Teco XP2506 Reference Drawing
AEHHXU
250
186.5
4
CONT.
460
60
1200
9. WEIGHT 4330 LBS.
FEBRUARY 2, 2016
CATALOG #
XP2506
6
ISSUED
06/08/16
TYPE
AEHHXU
PERFORMANCE DATA
3-PHASE INDUCTION MOTOR
NAMEPLATE INFORMATION
OUTPUT
HP KW
250 187 60
POLE
6
FRAME
SIZE
5007B
VOLTAGE
460
TYPICAL PERFORMANCE
FULL
LOAD
RPM
FULL LOAD
MIN. % NOM. %
EFFICIENCY
3/4 LOAD
%
1/2 LOAD
95.0
HZ
RATED
AMBIENT
40oC
%
INS.
CLASS
F
POWER FACTOR
F. L.
%
3/4 LOAD%1/2 LOAD
87.095.8 95.4 81.5
ENCLOSURE
CATALOG#
NEMA
DESIGN
B
%
86.2 81.5
TEXP
XP2506
TIME
RATING
CONT.
POWER FACTOR
CORRECTION
SERVICE
FACTOR
1.15
MAXIMUM
KVAR571186
NO LOAD
FULL LOAD
72 281
TORQUE
FULL LOAD
lb-ft
LOCKED
ROTOR
%FLT
153 120 100
SAFE STALL
TIME IN
SECONDS
COLD HOT
2 1
APPROVED:
CURRENTS
PULL
UP
%FLT
ALLOWABLE
STARTS
PER HOUR
COLD
M. PRATER
LOCKED ROTOR
1825
BREAK
DOWN
%FLT
ROTOR
WR
lb-ft
190.2
SOUND
PRESSURE
LEVEL @ 3 FT
HOT
1
DRAWING NO.
CODE LETTER
2
2
dB(A)
812
NEMA KVA
G
INERTIA
NEMA
LOAD
WK
lb-ft
2743
2
2
MAX
ALLOWABLE
WK
lb-ft
2
2
4937
31057XP2506
ACCEL TIME
NEMA
LOAD
WK
Sec
2
MAX
ALLOWABLE
WK
Sec
2
47.12200 82.37
REVISION
0
DATE:
REGARDING THE MOTOR CONNECTION.
CATALOG NO.:
May 14, 2011
CONNECTION DIAGRAM
SCHEMATIC - ∆ / Y CONNECTION
ACROSS THE LINE CONNECTION
XP2506
460 VOLT CONNECTION
*CONTACT TWMC IF YOU HAVE ANY QUESTIONS
PH: 1-800-873-8326
6DWG NO.
DAC-1545-4
OPERATION
&
MAINTENANCE
MANUAL
FOR
THREE PHASE
INDUCTION
MOTORS
Frame Size 5000 and Larger
INDEX PAGE
1. INTRODUCTION .......................................................................................................... 1
2. ACCEPTING, INSPECTION, STORAGE, TRANSPORTATION ................................. 2
3. INSTALLATION ........................................................................................................... 4
3.1 Site and environment for motor installation ...................................................... 4
3.2 Foundation ............................................................................................................ 4
3.3 Installation of shaft coupling ............................................................................... 6
3.4 Installation of belt drive ....................................................................................... 9
3.5 Conveyance with chain or gear ........................................................................... 10
3.6 Electrical connections ......................................................................................... 11
4. OPERATION ................................................................................................................ 12
4.1 Examination before starting ................................................................................ 12
4.2 Starting operation ................................................................................................. 15
5. MAINTENANCE ........................................................................................................... 17
5.1 Major points in regular inspection and maintenance ........................................ 17
5.2 Motor windings ..................................................................................................... 18
5.3 Cleaning of the interior of the motor .................................................................. 18
5.4 Cleaning of the exterior of the motor .................................................................. 19
5.5 Maintenance of anti-friction bearings ................................................................. 19
5.5.1 Frequency of re-lubrication ......................................................................... .19
5.5.2 Kinds of grease ............................................................................................ 20
5.5.3 Grease quantity ............................................................................................ 20
5.5.4 Re-greasing .................................................................................................. 20
5.5.5 Oil re-lubrication .......................................................................................... 22
5.5.6 Cleaning and installation of bearings ........................................................ 23
5.6 Maintenance of sleeve bearings .......................................................................... 24
5.6.1 Daily inspection ............................................................................................ 24
5.6.2 Regular examination .................................................................................... 24
5.6.3 Disassembly ................................................................................................. 25
5.6.4 Re-assembly ................................................................................................. 26
5.7 Maintenance of slip rings (for Wound Rotor only) ............................................ 27
5.8 Maintenance of non-reverse ratchet mechanism (Vertical Motors only) 29
6. FAULT FINDING AND RECOGNITION ....................................................................... .31
1. INTRODUCTION
This and the following instruction address the more common situations encountered in motor
installation, operation and maintenance. For the TWMC motor warranty to be and to remain in
effect, the motor must be installed and operated in strict accordance with the outline drawing,
motor nameplates and these instructions and must not be altered or modified in any unauthorized
manner.
During the installation and operation of motors in heavy industrial applications there is a danger of
live electrical parts and rotating parts. Therefore to prevent injury and/or damage the basic
planning work for installation, transportation, assembly, operation, etc... needs to be done and
checked by authorized and competent personnel only.
Since these instructions cannot cover every installation, operation, and maintenance the following
points should be considered and checked.
● The technical data and information on permissible use such as assembly, connection,
ambient and operating conditions given in the related catalogue, operating instructions,
nameplates and other production documentation.
● The general erection and safety regulations.
● The local and plant-specific specifications and requirements.
● The proper use of transport, lifting devices and tools.
● The use of personal protective equipment.
Following indications should be observed when reading these instructions.
Safety instructions are marked as follows:
Warning of electric hazards for personnel.
Warning of dangers for personnel.
ATTENTION!
Warning of damage for the motor or installation.
1
2
2. ACCEPTING, INSPECTION, STORAGE, TRANSPORTATION
2.1 Inspection upon receipt
Check the following points upon receipt:
• Are the nameplate ratings identical with what you ordered?
• Are dimensions and color in compliance with your specifications?
• Are the nameplate ratings for space heater, thermal protector, temperature detector, etc.
identical with what you ordered?
• Is there any damage?
• Are all accessories and accompanying instruction manuals in good order?
• Please ensure that the arrow head indicator really indicates direction of rotation.
• If there is any specific requirements, please ensure they are in conformity with your
specifications.
•
Motor stator housing may be outfitted with condensation drain holes that are
either open holes, drain holes with plugs or drain holes with breather drains. For
horizontally mounted motors position the drain holes at the lowest point possible
to allow for the egress of condensation. For vertical shaft installations the lower
end bracket must be outfitted with drains at the lowest point possible. Prior to
installation remove drain plugs if fitted.
•
2.2.1
Storage
When motors are not in operation, the following precautionary measures should be undertaken to
assure best performance.
2.2.2
Place
(a) High and dry, well ventilated without direct sun, dust or corrosive gas.
(b) Not located near a boiler or freezer.
(c) Entirely free from vibration and easy movement.
(d) Motors should be put on pallets to prevent moisture.
2.2.3
Motors should be well-shielded form dust, but under well-ventilated circumstances.
2.2.4 Moisture prevention
Since moisture can be very detrimental to electrical components, the motor temperature should
be maintained about 3ºC above the dew point temperature by providing either external or internal
heat. If the motor is equipped with space heaters, they should be energized at the voltage shown by
the space heater nameplate attached to the motor. Incandescent light bulbs can be placed within
the motor to provide heat. However, if used, they must not be allowed to come in contact with any
parts of the motor because of the concentrated hot spot that could result.
2.2.5
Even during storage, the insulation resistance should be kept above the specified values.
(a) For measurement of insulation resistance and acceptable standard values, please refer to
measures stated in 4.1.2 “Measurement of insulation resistance”.
ATTENTION!
(b) Insulation resistance test should be performed once every three months.
2.2.6
If the motor is not in operation for a long period (one week and above) after installation or has
been in operation but stopped for a period of time, the following precautions must be taken.
(a) Protect the motor as measures stated in 2.2.4.
(b) Insulation resistance test should be performed as stated in 2.2.5.
2.2.7 Bearing protection
(a) If the motor has been provided with a shaft shipping brace to prevent shaft movement
during transit, it must be removed before operating the motor. It is very important that
this brace be re-installed exactly as it was originally, before the motor is moved from
storage or any time when the motor is being transported. This prevents axial rotor
movement that might damage the bearings.
(b) Motors equipped with sleeve bearings are shipped from the factory with the bearing oil
reservoirs drained. In storage, the oil reservoirs should be properly filled to the center of
the oil level gauge with a good grade of rust inhibiting oil. This will keep the bearing
journals well oiled to prevent rusting. The motor shaft should be rotated several
revolutions every month ensuring the shaft does not come to rest in its original position.
While the shaft is rotating, it should be pushed to both extremes of the endplay.
(c) Motors with anti-friction bearings are properly lubricated with the correct grade of
grease at the factory and no further greasing is required in storage. The shaft should be
rotated several revolutions every month to maintain proper distribution of the grease
within the bearings. However, re-greasing is required if a significant period has
elapsed between manufacture and use, or while in storage for extended time. It is
It is a good practice to always replenish and purge with fresh grease at start up.
(d)
(e) Tilt-pad bearings are a type of sleeve bearing used in special design applications. Due to
the nature of this bearing, a loose oil ring for delivering lubricant cannot be provided.
Therefore, during the storage internal, oil must be periodically manually introduced into
the pads and housing to prevent the occurrence of oxidation of the precision machined
components.
(1) Remove the pipe plug from the bearing cap located above the tilt-bearing shell.
(2) Pour in approximately one cup of oil every month and rotate the shaft a few
revolutions about every two (2) weeks.
(3) For long periods of storage, the oil that accumulates in the housing should be
removed.
Care should be taken to keep parts such as fitting surfaces, key, shaft extension and axial
central hole from any collision with foreign matter. Grease should also be generously
applied to prevent rusting.
2.2.9 Transportation
To keep the rotating parts of motors from moving, thus preventing damage and scratching during
transportation, they should be held securely with a locking device. Remove all transit clamps
3
before operating the motor. It is very important that this device be reinstalled exactly as it was
Do not use the hoisting hook/eyebolts to lift more
than the motor itself. They are
and the sling angle is correct.
originally, before the motor is moved from storage or any time when the motor is being
transported. The vertical mounting type motors should be transported in the vertical position.
designed to support the motor only. Make sure the hoisting hook is correctly
attached to the eyebolt(s)/lug(s) and that they are fully screwed in before hoisting.
Also note such parts as fan cover, ventilation box, bracket, slip-ring, etc. may have
their own hoisting lugs which can only carry their own weight. Nothing extra
should be attached while hoisting.
Do not twist the steel wires and make sure the eyebolts have been firmly screwed
3 INSTALLATION
Motor installation – site and environment
3.1.1
Standard environment and site conditions for the installation of motors are usually set as follows:
(a) Ambient temperature: -10~40ºC
(b) Humidity: Relative humidity below 90%RH for totally enclosed types, and below 80%RH for
semi-enclosed types.
(c) Elevation: below 1000 meters or 3300 feet.
(d) Harmful gases, liquids, dusts, high moisture should be absent.
(e) Foundations should be strong and free of vibration.
If there are any special environmental conditions, please inform TWMC prior ordering.
3.1.2 Ventilation and space
(a) Installation area should be well ventilated.
(b) The installation space should be large enough to facilitate heat dissipation and
maintenance.
3.2 Foundation
4
3.2.1
Use rigid and solid sole plate or common bed as foundation.
For best motor performance, it is advisable to use a sole plate or common bed, particularly when using
a shaft coupling.
3.2.2 Installation
(a) Select an appropriate foundation surface for the sole plate or common bed, which will be,
considered the ultimate level.
(b) Align the position of the common bed with reference to that level.
(c) Align the level accuracy at least at four points such as bearing mounting, shaft extension etc.
The accuracy should be within 0.04mm or
.0015 inches
(d) Sole plate or common bed should be
embedded in concrete foundation as illustrated
in Fig. 3. Stiff pads should also be installed
beneath the wedges, which are welded
together at various spots about 400-500mm
(15.75-1 9.70 inches) apart. This will enable the
foundation to evenly carry the weight of the
whole motor.
(e) The base should be sturdy and rigid to keep it
flat and level.
(f) Make sure th e mo rta r and con cret e are
completely dry, and the precision of the level is acceptable, and then set the motor on the
mounting foundation.
(g) Accurately install shaft couplings, belt sheaves etc., then weld the wedges solid to prevent any
change in position.
3.2.3 The foundation of vertical induction motors: (Also the foundation of pump)
(a) Foundation of motor/pump must be rigid and secure to provide adequate support. There must
be no vibration, twisting, misalignment etc. due to inadequate foundations.
(b) A massive concrete foundation is preferred in order to minimize vibration. Rigidity and
5
stability are enhanced by prop plate and foundation bolt. As shown in Fig. 4.
ATTENTION!
ATTENTION!
3.2.4 Installation of vertical motors:
(a) All mounting surfaces must be clean and level.
(b) Foundation must be leveled at least at 4 points and guaranteed to be below 0.04mm
(.0015 in.) flat and level.
(c) Make sure the mortar and concrete are completely dry, and the precision of the level is
acceptable, and then set the motor on the mounting foundation.
(d) Accurately install shaft couplings.
3.3 Installation of shaft coupling
3.3.1
Motors must always be accurately aligned, and this especially applies where they are
directly coupled.
Incorrect alignment can lead to bearing failure, vibration and even shaft fracture. As soon
as bearing failure or vibration is detected, the alignment should be checked.
3.3.2
Field application of a coupling to the motor shaft should follow the procedures recommended by
the coupling manufacturer. The motor shaft extension must not be subjected to either extreme
heat or cold during coupling installation.
Basically, the coupling should be heated and pushed onto the shaft extension with slight
axial force. To prevent damages to the bearing do not hammer the coupling.
3.3.4
Although the sleeve bearings are equipped with thrust faces, these are intended only to provide
momentary axial restraint of rotor movement either during start-up or when operating the motor
disconnected from the driven equipment. They must not be operated under a constant thrust
load unless they were originally designed for this condition.
6
Motors with either sleeve or anti-friction bearings are suitable for connection to the driven load
through a flexible coupling. Solidly coupling to the load is not acceptable. With sleeve bearings, the
flexible coupling should be of the limited end float type to prevent the possibility of any end thrust
from load being transmitted to the motor bearings, which could cause bearing damage. The
recommended limits of end float are as follows:
(a) When the motor is in operation after installation, be sure that the end-play indicator is
within the 6mm (.236 in.) of the groove on the shaft or aligned to the shaft shoulder
immediately outboard of the drive-end bearing to assure there is low friction between shaft
and bearing.
(b) Unless otherwise specified, the designed end-play value X of the groove for TWMC
motors in general is within 6mm (.236 in.) as illustrated in Fig. 6. In essence, the endplay
indicator is adjusted to point at the center of the groove or the drive-end shaft shoulder; thus
X equals to 6±1 mm or so, and the endplay value (Y) of the couplings should equal or be
smaller than 3mm (.118 in.).
(c) If the desired value Y is greater than 3mm (.118 in.) caused for instance by a thrust load and/or
load machine with large endplay, please inform TWMC prior to entering an order.
3.3.5
In aligning the motor (and rotor) axially with the driven equipment, consideration should be given not
only to the endplay indicator position but also to axial shaft expansion and increase in shaft centerline
height due to thermal effects. In general, the axial shaft growth for motors can be disregarded since
neither bearing is fixed and any shaft growth due to temperature increase will produce an elongation
away from the coupling.
Shaft height growth (change in shaft centerline elevation) for TEFC machines can be calculated as
follows:
∆=(0.0005”) x (motor foot to shaft £ dimension)
For non-TEFC machines, divide the number by 2.
3.3.6
It is desirable, in normal operation that the motor operates on its magnetic center, so that no axial
force is exerted on the coupling.
7
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