Thermal Motor Protection And Overload Responses; Thermal Motor Model - Siemens MICROMASTER 420 Operating Instructions Manual

0.12 kw - 11 kw

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Table of Contents

Issue 07/04

3.19

Thermal motor protection and overload responses

Parameter range:

Warnings

Faults

Function chart number:

MICROMASTER 420 has a completely new integrated concept for thermal motor

protection. There are numerous possibilities of effectively protecting the motor but

at the same time ensuring high motor utilization. The basic philosophy of this

innovative concept is to detect critical thermal states, output warnings and initiate

the appropriate responses. By responding to critical states it is possible to operate

the drive at the thermal power limit and to avoid, under all circumstances, an

immediate shutdown (where the drive inverter is tripped).

Features

The protective concept distinguishes itself as a result of the following individual

features:

Protection is effective without using any temperature sensor. The temperatures

of various locations in the motor are indirectly determined using a temperature

model.

Selectable responses P0610 which are to be initiated when the warning

threshold is exceeded in order to prevent an overload condition.

The motor protection has been designed to be completely independent of the

drive inverter protection. Warning thresholds and responses for drive inverter

protection must be separately parameterized.

3.19.1

Thermal motor model

The motor temperature rise increases because of the losses occurring during the

energy-conversion process in the motor. These losses can be essentially sub-

divided into two groups:

No-load losses

The no-load losses include the bearing and air friction losses as well as the re-

magnetizing losses (eddy current and hysteresis losses). All of these loss

components dependent on the speed and electrical frequency.

Load losses

The load losses are mainly determined by the thermal losses in the windings

due to the current flowing through them.

An electrical motor represents a multi-material system (iron, copper, insulating

material, air) where the heat source is especially concentrated in the windings, the

laminated core and the shaft bearings. The following simplifications were made to

replicate the thermal processes in the motor:

The motor is a homogenous body

Heat sources are uniformly distributed in the motor

Heat is only dissipated using convection

MICROMASTER 420

Operating Instructions

6SE6400-5AA00-0BP0

P0610 – P0614

P0345

r 0034

A0511

F0011

3 Functions

135

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Thermal Motor Protection And Overload Responses; Thermal Motor Model - Siemens MICROMASTER 420 Operating Instructions Manual

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Thermal motor model

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