— Baldor-Reliance ® Integral Horsepower AC Induction Motors

—

MN408 January 2021

January 2021

—

Baldor-Reliance ® Integral Horsepower

AC Induction Motors

ODP, WPI Enclosures, TENV, TEAO, TEFC Enclosure,

Explosion Proof

Installation and Operating Manual

Any trademarks used in this manual are the property of their respective owners.

Important:

Be sure to check www.baldor.com to download the latest version of this manual in Adobe Acrobat PDF format.

Note! The manufacturer of these products, Baldor Electric Company became ABB Motors and Mechanical Inc. on March 1, 2018.

Nameplates, Declaration of Conformity and other collateral material may contain the company name of Baldor Electric Company

and the brand names of Baldor-Dodge and Baldor-Reliance until such time as all materials have been updated to reﬂect our new

corporate identity.

General Information 1-1MN408

Section 1

General Information

Overview This manual contains general procedures that apply to Baldor Motor products. Be sure to read and understand

the Safety Notice statements in this manual. For your protection, do not install, operate or attempt to perform

maintenance procedures until you understand the Warning and Caution statements.

A Warning statement indicates a possible unsafe condition that can cause harm to personnel.

A Caution statement indicates a condition that can cause damage to equipment.

Important: This instruction manual is not intended to include a comprehensive listing of all details for all

procedures required for installation, operation and maintenance. This manual describes general

guidelines that apply to most of the motor products shipped by Baldor. If you have a question about a

procedure or are uncertain about any detail, Do Not Proceed. Please contact your Baldor distributor for

more information or clariﬁcation.

Before you install, operate or perform maintenance, become familiar with the following:

• NEMA Publication MG-2, Safety Standard for Construction and guide for Selection, Installation and Use of

Electric Motors and Generators.

• IEC 34−1 Electrical and IEC72−1 Mechanical specications

• ANSI C51.5, the National Electrical Code (NEC) and local codes and practices.

Limited Warranty

www.baldor.com/support/warranty_standard.asp

Safety Notice: This equipment contains high voltage! Electrical shock can cause serious or fatal injury. Only qualiﬁed

personnel should attempt installation, operation and maintenance of electrical equipment. Be sure

that you are completely familiar with NEMA publication MG-2, safety standards for construction and

guide for selection, installation and use of electric motors and generators, the National Electrical Code

and local codes and practices. Unsafe installation or use can cause conditions that lead to serious or

fatal injury. Only qualiﬁed personnel should attempt the installation, operation and maintenance of this

equipment.

WARNING: Do not touch electrical connections before you ﬁrst ensure that power has been disconnected.

Electrical shock can cause serious or fatal injury. Only qualiﬁed personnel should attempt the

installation, operation and maintenance of this equipment.

WARNING: Disconnect all electrical power from the motor windings and accessory devices before disassembly of

the motor. Electrical shock can cause serious or fatal injury.

WARNING: Be sure the system is properly grounded before applying power. Do not apply AC power before you

ensure that all grounding instructions have been followed. Electrical shock can cause serious or fatal

injury. National Electrical Code and Local codes must be carefully followed.

WARNING: Avoid extended exposure to machinery with high noise levels. Be sure to wear ear protective devices to

reduce harmful effects to your hearing.

WARNING: Surface temperatures of motor enclosures may reach temperatures which can cause discomfort or

injury to personnel accidentally coming into contact with hot surfaces. When installing, protection

should be provided by the user to protect against accidental contact with hot surfaces. Failure to

observe this precaution could result in bodily injury.

WARNING: This equipment may be connected to other machinery that has rotating parts or parts that are driven by

this equipment. Improper use can cause serious or fatal injury. Only qualiﬁed personnel should attempt

to install operate or maintain this equipment.

WARNING: Do not by-pass or disable protective devices or safety guards. Safety features are designed to prevent

damage to personnel or equipment. These devices can only provide protection if they remain operative.

WARNING: Avoid the use of automatic reset devices if the automatic restarting of equipment can be hazardous to

personnel or equipment.

WARNING: Be sure the load is properly coupled to the motor shaft before applying power. The shaft key must be

fully captive by the load device. Improper coupling can cause harm to personnel or equipment if the

load decouples from the shaft during operation.

WARNING: UL Listed motors must only be serviced by UL Approved Authorized Baldor Service Centers if these

motors are to be returned to a hazardous and/or explosive atmosphere.

WARNING: Thermostat contacts automatically reset when the motor has slightly cooled down. To prevent injury or

damage, the control circuit should be designed so that automatic starting of the motor is not possible

when the thermostat resets.

WARNING: Use proper care and procedures that are safe during handling, lifting, installing, operating and

maintaining operations. Improper methods may cause muscle strain or other harm.

WARNING: Pacemaker danger − Magnetic and electromagnetic ﬁelds in the vicinity of current carrying carrying

conductors and permanent magnet motors can result result in a serious health hazard to persons

with cardiac pacemakers, metal implants, and hearing aids. To avoid risk, stay way from the area

surrounding a permanent magnet motor.

WARNING: Before performing any motor maintenance procedure, be sure that the equipment connected to the

motor shaft cannot cause shaft rotation. If the load can cause shaft rotation, disconnect the load from

the motor shaft before maintenance is performed. Unexpected mechanical rotation of the motor parts

can cause injury or motor damage.

Continued on next page.

1-2 General Information MN408

Safety Notice Continued

WARNING: Do not use non UL/CSA listed explosion proof motors in the presence of ﬂammable or combustible

vapors or dust. These motors are not designed for atmospheric conditions that require explosion proof

operation.

WARNING: Motors that are to be used in ﬂammable and/or explosive atmospheres must display the UL label on the

nameplate along with CSA listed logo. Speciﬁc service conditions for these motors are deﬁned in NFPA

70 (NEC) Article 500.

WARNING: Guards must be installed for rotating parts such as couplings, pulleys, external fans, and unused shaft

extensions, should be permanently guarded to prevent accidental contact by personnel. Accidental

contact with body parts or clothing can cause serious or fatal injury.

WARNING: Depending on operating conditions, sound levels for electric motors may exceed 70 dB. Protective

measures such as hearing protection may be needed when in close proximity to a motor in operation.

Caution: To prevent premature equipment failure or damage, only qualiﬁed maintenance personnel should

perform maintenance.

Caution: Do not over tension belts. Excess tension may damage the motor or driven equipment.

Caution: Do not over−lubricate motor as this may cause premature bearing failure.

Caution: Do not lift the motor and its driven load by the motor lifting hardware. The motor lifting hardware is

adequate for lifting only the motor. Disconnect the load (gears, pumps, compressors, or other driven

equipment) from the motor shaft before lifting the motor.

Caution: If eye bolts are used for lifting a motor, be sure they are securely tightened. The lifting direction should

not exceed a 20 º angle from the shank of the eye bolt or lifting lug. Excessive lifting angles can cause

damage.

Caution: To prevent equipment damage, be sure that the electrical service is not capable of delivering more than

the maximum motor rated amps listed on the rating plate.

Caution: If a HI POT test (High Potential Insulation test) must be performed, follow the precautions and procedure

in NEMA MG1 and MG2 standards to avoid equipment damage.

Caution: The space heaters are designed to operate at or below the maximum surface temperature stated on the

nameplate. If the marked ambient and/or voltage are exceeded this maximum surface temperature can

be exceeded and can damage the motor windings. If applied in a division 2 or zone 2 environment this

excessive temperature may cause ignition of hazardous materials.

Caution: Shaker Duty motors must be properly lubricated prior to Start Up to prevent damage. See Section 3.

If you have any questions or are uncertain about any statement or procedure, or if you require additional

information please contact your Baldor distributor or an Authorized Baldor Service Center.

Receiving Each Baldor Electric Motor is thoroughly tested at the factory and carefully packaged for shipment. When you

receive your motor, there are several things you should do immediately.

1. Observe the condition of the shipping container and report any damage immediately to the commercial

carrier that delivered your motor.

2. Verify that the part number of the motor you received is the same as the part number listed on your

purchase order.

Handling The motor should be lifted using the lifting lugs or eye bolts provided.

Caution: Do not lift the motor and its driven load by the motor lifting hardware. The motor lifting hardware is

adequate for lifting only the motor. Disconnect the load (gears, pumps, compressors, or other driven

equipment) from the motor shaft before lifting the motor.

1. Use the lugs or eye bolts provided to lift the motor. Never attempt to lift the motor and additional

equipment connected to the motor by this method. The lugs or eye bolts provided are designed to lift only

the motor. Never lift the motor by the motor shaft or the hood of a WPII motor.

2. To avoid condensation inside the motor, do not unpack until the motor has reached room temperature.

(Room temperature is the temperature of the room in which it will be installed). The packing provides

insulation from temperature changes during transportation.

3. When lifting a WPII (Weather Proof Type 2) motor, do not lift the motor by inserting lifting lugs into holes on

top of the cooling hood. These lugs are to be used for hood removal only. A spreader bar should be used

to lift the motor by the cast lifting lugs located on the motor frame.

4. If the motor must be mounted to a plate with the driven equipment such as pump, compressor etc., it may

not be possible to lift the motor alone. For this case, the assembly should be lifted by a sling around the

mounting base. The entire assembly can be lifted as an assembly for installation. Do not lift the assembly

using the motor lugs or eye bolts provided. Lugs or eye bolts are designed to lift motor only. If the load is

unbalanced (as with couplings or additional attachments) additional slings or other means must be used

to prevent tipping. In any event, the load must be secure before lifting. If the load is unbalanced (as with

couplings or additional attachments) additional slings or other means must be used to prevent tipping. In

any event, the load must be secure before lifting.

General Information 1-3MN408

Storage Storage requirements for motors and generators that will not be placed in service for at least six months from

date of shipment.

Improper motor storage will result in seriously reduced reliability and failure. An electric motor that does not

experience regular usage while being exposed to normally humid atmospheric conditions is likely to develop

rust in the bearings or rust particles from surrounding surfaces may contaminate the bearings. The electrical

insulation may absorb an excessive amount of moisture leading to the motor winding failure.

A wooden crate “shell” should be constructed to secure the motor during storage. This is similar to an export

box but the sides & top must be secured to the wooden base with lag bolts (not nailed as export boxes are) to

allow opening and reclosing many times without damage to the “shell”.

Minimum resistance of motor winding insulation is 5 Meg ohms or the calculated minimum, which ever is

greater. Minimum resistance is calculated as follows: Rm = kV + 1

where: (Rm is minimum resistance to ground in Meg−Ohms and kV is rated nameplate

voltage dened as Kilo−Volts.)

Example: For a 480VAC rated motor Rm =1.48 meg−ohms (use 5 M Ω).

For a 4160VAC rated motor Rm = 5.16 meg−ohms.

Preparation for Storage

1. Some motors have a shipping brace attached to the shaft to prevent damage during transportation.

The shipping brace, if provided, must be removed and stored for future use. The brace must be reinstalled

to hold the shaft rmly in place against the bearing before the motor is moved.

2. Store in a clean, dry, protected warehouse where control is maintained as follows:

a. Shock or vibration must not exceed 2 mils peak-to-peak maximum at 60 hertz, to prevent the

bearings from brinelling. If shock or vibration exceeds this limit vibration isolation pads must be used.

b. Storage temperatures of 10 ºC (50 ºF) to 49 ºC (120 ºF) must be maintained.

c. Relative humidity must not exceed 60%.

d. Motor space heaters (when present) are to be connected and energized whenever there is a possibility

that the storage ambient conditions will reach the dew point. Space heaters are optional.

Note: Remove motor from containers when heaters are energized, reprotect if necessary.

3. Measure and record the resistance of the winding insulation (dielectric withstand) every 30 days of storage.

a. If motor insulation resistance decreases below the minimum resistance, contact your Baldor District

ofce.

b. Place new desiccant inside the vapor bag and re−seal by taping it closed.

c. If a zipper−closing type bag is used instead of the heat−sealed type bag, zip the bag closed instead

of taping it. Be sure to place new desiccant inside bag after each monthly inspection.

d. Place the shell over the motor and secure with lag bolts.

4. Where motors are mounted to machinery, the mounting must be such that the drains and breathers are

fully operable and are at the lowest point of the motor. Vertical motors must be stored in the vertical

position. Storage environment must be maintained as stated in step 2.

5. Motors with anti−friction bearings are to be greased at the time of going into extended storage with

periodic service as follows:

a. Motors marked “Do Not Lubricate” on the nameplate do not need to be greased before or during

storage.

b. Ball and roller bearing (anti−friction) motor shafts are to be rotated manually every 3 months and

greased every 6 months in accordance with the Maintenance section of this manual.

c. Sleeve bearing (oil lube) motors are drained of oil prior to shipment. The oil reservoirs must be relled

to the indicated level with the specied lubricant, (see Maintenance). The shaft should be rotated

monthly by hand at least 10 to 15 revolutions to distribute oil to bearing surfaces.

d. “Provisions for oil mist lubrication” – These motors are packed with grease. Storage procedures are

the same as paragraph 5b.

e. “Oil Mist Lubricated” – These bearings are protected for temporary storage by a corrosion inhibitor.

If stored for greater than 3 months or outdoor storage is anticipated, connected to the oil mist

system while in storage. If this is not possible, add the amount of grease indicated under “Standard

Condition” in Section 3, then rotate the shaft 15 times by hand.

1-4 General Information MN408

6. All breather drains are to be fully operable while in storage (drain plugs removed). The motors must be

stored so that the drain is at the lowest point. All breathers and automatic “T” drains must be operable to

allow breathing and draining at points other than through the bearings around the shaft. Vertical motors

should be stored in a safe stable vertical position.

7. Coat all external machined surfaces with a rust preventing material.

An acceptable product for this purpose is Exxon Rust Ban # 392.

8. Carbon brushes should be lifted and held in place in the holders, above the commutator, by the brush

holder ngers. The commutator should be wrapped with a suitable material such as cardboard paper as a

mechanical protection against damage.

Non−Regreaseable Motors

Non−regreasable motors with “Do Not Lubricate” on the nameplate should have the motor shaft rotated

15 times to redistribute the grease within the bearing every 3 months or more often.

All Other Motor Types

Before storage, the following procedure must be performed.

1. Remove the grease drain plug, if supplied, (opposite the grease tting) on the bottom of each bracket prior

to lubricating the motor.

2. The motor with regreasable bearing must be greased as instructed in Section 3 of this manual.

3. Replace the grease drain plug after greasing.

4. The motor shaft must be rotated a minimum of 15 times after greasing.

5. Motor Shafts are to be rotated at least 15 revolutions manually every 3 months and additional grease

added every nine months (see Section 3) to each bearing.

6. Bearings are to be greased at the time of removal from storage.

Removal From Storage

1. Remove all packing material.

2. Measure and record the electrical resistance of the winding insulation resistance meter at the time of

removal from storage. The insulation resistance must not be less than 50% from the initial reading

recorded when the motor was placed into storage. A decrease in resistance indicates moisture in the

windings and necessitates electrical or mechanical drying before the motor can be placed into service. If

resistance is low, contact your Baldor District ofce.

3. Regrease the bearings as instructed in Section 3 of this manual.

4. Reinstall the original shipping brace if motor is to be moved. This will hold the shaft rmly against the

bearing and prevent damage during movement.

General Information 1-5MN408

Equipment Marking for IEC Certiﬁed Product

IEC certied products have special markings that identify the protection concept and environment

requirements. An example is shown in Figure 1-1.

Figure 1-1 IEC Certiﬁed Product Markings

Speciﬁc Conditions of Use:

If the motor certicate number is followed by the symbol “X”, this indicates that the motor has specic

conditions of use which are indicated on the certicate. It is necessary to review the product certication

certicate in conjunction with this instruction manual.

Operation On Frequency Converters:

If the motor is evaluated for operation with an adjustable speed drive, the type of converter (for example PWM

for Pulse Width Modulated) and safe speed ranges (for example 0- 120Hz) will be specied in the certication

documents or on motor nameplates. It is necessary to consult the adjustable speed drive manual for proper set

up. IECEx Certicates are available online at www.iecex.com

Unit Conversions

Inches to Millimeters Inches x 25.4 = mm

Millimeters to Inches mm x .03937 = Inches

Horsepower to Kilowatts Hp x .746 = Kw

Kilowatts to Horsepower Kw x 1.341 = Hp

Pounds to Kilograms Lbs x .454 = Kg

Kilograms to Pounds Kg x 2.205 = Lbs

Typical Speed vs Torque Curves are shown in Figure 1-2. For values relative to your specic motor,

consult the motor nameplate marking.

Ex ec MOTOR

MFG. BY BALDOR ELECTRICFORTSMITH,AR72901 USA

Ex ec IICGcTamb ºCto ºC

II 3G IP______

Sira__________________

IECEx__________________

Ex Protection Concept(Ex ec)

GasGroup (IIC)

Temperature Class

ATEX Specic

Markingof

ExplosionProtection

TEXEquipment Group and Category (II3)

Type of Atmosphere: G--Gas,D-- Dust(G)

AmbientRange

European ConformityMar

PlaceofManufacture

1-6 General Information MN408

Figure 1-2 Typical Speed vs Torque Curves

EMC Compliance Statement for European Union

The motors described in this instruction manual are designed to comply 2014/30/EU. These motors are

commercial in design and not intended for residential use. When used with converters, please consult

converter manufacturers literature regarding recommendations on cable types, cable shielding, cable shielding

termination, connection recommendations and any lters which may be recommended for EMC compliance.

For additional information, consult Baldor MN1383.

100

120

0 20 40 60 80 100 120 140 160 180 200

Percent Torque

Percent Speed

Load Types

CHP

Installation & Operation 2-1MN408

Section 2

Installation & Operation

Overview Installation should conform to the National Electrical Code as well as local codes and practices. When other

devices are coupled to the motor shaft, be sure to install protective devices to prevent future accidents.

Some protective devices include, coupling, belt guard, chain guard, shaft covers etc. These protect against

accidental contact with moving parts. Machinery that is accessible to personnel should provide further

protection in the form of guard rails, screening, warning signs etc.

Location It is important that motors be installed in locations that are compatible with motor enclosure and ambient

conditions. Improper selection of the motor enclosure and ambient conditions can lead to reduced operating

life of the motor.

For Group I Mining Motors where breather drains are used specied, Breather drain shall be mounted or

protected in installation such that it is guarded from direct impact.”

Proper ventilation for the motor must be provided. Obstructed airow can lead to reduction of motor life.

1. Open Drip−Proof/WPI motors are intended for use indoors where atmosphere is relatively clean, dry, well

ventilated and non−corrosive.

2. Totally Enclosed and WPII motors may be installed where dirt, moisture or dust are present and in

outdoor locations.

Severe Duty, IEEE 841 and Washdown Duty enclosed motors are designed for installations with high corrosion

or excessive moisture conditions. These motors should not be placed into an environment where there is the

presence of ammable or combustible vapors, dust or any combustible material, unless specically designed

for this type of service. IEEE841 motors are suitable for application in Class I Division 2 and Class I Zone 2

areas on sine wave power in accordance with the applicable codes and standards.

Hazardous Locations are those where there is a risk of ignition or explosion due to the presence of

combustible gases, vapors, dust, bers, or yings. Facilities requiring special equipment for hazardous

locations are typically classied in accordance with local requirements. In the US market, guidance is provided

by the National Electric Code.

EMC Compliance Statement for European Union

The motors described in this instruction manual are designed to comply 2014/30/EU . These motors are

commercial in design and not intended for residential use.

Mounting Location

The motor should be installed in a location compatible with the motor enclosure and specic ambient. To allow

adequate air ow, the following clearances must be maintained between the motor and any obstruction:

Table 2-1 Enclosure Clearance

TEFC / TENV ( IC0141 ) Enclosures

Fan Cover Air Intake 180 − 210T Frame 1” ( 25mm)

Fan Cover Air Intake 250 − 449T Frame 4” (100mm)

IEC 112 − 132 1” ( 25mm)

IEC 160 − 280 4” (100mm)

Exhaust Envelope equal to the P Dimension on the motor

dimension sheet

OPEN/Protected Enclosures

Bracket Intake Same as TEFC

Frame Exhaust Exhaust out the sides envelope

A minimum of the P dimension plus 2” (50mm)

Exhaust out the end same as intake.

The motor must be securely installed to a rigid foundation or mounting surface to minimize vibration and

maintain alignment between the motor and shaft load. Failure to provide a proper mounting surface may cause

vibration, misalignment and bearing damage.

Foundation caps and sole plates are designed to act as spacers for the equipment they support. If these

devices are used, be sure that they are evenly supported by the foundation or mounting surface.

When installation is complete and accurate alignment of the motor and load is accomplished, the base should

be grouted to the foundation to maintain this alignment.

The standard motor base is designed for horizontal or vertical mounting. Adjustable or sliding rails are

designed for horizontal mounting only. Consult your Baldor distributor or authorized Baldor Service Center for

further information.

2-2 Installation & Operation MN408

Frame Mounting Holes

Some motors have standardized frames containing 6 or 8 mounting holes. 6 hole frames are not suitable for

eld reversal of mounting from F−1 to F−2, etc. Figure 2-1 indicates the proper mounting holes to use.

Figure 2-1 6 & 8 Hole Motor Frame Mounting

Caution: Do not lift the motor and its driven load by the motor lifting hardware. The motor lifting hardware is

adequate for lifting only the motor. Disconnect the load (gears, pumps, compressors, or other driven

equipment) from the motor shaft before lifting the motor.

In the case of assemblies on a common base, any lifting means provided on the motor should not be used

to lift the assembly and base but, rather, the assembly should be lifted by a sling around the base or by other

lifting means provided on the base. Assure lifting in the direction intended in the design of the lifting means.

Likewise, precautions should be taken to prevent hazardous overloads due to deceleration, acceleration or

shock forces.

Alignment Accurate alignment of the motor with the driven equipment is extremely important. The pulley, sprocket,

or gear used in the drive should be located on the shaft as close to the shaft shoulder as possible. It is

recommended to heat the pulley, sprocket, or gear before installing on the motor shaft. Forcibly driving a unit

on the motor shaft will damage the bearings.

1. Direct Coupling

For direct drive, use exible couplings if possible. Consult the drive or equipment manufacturer for more

information. Mechanical vibration and roughness during operation may indicate poor alignment. Use dial

indicators to check alignment. The space between coupling hubs should be maintained as recommended

by the coupling manufacturer.

2. End-Play Adjustment

The axial position of the motor frame with respect to its load is also extremely important. The standard

motor bearings are not designed for excessive external axial thrust loads. Improper adjustment will cause

failure.

3. Pulley Ratio

The best practice is to not exceed an 8:1 pulley ratio.

Caution: Do not over tension belts. Excess tension may damage the motor or driven equipment.

4. Belt Drive

Align sheaves carefully to minimize belt wear and axial bearing loads (see End-Play Adjustment). Belt

tension should be sufcient to prevent belt slippage at rated speed and load. However, belt slippage may

occur during starting.

Doweling & Bolting

After proper alignment is veried, dowel pins should be inserted through the motor feet into the foundation.

This will maintain the correct motor position should motor removal be required.

(Baldor•Reliance motors are designed for doweling.)

1. Drill dowel holes in diagonally opposite motor feet in the locations provided.

2. Drill corresponding holes in the foundation.

3. Ream all holes.

4. Install proper tting dowels.

5. Mounting bolts must be carefully tightened to prevent changes in alignment.

Top View

Allows F-1 to F-2 Conversion on 8 hole

frames.

Not present on 6 hole frames.

Not used on 8 hole frames.

Shaft

Always use these holes, closer to the

shaft 112S, 132S, 160M, 180M,

200M, 225S, 250S, 280S, (IEC)

For short frame designations 182, 213,

254, 284, 324, 364, 404, 444 (NEMA)

For long frame designations 184, 215,

256, 286, 326, 365, 405, 445 (NEMA)

(IEC) 112M, 132M, 160L, 200L, 225M,

250M, 280M

Installation & Operation 2-3MN408

Use a at washer and lock washer under each nut or bolt head to hold the motor feet secure.

Flanged nuts or bolts may be used as an alternative to washers.

WARNING: Guards must be installed for rotating parts such as couplings, pulleys, external fans, and unused shaft

extensions, should be permanently guarded to prevent accidental contact by personnel.

Accidental contact with body parts or clothing can cause serious or fatal injury.

Guarding Guards must be installed for rotating parts such as couplings, pulleys, external fans, and unused shaft

extensions. This is particularly important where the parts have surface irregularities such as keys, key ways or

set screws. Some satisfactory methods of guarding are:

1. Covering the machine and associated rotating parts with structural or decorative parts of the driven

equipment.

2. Providing covers for the rotating parts. Covers should be sufciently rigid to maintain adequate guarding

during normal service.

Power Connection

Motor and control wiring, overload protection, disconnects, accessories and grounding should conform to the

National Electrical Code and local codes and practices.

For ExnA hazardous location motors, it is a specic condition of use that all terminations in a conduit box

be fully insulated. Fully insulated and lugged terminations must be bolted and provided with lock washer to

prevent rotation. Flying leads must be insulated with two full wraps of electrical grade insulating tape or heat

shrink tubing.

Grounding In the USA consult the National Electrical Code, Article 430 for information on grounding of motors and

generators, and Article 250 for general information on grounding. In making the ground connection, the

installer should make certain that there is a solid and permanent metallic connection between the ground point,

the motor or generator terminal housing, and the motor or generator frame. In non−USA locations consult the

appropriate national or local code applicable.

Motors with resilient cushion rings usually must be provided with a bonding conductor across the resilient

member. Some motors are supplied with the bonding conductor on the concealed side of the cushion ring to

protect the bond from damage. Motors with bonded cushion rings should usually be grounded at the time of

installation in accordance with the above recommendations for making ground connections. When motors

with bonded cushion rings are used in multimotor installations employing group fusing or group protection,

the bonding of the cushion ring should be checked to determine that it is adequate for the rating of the branch

circuit over current protective device being used.

There are applications where grounding the exterior parts of a motor or generator may result in greater hazard

by increasing the possibility of a person in the area simultaneously contacting ground and some other nearby

live electrical parts of other ungrounded electrical equipment. In portable equipment it is difcult to be sure that

a positive ground connection is maintained as the equipment is moved, and providing a grounding conductor

may lead to a false sense of security.

Select a motor starter and over current protection suitable for this motor and its application. Consult motor

starter application data as well as the National Electric Code and/or other applicable local codes.

For motors installed in compliance with IEC requirements, the following minimum cross sectional area of the

protective conductors should be used:

Cross sectional area of phase

conductors, S

Minimum cross sectional area of the

corresponding protective conductor, S

mm2 mm2

6 6

10 10

16 16

25 25

35 25

50 25

70 35

95 50

120 70

150 70

Equipotential bonding connection shall made using a conductor with a cross-sectional area of at least 4 mm

2-4 Installation & Operation MN408

Conduit Box For ease of making connections, an oversize conduit box is provided. Most conduit boxes can be rotated 360 º

in 90 º increments. In the case that a conduit box needs to be adjusted, remove conduit box mounting screws.

Rotate conduit box in 90 º increments to desired location. Reinsert mounting screws and tighten to grade 2

torque.

Auxiliary conduit boxes are provided on some motors for accessories such as space heaters, RTD’s etc.

AC Power Motors with ying lead construction must be properly terminated and insulated.

Connect the motor leads as shown on the connection diagram located on the name plate or inside the cover

on the conduit box. Be sure the following guidelines are met:

1. AC power is within +10% of rated voltage with rated frequency. (See motor name plate for ratings).

2. AC power is within +5% of rated frequency with rated voltage.

3. A combined variation in voltage and frequency of +10% (sum of absolute values) of rated values, provided

the frequency variation does not exceed +5% of rated frequency.

Performance within these voltage and frequency variations are shown in Figure 2-3.

Figure 2-2 Accessory Connections

Rotation

All three phase motors are reversible. To reverse the direction of rotation, disconnect and lock out power

and interchange any two of the three line leads for three phase motors. For single phase motors, check the

connection diagram to determine if the motor is reversible and follow the connection instructions for lead

numbers to be interchanged. Not all single phase motors are reversible.

Adjustable Frequency Power Inverters used to supply adjustable frequency power to induction motors produce

wave forms with lower order harmonics with voltage spikes superimposed. Turn−to−turn, phase−to−phase,

and ground insulation of stator windings are subject to the resulting dielectric stresses. Suitable precautions

should be taken in the design of these drive systems to minimize the magnitude of these voltage spikes.

Consult the drive instructions for maximum acceptable motor lead lengths, and proper grounding.

Note: Main power leads for CE Marked Motors may be marked U,V,W – for standard congurations,

please consult connection diagrams.

Caution: The space heaters are designed to operate at or below the maximum surface temperature stated on the

nameplate. If the marked ambient and/or voltage are exceeded this maximum surface temperature can

be exceeded and can damage the motor windings. If applied in a division 2 or zone 2 environment this

excessive temperature may cause ignition of hazardous materials.

One heater is installed in each end of motor.

Leads for each heater are labeled H1 & H2.

(Like numbers should be tied together).

Three thermistors are installed in windings and tied in series.

Leads are labeled TD1 & TD2.

Winding RTDs are installed in windings (2) per phase.

Each set of leads is labeled

1TD1, 1TD2, 1TD3, 2TD1, 2TD2, 2TD3 etc.

* One bearing RTD is installed in Drive endplate (PUEP), leads

are labeled RTDDE.

* One bearing RTD is installed in Opposite Drive endplate (FREP), leads

are labeled RTDODE.

* Note RTD may have 2−Red/1−White leads; or 2−White/1−Red Lead.

TD1

TD2

Installation & Operation 2-5MN408

Connection Diagrams

2-6 Installation & Operation MN408

Connection Diagrams Continued

Installation & Operation 2-7MN408

Figure 2-3 Typical Motor Performance VS Voltage Variations

Initial Lubrication

Baldor•Reliance motors are shipped from the factory with the bearings properly packed with grease and ready

to operate. Where the unit has been subjected to extended storage (6 months or more) the bearings should be

relubricated (regreasable type) prior to starting. When motors are equipped for oil mist lubrication refer to the

instruction manual for installation, operation, and maintenance of oil mist lubrication systems.

Caution: Shaker Duty motors must be properly lubricated prior to Start Up to prevent damage. See Section 3.

First Time Start Up

Be sure that all power to motor and accessories is off. Be sure the motor shaft is disconnected from the load

and will not cause mechanical rotation of the motor shaft.

1. Make sure that the mechanical installation is secure. All bolts and nuts are tightened etc.

2. If motor has been in storage or idle for some time, check winding insulation integrity.

3. Inspect all electrical connections for proper termination, clearance, mechanical strength and electrical

continuity.

4. Be sure all shipping materials and braces (if used) are removed from motor shaft.

5. Manually rotate the motor shaft to ensure that it rotates freely.

6. Replace all panels and covers that were removed during installation.

7. Momentarily apply power and check the direction of rotation of the motor shaft.

8. If motor rotation is wrong, be sure power is off and change the motor lead connections.

Verify rotation direction before you continue.

9. Start the motor and ensure operation is smooth without excessive vibration or noise.

If so, run the motor for 1 hour with no load connected.

10. After 1 hour of operation, disconnect power and connect the load to the motor shaft.

Verify all coupling guards and protective devices are installed. Ensure motor is properly ventilated.

+20

+15

+10

−5

−10

−15

−20

−15 −10 −5 0 +5 +10 +15

Voltage Variations (%)

Changes in Motor Performance (%)

Full -Load

Current

Full -Load

Current

Power

Factor

Power

Factor

Efficiency

Maximum

Torque

Maximum

Torque

2-8 Installation & Operation MN408

11. If motor is totally enclosed fan−cooled or non−ventilated it is recommended that condensation drain plugs,

if present, be removed. These are located in the lower portion of the end−shields. Totally enclosed fan−

cooled “XT” motors are normally equipped with automatic drains which may be left in place as received.

Coupled Start Up

This procedure assumes a coupled start up. Also, that the rst time start up procedure was successful.

1. Check the coupling and ensure that all guards and protective devices are installed.

2. Check that the coupling is properly aligned and not binding.

3. The rst coupled start up should be with no load. Apply power and verify that the load is not transmitting

excessive vibration back to the motor though the coupling or the foundation.

Vibration should be at an acceptable level.

4. Run for approximately 1 hour with the driven equipment in an unloaded condition.

The equipment can now be loaded and operated within specied limits. Do not exceed the name plate ratings

for amperes for steady continuous loads.

Jogging and Repeated Starts

Repeated starts and/or jogs of induction motors generally reduce the life of the motor winding insulation.

A much greater amount of heat is produced by each acceleration or jog than by the same motor under full

load. If it is necessary to repeatedly start or jog the motor, it is advisable to check the application with your

local Baldor distributor or Baldor Service Center.

Heating - Duty rating and maximum ambient temperature are stated on the motor name plate.

Do not exceed these values. If there is any question regarding safe operation, contact your local Baldor

distributor or Baldor Service Center.

Hazardous Locations

Hazardous locations are those where there is a risk of ignition or explosion due to the presence of combustible

gases, vapors, dust, bers or yings.

Selection Facilities requiring special equipment for hazardous locations are typically classied in accordance with

local requirements. In the US market, guidance is provided by the National Electric Code. In international

hazardous location areas, guidance for gas / vapor / mist classication is given in IEC60079−14, or for dust in

IEC61241−14. This classication process lets the installer know what equipment is suitable for installation in

that environment, and identies what the maximum safe temperature or temperature class is required.

It is the customer or users responsibility to determine the area classication and select proper equipment.

Areas are classied with respect to risk and exposure to the hazard. In the US market, areas are typically

classied as follows Class, Division, Group and Temperature Class. In some newer installations in the US and

in most international markets, areas are classied in Zones.

Protection Concepts

Class I Division 1 / Zone 1 [Equipment Group I (mining) or II (surface), Equipment Protection Level (EPL)

Gb, Mb ]

Baldor offers a range of motors suitable for installation in a Division 1 or Zone 1 environment.

These motors are known as explosion proof or ameproof.

Motors that are explosion proof or ameproof use specially machined ameproof joints between the end bell or

bracket and the frame, as well as along the rotating shaft and at connection box covers and entries.

The t of these ameproof joints are designed to contain the combustion or quench the ame of an explosive

gas atmosphere prior to it exiting the motor. These ameproof joints have lengths and widths selected and

tested based on the gas group present in the atmosphere. Baldor•Reliance motors are typically designed to

meet Class I (Division 1) Group C and D (explosion proof) or Ex d IIB (ameproof).

An application note regarding equipment applied in accordance with the US National Electric Code (NFPA

70−2008) − according to Article 500.8(C) Marking, sub clause (2) in the ne print note, it is noted that

Equipment not marked to indicate a division is suitable for both Division 1 and Division 2 locations.

These motors are not gas tight. To the contrary, this protection concept assumes that due to the normal

heating and cooling cycle of motor operation that any gas present will be drawn into the motor. Since

ameproof or explosion proof motors are designed to contain the combustion and extinguish any ame

transmission, for this protection concept, only external surface temperatures are of concern. Thermal limiting

devices such as thermostats, thermistors or RTDs may be provided on these motors to limit the external

surface temperature during overload conditions.

When explosion proof or ameproof motors are provided with intrinsically safe sensors, the integrity of that

system relies upon the proper application and selection of barriers and cables as described in the sensor

manufacturers control drawing. The control drawing will be shipped with the motor, and it is important that

those instructions be provided to the equipment installer.

Installation & Operation 2-9MN408

If thermostats are provided as a condition of certication, it is the installer’s responsibility to make sure that

these devices are properly connected to a suitable switching device. The ATEX directive requires that motor

shutdown on thermal trip be accomplished without an intermediate software command. Where intermediate

circuitry is involved the circuit shall fall within the scope of a safety, controlling and regulating device as dened

in article 1(2) of European Directive 2014/34/EU, and shall be covered by an appropriate EC Type Examination

Certicate.

Flameproof motors, internationally referred to as Ex d use a protection concept similar to that used in Class

I Division 1 motors, with minor differences in the ameproof joints and cable entry designs. Flameproof and

explosion proof motors are both type tested. Representative motors are connected to a reference gas and

ignited in laboratory conditions to verify that the ame is not transmitted outside the motor enclosure and to

determine the maximum internal pressure encountered.

Explosion proof and Flame proof motors shipped without a conduit box require use of a certied box of

suitable dimensions and that is appropriate for the classication. Openings in connection boxes must be

closed with suitably certied and dimensioned device.

Hazardous location motors equipped with NPT pipe nipples are designed and built such that the pipe nipple is

securely attached to the motor frame. This is accomplished externally by interference between the threads as

well as tack welding. The conduit box is securely attached to the pipe nipple at the factory per:

1. Standard Commercial NPT & Explosion Proof IEC/ATEX parts : L-1 gauging notch +/- 1 thread (ref.

ANSI/ASME B1.20.1 and Clarication Sheet ExNB/98/06/010/CS) Note: Clarication Sheet

ExNB/98/06/010/CS provides inspection criteria to meet (6 threads minimum per engineering part drawing

for ATEX parts).

2. Explosion Proof UL conduit boxes & MSHA parts: L-1 gauging notch “+1 min to + 3 1/2 max threads.

Note: Provides inspection criteria to meet (5 threads minimum per engineering part drawing for MSHA parts

and meet UL 1203 requirement for L-1 gauging notch ush to + 3 1/2 max threads).

This allows the end user to position the conduit box according to the application then secure when in place.

For obvious reasons having the conduit box snug prior to afxing to the pipe nipple is preferable. However, the

guidance in numbers 1 and 2 above can be used in determining thread engagement.

Note: In the United States most non-mining applications have rigid conduit for cabling, therefore not tack

welding the conduit box to the pipe nipple is standard. In markets outside the United States, exible

conduit/cabling are common and end users should take note to secure the conduit box to the pipe nipple

once in position. Further, the exible leads should be secured to inhibit forces acting on the conduit box.

Class I Division 2 / Zone 2 Ex nA, [Equipment Protection Level (EPL) Gc ]

This protection concept relies on having no sources of ignition present such as arcing parts or hot surfaces.

For this protection concept, internal temperatures as well as external temperatures are considered. In many

cases, the internal temperatures are higher than the external temperatures and therefore become the limiting

factor in determination of temperature code designation. In these applications, it is very important to use a

motor that has been evaluated thermally for use with an inverter or converter, if variable speed operation is

desired. Thermostats used for Class I Division 2 and Ex nA motors are used to protect the motor only. For

motors using ying lead construction, it is important to use connection lugs and insulate with heat shrink

tubing or a double wrap of insulation grade electrical tape to avoid the risk of spark or ignition.

Class II Division 1 / Zone 21 [Equipment Group III, Equipment Protection Level (EPL) Db ]

This area classication is one where the risk of ignitable concentrations of dust is present at all or some of the

time. The protection concepts used for Class II Division 1 is similar to amepath, except with additional dust

exclusion paths designed for the rotating shaft. In the international designations, this concept is referred to as

dust ignition proof or Ex tD. External surface temperature remains the limiting factor. Thermal limiting devices

such as thermostats, thermistors or RTDs may be provided on these motors to limit the external surface

temperature during overload conditions. If thermostats are provided as a condition of certication, it is the

installer’s responsibility to make sure that these devices are properly connected to a suitable switching device.

Note: In the North American area classication system, Class III exists for bers and yings.

In the IEC designation, both dusts and yings are absorbed into Group III.

Class II Division 2 / Zone 22 [Equipment Group III, Equipment Protection Level (EPL) Dc ]

This area classication is one where the risk of exposure to ignitable concentrations of dust are not likely

to occur under normal operating conditions and relies heavily on the housekeeping practices within the

installation.

Sine Wave Power Operation for Division 1 or 2 and Zone 1 or 2 and Zone 21 or 22 Hazardous Location.

These motors are designed to operate at or below the maximum surface temperature (or T−Code) stated

on the nameplate. Failure to operate the motor properly can cause this maximum surface temperature to

be exceeded. If applied in a Division 1 or 2 / Zone 1 or 2 and Zone 21 or 22 environment, this excessive

temperature may cause ignition of hazardous materials. Operating the motor at any of the following

conditions can cause the marked surface temperature to be exceeded.

2-10 Installation & Operation MN408

1. Motor load exceeding service factor nameplate value

2. Ambient temperatures above nameplate value

3. Voltages above or below nameplate value

4. Unbalanced voltages

5. Loss of proper ventilation

6. Altitude above 3300 feet / 1000 meters

7. Severe duty cycles of repeated starts

8. Motor stall

9. Motor reversing

10. Single phase operation of polyphase equipment

11. Variable frequency operation

Variable Frequency Power Operation for Division 1 or 2 and Zone 1 or 2 and Zone 21 or 22

Hazardous Location (motors with maximum surface temperature listed on the nameplate).

Only motors with nameplates marked for use on inverter (variable frequency) power, and labeled for specic

hazardous areas may be used in those hazardous areas on inverter power. The motor is designed to operate

at or below the maximum surface temperature (or T−Code) stated on the nameplate.

Failure to operate the motor properly can cause this maximum surface temperature to be exceeded.

If applied in a Division 1 or 2 / Zone 1 or 2 and Zone 21 or 22 environment, this excessive temperature may

cause ignition of hazardous materials. Operating the motor at any of the following conditions can cause the

marked surface temperature to be exceeded.

1. Motor load exceeding service factor nameplate value

2. Ambient temperature above nameplate value

3. Voltage (at each operating frequency) above or below rated nameplate value

4. Unbalanced voltages

5. Loss of proper ventilation

6. Operation outside of the nameplate speed / frequency range

7. Altitudes above 3300 feet / 1000 meters

8. Single phase operation of polyphase equipment

9. Unstable current wave forms

10. Lower than name plate minimum carrier frequency

Thermal Limiting

Thermal limiting devices are temperature sensing control components installed inside the motor to limit

the internal temperature of the motor frame by interrupting the circuit of the holding coil of the magnetic

switch or contactor. They are required for most Division 1 and Zone 1 applications. For Division 2 or Zone

2 applications, motors should be selected that preclude running temperatures from exceeding the ignition

temperatures for the designated hazardous material. In Division 2 or Zone 2 classied locations, thermal

limiting devices should only be used for winding protection and not considered for limiting all internal motor

temperatures to specic ignition temperatures.

Equipotential Bonding and Shaft Current Reduction

Larger motors (ie WP construction) may require proper bonding between motor enclosures and covers to

avoid the risk of stray currents during start up. Fastening methods and bonding straps must not be modied.

Bearing currents can exist in some motors for both line−fed and inverter−fed applications. Larger line−fed

motors may require at least one insulated bearing to prevent a ow of current through the bearings. Do not

defeat such insulation whether the motor is line−fed or inverter−fed applications. Inverter−fed motors may

require additional bearing insulation or even a shaft brush. Do not defeat such features. When the motor and

the coupled load are not on a common conductive baseplate, it may also be necessary to electrically bond

together the stationary parts of the motor and the coupled equipment.

Installation & Operation 2-11MN408

Repair of Motors used in Hazardous Locations

Repair of hazardous certied motors requires additional information, skill, and care. It is the customer’s

responsibility to select service shops with proper qualications to repair hazardous location motors. Contact

the manufacture for additional repair details. Use only original manufacturer’s parts.

Repair of Explosion Proof or Flame Proof Motors Class I Division 1 and Zone 1

In the North American market, recertication programs are offered by Underwriters Laboratories and Canadian

Standards Association which allow authorized service shops to mark the rebuilt motors as certied. In the

international markets using IEC based requirements, repair should be undertaken only after consulting

IEC60079−19 Explosive Atmospheres−Part 19 Equipment repair, overhaul and reclamation. If use of a certied

repair facility is desired, consult the IECEX Repair Scheme at http://www.iecex.com/service_facilities.htm

Explosion proof and ameproof motors achieve their safety based on the mechanical construction −

ameproof joints and bearing clearance, and the electrical design including any thermal limiting devices. If it is

necessary to repair a ameproof or explosion proof motor, it is critical that the mechanical ameproof joints be

maintained. Consult Baldor Electric Company for ameproof joint construction details.

Use only Baldor•Reliance supplied parts. Baldor does not recommend reclamation of parts.

Since this protection method also relies on temperature being maintained, make sure that any rewinding uses

the original electrical designs, including any thermal protection that may be present.

Repair of Dust Ignition Proof Motors − Class II Division 1 and 2, Zone 21 and 22.

For Dust Ignition Proof, proper sealing is required. Do not modify the motor construction to add any additional

opening, and ensure that proper sealing is maintained in the connection box and at the shaft seal. Since this

protection method also relies on temperature being maintained, make sure that any rewinding uses the original

electrical designs, including any thermal protection that may be present

Repair of Class I Division 2 and Zone 2 motors

For Division 2 and Zone 2, the internal and external temperatures are of concern. Since this protection method

also relies on temperature being maintained, make sure that any rewinding uses the original electrical designs,

including any thermal protection that may be present. Use only Baldor replacement thermostats, if provided.

Disposal of Electric Motors

WEEE EU Directive 2012/19/EU

Products that are marked with the crossed-out wheeled bin symbol as shown here; shall be handled by

applying following information:

The crossed-out wheeled bin symbol on the product(s) and / or accompanying documents

means that used electrical and electronic equipment (WEEE) should not be mixed with general

household waste. For users in the European Union, please contact your dealer or supplier for

more information on how to discard electrical and electronic equipment (EEE).

2-12 Installation & Operation MN408

Maintenance & Troubleshooting 3-1MN408

Section 3

Maintenance & Troubleshooting

WARNING: UL and EX Listed motors must only be serviced by UL or EX Approved Authorized Baldor Service

Centers if these motors are to be returned to a hazardous and/or explosive atmosphere.

General Inspection

Inspect the motor at regular intervals, approximately every 500 hours of operation or every 3 months,

whichever occurs rst. Keep the motor clean and the ventilation openings clear. The following steps should be

performed at each inspection:

WARNING: Do not touch electrical connections before you ﬁrst ensure that power has been disconnected.

Electrical shock can cause serious or fatal injury. Only qualiﬁed personnel should attempt the

installation, operation and maintenance of this equipment.

1. Check that the motor is clean. Check that the interior and exterior of the motor is free of dirt, oil, grease,

water, etc. Oily vapor, paper pulp, textile lint, etc. can accumulate and block motor ventilation. If the motor

is not properly ventilated, overheating can occur and cause early motor failure.

2. Perform a dielectric with stand test periodically to ensure that the integrity of the winding insulation has

been maintained. Record the readings. Immediately investigate any signicant decrease in insulation

resistance.

3. Check all electrical connectors to be sure that they are tight.

Relubrication & Bearings

Bearing grease will lose its lubricating ability over time, not suddenly. The lubricating ability of a grease (over

time) depends primarily on the type of grease, the size of the bearing, the speed at which the bearing operates

and the severity of the operating conditions. Good results can be obtained if the following recommendations

are used in your maintenance program.

Type of Grease A high grade ball or roller bearing grease should be used. Baldor motors are pregreased, normally with

Polyrex EM (Exxon Mobil) or as stated on the nameplate.

Do not mix greases unless compatibility has been checked and veried.

Ball Bearing Motors

Operating Temperature −25 ºC (−15 ºF) to 50 ºC (120 ºF)

EXXON POLYREX EM (Standard on Baldor motors)

EXXON UNIREX N2

EXXON BEACON 325

CHEVRON OIL SRI NO. 2 ( Compatible with Polyrex EM )

CHEVRON OIL BLACK PEARL

TEXACO, INC. PREMIUM RB

TEXACO, INC. POLYSTAR

AMOCO RYKON # 2

PENNZOIL PENNZLUBE EM−2

DARMEX DARMEX 707

DARMEX DARMEX 711

PETRO−CANADA PEERLESS LLG

SHELL OIL DOLIUM BRB

Minimum Starting Temperature −60 ºC (−76 ºF)

SHELL OIL CO. AEROSHELL 7 (Standard on Baldor motors)

MOBIL MOBIL 28

MOBIL MOBILITH SHC 100 (Low Temperature − Arctic Duty)

Roller Bearing Motors

Operating Temperature −25 ºC (−15 ºF) to 50 ºC (120 ºF)

TEXACO, INC. PREMIUM RB

MOBIL MOBILITH SHC 220 (Standard on Baldor motors)

CHEVRON OIL BLACK PEARL

3-2 Maintenance & Troubleshooting MN408

Relubrication Intervals

Recommended relubrication intervals are shown in Table 3-1. It is important to realize that the recommended

intervals of Table 3-2 are based on average use.

Refer to additional information contained in Tables 3-2, 3-3 and 3-4.

Table 3-1 Relubrication Intervals *

NEMA /

(IEC) Frame Size

Rated 60 Hz (50 Hz) Speed - RPM

10000 6000 3600 (3000) 1800 (1500) 1200 (1000) 900 (750)

Up to 210 incl. (132) ** 2700 Hrs. 5500 Hrs. 12000 Hrs. 18000 Hrs. 22000 Hrs.

Over 210 to 280 incl. (180) ** 3600 Hrs. 9500 Hrs. 15000 Hrs. 18000 Hrs.

Over 280 to 360 incl. (225) ** * 2200 Hrs. 7400 Hrs. 12000 Hrs. 15000 Hrs.

Over 360 to 449 incl. (315) ** *2200 Hrs. 3500 Hrs. 7400 Hrs. 10500 Hrs.

* Relubrication intervals are for ball bearings.

For vertically mounted motors and roller bearings, divide the relubrication interval by 2.

** For motors operating at speeds greater than 3600 RPM, contact Baldor for relubrication

recommendations.

Table 3-2 Service Conditions

Severity of Service Hours per day of

Operation

Ambient Temperature

Maximum

Atmospheric Contamination

Standard 8 40 ºC Clean, Little Corrosion

Severe 16 Plus 50 ºC Moderate dirt, Corrosion

Extreme 16 Plus >50 ºC* or Class H Insulation Severe dirt, Abrasive dust, Corrosion,

Heavy Shock or Vibration

Low Temperature <−29 ºC **

* Special high temperature grease is recommended (Dow Corning DC44). Note that Dow Corning DC44

grease does not mix with other grease types. Thoroughly clean bearing & cavity before adding grease.

** Special low temperature grease is recommended (Aeroshell 7).

Table 3-3 Relubrication Interval Multiplier

Severity of Service Multiplier

Standard 1.0

Severe 0.5

Extreme 0.1

Low Temperature 1.0

Some motor designs use different bearings on each motor end. This is normally indicated on the motor

nameplate. In this case, the larger bearing is installed on the motor Drive endplate. For best relubrication

results, only use the appropriate amount of grease for each bearing size (not the same for both).

Maintenance & Troubleshooting 3-3MN408

Table 3-4 Bearings Sizes and Types

Frame Size

NEMA (IEC)

Bearing Description (These are the “Large” bearings (Shaft End) in each frame size)

Bearing

Weight of Grease to

add * oz (Grams)

Volume of grease to be added

teaspoon

56 to 140 (90) 6203 0.08 (2.4) 0.15 0.5

140 (90) 6205 0.15 (3.9) 0.2 0.8

180 (100−112) 6206 0.19 (5.0) 0.3 1.0

210 (132) 6307 0.30 (8.4) 0.6 2.0

250 (160) 6309 0.47 (12.5) 0.7 2.5

280 (180) 6311 0.61 (17) 1.2 3.9

320 (200) 6312 0.76 (20.1) 1.2 4.0

360 (225) 6313 0.81 (23) 1.5 5.2

400 (250) 6316 1.25 (33) 2.0 6.6

440 (280) 6318 1.52(40) 2.5 8.2

440 (280) 6319 2.12 (60) 4.1 13.4

5000 to 5800 (315−355) 6328 4.70 (130) 9.2 30.0

5000 to 5800 (315−355) NU328 4.70 (130) 9.2 30.0

360 to 449 (225−280) NU319 2.12 (60) 4.1 13.4

AC Induction Servo

76 Frame 180 (112) 6207 0.22 (6.1) 0.44 1.4

77 Frame 210 (132) 6210 0.32 (9.0) 0.64 2.1

80 Frame 250(160) 6213 0.49 (14.0) 0.99 3.3

* Weight in grams = .005 DB of grease to be added

Note: Not all bearing sizes are listed. For intermediate bearing sizes, use the grease volume for the next larger

size bearing.

Caution: To avoid damage to motor bearings, grease must be kept free of dirt. For an extremely dirty

environment, contact your Baldor distributor or an authorized Baldor Service Center for additional

information.

Relubrication Procedure Be sure that the grease you are adding to the motor is compatible with the grease

already in the motor. Consult your Baldor distributor or an authorized service center if a grease other than the

recommended type is to be used.

Caution: Do not over−lubricate motor as this may cause premature bearing failure.

With Grease Outlet Plug

1. With the motor stopped, clean all grease ttings with a clean cloth.

2. Remove grease outlet plug.

Caution: Over−lubricating can cause excessive bearing temperatures, premature lubrication breakdown and

bearing failure.

3. Add the recommended amount of grease.

4. Operate the motor for 15 minutes with grease plug removed. This allows excess grease to purge.

5. Re-install grease outlet plug.

3-4 Maintenance & Troubleshooting MN408

Without Grease Provisions

Note: Only a Baldor authorized and UL or CSA certied service center can disassemble a UL/CSA listed

explosion proof motor to maintain it’s UL/CSA listing.

1. Disassemble the motor.

2. Add recommended amount of grease to bearing and bearing cavity. (Bearing should be about 1/3 full of

grease and outboard bearing cavity should be about 1/2 full of grease.)

3. Assemble the motor.

Sample Relubrication Determination

Assume - NEMA 286T (IEC 180), 1750 RPM motor driving an exhaust fan in an ambient temperature of 43 ºC

and the atmosphere is moderately corrosive.

1. Table 3-2 list 9500 hours for standard conditions.

2. Table 3-3 classies severity of service as “Severe”.

3. Table 3-5 shows that 1.2 in

or 3.9 teaspoon of grease is to be added.

Note: Smaller bearings in size category may require reduced amounts of grease.

Shaker Duty Motors only

Caution: Shaker Duty motors must be properly lubricated prior to Start Up to prevent damage. See Table 3-6.

Lubrication should be performed before Start Up and at regular maintenance intervals.

Follow these recommendations to ensure proper lubrication.

Recommended Lubricant

For ambient temperatures between −15 ºF to 120 ºF the following lubricants are recommended:

Mobil PolyrexEM, Texaco Premium RB, Exxon Unirex N−2.

Do not mix greases unless compatibility has been checked and veried.

Table 3-5 Lubrication Volume

NEMA Frame Size

Volume in Cubic Inches

Normal Duty Severe Duty Extreme Duty

Start Up Relub Start Up Relub Start Up Relub

184TY 1.4 0.5 1.4 0.5 2.7 0.5

215TY 1.6 0.5 1.6 0.5 4.5 1

256TY 7 1 11 2

286TY 9 1 15 3

Lubrication Frequency

Normal Duty 8 hours per day (16 hours per day in a clean environment). Lubricate every 2 months.

Severe Duty 16 hours per day or more in a dirty environment (corrosive atmosphere, chemical fumes, acids,

alkalies or extreme high humidity). Lubricate every month or 700 hours of operation.

Extreme Duty operation in extremely dirty or dusty environments and high ambient temperatures exceeding

104 ºF (40 ºC). Lubricate twice a month or 350 hours of operation.

Lubrication Procedure

1. Locate the grease inlet and outlet. Clean the areas.

2. Remove the plug(s) and install a grease tting in the inlet if grease tting is not already installed.

3. Add the recommended amount of lubricant.

4. Run the motor for two hours with the outlet plug removed.

5. Install outlet plug.

Note: To loosen hardened grease it may be necessary to insert a rod or wire into the grease inlet and outlet

holes.

Maintenance & Troubleshooting 3-5MN408

Table 3-6 Troubleshooting Chart

Symptom Possible Causes Possible Solutions

Motor will not start

Usually caused by line trouble, such as,

single phasing at the starter.

Check source of power. Check overloads, fuses,

controls, etc.

Excessive humming

High Voltage.

Eccentric air gap.

Check input line connections.

Have motor serviced at local Baldor service center.

Motor Over Heating

Overload. Compare actual amps

(measured) with nameplate rating.

Locate and remove source of excessive friction in motor

or load.

Reduce load or replace with motor of greater capacity.

Single Phasing. Check current at all phases (should be approximately

equal) to isolate and correct the problem.

Improper ventilation. Check external cooling fan to be sure air is moving

properly across cooling ns.

Excessive dirt build-up on motor. Clean motor.

Unbalanced voltage. Check voltage at all phases (should be approximately

equal) to isolate and correct the problem.

Rotor rubbing on stator. Check air gap clearance and bearings.

Tighten “Thru Bolts”.

Over voltage or under voltage. Check input voltage at each phase to motor.

Open stator winding. Check stator resistance at all three phases for balance.

Grounded winding. Perform dielectric test and repair as required.

Improper connections. Inspect all electrical connections for proper termination,

clearance, mechanical strength and electrical continuity.

Refer to motor lead connection diagram.

Bearing Over Heating

Misalignment. Check and align motor and driven equipment.

Excessive belt tension. Reduce belt tension to proper point for load.

Excessive end thrust. Reduce the end thrust from driven machine.

Excessive grease in bearing. Remove grease until cavity is approximately 3/4 lled.

Insufcient grease in bearing. Add grease until cavity is approximately 3/4 lled.

Dirt in bearing. Clean bearing cavity and bearing. Repack with correct

grease until cavity is approximately 3/4 lled.

Vibration

Misalignment. Check and align motor and driven equipment.

Rubbing between rotating parts and

stationary parts.

Isolate and eliminate cause of rubbing.

Rotor out of balance. Have rotor balance checked are repaired at your Baldor

Service Center.

Resonance. Tune system or contact your Baldor Service Center for

assistance.

Noise

Foreign material in air gap or ventilation

openings.

Remove rotor and foreign material. Reinstall rotor. Check

insulation integrity. Clean ventilation openings.

Growling or whining

Bad bearing. Replace bearing. Clean all grease from cavity and new

bearing. Repack with correct grease until cavity is

approximately 3/4 lled.

3-6 Maintenance & Troubleshooting MN408

Suggested bearing and winding RTD setting guidelines for Non−Hazardous Locations ONLY

Most large frame AC Baldor motors with a 1.15 service factor are designed to operate below a Class B

(80 ºC) temperature rise at rated load and are built with a Class H winding insulation system. Based on this

low temperature rise, RTD (Resistance Temperature Detectors) settings for Class B rise should be used as a

starting point. Some motors with 1.0 service factor have Class F temperature rise.

The following tables show the suggested alarm and trip settings for RTDs. Proper bearing and winding RTD

alarm and trip settings should be selected based on these tables unless otherwise specied for specic

applications.

If the driven load is found to operate well below the initial temperature settings under normal conditions, the

alarm and trip settings may be reduced so that an abnormal machine load will be identied.

The temperature limits are based on the installation of the winding RTDs imbedded in the winding as specied

by NEMA. Bearing RTDs should be installed so they are in contact with the outer race on ball or roller bearings

or in direct contact with the sleeve bearing shell.

Table 3-7 Winding RTDs − Temperature Limit In ºC (40 ºC Maximum Ambient)

Motor Load

(Typical Design)

Class B Temp Rise

< 80 ºC

Class F Temp Rise

< 105 ºC

Class H Temp Rise

< 125 ºC

Alarm Trip Alarm Trip Alarm Trip

< Rated Load 130 140 155 165 175 185

Rated Load to 1.15 S.F. 140 150 160 165 180 185

Note: • Winding RTDs are factory production installed, not from Mod−Express.

When Class H temperatures are used, consider bearing temperatures and relubrication requirements.

Table 3-8 Bearing RTDs − Temperature Limit In oC (40 ºC Maximum Ambient)

Bearing Type Oil or

Grease

Anti−Friction Sleeve

Alarm Trip Alarm Trip

Standard* 95 100 85 95

High Temperature** 110 115 105 110

Notes: * Bearing temperature limits are for standard design motors operating at Class B temperature rise.

** High temperature lubricants include some special synthetic oils and greases.

Greases that may be substituted that are compatible with Polyrex EM (but considered as “standard” lubricants

include the following:

− Texaco Polystar − Rykon Premium #2 − Chevron SRI #2

− Mobilith SHC−100 − Pennzoil Pennzlube EM−2 − Chevron Black Pearl

− Darmex 707 − Darmex 711 − Petro−Canada Peerless LLG

See the motor nameplate for replacement grease or oil recommendation.

Contact Baldor application engineering for special lubricants or further clarications.

Appendix - IEC 60079 Series 4-1MN408

Section 4

Appendix - IEC 60079 Series

INFORMATION REQUIRED PER IEC 60079-0:2017 Ed7

All italicized information below is quoted from the standard, clause 30.

Clause 30 (instructions) – Instructions are provided with each motor, the most recent version of this manual can

be download at baldor.com.

Instructions for purposes of this standard consists of the following that are shipped with your motor in the

literature package:

• Instruction Manual MN408

• Ex Certicates applicable for your motor

• Nameplate marking photos for your motor

Clause 30.1 (general)

The instructions prepared by the manufacturer shall include the following particulars as a minimum.

Marking

A recapitulation of the information with which the equipment is marked, except for the serial number

(see Clause 29), together with any appropriate additional information to facilitate maintenance (for

example, address of the importer, repairer, etc.)

A copy of the nameplates is included in the literature package and is shipped with each motor. These

instructions are used for a range of mining motors. An example of typical certication marking is shown in

Section 1. For motor specic information, please refer to the certication nameplate photos, electrical rating

information and any specic conditions conveyed in the motor marking such as but not limited to ambient

range, water ow, converter set up parameters and refer to the data package shipped with the product.

on-site assembling:

Not typically required.

installation and erection:

iii) guidance for the selection of ﬂameproof entry devices for termination compartments with reference

pressure greater than ...1 333 kPa for Group I and 2 000 kPa for Group II .

The reference pressure encountered in this Group I range of motors is below 1 333 kPa and is below 2 000 kPA

for the Group II range of motors.

adjustment and parameter setting

If operated on a converter, refer to nameplate marking for set-up parameters.

4-2 Appendix - IEC 60079 Series MN408

putting into service - of the equipment / of the whole installation:

i) information about veriﬁcations / tests prior to (ﬁrst) use

Refer to Section 2, Installation and Operation

ii) detailed information about any special installation requirements for the Type of Protection(s)

employed

For anged joints, inspect with feeler gauge 0,40mm maximum

Use and setting-up;

Ratings such as electrical values, ambient temperatures and pressures, maximum surface temperatures and

other limit values related to a designated use are included on the product nameplate photos and in the product

data package..

- maintenance;

ii) Information such as cleaning, oil level check or recalibration requirements;

Information on bearing inspection is in the Maintenance Section 3

iii) Requirements for the maintenance of the explosion protection.

Flameproof joints should be inspected during repair and overhaul contact manufacturer for schedule drawings

if needed for repair.

- repair

i) Repair should be conducted in accordance with the requirements given in IEC 60079-19

Refer to Repair of Motors used in Hazardous Locations

Information related to the tting or removal of parts / components; As each motor design is unique, it is

necessary to Contact the manufacture for additional repair details. Use only original manufacturer’s parts.

ii) information related to the ﬁtting or removal of parts / components

Contact ABB regarding any spare parts.

iii) Information about spare parts

Contact ABB regarding any spare parts.

Appendix - IEC 60079 Series 4-3MN408

iv) Requirements for a documentation of such repairs.

As any repair is undertaken after consultation with IEC60079-19, the documentation requirements for the repair

in this standard apply.

- taking out of service and dismantling

i) Use appropriate lock out tag out procedures to prevent restart and prior to making or breaking any

electrical connection.

• where applicable, Speciﬁc Conditions of Use according to 29.3 e)

As Specic Conditions of Use may vary with each certicate, if Specic Conditions are applied, the certicate

is shipped with each motor forming part of the Instructions. Refer to Marking and Acceptance section for an

explanation of the “X” sufx to certicate numbers.

Clause 30.3 (electrical machines)

In addition to the information required according to 30.1, the following additional information shall be prepared for

electrical machines, as applicable:

machines intended to be supplied by a converter

For speed torque information on motors intended to be supplied by converter, consult motor nameplate.

bearing lubrication requirements for both commissioning and maintaining;

Instructions for lubrication are included in the Bearing Maintenance Section. Only use ABB recommended

grease or contact ABB Motors and Mechanical Inc., product support team for guidance on equivalents suitable

for hazardous locations.

4-4 Appendix - IEC 60079 Series MN408

the permitted axial and radial loading of the shaft;

Table 4-1 Table to Address Permissible Radial and Axial Shaft Loads

AC Motors DC Motors

Frame Size Permissible Radial

Shaft Load (kN)*

Permissible Axial

Shaft Thrust (kN)*

Frame Size Permissible Radial

Shaft Load (kN)*

Permissible Axial

Shaft Thrust (kN)*

150 0.60 0.67 41-6,9 2.00 1.00

188 0.70 0.67 48-9,12 2.00 1.00

210 0.80 0.67 51-7,11,15 2.00 1.60

X215TCZ 0.90 0.67 51-9 2.00 1.60

240 0.95 0.67

XRL25OAY 4.30 1.60

XRL25OAY 3.80 1.50

XRL25OAY 11.60 15.00

250 1.00 0.67

0280 1.00 1.00

X286TCZ 1.40 1.00

320 1.60 1.00

X326TCZ 1.70 1.00

350 1.90 1.00

360 2.00 1.00

400 4.50 1.00

440 4.50 3.00

470 4.80 3.00

500 5.00 3.00

580 7.50 4.00

Furnace Fan Ex ec Motors

Frame Size Permissible Radial

Shaft Load (kN)*

Permissible Axial

Shaft Thrust (kN)*

326TY 5.9 2.2

Medium AC Ex d Motors (at 1800 RPM L10 of 100,000 hours)

Frame Size Permissible Radial

Shaft Load (kN)*

Permissible Axial

Shaft Thrust (kN)*

180 .5 --

210 .7 --

250 1.6 --

280 1.8 --

320 2.0 --

360 2.6 --

400 3.3 --

440 2.8 --

*Permissible shaft loads are for specied frame size mounted horizontally and are calculated for an extended service life of

17,500 operating hours of bearing according to DIN ISO 281. Consult engineering for application specic solutions that require

larger permissible shaft loads than those provided in this table. This table assumes pure radial loading for permissible radial

shaft loads and pure axial loading for permissible axial shaft thrust.

Appendix - IEC 60079 Series 4-5MN408

• the thermal expansion of the shaft and housing under rated conditions

Maintain minimum clearances necessary to accommodate thermal growth of up to 3mm of the frame and

up to 5mm (8mm for Furnace Fan Motor Designs) of the shaft during design operating conditions. Consult

engineering for application specic solutions where these minimum clearances are not permissible.

• any necessary maintenance of the protection provided by the manufacturer against stray circulating currents in the bearings or shafts.

Ensure that the motor is properly earthed and bonded. For motors operated by converter, consult converter

manufacturers instructions relative to cable recommendations.

• any necessary protection of the bearings from vibration, including during transportation, storage, or standby service;

Protection of bearings from vibration during storage and transportation are addressed in General. Bearings

requiring blocking are blocked during shipment.

• guidance on maintenance and replacement intervals for bearings based on the operating conditions.

Instructions for lubrication are included in the Bearing Maintenance Section

INFORMATION REQUIRED PER IEC 60079-1:2014

If it is necessary to repair a ameproof or explosion proof motor, it is critical that the mechanical ameproof

joints be maintained. Consult ABB Motors and Mechanical Inc., product support team for ameproof joint

construction details. Use only Baldor/Reliance supplied parts. ABB does not recommend reclamation of

Baldor/Reliance parts.

4-6 Appendix - IEC 60079 Series MN408

Appendix - IEC 60079 Series 4-7MN408

4-8 Appendix - IEC 60079 Series MN408

MN408_0121

MN408 01/2021

Additional information

We reserve the right to make technical

changes or modify the contents of this

document without prior notice. With

regard to purchase orders, the agreed

particulars shall prevail. ABB does not

accept any responsibility whatsoever for

potential errors or possible lack of infor-

mation in this document.

We reserve all rights in this document

and in the subject matter and illustra-

tions contained therein. Any reproduc-

tion, disclosure to third parties or

utilization of its contents – in whole or

in parts – is forbidden without prior

written consent of ABB.

—

ABB Motors and Mechanical Inc.

5711 R.S. Boreham, Jr. Street

Fort Smith, AR 72901

Ph: 1.479.646.4711

new.abb.com/motors-generators

Specifications subject to change without notice.