motor protection
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motor protection...
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Basics for practical operation Motor protection Necessity of motor protection The motor’s protection requirements Protective measures
Motor Management TM
Foreword This technical manual for “Motor Protection” is another publication on the subject of “Motor Management”. With these fundamentals, fundamentals, published at regular intervals, the user will have a growing reference work on the performance and operational data required for design and application. Topics covered include: • Moto torr Starti tin ng • Sel Selecti ection on and Ope Operati ration on of Swi Switch tchgea gearr • Co Comm mmun unic icat atio ion ns. The following manuals have already been published • “Three “Three-phase -phase Induct Induction ion Motors” Motors” - informs informs about about structure structure,, modes, modes, selection selection and dimensioning of motors • “Basic “Basicss of Power Power Circuit Breake Breakers” rs” - additio additional nal informat information ion for for the practical practical use of Power Circuit Breakers. Electric motors can be found in every production process today. The optimal use of the drives is becoming increasingly important in order to ensure cost-effective cost-effe ctive operations. “ Motor Management” from Rockwell Automation will help you: • to opt optimi imise se the the use use of of your your sys system temss • to re redu duce ce mai maint nten enan ance ce co cost stss • to incre increas asee oper operati ation onal al saf safety ety.. We are pleased that our publications may help you find economical and efficient solutions for your applications.
Copyrightt © 1997 by Rockwell Automation Copyrigh Automation AG AG All information given represents the current level of technology available and is not legally binding.
i
Motor protection
Table of contents
1
Necessity of motor protection
1.1
2
The motor’s protection requirements
2.1
2.1 2.1.1 2.1.2 2.1.3 2.1.4 2.1.5 2.1.6 2.1.7 2.1.8
Temperature Rise Operational behaviour Limiting temperature and insulation classes Insulation ageing Response limits Phase failure Asymmetry in the network Earth fault Short circuit
3
The system’s protection requirements
3.1 3.2 3.3 3.4 3.4.1 3.4.2
Stalling Underload Incorrect rotation Motors in explosion-risk areas Ignition protection type and increased safety EEx e Significance of time t E
4
Protection measures
4.1
5
Temperature-dependent protection measures
5.1
5.1 5.1.1 5.1.2 5.2 5.3 5.4
Application problems Applications Thermal inertia Bimetallic sensors in the winding PTC - sensors Linear temperature sensors
ii
2.1 2.1 2.3 2.4 2.5 2.6 2.8 2.9 2.9
3.1 3.1 3.1 3.1 3.1 3.1 3.2
5.1 5.1 5.1 5.2 5.3 5.4
Motor protection
6
Current-dependent protection
6.1
6.1 6.2 6.2.1 6.2.2 6.3 6.3.1 6.3.2 6.3.3 6.3.4 6.3.5 6.3.6 6.3.7 6.4 6.5 6.6 6.6.1 6.6.1.1 6.6.1.2 6.6.1.3 6.6.2 6.6.2.1 6.6.2.2 6.6.2.3
Function Device characteristics Stationary operation Intermittent operation Bimetallic protection principle Function Short circuit resistance Single-phase operation Phase failure Recovery time Current setting Trip Free Motor protection during heavy duty starting Motor protection in hazardous area locations Electronic motor protection Overload protection Thermal projection models Current setting Setting the tripping time Special motor protection functions Phase failure Asymmetry Short-to-earth Short-to-earth using the “Holmgreen”- method (rigidly earthed networks) Short-to-earth using cumulative current transformers Leakage protection in medium voltage networks Short-circuit protection of medium voltage motors System-protection functions High overload and stalling Underload Incorrect rotation protection Start time monitoring Stalling during start Control functions Pre-warning Load control Start lock-out Star-delta-change-over Warm start Possibilities for communication
6.1 6.1 6.1 6.2 6.3 6.3 6.5 6.5 6.5 6.7 6.8 6.9 6.9 6.10 6.10 6.11 6.11 6.12 6.13 6.14 6.14 6.14 6.15
6.6.2.4 6.6.3 6.6.3.1 6.6.3.2 6.6.3.3 6.6.3.4 6.6.3.5 6.6.4 6.6.4.1 6.6.4.2 6.6.4.3 6.6.4.4 6.6.4.5 6.6.4.6
iii
6.15 6.16 6.16 6.21 6.22 6.22 6.23 6.24 6.24 6.25 6.26 6.26 6.26 6.26 6.27 6.28 6.29
Motor protection
6.6.5 Applications of electronic motor overloads 6.6.5.1 Low thermal inertia motors 6.6.5.2 High thermal inertia motors 6.6.5.3 Rotorcritical motors 6.6.5.4 Medium voltage motors 6.6.5.5 Slip-ring motors 6.6.5.6 Multi-stage motors 6.6.5.7 Frequency-controlled motors 6.6.5.8 Soft start 6.6.5.9 Motors with remote ventilation 6.6.5.10 Increased ambient temperature 6.6.5.11 Motors in hazardous locations 6.6.5.12 Protection of compensated motors
6.29 6.29 6.30 6.30 6.30 6.31 6.31 6.32 6.32 6.33 6.33 6.33 6.34
7
Selecting the correct motor overload
7.1
7.1 7.2 7.3 7.4
Application-dependent selection Selection depending on motor and drive Selection depending on ambient conditions Selection in accordance with motor management criteria
iv
7.2 7.3 7.4 7.5
Motor protection
1
Necessity for motor protection
It could be assumed that properly planned, dimensioned, installed, operated and maintained drives should not break down. In real life, however, these conditions are hardly ever ideal. The frequency of different motor damage differs since it depends on different specific operating conditions. Statistics show that annual down times of 0.5...4% have to be expected. Most breakdowns are caused by an overload. Insulation faults leading to earth faults, turn-to-turn or winding short circuits are caused by excess voltage or contamination by dampness, oil, grease, dust or chemicals. The approximate percentages of by these individual faults are: • • • • • • •
overload insulation damage phase failure bearing damage ageing rotor damage others
30% 20% 14% 13% 10% 5% 8%
Therefore, the following points must be observed to guarantee fault-free operation of an electrical drive: • Correct design: a suitable motor has to be selected for each application. • Professional operation: professional installation and regular maintenance are preconditions for fault-free operation. • Good motor protection: this has to cover all possible problem areas. - It must not be tripped before the motor is put at risk. - If the motor is put at risk, the protection device has to operate before any damage occurs. - If damage cannot be prevented, the protection device has to operate quickly in order to restrict the extent of the damage as much as possible.
1.1
Motor protection
Table 1.2.1 represents a summary of the most frequent breakdown causes for motors, their extent and the possible damage caused.
Cause
Effect
Possible damage
Thermal overload: • extreme starting conditions
overcurrent and
soldered joint damage
• locked rotor
thus unacceptable
rotor cage
• high overload • undervoltage
heating-up of windings
burnt windings stator windings
• restricted cooling
unacceptable
burnt windings
• ambient temperature too high Electrical causes:
heating-up
stator windings
• single phase conditions
unbalanced
individual windings
• unbalanced voltage
overcurrent of
or parts burnt
• earth fault • shorted turns • winding short circuit
windings heating-up depending on motor size and bearing
• intermittent operation Cooling problems:
damage load Mechanical causes: • imbalance
uneven wear of
• mis-alignment • improperly installed drive (e.g., bearing load of V-belts too high)
bearings
Tab. 1.2.1
1.2
bearing damage
Breakdown causes, effects and possible motor damage.
Motor protection
2
The motor’s protection requirements
2.1 Temperature Rise In line with applicable standards, every motor manufacturer guarantees that critical machine parts remain within the permissible temperature range during rated operation and that short-term overloads do not damage the motor. The motor protection device, on the one hand, has to allow full use and thus the efficient operation of the motor and, on the other hand, react quickly enough in case of an overload. 2.1.1 Operational behaviour Electrical motors are energy transformers. They take in electrical energy and transform it into mechanical energy. This process causes energy losses, which takes the form of heat. The total energy loss comprises of two components:
• Current-independent losses: they are practically constant, this means they also occur at no-load. - core losses caused by polarity changes and eddy currents - mechanical losses caused by friction and aeration • Current-dependent losses: they increase with load, i.e. with increased current. - I2R losses in the stator - I2R losses in the rotor The power loss increases approximately in proportion to the square of the current . The latter is almost proportional to the motor’s slip. According to Figure 2.2.1, for a stalled , static rotor, the maximum starting current in the stator is 4...8 In. The total input power is transformed into heat. If the rotor remains stalled, the temperature of the stator and rotor winding increases considerably, as part of the heat can only flow into the motor casing after a delay. If the motor is not switched off in time, the stator and rotor winding can burn out The heat losses generated reduce with increased speed. After run-up, the temperature increases further in an e-function, as shown in Figure 2.2.2, until it reaches final temperature level. For a higher load, the final temperature will be correspondingly higher.
2.1
Motor protection
I
I I
I
Fig. 2.2.1
Squirrel-cage motor started direct on line (DOL). During starting time A t , a high motor starting current I A flows. It does not cause excessive heating if the starting time remains below the limit specified by the motor manufacturer, which is usually 10 sec. The short-term, unbalanced starting current peak can be ignored.
ϑ G insulation temperature limit (class of
ϑ ϑ G ϑ e ϑ s
ϑ K
0 t
A t B
Fig. 2.2.2
t
motor) ϑ K coolant temperature t A starting time ϑ S temperature increase during start ϑ e temperature increase during continuous operation with rated current Ie t B Stalling time
Temperature increase in the motor winding Due to the high starting current I A , the winding’s temperature increases during starting time t A very quickly. After the start, the temperature drops temporarily, as heat is transferred to the motor body. If the rotor remains stalled, the windings reach their temperature limits very quickly.
Electrical motors are thermally non-homogenous systems. The windings, stator iron and rotor have a different heat capacity and heat conductivity. After start and during load changes, a temperature compensation takes place between the different machine parts. The heat flows from the hot winding to the cooler iron until a temperature balance has been achieved.
2.2
Motor protection
2.1.2 Limiting temperature and insulation classes The limiting temperatures of the windings and, thus the permissible motor load are above all determined by the winding insulation. The IEC-recommendations for electrical machines (IEC 34-1 and IEC 85), as well as Regulation VDE 0530 Part 1, have been listed in Table 2.3.1. A difference is made between:
• Max. coolant temperature: the motor can achieve its rated power at this temperature. • Limiting temperature in K is the average value from resistance measurements. The winding temperature is the sum of the coolant temperature and the winding warm-up. If the coolant temperature is below 40 ºC, the motor load can be increased. If it exceeds 40 ºC, the load has to be reduced. • Highest permissible permanent temperature in ºC for the hottest winding spot. Insulation
Max. coolant
Temp. over
Highest permissible
class
temp. in ºC
limit in K
constant temp. in ºC
E B F H
40 40 40 40
75 80 105 125
120 130 155 180
Tab. 2.3.1
Insulation material classes and highest permissible constant winding temperatur
The highest permissible constant temperature of individual insulation materials comprises of coolant temperature, temperature over limit and a heating-up tolerance. The latter is a safety factor, since the temperature measurement by ohmic resistance does not establish the hottest winding spot. For very high ambient temperatures, motors with specially heat-resistant insulation are produced. These machines can also achieve their rated power at high coolant temperatures. By far the most widespread cooling type is self-ventilation with ambient air. By means of a shaft-mounted fan, self-cooled motors guide an airstream over the housing surface. This means that the coolant - air - has the same temperature as the area immediately surrounding the motor. The cooling power depends on the motor speed. Due to their simple structure (no insulation), ordinary squirrel-cage motor rotors do not have a critical temperature. Therefore, they are permitted to reach a higher temperature constantly.
2.3
Motor protection
Problems can occur during the starting of medium voltage and larger low voltage motors, since the value of the losses can limit the starting time. The starting time and the permissible stalling time are therefore limited by the rotor’s heat capacity. These motors are called “rotor critical” motors. The high temperature increase can lead to mechanical tensions and result in an de-soldering of rotor rods. For motors with protection type “increased protection - EEx e”, the increased temperature can serve as an ignition source.
2.1.3 Insulation ageing If the temperature limit is adhered to, the winding life time for all insulation classes can be estimated at 100,000 h. This corresponds to approximately 12 year of continuous operation at rated power. Insulation ageing is a chemical process, which is highly temperature-dependent as shown in Fig. 2.4.1. Due to heating up, part of the insulation material evaporates, which leads to an increasing porosity and, as a result of this, a decreased voltage resistance. The following rule applies: if the operating temperature exceeds the highest permissible temperature by 10K, the life span reduces by half. Short-term excessively high temperatures do not have a considerable impact on a motor’s life span. The continuous operating temperature, however, must not exceed the highest permissible value.
t Life span ϑ Temperature rise
Figure 2.4.1 Reduction of an average motor winding life span due to excessively high temperature.
2.4
Motor protection
Modern design methods take the motor’s overload-situations into consideration. This makes it possible to make full use of the life cycle reserve. This is called lifecycle oriented design, which has the aim to enable motor operation for as long as the motor has to operate for economic reasons. 2.1.4 Response limits In order to guarantee the protection of standard motors, the IEC has established response limits for time-delayed overload-relays.
Values according to IEC 947-4-1 apply to temperature-compensated, balanced pole load overload relays adjusted to the rated operating current. Figure 2.5.1 and Table 2.5.1.
overload as a multiple of the set current value ϑ ambient temperature IEC limiting values according to IEC 947-4-1
I
Figure 2.5.1 Current multiple limiting-values for temperature-compensated overload-relays acc. to IEC 947-4-1.
Function
should not respond from cold
to respond after following current increase
to respond from warm
to respond from cold
Multiple of the set current value Response 10 A time acc. to 10 response 20 class: 30
1.05
1.2
1.5
7.2
≥2h ≥2h ≥2h ≥2h
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