Tomy TEX Series User manual
Symbols used
Situation where improper handling or operation failure to follow this manual
would almost certainly result in death or serious bodily injury.
Situation where improper handling or operation failure to follow this manual
could result in death or serious bodily injury.
Situation where improper handling or operation failure to follow this manual
could result in bodily injury or equipment damage.
TEM SERIES
1
1. Foreword ....................................................................................................................... 2
2. Safety Requirements ..................................................................................................... 2
3. Inspecting the Pump Prior to Unpack the Carton/ Install the Pump ............................. 3
4. Installation, Piping and Wiring...................................................................................... 4
5. Notes for Operation....................................................................................................... 8
6. Operating Procedure and Notes................................................................................... 10
7. Maintenance and Inspection........................................................................................ 12
8. Incorrect Usage and Selection..................................................................................... 14
9. Repair and Warranty.................................................................................................... 15
Annex A: Disassembling & Assembling the TEX/TEM Pump ....................................... 16
Annex B: Exploded View and Parts List.......................................................................... 17
2
1. Foreword
Thank you for purchasing TOMY pump. To ensure proper operation and maximum
efficiency, please read this instruction manual carefully. Failure to follow the recommended
operating conditions outlined in this manual may result in serious personal injuries and/or
equipment damage.
2. Safety Requirements
This section lists general information about the safety. The relevant safety
requirements of installation, wiring, operation and maintenance will set out in the relevant
sections. TOMY ENG CORP. does not assume responsibility for personal danger or
property damage resulting from failure to follow the safety instructions contained herein.
1. The explosion-proof rating of the TEM-Series pump is dependent on the
material selected and motor used. Please consult our order specification
sheet or contact one of our local representatives to select the best product
for your needs.
2. Be sure to turn the power off before any wiring or disconnection
operations.
3. The customer should not modify the pump under any circumstances. Doing
so could result in an unexpected accident. TOMY ENG CORP. shall not be
responsible for accidents or damage resulting from equipment modified by
the customer.
4. Be sure to take special precautions when performing operations if using
hazardous, explosive or inflammable liquids.
5. Magnetic field hazard: TEM rotor (including the drive magnet and driven
magnet) uses strong permanent magnet. Pay attention to potential hazards
from powerful magnetic fields to persons, such as, who are assisted by
electronic devices.
1. The pump operator and pump operation supervisor must not allow any
operator who has little or no knowledge of the pump to run the pump.
Pump operators must have a sound knowledge of the pump and its
operation.
2. Do not use a damaged pump. Doing so could result in injury or fire.
3. Keep away from heat or flame: Do not place any open flame or flammable
object near the pump.
1. Transport, installation, piping and wiring connections, operation,
adjustment, maintenance and inspection should be carried out by qualified
personnel. Having unqualified personnel perform these tasks could result in
electrical shock, injury or fire.
2. Do not block name plate or warning labels for view.
3. Do not stand on the pump or use the pump as s step under any
circumstances. Otherwise, you may experience a serious injury.
4. Disposal of used or damaged pump must be done in accordance with local
laws and regulations.
3
3. Inspecting the Pump Prior to Unpack the Carton/ Install the
Pump
(1) Check the pump exterior for any physical damage that may have been incurred during
shipping.
(2) Use a small screwdriver to rotate the impeller of the motor’s cooling fan. The fan
should turn easily. If the fan feels tight or if there are unusual sounds, the interior of the
pump may have been damaged during shipping.
(3) If there is any damage to the pump, contact the shipping company and the distributor
immediately to determine who should pay for the damage, and to arrange for
replacement parts.
(4) Each pump has a nameplate, indicating the pump model, MFG number, rated head,
flow rate, and motor power, voltage and frequency. Check these data to ensure they
comply with your order and application.
(5) Although some motor marked usable for both 50Hz and 60Hz, but the impeller size of
the pump should be trimmed according to frequency applied. Apply under inadequate
frequency may cause motor overload (use under higher frequency) or pump
under-performance (use under lower frequency).
(6) Nameplate information (including motor nameplate and pump nameplate) plays an
important role for the operation and maintenance of the pump. It is proposed to re-copy
data on nameplates and store it securely.
(7) The flow and head on the nameplate is the rated operating point or the operating point
made to customer demand. Where "Head" means "Total head”
Total Head= Static Head + Dynamic Head
g
VV
HHeadTotal s2
2
1
2
2
The pump is designed and manufactured to the specifications agreed upon by
the user and TOMY ENG CORP. such as fluid composition, fluid temperature,
working pressure, environmental conditions and necessary operational
information. Use the pump strictly in accordance with the pump specifications
and application range. If the user intends to change any specification, contacts
TOMY ENG CORP. or the authorized dealer in the near region to obtain the
permission in writing before operation.
Unpack a pump for inspection without proper hoisting or support of lifting
equipment may cause serious personal injury or damage to the pump.
4
4. Installation, Piping and Wiring
4.1 Installation Location
(1) The pump should be close to the ground and located near the inlet tank.
(2) There should be sufficient space reserved around the pump to facilitate future
maintenance and repairs.
(3) The pump and its wiring should be placed in a relatively dry environment, protected
from possible flooding.
(4) Install in the place where the ambient temperature is not above 40°C.
(5) Fastening the pump to base plate or machine with anchor bolt.
1. Be sure to use the hanger bolt to lift the pump. Do not hang with the other
position of the pump. When hoisting, do not pass under a raised pump. A
serious injury could occur if the pump is accidentally dropped.
2. Before lifting, check the weight of the pump. Do not lift a pump which
exceeds the rated weight of the hoist. And, be sure no one standing below
the pump while lifting or transporting.
Install or store the pump in the following places with special care and consult
with TOMY ENG CORP. or authorized dealer in the near region:
a. Places where flammable gas, dust or material is used or placed.
b. Places where corrosive gas is generated.
Places where the ambient temperature is extremely higher than 40°C or
extremely lower than 0°C.
4.2 Piping
(1) TEM flange is the RF type adjustable
flange which can be oriented to
match corresponding bolt holes to
facilitate piping installation.
(2) TEM flange screw is either M16 or
5/8”. The tightening torque is 5 N-m.
(3) The allowable load of pipe on the
pump.
XY
Z
Z
Y
X
Model
SUCTION
Force (N) Moment (N-m)
Fx Fy Fz ΣF Mx My Mz ΣM
TEX/TEM-220/221/440/441 120 100 100 180 20 30 20 60
TEX/TEM-542/543/545 120 100 100 180 30 50 30 75
TEX/TEM-653/655 150 120 120 200 30 50 30 75
5
Model
DISCHARGE
Force (N) Moment (N-m)
Fx Fy Fz ΣF Mx My Mz ΣM
TEX/TEM-220/221/440/441 100 120 100 180 20 30 20 60
TEX/TEM-542/543/545 120 150 120 200 30 50 30 75
TEX/TEM-653/655 120 150 120 200 30 50 30 75
※The values in table are reference ones within 40oC
4.3 Notes for Installing the Piping System
14
12
10 11
9
4
3
13
1
2
5
7
8
6
15
1.Outlet Piping
2.Throttle Valve
3.Priming Piping
4.Priming Valve
5.Check Valve
6.Outlet Pressure Gauge
7.Motor
8.Pump
9.Inlet Pressure Gauge
10.Inlet Piping
11.Inlet Piping Support
12.Vibration Damper
13.Filter
14.Inlet Tank
15.Foot Valve
Fig. 4.1
Good
Bad
0.01~0.02 slope
Fig. 4.2
Bad Piping Designs
Fig. 4.3
>1.5D
>0.5m
or
>2D
>1.5D
D=Diameter
Fig. 4.4
6
Procedure Items to Note
General
Requirements
1. Suction condition must satisfy NPSHa>NPSHr+0.5m
2. Reduce inlet Head as much as possible. Use straight and short
piping.
3. The pipes should have adequate structural support and shouldn’t
use the pump as its primary support. (see Fig. 4.1)
4. When designing supports, consider the effects of temperature
changes on the supports to avoid thermal stress.
5. Inlet piping and connectors should be installed properly to prevent
sucking in air.
6. The piping system should not have upward bumps that may collect
air. The inlet piping should also have a 0.01~0.02 slope increase
towards the pump. (see Fig. 4.2)
7. There should not be any elbows for at least 5 times the pipe
diameter from the opening of the pump. The elbow closest to the
pump opening should be a long radial elbow.
Inlet Piping
1. There should be at least a 1.5 diameter distance between the pipe
inlet and the closest tank wall to prevent circulation. (see Fig. 4.4)
2. The submerge depth of the inlet should be at least 0.5m or at least
twice the pipe diameter below the liquid surface. (see Fig. 4.4)
3. There should be a distance of at least 1.5D between the bottom of
the tank and the beginning of the inlet pipe opening. (see Fig. 4.4)
4. If there are two or more inlet piping in the same tank, they should
be placed at least 3D apart to prevent mutually disrupting each
other’s flow.
Foot Valve Please install a foot valve if upward suction is used. (see Fig. 4.1)
Self-Priming
Cylinder
1. If suction method is upward suction, please install a self-priming
cylinder to prevent dry-running due to a leaking foot-valve.
2. The size of the self-
priming cylinder should have a minimum liquid
level of at least 0.5m above the opening of the pump.
Control Valve
1. A control valve should be installed to make disassembling of the
pump easier.
The valve should only be shut off when the pump is to
be detached for maintenance or repairs.
2. We recommend the use of valves that have the least loss when ful
ly
opened, like a gate valve.
Filter
1. It is generally not recommended to install a filter in front of a
pump, which can unpredictably increase suction system resistance.
2. If a filter has to be used, it should be cleaned regularly to ensure a
smooth flow.
Vacuum Gauge
1. The material used should be corrosion resistant, otherwise, a
pressure gauge diaphragm should be used.
2. During operation, if the vacuum gauge reading fluctuates, either
there are air bubbles in the system or cavitation has occurred.
General
Requirements
1. The weight of the outlet piping should be properly supported to
prevent putting excessive stress on the pump. (see Fig. 4.1)
2. A priming piping must be installed if the suction system does not
employ positive pressure, i.e. upward suction. (see Fig. 4.1)
3. The flow rate in the outlet piping should not exceed 3m/sec.
4. The ability for each component in the piping system to withstand
pressure should be calculated, to determine the maximum
allowable operating pressure.
7
Priming Piping Upward suction pumps that do not have a self-priming cylinder
should have a priming piping system.
Pressure Gauge
1. Pressure gauge used should be able to read beyond the maximum
operating pressure.
2. Pressure gauge should be made of material that is corrosive
resistant, otherwise a diaphragm should be used.
3. A valve can be installed on the piping that leads to the pressure
gauge, to facilitate maintenance and to lengthen the gauge’s service
life.
4. During operation, if the pressure gauge reading fluctuates, either
there are air bubbles in the system or cavitation has occurred.
Check Valve
A check valve should be installed in the following situations:
1. Outlet piping is long.
2. Head of outlet is more than 15m.
3. Discharge pressure exceeds 2kg/cm2and flow rate exceeds 3m/sec
4. Two or more pumps share the same outlet piping system.
5. To prevent back flow (water hammer) from damaging the pump
during unexpected power outages.
Control Valve
1. A control valve can be used for controlling the flow of fluids. Do
not run the pump with the control valve closed for an extended
period of time.
2. When starting the pump, always start with a closed valve, and then
slowly open the valve to obtain the desired operating pressure and
flow. Always open or close the valve gradually.
3. To facilitate th
e adjustment of discharge flow and the adjustment of
motor overload, it is recommended to install valves on outlet
piping. And if both a check valve and a control valve are to be
installed, the order of allocation is pump => Check Valve =>
Control Valve.
Exhaust Valve
A vent should be installed if the horizontal section of the outlet piping
is very long.
Cautions when dangerous liquids are transferred: When the pumps are used to
transfer the dangerous liquids mentioned as below, the pumps, piping and
fittings must be checked and watched so that the liquids can not be leaked.
Leaking the liquids may result in personal injury and/or explosion, fire
accidents.
a. Explosive and inflammable liquids.
b. Corrosive and stimulus toxic liquids.
c. Liquids could directly harm the human body or detrimental to health.
d. Liquids could produce a chemical reaction.
4.4 Wiring
The wiring system should be done properly, using premium equipment and complying
with rules and standards set by the electrical company. The following recommendations
should also be implemented:
(1) Power frequency, voltage and capacity should strictly follow according to motor
specification sheet and name plates.
8
(2) Please select the proper non-fuse switch (NFB) according to the rated current of the
motor.
(3) When using the pump for outdoor applications, please make sure the switch is protected
from rain.
(4) Keep the electromagnetic contactor (MC) from a pump with suitable distance, and
clearly mark warning sign to avoid false start.
(5) Tags at the end of wires (or Diagram shown in the terminal box) and method of
connection are based on the number wires (phases), power voltage and mode of start
for the motor. Be sure to connect the power cable in accordance with name plate for the
motor and the connection diagram in the terminal box
(6) Select the proper size of wire for power wiring, and tighten screws to prevent loosening.
Table 4.1 lists the reference value, and make sure to follow local electrical regulations.
Table 4.1 Wire diameter and terminal locking torque
Minimum diameter Locking torque
2.2kW & below 1.6 mm 18 kgf-cm
3.7kW 200~230V 2.0 mm 18 kgf-cm
380~480V 1.6 mm 18 kgf-cm
1. Be sure not to performing any type of maintenance while the power turns on.
It may lead to electric shock.
2. Power supply and wire connecting work should be performed by qualified
personnel only.
After wiring, be sure to replace the terminal box cover in its original position.
Failure to do so could result in electrical shock.
1. Install an earth leakage breaker: The operation of a pump without using an
earth leakage breaker may cause an electrical shock. Install an optional
leakage breaker in the system before running operation.
2. Grounding wire should be consistent with the third type of grounding
(grounding resistance is 10Ω or less).
3. Each pump must have a separate grounding wire directly connected to the
common ground terminal, and must not form a loop between wires.
4. If the long wiring results more than 3% voltage drop in the line, replaces with
bigger size of wires.
5. Notes for Operation
5.1 Dry-Running
(1) Our pump use the transfer fluid as its internal cooling system, therefore, dry-running
the pump can cause the temperature to rise to a dangerous level that may seriously
damage the pump.
(2) If dry-running occurs, switch off the pump immediately, let it cool for at least an hour
before priming the pump to prepare it for normal operation. NOTE: Do not subject the
pump to rapid cooling, which may damage the internal parts.
(3) We recommend using a dry-run protector to detect dry-run occurrences to avoid
9
causing unnecessary damage to the pump.
5.2 Operating Temperature
(1) Operating temperature may change the fluid’s viscosity, vapor pressure, and
corrosiveness. Please ensure that your pump is operating within the proper temperature
range.
(2) The optimal temperature range for pumping pure water:
Body material PPG:0~70oC
Body material ETFE+CF:0~90oC
(3) Please consult the distributor for the temperature range suitable for your chemicals.
(4) We recommend the operating environmental temperature to be between 0oC~40 oC.
When the pump is used to feed a hot liquid, do not touch the front cover or the
piping with your bare hands. It may cause burns. Any reachable hot surfaces,
including pumps, motors and piping, must provide isolate device and display
obvious warning signs for high temperature.
5.3 Concentrations, Viscosity and Specific Gravity
(1) A change in a fluid’s concentration will usually affect its viscosity and specific gravity.
Other physical properties like corrosiveness, may also change with the fluid’s
concentration, therefore, the selected pump material should be able to withstand the
corrosive properties of the fluid.
(2) When the fluid’s viscosity and/or Specific Gravity differ from that of water, the shaft
power, flow rate and pump head may change also.
5.4 Particle Size (Sludge)
(1) The service life of a pump can be greatly shortened by pumping fluids that carry small
particles or sludge. Its service life is dependent on the concentration of the particles, its
size, and hardness.
(2) For particle concentration less than 5%, particle size smaller than 50μm, and hardness
within 80Hs, which has SiC bushings, can be used. However, a shorter-than-normal
service life can be expected.
Should foreign matter enter the pump, it may cause pump damage or failure.
Turn off the power at once and remove the obstruction.
5.5 Maximum Operating Pressure
The pump’s maximum operating pressure is dependent on the operating temperature
and the structure of the pump. Please refer to figure 5.1 for the recommended maximum
operating pressure for our TEM SERIES pumps.
10
Figure 5.1
0 10 20 30 40 50 60 70 80
T ( oC )
0
1
2
3
4
5
6
7
8
P
(
K
g
/
c
m
2
)
AMX-555/553/552
AMX-655/653/221/220
AMX-441/440
5.6 Minimum Flow
Our pump uses the pumped fluid as its cooling and lubricating system. A low flow rate
may result in increasingly high temperature within the pump, and increased radial and axial
force, thus, affecting the pump’s performance and service life. Please use table 5.1 for the
recommended minimum flow rate:
Unit: l/min
Temperature
Model 20oC 40oC 60oC 80oC
TEX/TEM-220/221/440/441 15 15 20 30
TEX/TEM-542/543 20 20 30 40
TEX/TEM-545 30 30 40 50
TEX/TEM-653/655 50 50 70 100
Table 5.1
Note: The above data is based on water. For volatile or viscous fluids, consult your local
distributor.
Do not operate the pump with outlet valve shut off more than 1 minute. Long
time shut off will cause the inside to heat up and damage the pump.
6. Operating Procedure and Notes
6.1 Notes Prior to Starting the Pump
(1) Check the motor’s power rating, including frequency, voltage and wiring.
(2) Recheck to make sure all the parts (flange, pump casing, base plate, etc.) are securely
TEX/TEM-542/543
TEX/TEM-653/655
TEX/TEM-220/221/44
11
fastened.
(3) Fill the pump with liquid (priming) to remove any air within the pump and suction
piping.
(4) Check to ensure the inlet valve is open.
(5) Using a screwdriver, rotate the motor’s cooling fan to ensure it is not too tight or stuck.
6.2 Starting Up the Pump
(1) Check the direction of rotation of the motor by rapidly switching on and off the power.
(2) Direction of motor rotation can be checked from the fan side. It should be clockwise
seeing from the fan cover (follow arrow direction on the fan cover). If the rotating
direction reverses, change wiring phases by shifting any two wire connections.
(3) Close the outlet valve and start up the pump.
(4) Slowly open the outlet valve when the motor has reached a stable speed. Adjust the
outlet valve to obtain the desired operating pressure or flow rate.
6.3 Operating the Pump
(1) Shut down the pump immediately in the case of cavitation or dry-running.
(2) If decoupling should happen, shut down the pump to prevent reducing the magnet’s
strength.
(3) During power outages, shut off the pump’s power supply and close the outlet valve.
(4) When switching on the pump with the outlet valve closed, the outlet pressure should
increase. If the pressure fails to rise, or if the pressure is too low, shut down the pump
and check the piping and wiring.
NOTE: Outlet Pressure = Inlet Pressure + Pump Pressure
Pump Pressure (kg/cm2) = Fluid Specific Gravity * Pump Head / 10
6.4 Shutting Down the Pump
(1) Close the outlet valve slowly to prevent damage to the pump due to reverse fluid flow
(water hammer).
(2) Shut off the pump. It should stop gradually. If not, check the interior of the pump for
problems.
(3) The pump should be checked periodically. If the pump is used in a cold operating
environment (relative to the fluid’s freezing point), the fluid may crystallize even if the
pump is shut down for a very short amount of time. To prevent crystallization, a drain
plug should be included in the piping system or a heating system could be used to
maintain the temperature during shutdown.
12
7. Maintenance and Inspection
7.1 Daily Inspection (See Table 7.1)
Appearance
1. Check for oxidation or corrosion of the front casing, bracket, and base
plate.
2. Check for leakage of the pump and the piping system.
3. Check the pump exterior for any physical damage such as corrosion,
paint stripped off.
Operation
1. Check for irregular sounds and vibrations.
2. Check any abnormal overheat on the surface of motor, three-phase
current is imbalanced, bearing noise, foreign material blocking the vent
of fan.
3. Check the in-tank fluid levels and inlet/outlet pressures.
4. Check the current and motor loading.
5. Check and test-run backup pumps regularly to ensure they can function
properly when needed.
Table 7.1
7.2 Periodic Maintenance
(1) The following items should be inspected quarterly referring to table 7.2.
(2) Pump’s disassembly, assembly and notes to be attended refer to Annex A.
Part Name Inspection Item Solution
Front and Rear
Casing
1. Cracks
2. Scratch marks (except when pumping
particle laden fluids)
3. Crystallization or sludge
4. Shaft support loose or deformed
1. Replace
2. Contact the distributor
3. Clean
4. Contact distributor
Front Casing
O-ring Deformed, corroded or swollen Replace
Impeller and
Magnet
Assembly
1. Scratch marks or cracks
2. Cracked bearing or crystallization
3. Bearing displays signs of some wear
and tear
4. Crystallization and other sludge
5. Foreign objects stuck in impeller
6. Impeller deformed
1. Contact distributor
2. Contact distributor
3. Replace if worn
excessively
4. Clean
5. Remove the objects
6. Contact distributor
Shaft and Thrust
Ring
1. Scratch marks
2. Cracks
1. Contact distributor
2. Replace
Motor
1. Resistance of three phases and
insulation impedance
2. Check amount of lubricant when
using open bearing.
1. Repair or change if
abnormal is found.
2. Keep amount of lubricant
at proper level.
Table 7.2
13
Wear limit
Dimension
Model
A(mm) D(mm)
New part Time to change New part Time to change
TEX/TEM-220/221/440/441 6 <515 >15.5
TEX/TEM-542/543/545/653/655 7 <618 >18.5
7.3 Preventive Maintenance
Operational data, like vibration, flow rate, voltage, etc. can be collected, and upper and
lower limits can be set for each of the values. The collected data can be used for trend
analysis (see Fig. 7.1), which can be a basis in which to determine when to carry out
preventive maintenance.
TEM is made at factory with vibration below 3.0 mm / sec (rms) (measured at flange
edge of bracket), and the noise value is below 80dB (at rated point).
Time
LCL
UCL
UCL Upper contorl Limit
LCL Lower contorl Limit
Fig. 7.1
1. TEX/TEM powerful permanent magnetic coupling could adversely affect
persons who are assisted by electronic devices such as pacemaker.
2. Be sure to turn the power off before performing any type of maintenance,
repair or inspection. Make special provisions so that no other operator
mistakenly turns on the power supply while someone is working on the
pump. In a noisy or poor visibility environment, display a sign near the
14
power supply switch to notify others that someone is “WORKING” on the
pump. Power supply mistakenly turned on during maintenance may lead to
personal injury.
1. When handling a toxic or odorant liquid, ventilate the working area well. In
addition, the operator must wear protector gear (such as a safety mask,
safety goggles, and protective gloves).
2. No remodeling: Remodeling of the pump by the user may result in serious
injury, electric shock, or damage to the pump. Do not attempt to remodel as
it is very dangerous.
3. Magnetic field hazard: Be careful not to get your hands or fingers pinched
by parts. Impeller is encapsulated strong magnet inside. While, do not let the
magnet close to the magnetic sensitive objects such as magnetic cards,
computer equipment, etc.
1. Use the right tools for any maintenance or disassembly and assembly.
2. Be careful with hazardous liquids:
If pumping dangerous chemicals, be sure to drain and wash well before
disassembling. A small amount of fluid may however remain in the internal
parts or pipe fittings.
8. Incorrect Usage and Selection
Abnormal Condition Possible Effect/Damage
System resistance too high
or
Pump head too low
1. Insufficient or no flow.
2. Pump unable to effectively dissipate heat.
3. Excessive wear on bearing and thrust rings.
Resistance lower than expected
or
Pump head too high
1. Excessive flow.
2. Overloading of the motor.
3. NPSHa too low, resulting in cavitation.
NPSHa too low,
resulting in cavitation
1. High frequency vibration and noise.
2. Fracturing of the bearing and thrust rings.
3. Decreased pump performance and low flow rate.
4. Serious cases may result in dry-running.
Specific Gravity higher than
anticipated
1. Motor overloading.
2. Decoupling of the magnetic drive.
Viscosity higher than anticipated
1. Motor overloading.
2. Decoupling of the magnetic drive.
3. Decreased pump performance and reduced flow.
Wrong pump material selected
1. Corrosion and cracking.
2. Rapid corrosion and wearing of bearing.
3. Corrosion of the O-ring resulting in leakage.
Inlet pipe not submerged sufficiently
into the fluid or air sucked into piping
system
1. Produce high frequency vibrations and noise.
2. Fracturing of the bearing and thrust rings.
3. Reduced pump performance.
4. Serious cases can lead to dry-running.
Air pockets in inlet piping 1. Reduced pump performance.
2. Serious cases can lead to dry-running.
Parallel pumps improperly installed Improper suction, resulting in low efficiency,
insufficient flow, cavitation or dry-running.
Leaking foot valve or inlet piping Fluids within pump leaks during shut-down period,
resulting in dry-running when pump is restarted.
15
Abnormal Condition Possible Effect/Damage
Starting the pump without priming Dry-running, causing damage to pump.
Low speed or wrong rotation direction Low fluid flow.
Incorrect motor frequency or voltage Overloading of the motor.
Low inlet tank fluid level
1. Low performance and vibrations caused by
sucked-in air.
2. Fracturing of the bearing and thrust rings.
3. Dry-running.
Foreign objects stuck in impeller
1. Produce vibrations and noise.
2. Reduced efficiency and flow. Serious cases may
result in dry-running.
Low flow over extended period of
time
1. Insufficient cooling of pump.
2.
Excessive radial and axial force, reducing service
life of bearing and thrust rings.
Inlet valve closed Dry-running, seriously damaging the pump.
Transfer fluid temperature too high
1. Low NPSHa, resulting in cavitation.
2. Reduced strength of the magnet, resulting in
decoupling.
Fluid carries hard particles 1. Rapid wearing of the bearing.
2. Wearing of the impeller and casing surfaces.
Deformation of the O-ring Result in leakage.
Damaged impeller 1. Resulting in vibrations and noise.
2. Reduced pump performance and fluid flow.
Damaged motor bearings
1. Produce vibrations and noise.
2. Overloads the motor.
3. High Motor temperature.
Wear ring worn off 1. Produce vibrations and noise.
2. Overloads the motor.
Wearing of the impeller bearings 1. Produce vibrations and noise.
2. May result in fracturing of the impeller shaft.
Pump’s base screws loose Produce vibrations and noise.
Blockage of inlet piping or foot valve
1. Reduced pump performance and low flow rate or
may result in cavitation.
2. Serious cases may result in dry-running.
Blockage of the outlet piping
1. Low flow or no flow.
2. Pump unable to dissipate heat.
3. Serious cases may result in overheating of the
pump and outlet piping
9. Repair and Warranty
When a problem arises, please read this instruction manual and try to troubleshoot the
problem. If the problem cannot be found, or if replacement parts are needed, please call the
distributor, and give them the following information:
(1) The pump model and manufacturing serial number indicated on the nameplate.
(2) The operating condition.
(3) The situation under which the pump fails.
Please refer to the warranty card for details of the warranty terms and conditions.
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Annex A: Disassembling & Assembling the TEM/TEX Pump
A. Preparing for Disassembly
(1) For personal safety, wear protective gear, like corrosive resistant aprons and protective
eyeglasses during disassembly, to prevent injuries caused by spilled chemicals.
(2) The magnets used in our TEX/TEM magnetic drive seal-less pumps have very strong magnetic
strength. Take extra precautions when disassembling the pump to prevent personal injury
and damage to electronic and magnetic equipments (like diskettes, magnetic stripe cards,
etc.).
(3) Make marks on corresponding terminals and contact points when disconnect and remove
motor wirings. It would prevent wrong connections in future application.
B. Notes for assembly
(1) Please follow the reverse procedure for disassembly to assemble the pump.
(2) When pressing the shaft bearing into the impeller, make sure the cut edge of the bearing
matches the flat edge inside the impeller.
(3) Before assembly, use an adhesive tape to remove all metal fragments or debris that may be
on the outside of the magnet housing.
(4) When fastening the different parts of the pump, make sure to fasten the corresponding
opposite screws in turn to ensure a uniform tightness.
(5) After the entire pump is assembled, use a small screwdriver to rotate the motor cooling fan to
ensure everything is installed correctly.
(6) The tightening torque for the front casing of TEM /TEXSeries is 32 ± 1 kgf-cm (3.2 ± 0.1Nm).
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Annex B: Exploded View and Parts List
No. Part Name No. Part Name
725.01 Inlet flange adaptor S21 Bearing
F21 Inlet flange R01 Rear casing
725.02 Outlet flange adaptor 161 Backup plate(except TEX/TEM-220/221/440)
F31 Outlet flange 516 Protection ring (optional part, see Annex C.)
101 Pump casing M01 Drive magnet
S11 Shaft B11 Base
319 Front thrust ring 181 Bracket
230 Impeller EM Motor
RG + No. O-ring. According to No.AS568. Each type is refer to the sectional drawing.
S21
230
This manual suits for next models
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