SHOCK RELAY OVERLOAD PROTECTION Product Catalog
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TSUBAKI SHOCK RELAY INTRODUCTION TO SHOCK RELAY OVERLOAD PROTECTION The truth is any machine can break. The probability of impact damage to a machine
It doesn’t have to happen. Tsubaki’s family of overload protection devices offer a solution to fit every need. Our family of overload protection devices keeps you productive all day, every day without interruption to assure maximum productivity is maintained. Tsubaki offers the finest power transmission products in the industry and provides protection for those parts and the equipment they belong to. Tsubaki Shock Relay and Shock Monitor products provide inexpensive insurance for expensive equipment.
is inevitable. Eventually, a machine will jam due to an obstruction, feed jam, foreign object intrusion, mechanical failure, etc. Something will happen, and there’s no telling when. Unintended load changes on the equipment can have big consequences. As equipment becomes more integrated, a shock or jam in one part of the production line can snowball into a complete system shutdown – resulting in damaged equipment, loss of product, and reduced productivity.
Protect what you value.
Protect Cutter
Protect Roller
Protect Machine
Protect Conveyor
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TSUBAKI SHOCK RELAY
Table of Contents SHOCK RELAY PRODUCT OVERVIEW
Designed to work with inverters. Product features include: digital display, built-in tamper-proof cover, and built-in test button. Choose between self-holding output relay and automatic reset. UL listed.
TSBED SERIES Dimensional Envelope 2.8"H X 2.2"W X 3.1"D
Overload or underload, pre-alarm notification and thermal energy protection. Product features include: communication function (4 to 20 mA) to allow central monitoring, works with 20Hz to 200Hz inverters. Panel mount option.
TSBSC SERIES Dimensional Envelope 2.9"H X 2.8"W X 3.3"D
Provides overload protection. Select manual or automatic reset output. Monitor AC motors up to 600 volts and 300 Amps. Shock Relay power supply can be AC or 24VDC. 35 mm DIN rail or panel mount. Economically priced, OEM style. UL Listed.
TSBSB SERIES Dimensional Envelope 2.6"H X 2.2"W X 3"D
The original Shock Relay with self-holding circuit and analog meter. In many cases, this Shock Relay series is the easiest to set up.
TSB150N SERIES Dimensional Envelope 4.5"H X 4.9"W X 4.3"D
A variation of the original Shock Relay, the M series, in addition to standard overload protection provides impact protection with a response time of 0.05 seconds.
TSB150M SERIES Dimensional Envelope 4.5"H X 4.9"W X 4.3"D
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THE ELECTRONIC SHEAR PIN! TSUBAKI SHOCK RELAY
Pioneered by Tsubaki, the Shock Relay protects your equipment against unexpected shock loads, overloads, and underloads before damage occurs. The Shock Relay protects the mechanical parts of your equipment by monitoring the current draw on your electric drive motor, and shutting it down when the motor works too hard for too long. Advantages to you: • Back to work with the press of a button • No moving parts, CPU design ensures repeatability • Precise set-points retain accuracy day after day • Permits problem notification by alarm or warning lights • Protect equipment that is up to 1000 feet away The Shock Relay adapts to virtually any kind of equipment that's driven by an electric motor and is used in applications in a broad variety of industries. Some of the common industries and applications are listed below:
Shock Relay selection is simple; it is based on the motor voltage and amperage of your equipment. Shock Relay has an unlimited life – it does not wear out. Shock Relay accepts single three-phase motors up to 600 volts.
Industry
Application
Material handling
Conveyors, turntables, elevators Pumps, scrapers, water screens
Water treatment plants
Food machinery
Screw and belt conveyors, bucket elevators
Machine tool
Tapping machines, drill presses
Chemical
Pumps, agitators, filters
Reacts only when there is a problem At installation, two set-points are made to the Shock Relay: • How hard is the equipment allowed to work as measured by motor amperage • Once the motor starts to work too hard, how soon in seconds must we stop production Balancing these two settings allows for protection when the unexpected happens, limiting damage and downtime.
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TSUBAKI SHOCK RELAY THEORY OF OPERATION – HOW DOES IT WORK?
Shock time: The Shock Relay does not respond to excess current if it does not exceed the preset shock time.
Shock time: When excess current goes beyond the preset time the Shock Relay responds.
Start time: Within a set time, the Shock Relay does not respond to motor starting current.
Shock Relay operation (trip)
Motor rotation speed
Rotation speed /current
Set current value
Motor load current
Short period of current surge
Overload
Set start time value
Set shock time value Set shock time value
Time
Start-up
Steady area
Overload area Stoppage
Figure 1: Shock Relay operation example
Figure 1 above reflects a typical set-up for a Tsubaki Shock Relay. As depicted in the above example, the Shock Relay is set up to accept a higher motor amperage draw at start-up for a limited amount of time. This “Start Time” period allows the motor to spool to its steady state operation mode where maximum continuous RPM is achieved, and current draw drops to a normal value that is below the maximum “Current Value” set in the Shock Relay. As depicted, the amperage draw of the motor then momentarily increases (resulting in a drop in RPM due to induced load) above the maximum “Current Value” setting, but quickly falls back to a steady state value. Since the “Shock Time” value was not exceeded, the Shock Relay does not trip, and allows continued operation. However, as time passes by, the Shock Relay senses an increase in motor amperage draw and a drop in RPM that exceeds set current value and “Shock Time.” The overload condition sensed by the Shock Relay causes the unit to trip, resulting in the Shock Relay breaking the motor starter contact – thus, shutting the system down to prevent mechanical damage from occurring.
Important Key Concepts: * Shock Relays generally work with any voltage AC motor, single or three-phase. * Besides the power to the motor, the Shock Relay needs its own power supply. Power supply requirements generally fall into 115 or 230V single phase. * It is best practice to have one Shock Relay monitor one motor. Grouping multiple motors to a single Shock Relay generally does not give satisfactory results.
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TSUBAKI SHOCK RELAY TARGET MARKETS & APPLICATION EXAMPLES Target Markets • Material Handling Conveyors, Turntables, Elevators • Water Treatment Plants Pumps, Scrapers, Water Screens • Food Machinery Pumps, Agitators, Mixers • Agriculture Screw and Belt Conveyors, Bucket Elevators • Machine Tool Tapping Machines, Drill Press • Chemical Industry Pumps, Agitators, Packagers
Application Examples
Bucket Elevators
Drag Conveyors
Excessive buildup can damage conveyor flights and reducers
Gear Drives
Conveyor Applications
Chain Feeders
steel pipe
rails
SHOCK RELAY
M
Detect damaging overloads that lead to downtime
Protect gears from damage
Protect attachments from damage
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HOW TO ORDER
The model code listed below is intended to provide an example of how a given Tsubaki Shock Relay is configured. The most important aspect of ordering a Tsubaki Shock Relay is knowing the electric drive motor horsepower, voltage and amperage rating. As seen below, these three attributes are used to select the correct size range. Selecting a given series is a matter of preference based upon the features and benefits of a given Shock Relay series.
How to Order Code: Example Model # TSBSB Series Shock Relay TSB SB 30
Shock Relay
Series
Max Amperage Amperage Range 230 Volt Motor HP* 460 Volt Motor HP*
5
0.5 - 6A
1/8 to 1 HP
1/4 to 3 HP
10
1 - 12A
2 to 3 HP
3 to 5 HP
30
3 - 30A
5 to 7 HP
7 to 15 HP
SB Series: Basic overload protection. Manual reset with fail safe contact
Tsubaki Shock Relay Overload Protection
60
5 - 60A
10 to 15 HP
20 to 30 HP
100
10 - 100A
20 to 25 HP
40 to 60 HP
200
20 - 200A
30 to 50 HP
70 to 120 HP
300
30 - 300A
60 to 100 HP
150 to 175 HP
* The motor horsepower ranges are approximates; best option is to select based on actual current readings.
The above example for the TSBSB series Shock Relay is used to illustrate the various models within one Shock Relay series and How to Order a Shock Relay for your application. TSB: There are two families within Tsubaki’s line of electronic protection devices. The Shock Relay series begins with TSB. The Shock Monitor series begins with TSM. SB: The SB-series is one of five types of Shock Relays, each having slightly different features and focusing on different types of applications. While there is overlap between the Shock Relay series, the combinations of features such as ease of set-up, type of display, and communication options will make one Shock Relay series more desirable than another. See the preceding page for a delineation of the various Shock Relay series. 30: The numerical sizing of a Shock Relay series. The TSBSB series is available in seven sizes and for this series, the number relates to the max amperage rating for that Shock Relay. While all Shock Relays can be adjusted over a wide range of amperages, here are a few suggestions that will aid with selection: • Select the Shock Relay based on actual running amperage There is a tendency to oversize the electric motor for the application. For example, the motor nameplate may say 6 amps but measurement shows the application only uses 3 amps. Select the Shock Relay based on the 3-amp reading.
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TSBSB SERIES - SHOCK RELAY r ies
Features: • Output relay is self-holding type • Contacts open when an overload is detected and remain until the reset button is pushed • Fail-safe relay de-energizes when over current detected • Economically priced • Wide current setting range • High degree of repeatability with low hysteresis • Includes TEST and RESET buttons • All-in-one unit with built-in current transformer • 35 mm DIN rail mount or panel mount • Can be used with single-phased motors • UL listed • Permits trip notification by alarm or warning lights How to Order Code: Example Model # for TSBSB Series Shock Relay TSB SB 30
All-in-one unit with CT
CT (current transformer)
External CT (current transformer)
Shock Relay
Series
Max Amperage Amperage Range 230 Volt Motor HP* 460 Volt Motor HP*
5
0.5 - 6A
1/8 to 1 HP
1/4 to 3 HP
Sta
10
1 - 12A
2 to 3 HP
3 to 5 HP
30
3 - 30A
5 to 7 HP
7 to 15 HP
SB Series: Basic overload protection. Manual reset with fail safe contact
Tsubaki Shock Relay Overload Protection
60
5 - 60A
10 to 15 HP
20 to 30 HP
100
10 - 100A
20 to 25 HP
40 to 60 HP
200
20 - 200A
30 to 50 HP
70 to 120 HP
300
30 - 300A
60 to 100 HP
150 to 175 HP
* The motor horsepower ranges are approximates; best option is to select based on actual current readings. Select the Shock Relay based on the motor amperage or motor horsepower.
The following table provides a breakdown of the components provided when ordering a given TSBSB Series Shock Relay. Note that TSBSB Shock Relay sizes with model numbers containing 100, 200, and 300 require additional components when selected. For example, a TSBSB100 Shock Relay will be supplied with a TSBSB05 Shock Relay and a TSB2CT100 current transformer.
TSBSB - All in one unit
TSBSB Externally Mounted Current Transformer Type
Shock Relay Assembly Part Number
Current Transformer Part Number
Shock Relay Assembly Part Number
Shock Relay Part Number
Current Transformer Part Number
TSBSB05 TSBSB10 TSBSB30 TSBSB60
Not Applicable Not Applicable Not Applicable Not Applicable
TSBSB100 TSBSB200 TSBSB300
TSBSB05 TSBSB05 TSBSB05
TSB2CT100 TSB2CT200 TSB2CT300
NA
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TSBSB SERIES - SHOCK RELAY
MON lamp The lamp lights during normal monitoring conditions. When the shock time exceeds the preset time, the lamp turns off.
CT (current transformer)
OC lamp When the motor current
exceeds preset current value, the lamp flickers. When shock time exceeds the preset time, the lamp lights.
3
Test
1
Load Current
4
Reset
2
Start time (Setting range of 0.2-30s)
5
Shock time
(Setting range of 0.2-10s)
Control interface LOAD CURRENT
1
Load current can be set to stop the motor at the desired level when overload occurs. When the motor current exceeds the preset CURRENT value (at the same time, overload time continues to exceed the preset SHOCK TIME), the Shock Relay activates and stops the motor. START TIME When the motor starts there is a possibility that the motor current will exceed the set current value. To prevent the Shock Relay from tripping due to the spike in start current, start time is set a little bit longer than the period of motor start-up to ignore the spike. TEST Button Shock Relay operation can be tested stand-alone or during motor operation. (When testing the Shock Relay, continue to press and hold the TEST button longer than the set START TIME or SHOCK TIME, whichever is longer.) RESET Button After the Shock Relay activates, the RESET button is used to cancel the self-holding of the output contact. SHOCK TIME Shock time is the amount of time set until the Shock Relay will activate when overload occurs. Within the set time, the Shock Relay will not activate, even if it is overloaded.
2
3
4
5
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TSBSB - OPERATING MODE
Operation mode
Rotation speed/ current
Starting current
Motor rotation speed
Shock Relay operation (trip)
Set load current value
Motor load current
Momentary overload
Overload
Time
Start time Set value
Shock time Set value
Shock time Set value Overload area
Steady area
Stop
Output relay
0.5s
Power source
Dimensional envelope drawing
TSBSB All dimensions in millimeters unless noted.
77.2
13.5
12.8
52.3
N.P.
56
2-Ø4.5
63 70.8
Wiring screw 5-M3.5
Cover Hole
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TSBSB - OUTLINE DIMENSIONS & BASIC WIRING SCHEMATIC
Basic electrical schematic
DIP Switch Set to SS
DIP Switch Set to SA
OCR
OCR
MC
MC
Power source CB
Power source CB
MOTOR
M MOTOR
R (L1) S (L2) T (L3)
T (L3) S (L2) R (L1)
M
SS SA DIP switch:SA
DIP switch:SS
CT
CT
F
F
SS
SA
SHOCK RELAY
SHOCK RELAY
TR
TR
A1 A2 95 96 97 98
A1 A2 95 96 97 98
RESET
A1
A2
A1
A2
RUN
RUN
OCR
OCR
STOP
95
96 STOP
97
98
MC
MC
MC
MC
TSBSB SHOCK RELAY
SHOCK RELAY TSBSB
98
96
97
95
Notes: 1) Transformers (Tr) should be attached as necessary according to the operating power of the SHOCK RELAY. In addition, the use of inverters or other harmonic noise generators may cause a malfunction. In such cases, make sure to install an isolation transformer. 2) Make sure that two of the three-phase wires routed to the motor pass through the two SHOCK RE- LAY CTs in the same orientation. 3) The coil capacity of the electromagnetic contactor (MC) to be connected to the output relay of the SHOCK RELAY should be less than 200 VA when ON and less than 20 VA during retention. 4) Be cautious of the DIP switch selection of the SHOCK RELAY when connecting.
Terminal
Function
Contents
95
DIP Switch: SS 95-96: normal/open, trip/close 97-98: normal/close, trip/open DIP Switch: SA 95-96: normal/close, trip/open 97-98: normal/open, trip/close
96
Output Relay
97
98
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Features: • Works with inverter 20 to 200 Hz • User adjustable for manual or automatic reset • Digital display • Adjustable Start Time, Shock Time, and Current setting • Built-in tamper-resistant cover over controls • Built-in Test Function • Includes motor locked rotor protection • DIN rail or panel mount • Manual or Automatic Reset • UL listed • Permits trip notification by alarm or warning lights TSBED SERIES - SHOCK RELAY
TSBED Series Shock Relay
How to Order Code: Example Model # TSBED Series Shock Relay
TSB 020 ED
Shock Relay
Model Size
Series
Amperage Range 230 Volt Motor HP* 460 Volt Motor HP*
020
0.2 – 2.4A
1/8 to 1 HP
1/8 to 2HP
075
1.2 – 5.8A
1/2 to 2 HP
1/2 to 5 HP
Tsubaki Shock Relay
ED Series: Digital Display
220
3 – 14 A
1 - 1/2 to 5 HP
2 to 10 HP
550
6 – 34 A
2 - 1/2 to 10 HP
5 to 25 HP
* The motor horsepower ranges are approximates; best option is to select based on actual current readings. Select the Shock Relay based on the motor amperage or motor horsepower.
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TSBED - CONTROL INTERFACE
4 CT ( current transformer ) DIP switch ( selector switch ) TEST button 5
7
LED display
2
START TIME set
6
CHECK/RESET
1
CURRENT set
3
SHOCK TIME
Current Setting (CURRENT) Sets current at the value at which trip occurs. Start Time Setting (START TIME)
1
2
Sets start time (start compensating time). When the motor starts, there is a possibility that the motor current will exceed the set current value, but during the start time period it will not trip. Shock Time Setting (SHOCK TIME) Sets shock time (output delay time). When the motor current exceeds the set current value the count begins, and when shock time has elapsed, it will trip. DIP Switch (selector switch)
3
4
Setting
Purpose
No. of motor leads that pass through the CT T1/ T2
Current value set range selection Output relay reset selection
No. of passes through the CT:2
T1 No. of passes through the CT:1
T2
It automatically returns from the trip state one second after current value returns below the current setting value.
Trip state is maintained until the check/reset button is pressed. It then resets.
Trip reset A / M
A
M
TEST Button (TEST) When the LED displays current value, pressing the TEST button will carry out an operation test. CHECK/RESET Button (CHECK/RESET) (During normal operation) By pressing the CHECK/RESET button when the LED displays current value, it switches to the setting screen. (During trip) When the CHECK/RESET button is pressed, trip is cleared and the display switches to the current value. (During set-up) When the LED display is at the setting screen, pressing the CHECK/RESET button will switch between the current, start time, and shock time settings, in this order. LED Display
5
6
7
Current value and set current are displayed when (A) is indicated on the display screen (to the left of the A). (A = ampere)
Start time and shock time set up are displayed when (s) is indicated on the display screen (to the left of the s). (s = second)
Current value
Current set-up
Start time set-up
Shock time set-up
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TSBED - OPERATING MODE
Operation mode
Shock time: The Shock Relay does not respond to excess current if it does not exceed the preset shock time.
Shock time: When excess current goes beyond the preset time the Shock Relay responds.
Start time: Within a set time, the Shock Relay does not respond to motor starting current.
Shock Relay operation (trip)
Motor rotation speed
Rotation speed /current
Set current value
Motor load current
Short period of current surge
Overload
Set start time value
Set shock time value Set shock time value
Time
Start-up
Steady area
Overload area Stoppage
Figure 2: TSBED Series Shock Relay operation mode
Figure 2 above reflects a typical set-up for a TSBED Series Shock Relay. As depicted in the above example, the Shock Relay is set up to accept a higher motor amperage draw at start-up for a limited amount of time. This “Start Time” period allows the motor to spool to its steady state operation mode where maximum continuous RPM is achieved, and current draw drops to a normal value that is below the maximum “Current Value” set in the Shock Relay. As depicted, the amperage draw of the motor then momentarily increases (resulting in a drop in RPM due to induced load) above the maximum “Current Value” setting, but quickly falls back to a steady state value. Since the “Shock Time” value was not exceeded, the Shock Relay does not trip, and allows continued operation. However, as time passes by, the Shock Relay senses an increase in motor amperage draw and a drop in RPM that exceeds set current value and “Shock Time.” The overload condition sensed by the Shock Relay causes the unit to trip, resulting in the Shock Relay breaking the motor starter contact – thus, shutting the system down to prevent mechanical damage from occurring.
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TSBED - OUTLINE DIMENSIONS & BASIC WIRING SCHEMATIC
Dimensional envelope drawing
Dimensional outline drawing
Basic diagram
All dimensions in millimeters unless noted.
Shock Relay ED Series
2-φ4.5 or M4 tap holes Installation hole
TSBED basic wiring schematic Basic diagram
CB: Circuit breaker MC: Magnetic contactor F: Fuse TR: Transformer OCR: Over current relay PL: Trip light
Motor
Shock Relay ED Series
96
Stop Start
Shock Relay ED Series
p holes
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TSBSC SERIES - SHOCK RELAY
All-in-one type (built-in current transformer)
Features: • Communication function allows central monitoring • The 4 to 20 mA output allows communication to a central control, or as input to controls that operators monitor and adjust to maintain production • Panel mounting with remote display option • Both Under current and Over current monitoring • Inverter compatible from 20 to 200 Hz • Locked rotor protection • Phase imbalance protection • Phase loss protection • Thermal overload protection • Can be used with single-phased motors • Multiple operations can be linked together and monitored from one location.
Panel type (external current transformer)
How to Order Code: Example Model # TSBSC Series Shock Relay
TSB SC B 34
Shock Relay
Series
Type
Max Amperage Amperage Range 230 Volt Motor HP* 460 Volt Motor HP*
06
0.15 – 6.40A
1/16 to 2 HP
1/8 to 5 HP
B: All-in One Type
34
3 – 34A
1 to 10 HP
2 to 25 HP
SC Series: Serial Communication
60
10 – 60A
5 to 25HP
10 to 50 HP
Tsubaki Shock Relay
OR
100
12 – 100A
5 to 40 HP
10 to 75 HP
S: Panel Mount Type
200
24 – 200A
10 to 75H
20 to 150 HP
300
36 – 300A
15 to 125 HP
25 to 250 HP
* The motor horsepower ranges are approximates; best option is to select based on actual current reading. Select the Shock Relay based on the motor amperage or motor horsepower.
The following table provides a breakdown of the components provided when ordering a given TSBSC Series Shock Relay. Note that TSBSC Shock Relay sizes with model numbers containing 100, 200, and 300 require additional components when selected. For example, a Panel Type TSBSCS200 Shock Relay will be supplied with a TSBSC06 unit, TSBSCD display, TSB3CT200 current transformer, and a TSBSCC05 cable.
TSBSC Model Composition - All in One Type Unit
TSBSC Model Composition - Panel Type Unit
Shock Relay Assembly Model #
Shock Relay #
Current Transformer # Not Applicable Not Applicable Not Applicable
Shock Relay Assembly Model #
Shock Relay #
Display Model #
Current Transformer #
Cable Model #
TSBSCB06 TSBSCB34 TSBSCB60 TSBSCB100 TSBSCB200 TSBSCB300
TSBSCB06 TSBSCB34 TSBSCB60 TSBSCB06 TSBSCB06 TSBSCB06
TSBSCS06 TSBSCS34 TSBSCS60 TSBSCS100 TSBSCS200 TSBSCS300
TSBSCS06 TSBSCS34 TSBSCS60 TSBSCS06 TSBSCS06 TSBSCS06
TSBSCD Not Applicable TSBSCC05-30 TSBSCD Not Applicable TSBSCC05-30 TSBSCD Not Applicable TSBSCC05-30 TSBSCD TSB3CT100 TSBSCC05-30 TSBSCD TSB3CT200 TSBSCC05-30 TSBSCD TSB3CT300 TSBSCC05-30
TSB3CTC100 TSB3CTC200 TSB3CTC300
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Communication function
No. 1
No. 2
No. 3
No. 4
TSBSC - COMMUNICATION FUNCTION No. 1
Communication function
1
19.2A
19.5A
19.7A
No. 1
No. 2
No. 3
No. 4
No. 1
2
Maximum connection: up to 247 units Maximum total extension: up to 400 ft.
Specifications of RS485
1 1
Signal converter RS485/USB (Commercially available)
3
19.2A
19.5A
19.7A
USB
2 2
PC
Maximum connection: up to 247 units Maximum total extension: up to 400 ft.
Specifications of RS485
Signal converter RS485/USB (Commercially available)
3 3
USB
Remote Control Display the current of each phase L1, L2 and L3 on the PC screen by reading them from specified Shock Relay address. Display Current Change Plot the current value of each phase at specified intervals. Data for the last 159 events can be displayed. Display Accumulated Operation Time Can be utilized for equipment maintenance such as oil filling, filter cleaning, etc. PC
1
2
3
4 to 20 mA analog signal “What is a 4 to 20 mA analog signal?” A 4 to 20 mA analog signal is a standard instrumentation signal used around the world. Instrumentation signal: • Voltage signal: DC 0 to 5 V, DC 0 to 10 V, etc. • Current signal: DC 4 to 20 mA, DC 0 to 20 mA, etc. Current signals are less susceptible to influence from electrical noise than voltage signals.
In addition, DC 4 to 20 mA, when compared to DC 0 to 20 mA, is more precise in the event of wire disruption or breaks. Therefore, DC 4 to 20 mA is used frequently, specifically in the case of long transmission distances (several tens of meters) or in answer to requests for reducing noise influence.
Example of application 1 Automatic control of the input and viscosity depending on the load by inputting the current draw to the sequencer of a crusher or mixer. 2 Figuring out the operation and loading conditions for the equipment by recording the load current of a trial unit, then using it as the basis for an optimal equipment design. 3 , 4 Activation of a digital or analog meter
1
2 2
1
Display of the wave pattern with recorder
Input to sequencer
3
4 4
3
100
130
0
1
2
Display with digital panel meter
Display with analog meter
with DC 4 to 20 mA signal for remote centralized monitoring of pumps, etc. 100
Display of the wave pattern with recorder
Input to sequencer
4 to 20 mA signal
3
4
130
0
In the case of TSBSCB60 (Max. 60 A), it is possible to transmit DC 0 to 60 A as a DC 4 to 20 mA signal. In addition, output value correction is available due to the scaling adjustment function of the DC 4 to 20 mA output of the TSBSC Series.
Display with digital panel meter
Display with analog meter
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4 to 20 mA signal
TSBSC - CONTROL INTERFACE
All-in-one type
Panel type
4 LED displa y
4
LED display
1
ESC button
2
UP /DN button
3
SET button
1
ESC button
3
SET button
2
UP /DN button
ESC Button (reset) Releases the trip or returns back to the initial setting display. Pushing the reset button after completing parameter settings to return back to initial screen. UP/DN Button (UP/DOWN) Switch to parameter mode and change data settings. SET Button (set) Confirm and register parameter setting data. LED display
1
2
3
3
Amp X10 sec Amp X10 sec
Amp X10 sec
L1 L2 L3
L1 L2 L3
a Phase display LED
b Unit display LED b Unit display LED
Amp X10 sec
L1 L2 L3
L1 L2 L3
a Phase display LED
65 70 75 80 85 90 95 100% 65 70 75 80 85 90 95 100% Phase L1 operating current Phase L1 operating current
65 70 75 80 85 90 95 100% 65 70 75 80 85 90 95 100% Phase L2 operating current Phase L2 operating current
Amp X10 sec
L1 L2 L3
Amp X10 sec
L1 L2 L3
Automatic transfer display Automatic transfer display
Amp X10 sec
L1 L2 L3
Amp X10 sec
L1 L2 L3
65 70 75 80 85 90 95 100% 65 70 75 80 85 90 95 100%
65 70 75 80 85 90 95 100%
Phase L3 operating current display
c Load ratio display bar graph
c Load ratio display bar graph
d 7 segments LED display d 7 segments LED display
1) While in normal operation, it is possible to change the displayed phase, and set it. Release by pushing the ESC button. 2) Trip record (3 most recent) can be viewed by pushing and holding the ESC button 5 sec. or longer. Push the UP/DN buttons to cycle through and confirm current values (cycles L1"L2"L3"L1"...). The order of the trip record appears on a bar graph in the order of 100%, 95%, and 90% for easy confirmation. Release by pushing the ESC button. Digital ammeter functions
a. Phase display LED Displays the electric motor phase (L1(R) L2(S) L3(T)) which shows the current, changes every 2 seconds. b. Unit display LED LED which indicates the unit. c. Load ratio display bar graph Can be utilized as a guide when setting OC (Over current setting value). Displays the ratio as a percentage (%); Operational load current/OC current setting value d.Seven segment LED Displays operation current, parameter setting value, cause of trip, etc.
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TSBSC - OPERATING MODE
Overload operation mode Overload operating mode
The Shock Relay does not respond to motor starting current within the preset start time period. The Shock Relay does not respond to motor starting current within the preset start time period. Overload operating mode
The Shock Relay does not respond to excess current (spike) if it does not exceed the preset shock time. The Shock Relay does not respond to excess current (spike) if it does not exceed the preset shock time.
The Shock Relay responds when excess current exceeds the preset shock time. The Shock Relay responds when excess current exceeds the preset shock time.
Motor rotational speed
Shock Relay operation (trip)
Motor rotational speed
Shock Relay operation (trip)
Motor load current
Short period of over current (not want to stop due to spike)
Overload
Motor load current
Short period of over current (not want to stop due to spike)
Time
Start time setting value
Shock time setting value
Shock time setting value Overload Abnormal (Overload) area
When motor starts
Steady area
Motor stops
Time
Start time setting value
Shock time setting value
Shock time setting value
Light load operation (underload detection) mode Abnormal (Overload) area Steady area When motor starts
Motor stops
Once the motor current falls below the preset level, underload is detected and a signal is sent to stop the motor. For under-load detection, the output contact is set to alarm output.* * However, in case of the underload detection, the output contact becomes choice of either alarm output or no action.
The Shock Relay does not respond to short- term current degradation if it does not exceed the preset shock time. The Shock Relay does not respond to short- term current degradation if it does not exceed the preset shock time.
The Shock Relay responds when current degradation continues for longer than the preset shock time. The Shock Relay responds when current degradation continues for longer than the preset shock time.
Shock Relay operation (trip)
Motor load current
Shock Relay operation (trip)
Short period of under current (not want to stop due to spike) Motor load current
Current drop
Short period of under current (not want to stop due to spike)
Time
Start time setting
Shock time starting
Shock time starting Current drop Abnormal (Underload) area
When motor starts
Steady area
Motor stops
Time
Start time setting
Shock time starting
Shock time starting
When motor starts
Steady area
Abnormal (Underload) area
Motor stops
Communication function
Communication Specification
Item
Content
Transmittance standards
RS-485
Max. transmittance distance
1200m (depends on transmittance speed) Half-duplex system; modbus protocol
Transmittance system Transmittance speed
1.2k to 38.4kbps
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18
TSBSC - OUTLINE DIMENSIONS
Dimensional envelope drawing TSBSCB06/TSBSCB34/TSBSCB60 All-in-one type main unit All dimensions in millimeters unless noted. TSBSCB06, TSBSCB34, TSBSCB60 All dimensions in millimeters unless noted. ALL-in-one type main unit
TSBSCS06, TSBSCS34, TSBSCS60 TSBSCS06/TSBSCS34/TSBSCS60 Panel type main unit All dimensions in millimeters unless noted. All dimensions in millimeters unless noted. Panel type main unit
22.5 22.5 All dimensions in millimeters unless noted. Panel type main unit 3- ∅ 12
22.5 22.5 3- ∅ 12 All dimensions in millimeters unless noted. ALL-in-one type main unit
83.8
83.8
18
18
46.5
46.5
TSBSCB06, TSBSCB34, TSBSCB60
TSBSCS06, TSBSCS34, TSBSCS60
8.7
8.7
83.8
83.8
3- ∅ 12
22.5 22.5 3- ∅ 12
22.5 22.5
18
18
46.5
46.5
8.7
8.7
∅ 4.5
∅ 4.5
70 82.3
70 82.3
∅ 4.5
∅ 4.5
Mounting plate
Mounting plate
70 82.3
70 82.3
TSBSCC05, TSBSCC10, TSBSCC15, TSBSCC20, TSBSCC30 TSBSCC05, TSBSCC10, TSBSCC15, TSBSCC20, TSBSCC30 500 ※ All dimensions in millimeters unless noted. TSBSCC05/TSBSCC10/TSBSCC15/ TSBSCC20/TSBSCC30 Panel type communication cable All dimensions in millimeters unless noted. Cable (Panel type) Mounting plate All dimensions in millimeters unless noted. Cable (Panel type)
TSBSCD TSBSCD Panel type display unit All dimensions in millimeters unless noted. All dimensions in millimeters unless noted. Panel unit (Panel type) Mounting plate All dimensions in millimeters unless noted. Panel unit (Panel type)
TSBSCD
SHOCK RELAY
L1 L2 L3
SEC x10 Amp
65 70 75 80 85 90 95 100 %
1
1
TSBSCC05 ( 0.5m ) 500 ※
SHOCK RELAY
8
8
L1 L2 L3
SEC x10 Amp
65 70 75 80 85 90 95 100 %
( 23 )
( 23 ) 1
1
9.7
9.7
TSBSCC05 ( 0.5m )
Dimension of hole for installation
8
8
( 28.1 )
※ In case of TSBSCC05 (0.5m specification)
72
( 23 )
( 23 )
9.7
9.7
TSB3CTC100, TSB3CTC200, TSB3CTC300 TSB3CTC100/TSB3CTC200/ TSB3CTC300 External CT All dimensions in millimeters unless noted. 140 All dimensions in millimeters unless noted. All dimensions in millimeters unless noted. External CT 72 ( 28.1 ) Dimension of hole for installation External CT 4-M4 Nut TSB3CTC100, TSB3CTC200, TSB3CTC300
※ In case of TSBSCC05 (0.5m specification) Cable Part No.
Length (in mm)
TSBSCC05 TSBSCC10 TSBSCC15 TSBSCC20 TSBSCC30
500
1,000 1,500 2,000 3,000
140
4-M4 Nut
2- ∅ 4.5
6-M4 Bolt
2- ∅ 4.5
6-M4 Bolt
150
150
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TSBSC - BASIC WIRING SCHEMATIC
Basic wiring schematic
T ( L3 ) S ( L2 ) R ( L1 ) Power supply
CB
OCR
MC
M
Motor
Single-phase motor
OCR
MC
F
CT
M Motor
TR
Shock Relay TSBSC Series
CT
Shock Relay TSBSC Series
A1 A2
OC
OCR
STOP RUN MC
95
96
MC
RUN
CT: Current transformer CB: Circuit breaker MC: Magnetic contactor F: Fuse TR: Transformer OCR: Over current relay PL: Trip light
98
PL
TRIP
08
AL/UC /TO
Fail Safe mode :OFF ( FS:off )
+ ー
4-20 mA OUTPUT
RS485 Communication
TSBSC
Notes: 1) If necessary, set the stepdown transformer (TR) depending on the voltage on the Shock Relay and electromagnetic contactor (MC). Install an isolating transformer if there is any harmonic noise generating device, such as an inverter. 2) Output relay; Normal condition: not excited, Trip condition: excited 3) Coil capacity of MC connected to the output relay of the Shock Relay is: Throw = less than 200VA Hold = less than 20VA In the event that an auxiliary relay is used, have the output relay of the Shock Relay activate the Auxiliary Relay and have the Auxiliary Relay open/close the MC.
Connection with signal converter
1) Prepare a signal converter to use the monitoring software (PCON) of TSBSC. 2) Use twisted cables and connect as follows.
Terminal
Signal
RS485 Terminal
COMM
V-
GND
GND
D1
Data (B)
Tx+
V- D1 D0 S
D0
Data (A)
Tx-
S
Shield
Shield
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TSUBAKI OVERLOAD PROTECTION
TSUBAKI OVERLOAD PROTECTION PRODUCTS
Torque Guard TGB Series An economical choice for general use. The TGB series can be used with about any machine. Offers automatic resetting, easy-to-read torque indicator and no backlash.
Torque Guard TGM Series The gasket and O-ring sealed construction in the TGM series is unique. Excels in wet, dusty, and oily applications. Designed for long life, tough environments.
Torque Guard TGX Series A high-precision option, the TGX series features no backlash and unsurpassed operation rigidity. Ideal for machines that require accurate positioning.
Torque Guard TGZ Series A release-type protection
Torque Limiter TL Series
Torque Limiter Coupling
A friction system, mechanical device that limits damage to equipment when an unexpected increase in torque occurs because of a jam or overload by slipping and absorbing the brunt of the force, preventing the increased power from damaging your equipment.
A flexible coupling that uses a Torque Limiter and special type sprocket and is connected by two rows of roller chains. It acts as an automatic safety device,
device, the TGZ series offers on-off clutch capability. Its simple and straightforward adjustments make it easy to use.
protecting machinery from damage due to overload.
21
PRODUCT OVERVIEW
Axial Guard TGA Series
Torque Keeper TFK Series A mechanical device for industrial equipment brake mechanisms has been designed with abrasion resistance, the use of a torque indicator, weight savings and other aspects that make it easy to use.
MINI-KEEPER MK Series
Offers overload protection using ball and grooves that provide a consistent, user-defined trip point for applications where motion is back and forth rather than rotating. When overloads occur, the Axial Guard “trips” and eliminates the overload that can result in damage and downtime.
A super-compact slipping clutch and brake, constructed from fine chemicals and engineering plastic. The MINI-KEEPER has a supreme level of lightness, compactness and accuracy and is ideal for braking, accumulating and dragging applications.
FOR COMPLETE SPECIFICATIONS ON THESE PRODUCTS PLEASE VISIT OUR WEBSITE AND DOWNLOAD THE FULL CATALOG
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22
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NOTE: IN ACCORDANCE WITH THE POLICY OF U.S. TSUBAKI POWER TRANSMISSION, LLC TO CONSISTENTLY IMPROVE ITS PRODUCTS, THE SPECIFICATIONS IN THIS CATALOG ARE SUBJECT TO CHANGE WITHOUT NOTICE.
©2013 U.S. Tsubaki Power Transmission, LLC. All Rights Reserved. Printed in U.S.A. 03/13 Rev. 0 L14010 © 2016 U.S. Tsubaki Power Transmission, LLC. All Rights Reserved. Printed in U.S.A. 09/18 Rev. 1 L14020
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