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Grundfos CR, CRI, CRN, CRT Installation And Operating Instruction Manual

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GRUNDFOS INSTRUCTIONS
CR, CRI, CRN, CRT
Installation and operating instructions
LIMITED WARRANTY
To obtain service under this warranty, the defective product must be returned to the distributor or dealer of Grundfos' products from which it was purchased together with proof of purchase and installation date, failure date, and supporting installation data. Unless otherwise provided, the distributor or dealer will contact Grundfos or an authorized service station for instructions. Any defective product to be returned to Grundfos or a service station must be sent freight prepaid; documentation supporting the warranty claim and/or a Return Material Authorization must be included if so instructed.
GRUNDFOS WILL NOT BE LIABLE FOR ANY INCIDENTAL OR CONSEQUENTIAL DAMAGES, LOSSES, OR EXPENSES ARISING FROM INSTALLATION, USE, OR ANY OTHER CAUSES. THERE ARE NO EXPRESS OR IMPLIED WARRANTIES, INCLUDING MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE, WHICH EXTEND BEYOND THOSE WARRANTIES DESCRIBED OR REFERRED TO ABOVE.
Some jurisdictions do not allow the exclusion or limitation of incidental or consequential damages and some jurisdictions do not allow limit actions on how long implied warranties may last. Therefore, the above limitations or exclusions may not apply to you. This warranty gives you specific legal rights and you may also have other rights which vary from jurisdiction to jurisdiction.
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CR, CRI, CRN, CRT
Installation and operating instructions 5
Notice d'installation et de fonctionnement ?
Instrucciones de instalación y funcionamiento ?
3
4
CONTENTS
Page Shipment inspection 5 Understanding nameplate data 6
Understanding codes 7
Confirming proper application 8 Checking operating conditions 8 Installing the pump 10
Pump location 10 Foundation 10 Pump mounting 11 Check valves 13 Electrical 14 Motor 14
Starting the pump the first time 14 Preventative pump maintenance 16
Maintaining the pump’s motor 16 Motor Lubrication 16 Lubrication Procedure 17
Replacing the motor 17 Parts List 19 Spare Parts 19 Preliminary electrical tests 20 Startup for Cool-Top® 21 Diagnosing specific problems 22 Worksheet for three-phase motors 24
Warnin g Electrical Work: All electrical work should be
performed by a qualified electrician in accordance with the latest edition of the National Electrical Code, local codes and regulations.
Warnin g Shock Hazard: A faulty motor or wiring can cause
electrical shock that could be fatal, whether touched directly or conducted through standing water. For this reason, proper grounding of the pump to the power supply’s grounding terminal is required for safe installation and operation.
In all installations, the above-ground metal plumbing should be connected to the power supply ground as described in Article 250-80 of the National Electrical Code.
1. General
The CR range is based on the inline multistage centrifugal pump first pioneered by Grundfos. CR is available in four basic materials and over one million configurations. CR is suitable for pumping water and water-like liquids in industry, petrochemical, water treatment, commercial buildings, and many other applications. Some of CR’s outstanding characteristics are:
• superior efficiency
• reliability
• ease of maintenance
• compact size and small footprint
• quiet operation.
2. Shipment inspection
Examine the components carefully to make sure no damage has occurred to the pump during shipment. Care should be taken to ensure the pump is NOT dropped or mishandled.
2.1 Ensure you have the right pump
Read the pump nameplate to make sure that it is the one you ordered.
CR Centrifugal pump with standard cast iron and 304 stainless steel construction
CRI Centrifugal pump; all parts in contact with water are 304 stainless steel construction
CRN Centrifugal pump; all parts in contact with water are 316 stainless steel construction
CRT Centrifugal pump; all parts in contact with water are titanium construction
CRE Centrifugal pump with a Grundfos MLE VFD motor attached.
2.2 Checking the condition of the pump
The shipping carton in which your pump arrived is specially designed around your pump during production to prevent damage during shipment. As a precaution, the pump should remain in the carton until you are ready to install it. Examine the pump for any damage that may have occurred during shipping. Examine any other parts of the shipment as well for any visible damage.
Note: If the pump is shipped as a complete unit (motor attached to pump end), the position of the coupling (that connects the pump shaft to the motor shaft) is set at factory specifications. No adjustment is required. If the unit is delivered as a pump end only, follow the adjustment procedures in the section on replacing the motor.
Pump without Motor (CR(I)(N) 1s, 1, 3, 5, 10, 15, and 20 Only):
If you purchased a pump without a motor, the shaft seal has been set by the factory . Do not loosen the three set screws on the shaf t seal when attaching the motor.
Pump without Motor (CR(N) 32, 45, 64, 90, 120, and 150 Only):
If you purchased a pump without a motor, you must install the seal. The seal is protected in its own sub boxing within the pump packaging crate. To protect the shaft and bearings during shipment, a shaft holder protective device is used. This device must be removed prior to installation of the seal. Read the seal installation instructions which are included in the pump package.
2.3 Verifying electrical requirements
Verification of the electrical supply should be made to be certain the voltage, phase and frequency match that of the pump motor. The proper operating voltage and other electrical information can be found on the motor nameplate. These motors are designed to run on –10 % / + 10 % of the nameplate-rated voltage. For dual- voltage motors, the motor should be internally connected to operate on the voltage closest to the 10% rating, i.e., a 208 voltage motor wired per the 208 volt connection diagram. The wiring connection diagram can be found on either a plate attached to the motor or on a diagram inside the terminal box cover. If voltage variations are larger than –10 % / + 10 %, do not operate the pump.
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3. Understanding nameplate data
1
2 43 6 87
910
5
11
Type key CR, CRI, CRN 1s, 1, 3, 5, 10, 15, and 20
Example
Type range: CR, CRI,
3
Rated flow rate in [m
/h] (x 5gpm) Number of impellers Code for pump version Code for pipe connection Code for materials Code for rubber parts Code for shaft seal
CRT 2, 4, 8, and 16 Example
Type range: CRT Rated flow rate in [m
3
/h] (x 5gpm) Number of stages x 10
Code for impellers (used only if the pump has fewer impellers than stages)
Code for pump version Code for pipe connection Code for materials Code for shaft seal and rubber parts
CR, CRN 32, 45, 64, 90, 120, and 150 Example
Type CR, CRN Rated flow rate in [m
3
/h] (x 5gpm) Number of impellers Number of reduced diameter impellers Code for pump version Code for pipe connection Code for materials Code for rubber pump parts Code for shaft seal
CR 3 -10 A FG A E HQQE
CRT 16 -30 /2 U G A AUUE
C 32 -2 -1 U G A E KUBE
Fig. 1 Nameplate
QH
P
GPM FEET
N
HP
Fig. 2 Nameplate
A
Designated Model (eg.ABCD)
12345678
Material Number
Production week number(01-52)
Fig. 3 Model key
1. Type designation
2. Model, material
3. Head in feet at
4. Nominal motor hp
5. Head at zero flow
6. Rated rp m
7. Nominal flow
8. Rated frequency
9. Maximum pre ssure
10. Direction of rotation
11. Production country
TM04 3895 0309
PSI °F max
P1
Production Company
Last two digits of production year
number, product ion number
nominal flow
and maximum fluid temperature
RPM
01
41
TM04 3894 0309TM04 3904 0409
6
3.1 Understanding codes
Example Pump version:
A *Basic pump version U *NEMA Version Pump
Oversize motor,
B
one flange size bigger CR pump for high
F
temperatures (Cool-Top®)
H Horizontal version A O-ring with fixed driver
High pressure pump with
HS
over-synchronous speed and reversed direction of rotation
I Different pressure rating K Low NPSH M Magnetic drive
P Undersize motor
Horizontal version with
R
bearing bracket High pressure pump with
SF
reversed chamber stack and direction of rotation
Oversize motor,
T
two flange sizes bigger
X **Special version
Pipe connection
A Oval flange B NTP thread Q Silicon carbide C Clamp coupling CA FlexiClamp CX TriClamp E EPDM F DIN flange F FXM (Flouraz®) G ANSI flange J JIS flange N Changed diameter of ports O Externally threaded, union P PJE coupling X Special version
Materials
A Basic version
Carbon-filled graphite PTFE
A
(bearings) G Stainless steel parts of 316 SS GI Base plate and flanges of 316 SS
I
Stainless steel parts of 304 SS II Base plate and flange of 304 SS K Bronze (bearings)
SiC bearing ring + PTFE neck
S
ring (only CR, CRN 32 to 90 T Titanium X Special version
U
FGJ
AEHQQE
Shaft seal
B Rubber bellows seal D O-ring seal, balanced
Cartridge seal with
E
O-ring Balanced cartridge
H
seal with O-ring Cartridge shaft seal
K
with metal bellows Double seal, back to
O
back
P Double seal, tandem
O-ring seal with
R
reduced face
X Special version
Carton, synthetic
B
resin-impregnated Cemented tungsten
H
carbine, embedded
Cemented tungsten
U
carbide
K FFKM (Kalraz®) V FKM (Viton®)
* In August 2003 the NEMA pump code was
discontinued for all material numbers created by GRUNDFOS manufacturing companies in North America. The NEMA version pump code will still remain in effect for existing material numbers. NEMA version pumps built in North America after this change will have either an A or U as the pump version code depending on the date the material number was created.
If a pump incorporates more than two pump
**
versions, the code for the pump version is X. X also indicates special pump versions not listed above.
HQQE
Code for rubber parts
EEPDM F FXM (Flouraz®) K FFKM (Kalrez®)
VFKM (Viton®)
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4. Confirming proper application
Compare the pump’s nameplate data or its performance curve with the application in which you plan to install it. Will it perform the way you want it to perform? Also, make sure the application falls within the following limits.
Type Designed to pump
CR
CRI/CRN
CRN-SF
CRT
Hot and chilled water, boiler feed, condensate return, glycols and solar thermal fluids.
Deionized, demineralized and distilled water. Brackish water and other liquids unsuitable for contact with iron or copper alloys. (Consult manufacturer for specific liquid compatibilities.)
High pressure washdown, reverse osmosis, or other high pressure applications.
Salt water, chloride based fluids and fl uids app rove d for titanium.
5. Checking operating conditions
5.1 Fluid temperatures
s
Pump
CR(I)(N) 1s, 3, 5, 10, 15, and 20
*CR(N) 32, 45, 64, and 90 *CR(N) 120 and 150
(up to 60 hp) CR(N) 120 and 150
(75 and 100 hp) CRT 2, 4, 8, 16
CRN-SF
with Cool-Top™
All motors are designed for continuous duty in +104 °F (+40 °C) ambient air conditions. For higher ambient temperature conditions consult Grundfos.
* xUBE Shaft Seals are recommended for temperatures above +200 °F. Pumps with hybrid shaft KUHE seals can only operate up to +200 °F (+90 °C). Pumps with xUUE shaft seals can be operated down to –40 °F (–40 °C) (where “x” is the seal type).
Fluid
Temperatures
–4 to +248 °F
(–20 to +120 °C)
–22 to +248 °F
(–30 to +120 °C)
–22 to +248 °F
(–30 to +120 °C)
+32 to +248 °F
(0 to +120 °C)
–4 to +248 °F
(–20 to +120 °C)
–4 to +221 °F
(–15 to +105 °C)
up to +356 °F
(+180 °C)
5.2 Minimum inlet pressures
All CR, CRI, CRN NPSHR + 2 feet CRN-SF 29 psi (2 bar)
5.3 Maximum inlet pressures
Pump Type/ Connection
CR, CRI, CRN 1s 2 to 36 2 to 36 145 / 10
CR, CRI, CRN 1 2 to 36 2 to 36 145 / 10
CR, CRI, CRN 3 2 to 29 2 to 15 145 / 10
CR, CRI, CRN 5 3 to 16 2 to 9 145 / 10
CR, CRI, CRN 10 1 to 6 1 to 5 116 / 8
CR, CRI, CRN 15 1 to 3 1 to 2 116 / 8
CR, CRI, CRN 20 1 to 3 1 116 / 8
CR, CRN 32 1-1 to 4 1-1 to 2 58 / 4
CR, CRN 45 1-1 to 2 1-1 to 1 58 / 4
CR, CRN 64 1-1 to 2-2 1-1 58 / 4
CR, CRN 90 1-1 to 1 58 / 4
CR, CRN 120 1 to 2-1 1-1 to 1 145 / 10
CR, CRN 150 1-1 to 1 1-1 145 / 10
CRT 2 2 to 11 2 to 6 145 / 10
CRT 4 1 to 12 1 to 7 145 / 10
CRT 8 1 to 20 1 to 16 145 / 10 CRT 16 2 to 16 2 to 10 145 / 10 CRN-SF all all 72 / 5*
* while pump is off or during start-up ** during operation
50 Hz
Stages
31 to 36 17 to 25 217 / 15
18 to 36 10 to 24 217 / 15
7 to 22 6 to 18 145 / 10
4 to 17 3 to 12 145 / 10
4 to 17 2 to 10 145 / 10
5-2 to 10 3-2 to 6 145 / 10
11 to 14 7-2 to 11-2 217 / 15
3-2 to 5 2-2 to 3 145 / 10
6-2 to 13-2 4-2 to 8-1 217 / 15
2-1 to 4-2 1 to 2-1 145 / 10 4-1 to 8-1 2 to 5-2 217 / 15
2-2 to 3-2 1-1 to 1 145 / 10
3 to 6 2-2 to 4-1 217 / 15
2 to 5-1 2-2 to 3 217 / 15 6-1 to 7 4-1 to 5-2 290 / 20
2-1 to 4-1 1 to 2 217 / 15
5-2 to 6 3-2 to 4-2 290 / 20
13 to 26 7 to 18 217 / 15
14 to 22 8 to 16 217 / 15
60 Hz
Stages
27 217 / 15
27 217 / 15
psi/bar
362 / 25**
Max.
8
5.4 Maximum operating pressures
at +250 °F (194 °F for CRN-SF)
Pump type/ connection
CR, CRI, CRN 1s
Oval flange 1 to 23 1 to 17 232 / 16 FGJ, PJE 1 to 36 1 to 27 362 / 25
CR, CRI, CRN 1
Oval flange 1 to 23 1 to 17 232 / 16 FGJ, PJE 1 to 36 1 to 27 362 / 25
CR, CRI, CRN 3
Oval flange 1 to 23 1 to 17 232 / 16 FGJ, PJE 1 to 36 1 to 27 362 / 25
CR, CRI, CRN 5
Oval flange 1 to 22 1 to 16 232 / 16 FGJ, PJE 1 to 36 1 to 24 362 / 25
CR, CRI 10
Oval flange CR 1 to 6 145 / 10 Oval flange, CRI 1 to 16 1 to 10 232 / 16 FGJ, GJ, PJE 1 to 16 1 to 10 232 / 16 FGJ, GJ, PJE 17 to 22 12 to 17 362 / 25
CRN 10
All 1 to 22 1 to 17 362 / 25
CR, CRI 15
Oval flange 1 to 7 1 to 5 145 / 10 FGJ, GJ, PJE 1 to 10 1 to 8 232 / 16 FGJ, GJ, PJE 12 to 17 9 to 12 362 / 25
CRN 15
All 1 to 17 1 to 12 362 / 25
CR, CRI 20
Oval flange 1 to 7 1 to 5 145 / 10 FGJ, GJ, PJE 1 to 10 1 to 7 232 / 16 FGJ, GJ, PJE 12 to 17 8 to 10 362 / 25
CRN 20
All 1 to 17 1 to 10 362 / 25
CR, CRN 32
CR, CRN 45
CR, CRN 64
CR, CRN 90
CR, CRN 120
CR, CRN 150
50 Hz
stages
1-1 to 7 1-1 to 5 232 / 16
8-2 to 14 6-2 to 11-2 435 / 30
1-1 to 5 1- 1 to 4-2 232 / 16
6-2 to 13-2 4-2 to 8-1 435 / 30
1-1 to 5 1-1 to 3 232 / 16
6-2 to 8-1 4-2 to 5-2 435 / 30
1-1 to 4 1-1 to 3 232 / 16 5-2 to 6 4- 2 to 4-1 435 / 30
1-1 to 5-2 4-2 to 5-2 435 / 30
1-1 to 4-2 4-1 to 4-2 435 / 30
60 Hz
stages
1-1 to 3
1-1 to 3 232 / 16
Max.
psi/bar
232 / 16
CRT 2 2 to 26 2 to 18 305 / 21 CRT 4
CRT 8
CRT 16
1 to 22 1 to 16 305 / 21 1 to 12 1 to 8 232 / 16
14 to 20 10 to 16 362 / 25
1 to 8 1 to 8 232 / 16
10 to 16 10 to 12 362 / 25
Consult Grundfos for other working conditions.
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6. Installing the pump
2
1
2
1
L
L
B
4 x ø
B
Warnin g Do not energize pump until properly installed.
6.1 Pump location
The pump should be located in a dry , well-ventilated area which is not subject to freezing or extreme variation in temperature.
Care must be taken to ensure the pump is mounted at least 6 inches (150 mm) clear of any obstruction or hot surfaces.
The motor requires an adequate air supply to prevent overheating and adequate vertical space to remove the motor for repair.
For open systems requiring suction lift the pump should be located as close to the water source as possible to reduce piping losses.
6.2 Foundation
Concrete or similar foundation material should be used to provide a secure, stable mounting base for the pump.
See table of bolt hole center line dimensions for the vario us pump types.
Secure the pump to the foundation using all four bolts and shim pump base to assure the pump is vertical and all four pad s on th e base are properly supported (uneven surfaces can result in pump base breakage when mounting bolts are tightened).
TM04 3906 0409
Fig. 4 Pump position
The pump can be installed vertically or horizontally; see fig. 4. Ensure that an adequate supply of cool air reaches the motor
cooling fan. The motor must never fall below the horizontal plane. Arrows on the pump base show the direction of flow of liquid
through the pump. To minimize possible noise from the pump, it is advisable to fit
expansion joints on either side of the pump and anti-vibration mountings between the foundation and the pump.
Note: Care should be taken to ensure that the vent plug is located in the uppermost position.
Isolating valves should be fitted either side of the pump to avoid draining the system if the pump needs to be cleaned, repaired or replaced.
TM00 2256
Pump type
CR 1s, 1, 3, 5 3 15/16 100 5 11/16 145 7 1/16 180 8 11/16 220 1/2 13 CRI, CRN 1s 1, 3, 5 CR 10, 15, 20 5 1/8 130 6 15/16 176 8 7/16 215 10 1/16 256 9/16 13.5 CRN 10, 15, 20 CR 32 6 11/16 170 8 3/4 223 9 7/16 240 11 3/4 298 9/16 14 CRN 32 6 11/16 170 8 7/8 226 9 7/16 240 11 3/4 298 9/16 14 CR 45,64 7 1/2 190 9 3/4 248 10 1/2 266 13 1/16 331 9/16 14 CRN 45,64 7 1/2 190 9 7/8 251 10 1/2 266 13 1/16 331 9/16 14 CR(N) 90 7 13/16 199 10 1/4 261 11 280 13 11/16 348 9/16 14 CR(N) 120, 150 10 13/16 275 13 9/16 344 14 15/16 380 18 9/16 472 11/16 18
L1 L2 B1 B2 ø
in mm in mm in mm in mm in mm
3 15/16 100 5 7/8 150 7 1/16 180 8 11/16 220 1/2 13
5 1/8 130 7 7/8 200 8 7/16 215 9 3/4 248 1/2 13
10
6.3 Pump mounting
r
Warnin g CR, CRI, CRN pumps are shipped with covered
suction and discharge. The covers must be removed before the final pipe flange to pump connections are made.
6.3.1 Recommended installation torques
6.5 Minimum suction pipe sizes
The following recommended suction pipe sizes are the smallest sizes which should be used with any specific CR pump type.
The suction pipe size should be verified with each installation to ensure good pipe practices are being observed and excess friction losses are not encountered.
High temperatures may require larger diameter pipes to reduce friction and improve NPHSA.
Model
Recommended
foundation torque
(ft - lbs)
Recommended
flange torque
(ft - lbs)
CR, CRI, CRN 1s/1/3/5, and
30 37 - 44
CRT 2/4 CR, CRI,
CRN 10/15/20, and
37 44 - 52
CRT 8/16 CR, CRN
32/45/64/90/
52 52 - 59
120/150
6.4 Suction pipe
The suction pipe should be adequately sized and run as straight and short as possible to keep friction losses to a minimum (minimum of four pipe diameters straight run prior to the suction flange). Avoid using unnecessary fittings, valves or accessory items. Butterfly or gate valves should only be used in the suction line when it is necessary to isolate a pump because of a flooded suction condition. This would occur if the water source is above the pump; see fig. 5 and fig. 6. Flush piping prior to pump installation to remove loose debris.
Reservoir
Butterfly Valve
Check Valve
Expansion Joint
Fig. 5 Flooded suction
Butterfly
Check
Valve
Valve
Eccentric Reducer
Butterfly Valve
Strainer
Model Min. suction pipe size
CR(I)(N) 1s, 1, 3; CRT 2 1" CR(I)(N) 5;
CRT 4 CR(I)(N) 10, 15, 20;
CRT 8, 16
1-1/4"
2"
CR(N) 32 2-1/2"
CR(N) 45 3"
CR(N) 64, 90 4"
CR(N) 120, 150 5"
Nominal diameter sch 40 pipe
Nominal diameter sch 40 pipe
Nominal diameter sch 40 pipe
Nominal diameter sch 40 pipe
Nominal diameter sch 40 pipe
Nominal diameter sch 40 pipe
Nominal diameter sch 40 pipe
6.6 Discharge piping
It is suggested that a check valve and isolation valve be installed in the discharge pipe.
Pipe, valves and fittings should be at least the same diameter as the discharge pipe or sized in accordance with good piping practices to reduce excessive fluid velocities and pipe friction losses.
Note: Pipe, valves and fittings must have a pressure rating equal to or greater than the maximum system pressure.
Before the pump is installed it is recommended that the discharge piping be pressure checked to at least the maximum pressure the pump is capable of generating or as required by codes or local regulations.
Whenever possible, avoid high pressure loss fittings, such as elbows or branch tees directly on either side of the pump. The piping should be adequately supported to reduce thermal and mechanical stresses on the pump.
Good installation practice recommends the system be thoroughly
TM04 3925 0409
cleaned and flushed of all foreign materials and sediment prior to pump installation. Furthermore, the pump should never be installed at the lowest point of the system due to the natural accumulation of dirt and sediment. If there is excessive sediment or suspended particles present, it is advised a strainer or filter be used. Grundfos recommends that pressure gauges be installed on inlet and discharge flanges or in pipes to check pump and system performance.
Suction Pipe
Foot Valve
Fig. 6 Suction lift*
*The suction pipe should have a fitting on it for priming. CRN-SF pumps cannot be used for suction lift.
Reservio
Warnin g To avoid problems with waterhammer, fast
closing valves must not be used in CRN-SF applications.
TM04 3910 0409
11
6.7 Bypass orifice
By-pass line
Nipple Orifice
Inlet
Outlet
Inlet
Outlet
By-Pass Line
Nipple Orifice
Outlet
Inlet
Nipple Orifice
By-Pass Line
Y-direction: Direction of chamber stack Z-direction: 90 ° from inlet/outlet X-direction: Inlet/outlet
A bypass should be installed in the discharge pipe if there is any possibility the pump may operate against a closed valve in the discharge line. Flow through the pump is required to ensure adequate cooling and lubrication of the pump is maintained. See
6.9 Minimum continuous duty flow rates for minimum flow rates. Elbows should be a minimum of 12” from the orifice discharge to
prevent erosion.
Fig. 7 Recommended bypass arrangement
6.8 Nozzle loads
If not all loads reach the maximum permissible value stated in the forces and moments tables included here with fig. 10, one of these values may exceed the normal limit. Contact Grundfos for further information.
TM04 3926 0409TM04 3909 0409TM04 3924 0409
Fig. 8 Optional bypass arrangement
Fig. 9 Optional bypass arrangement for CR(N) 32, 45, 64,
and CR 90, 120, and 150 only
Fig. 10 Nozzle forces and moments
Forces
Flange
CR, CRI,
CRN
Y-direction
[lb]
Z-direction
[lb]
X-direction
[lb]
1-1/4" 1s to 5 171 263 175
2"
10, 15
and 20
303 371 337
2-1/2" 32 382 466 422
3" 45 461 562 506 4" 64 and 90 607 753 674
5" & 6"
120 and
150
607 753 674
Moments
Flange
CR, CRI,
CRN
Y-direction
[ft-lb]
Z-direction
[ft-lb]
X-direction
[ft-lb]
1-1/4" 1s to 5 605 715 900
2"
10, 15 and 20
738 848 1,033
2-1/2" 32 7 93 904 1,106
3" 45 848 959 1,180 4" 64 and 90 922 1,069 1,291
5" & 6"
120 and
150
922 1,069 1,291
TM04 0346
12
6.9 Minimum continuous duty flow rates
Pump Type
CR, CRI, CRN 1s 0.5 0.7 1.2 1.2* CR, CRI, CRN 1 0.9 1.3 2.3 2.3* CR, CRI, CRN 3 1.6 2.4 4.0 4.0* CR, CRI, CRN 5 3.0 4.5 7.5 7.5* CR, CRI, CRN 10 5.5 8.3 14 14* CR, CRI, CRN 15 9.5 14 24 24* CR, CRI, CRN 20 11 17 28 28* CR, CRN 32 14 21 35 3 5* CR, CRN 45 22 33 55 5 5* CR, CRN 64 34 51 85 8 5* CR, CRN 90 44 66 110 110* CR, CRN 120 60 90 N/A N/A CR, CRN 150 75 115 N/A N/A CRT 2 1.3 2.0 3.3 N/A CRT 4 3.0 4.5 7.5 N/A CRT 8 4.0 6.0 10 N/A CRT 16 8.0 0.7 20 N/A
min °F to 176 °F
(min °C to 80 °C)
at 210°F
(at 99°C)
at 248°F
(at 120°C)
at 356°F
(at 180°C)
* Grundfos Cool-Top® is only available in the following pump types.
Pump Type CR 1s CR 1 CR 3 CR 5 CR 10 CR 15 CR 20 CR 32 CR 45 CR 64 CR 90
Standard (CR) •••• I Version (CRI) ••••••• N Version (CRN) •••••••••••
6.10 Check valves
A check valve may be required on the discharge side of the pump to prevent the pump’s inlet pressure from being exceeded.
For example, if a pump with no check valve is stopped because there is no demand on the system (all valves are closed), the high system pressure on the discharge side of the pump will “find” its way back to the inlet of the pump.
If the system pressure is greater than the pump’s maximum inlet pressure rating, the limits of the pump will be exceeded and a check valve needs to be fitted on the discharge side of the pump to prevent this condition. This is especially critical for CRN-SF
applications because of the very high discharge pressures involved. As a result, most CRN-SF installations require a check valve on the discharge piping.
Pump type
CR 1s, 1, 3 210 3.5 CR 5 240 4.0 CR 10 210 3.5 CR 15 150 2.5 CR 20 120 2.0 CR 32, 45, 64, 90,
120, 150
Time for temperature rise
of 18 °F (10 °C)
Seconds Minutes
60 1.0
6.11 Temperature rise
It may sometimes be necessary to stop the flow through a pump during operation.
At shut-off, the power to the pump is transferred to the pumped liquid as head, causing a temperature rise in the liquid.
The result is risk of excess heating of and consequent damage to the pump. The risk depends on the temperature of the pumped liquid and for how long the pump is operating without flow; see the following temperature rise chart.
6.12 Conditions/Reservations
The listed times are subject to the following conditions/ reservations:
• No exchange of heat with the surrounding.
Btu
/
• The pumped liquid is water with a specific heat of 1.0 (4.18
kJ
/
°C).
kg
lb.
°F
• Pump parts (chambers, impellers and shaft) have the same thermal capacity as water.
• The water in the base and the pump head is not included.
These reservations should give sufficient safety margin against excessive temperature rise.
The maximum temperature must not exceed the pump maximum rating.
13
6.13 Electrical
Discharge
Terminal Box 12:00 Position
Standard Terminal Box 6:00 Position
Terminal Box 9:00 Position
Terminal Box 3:00 Position
Suction
Warnin g The safe operation of this pump requires that it
be grounded in accordance with the national electrical code and local governing codes or regulations. Connect the ground wire to the grounding screw in the terminal box and then to the ACCEPTABLE grounding point. All electrical work should be performed by a qualified electrician in accordance with the latest edition of the National Electrical Code, local codes and regulations.
6.14 Motor
Grundfos CR pumps are supplied with heavy-duty 2-pole (3600 rpm nominal), ODP or TEFC, NEMA C frame motors selected to our rigid specifications.
Motors with other enclosure types and for other voltages and frequencies are available on a special-order basis.
CRN-SF pumps are supplied with an IEC (metric) type motor with a reverse thrust bearing.
If you are replacing the pumping unit, but are using a motor previously used on another CR pump, be sure to read
10. Replacing the mo tor for proper adjustment of the coupling height.
6.15 Position of Terminal Box
The motor terminal box can be turned to any of four positions in steps of 90°.
To rotate the terminal box, remove the four bolts securing the motor to the pump but do not remove the shaft coupling. Turn the motor to the desired location; replace and securely tighten the four bolts; see fig. 11.
6.17 Motor protection
6.17.1 Single-Phase Motors
With the exception of 10 HP motors which require external protection, single-phase CR pumps are equipped with multi­voltage, squirrel-cage induction motors with built-in thermal protection.
6.17.2 Three-Phase Motors
CR pumps with three-phase motors must be used with the proper size and type of motor-starter to ensure the motor is protected against damage from low voltage, phase failure, current imbalance and overloads.
A properly sized starter with manual reset and ambient­compensated extra quick trip in all three legs should be used. The overload should be sized and adjusted to the full-load current rating of the motor. Under no circumstances sh ould the overloads be set to a higher value than the full load current shown on the motor nameplate. This will void the warranty.
Overloads for auto transformers and resistant starters should be sized in accordance with the recommendations of the manufacturer.
Three phase MLE motors (CRE-Pumps) require only fuses as a circuit breaker. They do not require a motor starter. Check for phase imbalance (worksheet is provided; see p. 23).
Note: Standard allowable phase imbalance difference is 5%.
6.17.3 CRN-SF
The CRN-SF is typically operated in series with a feed pump. Because the maximum allowable inlet pressure of the CRN-SF increases from 73 psi (when pump is off and during start-up) to 365 psi (during operation), a control device must be used to start the CRN-SF pump one second before the feed pump starts. Similarly, the CRN-SF must stop one second after the feed pump stops. See CRN-SF startup timeline below.
TIME
CRN-SF starts
1 or more seconds
Feed pump starts
Fig. 12 CRN-SF startup
Both pumps operating
Feed pump stops
1 or more seconds
CRN-SF stops
TM04 3921 0409
Fig. 11 Motor terminal box positions (top view)
6.16 Field Wiring
Wire sizes should be based on the current carrying properties of a conductor as required by the latest edition of the National Electrical Code or local regulations. Direct on line (D.O.L.) starting is approved due to the extremely fast run-up time of the motor and the low moment of inertia of the pump and motor. If D.O.L. starting is not acceptable and reduced starting current is required, an auto transformer , resist ant st a rter or sof t st art should be used. It is suggested that a fused disconnect be used for each pump where service and standby pumps are installed.
14
7. Starting the pump the first time
7.1 Priming
To prime the pump in a closed system or an open system where the water source is above the pump, close the pump isolation valve(s) and open the priming plug on the pump head; see fig. 13 and fig. 14.
TM04 3923 0409
Priming Vent Plug CR(I)(N) 1s, 1, 3, 5, 10, 15, 20 CRT 2, 4, 8, 16
Suction
Drain Plug
Fig. 13 Plug and valve locations
Discharge
TTM04 3922 0409
Fig. 14 Plug/valve locations CR(N) 32, 45, 64, 90, 120, 150
Priming Plug (Opposite side)
Drain Plugs (G 1 / 2 A)
with 1 / 4” NPI gauge/sensor taps
Discharge
Vent Plug
Suction
Drain Plugs (G 1 / 2 )
with 1/4" NPT gauge/sensor taps
Caution
Fig. 15 Vent plug
Gradually open the isolation valve in the suction line until a steady stream of airless water runs out the priming port. Close the plug and securely tighten. Completely open the isolation valves.
In open systems where the water level is below the pump inlet, the suction pipe and pump must be filled and vented of air before starting the pump. Close the discharge isolation valve and remove the priming plug. Pour water through the priming hole until the suction pipe and pump are completely filled with water. If the suction pipe does not slope downward from the pump toward the water level, the air must be purged while being filled. Replace the priming plug and securely tighten. For pumps with Cool-Top®, see 14. Startup for Cool-Top®.
Follow these steps:
1. Switch power off.
2. Check to make sure the pump has been filled and vented.
3. Remove the coupling guard and rotate the pump sha ft by ha nd
4. Verify that the electrical connections are in accordance with
5. Switch the power on and observe the direction of rotation.
6. To reverse the direction of rotation, first switch OFF the supply
7. On three-phase motors, interchange any two power leads at
Loosen center plug to vent pump
Vent Plug
to be certain it turns freely.
the wiring diagram on the motor.
When viewed from the top, the pump should rotate counter­clockwise (clockwise for CRN-SF).
power.
the load side of the starter. On single-phase motors, see connection diagram on nameplate. Change wiring as required.
8. Switch on the power and again check for proper motor rotation. Once rotation has been verified, switch off power again. Do not attempt to reinstall the coupling guards with the motor energized. Replace the coupling guard if the rotation is correct. After guards are in place the power can be reapplied. Note: CR, CRI, CRN 1s to 5: For these pumps, it is advisable to open the bypass valve during start-up; see fig. 13. The bypass valve connects the suction and discharge sides of the pump, thus making the filling procedure easier. When the operation is stable, the bypass valve must be closed.
.
Motors should not be run unloaded or uncoupled from the pump at any time; damage to the motor bearings will occur.
Do not start the pump before priming or venting the pump; see fig. 15. Never operate the pump dry.
7.2 Operating Parameters
CR multi-stage centrifugal pumps installed in accordance with these instructions and sized for correct performance will operate
TM04 4036 0609
efficiently and provide years of service. The pumps are water­lubricated and do not require any external lubrication or inspection. The motors may require periodic lubrication as noted in 9. Maintaining the pump’s motor.
Under no circumstances should the pump be operated for any prolonged periods of time without flow through the pump. This can result in motor and pump damage due to overheating. A properly sized relief valve should be installed to allow sufficient water to circulate through the pump to provide adequate cooling and lubrication of the pump bearings and seals.
7.3 Pump Cycling
Pump cycling should be checked to ensure the pump is not starting more than the following.
TM04 3920 0409
Grundfos ML motors:
• 200 times per hour on 1/3 to 5 hp models
• 100 times per hour on 7 1/2 to 15 hp models
• 40 times per hour on 20 to 30 hp models.
Baldor motors:
• 20 times per hour on 1/3 to 5 hp models
• 15 times per hour on 7 1/2 to 15 hp models
• 10 times per hour on 20 to 100 hp models.
Rapid cycling is a major cause of premature motor failure due to increased heat build-up in the motor. I f necessary, adjust controls to reduce the frequency of starts and stops.
7.4 Boiler-feed installations
If the pump is being used as a boiler-feed pump, make sure the pump is capable of supplying sufficient water throughout its entire evaporation and pressure ranges. Where modulating control valves are used, a bypass around the pump must be installed to ensure pump lubrication (see “Minimum Continuous Duty Flow Rates”).
7.5 Freeze Protection
If the pump is installed in an area where freezing could occur, the pump and system should be drained during freezing temperatures to avoid damage. To drain the pump, close the isolation valves, remove the priming plug and drain plug at the base of the pump. Do not replace the plugs until the pump is to be used again. Always replace the drain plug with the original or exact replacement. Do not replace with a standard plug. Internal recirculation will occur, reducing the output pressure and flow.
15
8. Preventative pump maintenance
At regular intervals depending on the conditions and time of operation, the following checks should be made:
1. Pump meets required performance and is operating smoothly and quietly.
2. There are no leaks, particularly at the shaft seal.
3. The motor is not overheating.
4. Remove and clean all strainers or filters in the system.
5. Verify the tripping of the motor overload protection.
6. Check the operation of all controls. Check unit control cycling twice and adjust, if necessary.
7. If the pump is not operated for unusually long periods, the unit should be maintained in accordance with these instructions. In addition, if the pump is not drained, the pump shaft should be manually rotated or run for short periods of time at monthly intervals.
8. To extend the pump life in severe duty applications, consider performing one of the following actions:
– Drain the pump after each use. – Flush the pump, through system, with water or other fluid
that is compatible with the pump materials and process liquid.
– Disassemble the pump liquid components and thoroughly
rinse or wash them with water or other fluid that is compatible with the pump materials and process liquid.
If the pump fails to operate or there is a loss of performance, refer to Section 15. Diagnosing specific problems.
9. Maintaining the pump’s motor
Warnin g 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 installation, operation, and maintenance of this equipment.
9.1 Motor Inspection
Inspect the motor at regular intervals, approximately every 500 hours of operation or every three months, whichever occurs first. Keep the motor clean and the ventilation openings clear.
The following steps should be performed at each inspection:
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. Use an Ohmmeter (“Megger”) periodically to ensure that the integrity of the winding insulation has been maintained. Record the Ohmmeter readings. Immediately investigate any significant drop in insulation resistance.
3. Check all electrical connectors to be sure that they are tight.
9.2 Motor Lubrication
Electric motors are pre-lubricated at the factory and do not require additional lubrication at start-up. Motors without external grease fittings have sealed bearings that cannot be re-lubricated. Motors with grease fittings should only be lubricated with approved types of grease. Do not over-grease the bearings. Over-greasing will cause increased bearing heat and can result in bearing/motor failure. Do not mix petroleum grease and silicon grease in motor 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 bearings, the speed at which the bearings operate and the severity of the operating conditions.
Good results can be obtained if the following recommendations are used in your maintenance program. It should also be noted that pumps with more stages, pumps running to the left of the performance curve, and certain pump ranges may have higher thrust loads. Pumps with high thrust loads should be greased according to the next service interval level.
9.3 Recommended lubricant
Severity of service Ambient temp. (max.) Environment Approved types of grease
Standard +104 °F (+40 °C) Clean, little corrosion Grundfos ML motors are greased
Severe +122 °F (+50 °C) Moderate dirt, corrosion
Extreme
Note: If pump is fitted with a bearing flange that requires grease, see the stickers on either the bearing flange or coupling guards for proper grease type and greasing schedule.
>122 °F (+50°C)
or Class H insulation
Severe dirt, abrasive dust,
corrosion
for life or will have the grease type on the nameplate. Baldor motors are greased with Polyrex EM (Exxon Mobile).
16
9.4 Motor lubrication schedule
Caution
Caution
(for motors with grease nipples)
New motors that have been stored for a year or more should be regreased according to the following:
NEMA (IEC)
Frame Size
Up through 210 (132)
Over 210 through 280 (180)
Over 280 up through 360 (225)
Over 360 (225)
Warnin g The grease outlet plug MUST be removed before adding new grease.
Standard Service
Interval
5500 hrs 2750 hrs 550 hrs 0.30 (8.4) 0.6 (2)
3600 hrs 1800 hrs 360 hrs 0.61 (17.4)* 1.2 (3.9)
2200 hrs 1100 hrs 220 hrs 0.81 (23.1)* 1.5 (5.2)
2200 hrs 1100 hrs 220 hrs 2.12 (60.0)* 4.1 (13.4)
Severe
Service Interval
9.5 Lubrication Procedure
To avoid damage to motor bearings, grease must be kept free of dirt. For an extremely dirty environment, contact Grundfos, the motor manufacturer, or an authorized service center for additional information.
Mixing dissimilar grease is not recommended.
1. Clean all grease fittings. If the motor does not have grease fittings, the bearing is sealed and cannot be greased externally.
2. If the motor is equipped with a grease outlet plug, remove it. This will allow the old grease to be displaced by the new grease. If the motor is stopped, add the recommend ed amount of grease. If the motor is to be greased while running, a slightly greater quantity of grease will have to be added. Note: If new grease does not appear at the shaft hole or grease outlet plug, the outlet passage may be blocked. At the next service interval the bearings must be repacked.
3. Add grease SLOWLY taking approximately one minute until new grease appears at the shaft hole in the endplate or grease outlet plug. Never add more than 1-1/2 times the amount of grease shown in the lubrication schedule.
4. For motors equipped with a grease outlet plug, let the motor run for 20 minutes before replacing the plug.
10. Replacing the motor
If the motor is damaged due to bearing failure, burning or electrical failure, the following instructions detail how to remove the motor for replacement.
It must be emphasized that motors used on CR pumps are specifically selected to our rigid specifications. Replacement motors must be of the same frame size, should be equipped with the same or better bearings and have the same service factor. Failure to follow these recommendations may result in premature motor failure.
Extreme
Service Interval
Weight of grease
to add
[oz (grams)]
Volume of grease
to add
3
(teaspoons)]
[in
10.1 Disassembly
For disassembly, proceed as follows:
1. Turn off and lock out power supply. The power supply wiring can now be safely disconnected from the motor wires. Remove the coupling guards. Note: CR 1s, 1, 3, 5, 10, 15, and 20: do not loosen the three shaft seal securing allen screws.
2. Using the proper metric Allen wrench, loosen the four cap screws in the coupling. Completely remove coupling halves. On CR1s-CR20, the shaft pin can be left in the pump shaft. CR(N)32, 45, 64, 90, 120, and 150 do not have a shaft pin.
3. With the correct size wrench, loosen and rem ove the four bolt s which hold the motor to the pump end.
4. Lift the motor straight up until the shaft has cleared the motor stool.
10.2 Assembly
For assembly, proceed as follows:
1. Remove key from motor shaft, if present, and discard.
2. Thoroughly clean the surfaces of the motor and pump end mounting flange. The motor and shaft must be clean of all oil/ grease and other contaminants where the coupling attaches. Set the motor on the pump end.
3. Place the terminal box in the desired position by rotating the motor.
4. Insert the mounting bolts, then diagonally and evenly tighten:
– for 3/8” bolts (1/2 to 2 hp), torque to 17 ft-lb – for 1/2” bolts (3 to 40 hp) torque to 30 ft-lb – for 5/8” bolts (50 - 100 hp) torque to 59 ft-lb – follow instructions for particular pump model in sections
10.2.1 Torque specifications for CR 1s, 1, 3, and 5 through
10.2.4 CR(N) 32, 45, 64, 90, 120, and 150.
17
10.2.1 Torque specifications for CR 1s, 1, 3, and 5
• Note the clearance below the coupling
• Raise the coupling higher, as far as it will go
• Lower it halfway back down (1/2 the distance you just raised it)
• Tighten screws (see torque specifications below)
Insert shaft pin into shaft hole. Reinstall the coupling halves onto shaft and shaft pin. Reinstall the coupling screws and leave loose. Check that the gaps on either side of the coupling are even, and that the motor shaft keyway is centered in the coupling half, as shown in fig. 16.
Tighten the screws to the correct torque; see torque specifications table below.
Torque specifications
CR(I)(N) 1s, 1, 3, 5, 10, 15, and 20
CRT 2, 4, 8, and 16
Coupling bolt size Min. torque
M6 10 ft-lb M8 23 ft-lb
M10 46 ft-lb
10.2.2 CR 10, 15 and 20
Insert shaft pin into shaft hole. Insert plastic shaft seal spacer beneath shaft seal collar. Reinstall the coupling halves onto shaft and shaft pin. Reinstall the coupling screws and leave loose. Check that the gaps on either side of the coupling are even and that the motor shaft key way is centered in the coupling half, as shown in fig. 16. Tighten the screws to the correct torque. Remove plastic shaft seal spacer and hang it on inside of coupling guard.
Keyway Keyway
Note: The shaft can only be raised approximately 0.20 in (5mm). Now lower the shaft halfway back down the distance you just raised it and tighten the coupling screws (finger tight) while keeping the coupling separation equal on both sides. When the screws are tight enough to keep the couplings in place, then torque the screws evenly in a criss-cross pattern.
TM02 1051 0501TM04 3913 0409
Fig. 18 Coupling adjustment clearance CRT 2, 4, 8, and 16
10.2.4 CR(N) 32, 45, 64, 90, 120, and 150
1. Make sure shaft is all the way down. TIghten the set screws on the mechanical seal.
2. Place the plastic adjustment fork under the cartridge seal collar; see fig. 19.
CORRECT
TOP View
Gap between coupling
CORRECT NOT CORRECT
Fig. 16 Coupling adjustment all CR(I)(N)(X)(T)
10.2.3 CRT 2, 4, 8 and 16
Reinstall coupling halves. Make sure the shaft pin is located in the pump shaft. Put the cap screws loosely back into the coupling halves.
Using a large screwdriver, raise the pump shaft by placing the tip of the screwdriver under the coupling and carefully elevating coupling to its highest point; see fig. 17.
M6 - 13 Nm M8 - 31 Nm M10 - 62 Nm
x
Fig. 17 Coupling adjustment CRT 2, 4, 8, and 16
0.5x
18
TM04 3919 0409
Fig. 19 Coupling adjustment
CR(N) 32, 45, 64, 90, 120, and 150
3. Fit the coupling on the shaft so that the top of the pump shaft is flush with the bottom of the clearance chamber in the coupling; see fig. 20. Note: To avoid damaging the coupling halves, ensure that no portion of the keyway on the motor shaft lies within the gap between the two coupling halves.
TM02 1051 0501
Fig. 20 Coupling adjustment clearance
CR(N) 32, 45, 64, 90, 120, and 150
TM04 3914 0409
4. Lubricate the coupling screws with an anti-seize and lubricating compound. Tighten the coupling screws (finger tight) while keeping the coupling separation equal on both sides and the motor shaft keyway centered in the coupling half as shown in fig. 16.
5. When the screws are tight enough to keep the couplings in place, then torque the screws evenly in a crisscross pattern.
6. Torque coupling screws to 62 ft.-lbs (75 and 100 hp motors to 74 ft-lbs). Remove the adjustment fork from under the cartridge seal collar and replace it to the storage location; see fig. 21.
Fig. 21 Adjustment fork storage
CR(N) 32, 45, 64, 90, 120, and 150
11. Parts List
For each CR pump model Grundfos offers an extensive Parts List and diagram of part used in that pump and is recommended to have on hand for future maintenance. In addit ion, t he listings also provide information about prepackaged Service Kits for those pump components most likely to exhibit wear over time, as well as the complete Impeller Stack needed to replace the “guts” of each model. These Parts Lists are available separately from the Grundfos literature warehouse or as a set with extensive service instructions in the Grundfos CR Service Manuals (for a small charge).
TM04 3917 0409
Fig. 22 Prepackaged impeller stack kits
TM04 3915 0409
7. Check to see that the gaps between the coupling halves are equal. Loosen and readjust, if necessary.
8. Be certain the pump shaft can be rotated by hand. If the shaft cannot be rotated or it binds, disassemble and check for misalignment.
9. Prime the pump.
10.Follow the wiring diagram on the motor label for the correct motor wiring combination which matches your supply voltage. Once this has been confirmed, reconnect the power supply wiring to the motor.
11.Check the direction of rotation, by bump-starting the motor. Rotation must be left to right (counter-clockwise) when looking directly at the coupling.
12.Shut off the power, then re-install the coupling guards. After the coupling guards have been installed the power can be turned back on.
TM04 3916 0409
Fig. 23 Prepackaged flange kits
12. Spare Parts
Grundfos offers an extensive list of spare parts. For a current list of these parts, refer to: “All Product Spare Parts/Service Kits” Price List, Form #L-SK-SL-002.
19
13. Preliminary electrical tests
Warning When working with electrical circuits, use caution
to avoid electrical shock. It is recommended that rubber gloves and boots be worn, and metal terminal boxes and motors are grounded before any work is done. For your protection, always disconnect the pump from its power source before handling.
13.1 Supply voltage
13.1.1 How to measure the supply voltage
Use a voltmeter, (set to the proper scale) measure the voltage at the pump terminal box or starter.
On single-phase units, measure between power leads L1 and L2 (or L1 and N for 115 volt units).
On three-phase units, measure between:
– Power leads L1 and L2 – Power leads L2 and L3 – Power leads L3 and L1
Fig. 24 Measuring supply voltage
13.1.2 What the supply voltage measurement means
When the motor is under load, the voltage should be within ±10% of the nameplate voltage. Larger voltage variation may cause winding damage.
Large variations in the voltage indicate a poor electrical supply and the pump should not be operated until these variations have been corrected.
If the voltage constantly remains high or low, the motor should be changed to the correct supply voltage.
Fig. 25 Measuring current
13.2.2 What the current measurement means
If the amp draw exceeds the listed service factor amps (SFA) or if the current imbalance is greater than 5% between each leg on three-phase units, check the following:
– Burned contacts on motor starter. – Loose terminals in starter or terminal box or possible wire
defect. – Too high or too low supply voltage. – Motor windings are shorted or grounded. Check winding and
insulation resistances. – Pump is damaged causing a motor overload.
13.3 Insulation resistance
13.3.1 How to measure the insulation resistance
Turn off power and disconnect the supply power leads in the pump terminal box. Using an ohm or mega ohm meter, set the scale selector to Rx 100K and zero adjust the meter.
TM04 3911 0409
Measure and record the resistance between each of the terminals and ground.
TM04 3908 0409TM04 3907 0409
13.2 Current measurement
13.2.1 How to measure the current
Use an ammeter (set on the proper scale) to measure the current on each power lead at the terminal box or starter. See the motor nameplate for amp draw information.
Current should be measured when the pump is operating at constant discharge pressure.
20
Fig. 26 Measuring insulation resistance
13.3.2 What the insulation resistance means
Motors of all hp, voltage, phase and cycle duties have the same value of insulation resistance. Resistance values for new motors must exceed 1,000,000 ohms. If they do not, motor should be repaired or replaced.
14. Startup for Cool-Top®
Caution
Do not start the pump until it has been filled with liquid and vented.
Warnin g Pay attention to the direction of the vent hole and take care to ensure that the escaping liquid does not cause injury
to persons or damage to the motor or other components. In hot-liquid installations, special attention should be paid to the risk of injury caused by scalding hot liquid. It is recommended to connect a drain pipe to the 1/2" air vent in order to lead the hot water/steam to a safe place.
1
2
Step Action
Note: The air-cooled top should only be started up with cold
liquid. Close the isolation valve on the discharge side and open the isolation valve on the suction side of the pump.
TM02 4151 5001
Remove the priming plug from the air-cooled chamber (2) and slowly fill the chamber with liquid.
When the chamber is completely filled with liquid, replace the priming plug and tighten securely.
TM02 4153 1503
3
Open the isolation valve on the discharge side of the pump. Valve may have to be partially closed when pump is started if no back pressure is present (i.e. boiler not up to pressure).
TM02 5907 4002
4
Start the pump and check the direction of rotation. See the correct rotation of the pump on the motor fan cover. If the direction of rotation is wrong, interchange any two of the
incoming supply wires. After 3 to 5 minutes, the air vent has been filled with liquid. Note: During startup of a cold pump with hot liquid, it is normal
that a few drops of liquid are leaking from the sleeve.
TM01 41406 3702
TM01 1405 4497
21
15. Diagnosing specific problems
Problem Possible cause Remedy
The pump does not run. 1. No power at motor.
Fuses are blown or circuit
2. breakers are tripped.
Motor starter overloads are burned
3. or have tripped out.
4. Starter does not energize.
5. Defective controls.
6. Motor is defective.
Defective capacitor
7. (single-phase motors).
8. Pump is bound.
Check voltage at motor terminal box. If no voltage at motor, check feeder panel for tripped circuits and reset circuit.
Turn off power and remove fuses. Check for continuity with ohmmeter. Replace blown fuses or reset circuit breaker. If new fuses blow or circuit breaker trips, the electrical installation, motor and wires must be checked.
Check for voltage on line and load side of start er. Replace burned heaters or reset. Inspect starte r for other damage. If heater trips again, check the supply voltage and s tarter holding coil.
Energize control circuit and che ck for voltage at the holding coil. If no voltage, check control circuit fuses. If voltage, check holding coil for shorts. Replace bad coil.
Check all safety and pressure switches for operation. Inspect contacts in control devices. Replace worn or defective parts or controls.
Turn off power and disconnect wiring. Measure the lead to l ead resistances with ohmmeter (RX-1). Measure lead to ground values with ohmmeter (RX-100K). Record measured values. If an open or grounded winding is found, remove mot or and repair or replace.
Turn off power and discha rge capacitor. Check with ohmme­ter (RX-100K). When the meter is connected to the capaci­tor, the needle should jump towards 0 ohms and slowly drift back to infinity (h). Replace if defective.
Turn off power and manually rotate pump shaft. If shaft does not rotate easily, check coupling setting and adjust as necessary. If shaft rotation is still tight, re mov e pu mp an d inspect. Disassemble and repair.
The pump runs but at reduced capacity or does not deliver water.
1. Wrong rotation. Check wiring for proper connections. Correct wiring.
2. Pump is not primed or is airbound.
Strainers, check or foot valves are
3. clogged.
4. Suction lift too large.
Suction and/or discharge piping
5. leaks.
6. Pump worn.
Pump impeller or guide vane is
7. clogged.
8. Incorrect drain plug is installed.
9. Improper coupling setting. Check/reset the coupling; see page 18.
Turn pump off, close isolation valve(s), remove priming plug. Check fluid level. Refill the pump, replace plug and start the pump. Long suction lines must be filled before starting the pump.
Remove strainer, screen or valve and inspect. Clean an d replace. Reprime pump.
Install compound pressure gauge at the suction side of the pump. Start pump and compare reading to performance data. Reduce suction lift by lowering pump, incre ase suction line size or removing high friction loss devices.
Pump spins backwards when turned off. Air in suction pipe. Suction pipe, valves and fittings must be airtight. Repair any leaks and retighten all loose fittings.
Install pressure gauge, start pump, gradually close the discharge valve and read pressure at shutoff. Convert measured pressure (in psi) to head (in feet): (Measured psi x 2.31 ft/psi = ___ ft). Refer to the specific pump curve for shutoff head for that pump model. If head is close to curve, pump is probably OK. If not, re mo v e pu m p and inspect.
Disassemble and inspect pump passageways. Remove any foreign materials found.
If the proper drain plug is replaced with a standard plug, water will recirculate internally. Replace with proper plug.
22
Problem Possible cause Remedy
Pump cycles too much 1.
Fuses blow or circuit breakers or overload relays trip
Pressure switch is not properly adjusted or is defective.
Level control is not properly
2. adjusted or is defective.
Insufficient air charging or
3. leaking tank or piping.
4. Tank is too small.
5. Pump is oversized.
1. Tank is too small.
2. Motor overloads are set too low.
Three-phased current is
3. imbalanced.
4. Motor is shorted or grounded.
5. Wiring or connections are faulty.
6. Pump is bound.
Defective capacitor
7. (single-phase motors).
Motor overloads at higher ambient
8. temperature than motor.
Check pressure setting on switch and operation. Check voltage across closed contacts. Readjust switch or replace if defective.
Check setting and operation. Readjust setting (refer to level control manufacturer’s data). Replac e if defective.
Pump air into tank or diaphragm chamber. Check diaphragm for leak. Check tank and piping for leaks with soap and water solution. Check air to water volume. Repair as necessary.
Check tank size and air volume in tank. Tank volume should be approximately 10 gallons for each gpm of pump capacity. The normal air volume is 2/3 of the total tank volume at the pump cut-in pressure. Replace tank with one of correct size.
Install pressure gauges on or near pu mp suction and discharge ports. Start and run pump under normal conditions, record gauge readings. Convert psi to feet (Measured psi x 2.31 ft/psi = ____ ft) Refer to the specific pump curve for that model, ensure that total head is sufficient to limit pump de livery within it s desi gn flow rang e. Throttle pump discharge flow if necessary.
Check voltage at starter panel and motor. If voltage varies more than –10 % / + 10 %, contact power company. Check wire sizing.
Cycle pump and measure amperage. Incr ease heater size or adjust trip setting to a maximu m of motor nameplate (full load) current.
Check current draw on each lead to the motor. Must be within –5 % / + 5 %. If not, check motor and wiring. Rotating all leads may eliminate this problem.
Turn off power and disconnect wiring. Measure the lead -to-lead resistance with an ohmmeter (RX-1). Mea sure lead-to-ground values with an ohmmeter (RX-100K) or a megaohm meter. Record values. If an open or grounded winding is found, remove the motor, repair and/or replace.
Check proper wiring and loose terminals. Tighten loose terminals. Replace damaged wire.
Turn off power and manually rotate pump shaft. If shaft does not rotate easily, check coupling setting and adjust as necessary. If shaft rotation is still tight, re mov e pu mp an d inspect. Disassemble and repair.
Turn off power and discharge capacitor. Check with ohmmeter (RX-100K). When the meter is connected to the capacitor, the needle should jump towards 0 ohms and slowly drift back to infinity
(h). Replace if defective.
Use a thermometer to check the ambien t temperature near the overloads and motor. Record these values. If ambient temperature at motor is lower than at overloads, especially where temperature at overloads is above +104 °F (+40 °C ), ambient-compensated heaters should replace standard heaters.
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16. Worksheet for three-phase motors
Below is a worksheet for calculating current unbalance on a three-phase hookup. Use the calculations below as a guide.
Note: Current unbalance should not exceed 5% at service factor load or 10% at rated input load. If the unbalance cannot be corrected by rolling leads, the source of the unbalance must be
farthest from the average stays on the same power lead, most of the unbalance is coming from the power source. However, if the reading farthest from the averages moves with the same motor lead, the primary source of unbalance is on the “motor side” of the starter. In this instance, consider a damaged cable, leaking splice, poor connection, or faulty motor winding.
located and corrected. If, on the three possible hookups, the leg
Explanation and examples
Here is an example of current readings at maximum pump loads on each leg of a three-wire hookup. You must make calculations for all three hookups. To begin, add up all three readings for hookup numbers 1, 2, and 3.
Hookup 1
T1 = 51 amps T2 = 46 amps T3 = 53 amps
TOTAL =
150
Divide the total by three to obtain the average.
Hookup 1
3150 amps
Hookup 1
Calculate the greatest current difference from the average.
—46amps
Divide this difference by the average to obtain the percentage of the unbalance.
Hookup 1
In this case, the current unbalance for Hookup 1 is 8%.
50 4.00 amps
Figure here
Hookup 1 Hookup 2 Hookup 3
L L L
to T
1
to T
2
to T
3
= ___ amps
1
= ___ amps
2
= ___ amps
3
L L L
to T
1
to T
2
to T
3
= ___ amps
3
= ___ amps
1
= ___ amps
2
L L L
to T
1
to T
2
to T
3
= ___ amps
2
= ___ amps
3
= ___ amps
1
TOTAL = ___ amps TOTAL = ___ amps TOTAL = ___ amps
Hookup 1 Hookup 2 Hookup 3
___ amps ___ amps ___ amps
3 ___ amps 3 ___ amps 3 ___ amps
50 amps
50 amps
4amps
.08 or 8%
Hookup 1 Hookup 2 Hookup 3
___ amps ___ amps ___ amps ___ amps ___ amps ___ amps ___ amps ___ amps ___ amps
Hookup 1 Hookup 2 Hookup 3
___ or ___ % ___ or ___ % ___ or ___ %
___ ___ amps ___ ___ amps ___ ___ amps
24
U.S.A.
GRUNDFOS Pumps Corporation 17100 West 118th Terrace Olathe, Kansas 66061 Phone: +1-913-227-3400 Telefax: +1-913-227-3500
Canada
GRUNDFOS Canada Inc. 2941 Brighton Road Oakville, Ontario L6H 6C9 Phone: +1-905 829 9533 Telefax: +1-905 829 9512
México
Bombas GRUNDFOS de México S.A. de C.V. Boulevard TLC No. 15 Parque Industrial Stiva Aeropuerto Apodaca, N.L.C.P. 66600 Phone: +52-81-8144 4000 Telefax: +52-81-8144 4010
Addresses revised 22.09.2005
Being responsible is our foundation
Thinking ahead makes it possible
Innovation is the essence
L-CR-TL-001 0309
Repl. L-CP-TL-003 1205
www.grundfos.com
US
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