Characteristics, 1 overload protection characteristics – MITSUBISHI ELECTRIC MR-E- A/AG User Manual

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12. CHARACTERISTICS

12. CHARACTERISTICS

12.1 Overload protection characteristics

An electronic thermal relay is built in the servo amplifier to protect the servo motor and servo amplifier

from overloads. Overload 1 alarm (AL.50) occurs if overload operation performed is above the electronic

thermal relay protection curve shown in any of Figs 12.1, Overload 2 alarm (AL.51) occurs if the

maximum current flew continuously for several seconds due to machine collision, etc. Use the equipment

on the left-hand side area of the continuous or broken line in the graph.

In a machine like the one for vertical lift application where unbalanced torque will be produced, it is

recommended to use the machine so that the unbalanced torque is 70% or less of the rated torque.

1000

100

10

1

0.1

0

50

150

200

250

300

(Note) Load ratio [%]

Operat

io

n

t

im

e

[s

]

100

During rotation

During servo lock

a. MR-E-10A to MR-E-100A

1000

100

10

1

0.1

0

50

150

200

250

300

(Note) Load ratio [%]

O

perat

io

n t

im

e

[s

]

100

During rotation

During servo lock

b. MR-E-200A

Note: If the servo motor is stopped or low-speed (30r/min or less) operation is performed at an abnormally high duty with torque more

than 100% of the rating being generated, the servo amplifier may fail even in a status where the electronic thermal relay
protection is not activated.

Fig 12.1 Electronic thermal relay protection characteristics

12.2 Power supply equipment capacity and generated loss

(1) Amount of heat generated by the servo amplifier

Table 12.1 indicates servo amplifiers' power supply capacities and losses generated under rated load.

For thermal design of an enclosure, use the values in Table 12.1 in consideration for the worst

operating conditions. The actual amount of generated heat will be intermediate between values at

rated torque and zero torque according to the duty used during operation. When the servo motor is run

at less than the maximum speed, the power supply capacity will be smaller than the value in the

table, but the servo amplifier's generated heat will not change.

Table 12.1 Power supply capacity and generated heat per servo amplifier at rated output

(Note 2)

Servo amplifier-generated heat[W]

Area required for heat dissipation

Servo amplifier

Servo motor

(Note 1)

Power supply
capacity[kVA]

At rated torque

With servo off

[m

2

]

[ft

2

]

MR-E-10A(1)

HC-KFE13

0.3

25

15

0.5

5.4

MR-E-20A(1)

HC-KFE23

0.5

25

15

0.5

5.4

MR-E-40A(1)

HC-KFE43

0.9

35

15

0.7

7.5

MR-E-60A

HC-SFE52

1.0

40

15

0.8

8.6

MR-E-70A

HC-KFE73

1.3

50

15

1.0

10.8

MR-E-100A

HC-SFE102

1.7

50

15

1.0

10.8

MR-E-200A

HC-SFE202

3.5

90

20

1.8

19.4

Note:1. Note that the power supply capacity will vary according to the power supply impedance. This value assumes that the power

factor improving reactor is not used.

2. Heat generated during regeneration is not included in the servo amplifier-generated heat. To calculate heat generated by the

regenerative brake option, use Equation 13.1 in Section 13.1.1.