

When the heatsink temperature reaches an alarm level the drive
continues operating; the lower line of the display indicates hot as a
pre-warning

•

If the load is not reduced and the heatsink temperature continues to
rise the drive will trip; the lower line of the display indicates O.ht2

Table 2-8

Maximum currents and heat dissipated into the

enclosure (these do not show de-rating for altitude)

2.13

When to use a braking resistor

When an AC motor is decelerated, or the drive is preventing the motor
from gaining speed due to mechanical influences, energy is returned to
the drive from the motor. When this energy is too great for the drive to
absorb, the DC-bus voltage is raised, which increases the possibility of
the drive tripping due to excessive DC-bus voltage.

Depending on the braking requirements, an internal braking resistor
fitted in the drive, or an external braking resistor, can be used for
absorbing the returned energy. The braking resistor is then switched into
circuit by an internal transistor when the DC-bus voltage reaches 780V.

The required value for the braking resistor is determined by the
maximum required braking torque, while the required power rating is
determined by the amount of energy to be dissipated, the duty cycle and
repetition time, as well as the cooling available for the resistor. When the
value and power rating have been calculated, a decision can be made to
use the internal resistor or an external resistor.

It is important that the braking resistor is adequately
rated otherwise the drive could trip due to excessive DC-
bus voltage; braking will then cease, allowing the motor
to coast uncontrolled.

2.14

Braking resistor data

Table 2-9

Internal braking resistor

Table 2-10

External braking resistor

The instantaneous power rating refers to the power dissipated during the
conducting periods (milliseconds) of the braking transistor (this operates
under a form of pulse width modulation during braking). Higher
resistance values require proportionately lower instantaneous power
ratings.

The required average power rating of (and heat dissipated by) the
braking resistor depends on the duty cycle of the application (see 2.17
Braking-resistor example calculations on page 9).

Model

Output current

Maximum heat
dissipated into

enclosure

AMB

max.

Maximum

continuous

Maximum

overload

(2 secs.

max.)