Section 8 - Motor Thermal Protection Basics; General; Sensing Inputs; Protective Functions - Eaton MP-3000 Instruction Leaflet

SECTION 8 - MOTOR ThERMaL PROTECTION BaSICS

8.0 General

This section describes how the MP-3000 hardware and software func-
tion together to control, monitor, and protect the motor.

8.1 Sensing Inputs

The MP-3000 receives motor phase currents from three main motor
phase current transformers (see Figure 8-1). If an optional ground
fault transformer is used, the MP-3000 monitors ground leakage or
fault current as well.
The MP-3000 takes 36 samples per power cycle of the input current
signals, digitizes each sample, and stores it in the microprocessor
memory. From these samples, the MP-3000 computes rms cur-
rents and average currents. It also performs phasor calculations
leading to direct and precise measurement of positive and negative
sequence currents. Refer to Subsection 8.2 for further details. The
high sampling rate, plus a unique patented sample-shifting technique,
allows the MP-3000 to properly measure and account for the impact
of harmonics in heating the motor.
If the optional URTD module is used, the MP-3000 gathers winding
temperature data from up to six resistance temperature detectors
(RTDs) embedded in the stator windings of the motor. It can monitor
four RTDs associated with the motor bearings and load bearings. It
can also monitor one auxiliary RTD, such as motor case temperature.

8.2 Protective functions

Protective functions continuously monitor motor operating conditions,
such as current history and temperature. When measured or derived
measurements exceed user-selected levels, an alarm condition is initi-
ated, and then, if necessary, a trip output opens the motor contactor or
trips a breaker.
The MP-3000 can protect the motor, starter, and load in the following
ways:
• Stator and rotor thermal protection by modeling of heating
and cooling effects, including heating by negative sequence
currents
• Stator over-temperature protection by direct measurement
(with optional URTD module)
• Instantaneous over-current protection for faults
• Ground fault protection
• Phase reversal protection
• Phase unbalance protection
• Motor bearing, load bearing, and auxiliary RTD temperature
protection (with optional URTD module)
• Jam protection
• Under-load protection
• Transition trip for abnormal starting time-versus-current
behavior
• Incomplete sequence protection (missing status feedback
from load or starter)
• Trip-bypass output for failure of contactor to interrupt current
after a trip command
• Zero-speed switch stalled-motor trip protection
MP-3000
• Process load shedding function to forestall impending jam
or thermal trips
• Jogging protection—minimum time between starts, maxi-
mum number of starts per set time, maximum number of
consecutive cold starts, and minimum time between stop
and start (anti-backspin protection).
Many of these functions also have separate alarm thresholds to warn
the user, who may be able to act before a trip occurs.
The MP-3000 has four output relays. The Trip relay is connected
in series with the motor contactor, and de-energizes the contactor
or blocks motor starting for any MP-3000 trip condition. All trips are
steered to this relay.
The three other relays are designated as Alarm, Auxiliary 1, and Aux-
iliary 2. Normally, all alarm and warning conditions are steered to the
Alarm relay. However, the Alarm relay and the two Auxiliary relays are
all fully programmable. They can be set by the user to operate for a
designated list of internal MP-3000 measured or calculated conditions.
8.2.1 Direct Load-Based Protection
The monitored level of actual motor current is used to determine
when the instantaneous over-current trip, jam trip, load shedding,
under-load trip, transition trip, and load-shedding settings have been
reached. Also, direct temperature feedback from the stator, load bear-
ing, motor bearing, and auxiliary RTDs are compared with respective
settings. If necessary, the relay gives alarm and/or trip outputs.
8.2.2 Thermal Model and Rotor Temperature Protection
Each motor has a specific damage curve. Usually it is called the I
(current squared multiplied by time) curve. With larger horsepower
motors, the thermal capability is usually rotor-limited, so it is impor-
tant to track the total heating of the rotor. In ac motors, the current
balance between phases is of major concern due to the additional
rotor heating associated with the negative sequence component of
an unbalanced phase current condition. Current unbalance is usually
caused by voltage unbalance, the result of single-phase loads on a
3-phase system, and/or motor winding unbalance.
Any unbalanced set of 3-phase currents or voltages can be math-
ematically transformed into a linear combination of positive, negative,
and zero sequence components. The measured current phasor in
each phase is the sum of the three sequence component phasors
in that phase. The zero-sequence component is a common-mode
component which is equal in the three phases, and requires a neutral
or ground path for return. So, in a motor without a neutral return, no
zero-sequence current is seen unless there is a ground fault. Thus,
the focus is on the positive and negative sequence components which
can routinely be present.
For analysis and understanding, consider the motor to have two
tandem virtual rotors as shown in Figure 8.2. One is driven only by
the positive sequence current I
The other is driven only by counter rotating negative sequence current
I , directly related to unbalanced current, and produces a proportional
2
torque in the reverse direction. If perfect current balance and phase-
angle symmetry exists among the three phases, I
component of line current squared, with no effect from the second ro-
tor. This positive sequence component of current produces the motor
output torque and work.
The negative sequence current I
a reverse phase rotation compared to that of the ac source. This cur-
rent generates a reverse torque in the second rotor, and works against
the main action of the motor, doing negative work. Because the nega-
tive work caused by I
as heat and, therefore, has a far more significant effect on the rotor
heating than the balanced l
www.eaton.com
, which is symmetrical and balanced.
1
would be the only
1
is a 3-phase current component with
2
stays within the rotor, it is completely absorbed
2
.
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2
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