CSM_SDV_DS_E_6_1
1
Voltage Sensor
SDV
Overvoltage/Undervoltage Monitoring
Relay for AC and DC Input
• Detect overvoltages or undervoltages (switch select-
able) from 4 mV to 300 V.
• Detect undercurrent, reverse current, or overcurrent in
DC circuits using shunt (SDV-FL).
• Detect three-phase AC current for under and/or overcur-
rent using current converter.
• Available in 7 supply voltage configurations.
• Single-function model with ON-delay, OFF-delay, or star-
tup lock settings (SDV-FH@T).
• Select either AC or DC voltage input.
• Polarity can be specified (SDV-FL) to enable easy re-
verse current detection.
• Selectable reset value range from 2% to 30% of operat-
ing value (SDV-F).
• LED operation indicator.
• UL/CSA approval (single-function models).
Model Number Structure
■Model Number Legend
1. Voltage Sensor
2. Operation
F: Single-function (overvoltage or undervoltage detection)
D: Dual-function (overvoltage and undervoltage detection)
3. Operating Voltage Range
L: 4 to 240 mV (DC input only) (For SDV-F only)
M: 0.2 to 12 V (AC or DC input)
H: 10 to 300 V (AC or DC input)
4, 5. Control Power Supply Voltage
2: 24 VDC
3: 48 VDC
4: 100/110 VDC
5: 125 VDC
51: 200/220 VDC (Single-function models)
6: 100/110 VAC
61: 120 VAC (Single-function models)
7: 200/220 VAC
71: 240 VAC (Single-function models)
6. Timing Function (SDV-FH Only (See Note))
None: Not provided
T: Provided
Note: SDV-FL and SDV-FM models can also be equipped with the
timing function as a special specification. Ask your OMRON
representative for details.
Note: Not possible for the SDV equipped with the timing function
(SDV-FH@T).
SDV-@@@@@
123456
SDV
2
1. Shunt (For SDV-FL Only)
2, 3, 4, 5. Rated Current
Available Models
Note: All the above listed shunts have an accuracy in the 1.0 class.
Connecting Socket (Order Separately)
Ordering Information
Single-function Models
Overvoltage or Undervoltage Detection (Switch Selectable)
Dual-function Models
Overvoltage and Undervoltage Detection
Note: 1. Inquire about production of models with 120- and 240-VAC control power supply.
2. Inquire about models with special processing for high-temperature, high-humidity applications.
3. The ripple factor must be 5% or less for DC power supplies.
SDV-SH @@@@ (Order Separately)
12345
Rated current Rated voltage Model Rated current Rated voltage Model
5 A 60 mV SDV-SH5 75 A 60 mV SDV-SH75
7.5 A SDV-SH7.5 100 A SDV-SH100
7.5 A 100 mV SDV-SH7.5 100MV 150 A SDV-SH150
10 A 60 mV SDV-SH10 200 A SDV-SH200
15 A SDV-SH15 300 A SDV-SH300
20 A SDV-SH20 500 A SDV-SH500
30 A SDV-SH30 750 A SDV-SH750
50 A SDV-SH50 1,000 A SDV-SH1000
Applicable models Socket
Type Model
SDV-F@@/-FH@T Front Connecting Socket 8PFA1
Back Connecting Socket PL08
SDV-D@@ Front Connecting Socket 14PFA
Back Connecting Socket PL15
Control power supply voltage Input
DC DC or AC (selectable)
Input voltage range
4 to 240 mV 0.2 to 12 V 10 to 300 V
24 VDC SDV-FL2 SDV-FM2 SDV-FH2
48 VDC SDV-FL3 SDV-FM3 SDV-FH3
100/110 VDC SDV-FL4 SDV-FM4 SDV-FH4
125 VDC SDV-FL5 SDV-FM5 SDV-FH5
200/220 VDC --- --- SDV-FH51
100/110 VAC SDV-FL6 SDV-FM6 SDV-FH6
120 VAC --- --- SDV-FH61
200/220 VAC SDV-FL7 SDV-FM7 SDV-FH7
240 VAC --- --- SDV-FH71
Control power supply voltage Input: DC or AC (selectable)
Input voltage range
0.2 to 12 V 10 to 300 V
24 VDC SDV-DM2 SDV-DH2
48 VDC SDV-DM3 SDV-DH3
100/110 VDC SDV-DM4 SDV-DH4
125 VDC SDV-DM5 SDV-DH5
100/110 VAC SDV-DM6 SDV-DH6
200/220 VAC SDV-DM7 SDV-DH7
240 VAC SDV-DM71 SDV-DH71
SDV
3
Single-function Models with Timing Function
Note: SDV-FL and SDV-FM models can also be equipped with the timing function as a special specification. Ask your OMRON representative for
details.
Specifications
Single-function Models
Overvoltage or Undervoltage Detection (Switch Selectable)
Note: Ripple is 5% max. with DC power supplies.
Dual-function Models
Overvoltage and Undervoltage Detection
Note: 1. Inquire about production of models with 120- and 240-VAC control power supply.
2. The ripple factor must be 5% or less for DC power supplies.
Control power supply voltage Input: DC or AC (selectable); input voltage range: 10 to 300 V
Operating mode
ON-delay OFF-delay Startup lock
24 VDC SDV-FH2T
48 VDC SDV-FH3T
100/110 VDC SDV-FH4T
125 VDC SDV-FH5T
200/220 VDC SDV-FH51T
100/110 VAC SDV-FH6T
120 VAC SDV-FH61T
200/220 VAC SDV-FH7T
240 VAC SDV-FH71T
Model Input voltage Selectable operating range Selectable reset value range Control power supply
SDV-FL@DC 4 to 240 mV
(4 to 12 mV, 10 to 30 mV,
20 to 60 mV, 40 to 120 mV,
80 to 240 mV)
2% to 30% (related to
operating value)
24, 48, 100/110, 125, 200/220 VDC
(see note);
100/110, 200/220/240 VAC
(50/60 Hz)
SDV-FM@DC or AC
(selectable)
0.2 to 12 V
(0.2 to 0.6 V, 0.5 to 1.5 V, 1 to 3 V,
2 to 6 V, 4 to 12 V)
SDV-FH@
SDV-FH@T
10 to 300 V
(10 to 30 V, 25 to 75 V, 50 to 150 V,
100 to 300 V)
Model Input voltage Selectable operating range Reset value Control power supply
Intermediate voltage of
dead band
Dead band
voltage
SDV-DM@DC or AC
(selectable)
0.2 to 12 V 0.2 to 0.6 V 0.02 to 0.1 V Overvoltage:
(Intermediate voltage of
dead band + dead band
voltage) – (dead band volt-
age x 2/3) min.
Undervoltage:
(Intermediate voltage of
dead band – dead band
voltage) + (dead band volt-
age x 2/3) max.
24, 48, 100/110, 125 VDC;
100/110, 200/220/240 VAC
(50/60 Hz)
0.5 to 1.5 V 0.05 to 0.25 V
1 to 3 V 0.1 to 0.5 V
2 to 6 V 0.2 to 1 V
4 to 12 V 0.4 to 2 V
SDV-DH@10 to 300 V 10 to 30 V 1 to 5 V
25 to 75 V 2.5 to 12.5 V
50 to 150 V 5 to 25 V
100 to 300 V 10 to 50 V
SDV
4
■Ratings
Note: The impedance value is a reference value; actual values may vary.
■Characteristics
Note: Overvoltage: Operation when voltage is changed from 80% to 120% of the operating value.
Undervoltage: Operation when voltage is changed from 120% to 80% of the operating value.
Item SDV-FL@SDV-FM@SDV-FH@/FH@TSDV-DM@SDV-DH@
Allowable continuous
input overvoltage range
±10 VDC ±150 VDC
150 VAC
±350 VDC
(±500 VDC for 1 min)
350 VAC
(500 VAC for 1 min)
±150 VDC
150 VAC
±350 VDC
(±500VDC for 1min)
350 VAC
(500 VAC for 1 min)
Input impedance 1 kΩ50 kΩ2,500 kΩ50 kΩ2,500 kΩ
Control output SPDT SPST-NO and SPST-NC
Rated load: 5 A at 220 VAC (cosφ = 1),
5 A at 24 VDC (cosφ = 1),
2 A at 220 VAC (cosφ = 0.4),
2 A at 24 VDC (L/R = 7 ms)
Max. contact voltage: 250 VAC, 125 VDC
Max. contact current: 5 A
Max. switching capacity: 1,100 VA (cosφ = 1), 120 W (cosφ = 1),
440 VA (cosφ = 0.4), 48 W (L/R = 7 ms)
Power consumption DC: 5 W max.; AC: 5 VA max.
Ambient temperature –10 to 55°C (with no icing)
Control supply voltage
(see note)
24, 48, 100/110, 125, 200/220 VDC; DC operating voltage range: 80% to 130% of control power supply
100/110/120, 200/220/240 VAC (50/60 Hz); AC operating voltage range: 85% to 110% of control power supply
Item SDV-F@@ SDV-FH@TSDV-D@@
Operating value 100% operation for voltage setting
Setting error Operating value: ±2% of operating value
(This is the ratio for the setting value.)
Reset value: ±7% of reset value
(This is the ratio for the setting value.)
±2% of intermediate voltage of dead band,
±1% of dead band voltage
Operating time 0.5 s max. (see note)
Influence of temperature 0 to 40°C:
±2% max. of operating value
(SDV-FL (operating value range: 4 to 12 mV)
±4% max. of operating value)
–10 to 0°C, 40 to 55°C:
±4% max. of operating value
(SDV-FL (operating value range: 4 to 12 mV)
±8% max. of operating value)
0 to 40°C:
±2% max. of dead band voltage
–10 to 0°C, 40 to 55°C:
±4% max. of dead band voltage
Influence of control power ±1% max. of operating value
DC operating voltage range: 80% to 130%
AC operating voltage range: 85% to 110%
±1% max. of dead band voltage
DC operating voltage range: 80% to 130%
AC operating voltage range: 85% to 110%
Influence of frequency
(Input frequency changed
from 10 to 500 Hz for AC in-
put)
±1% max. of operating value ±1% max. of dead band voltage
Influence of waveform
(For commercial frequency,
single-phase, full-wave AC
input)
±3% max. of operating value ±3% max. of dead band voltage
Insulation resistance 10 MΩ min. (at 500 VDC) between the entire electric circuitry and external case, and between the input terminal
and power terminal
Dielectric strength 2,000 VAC for 1 min between the entire electric circuitry and external case, and between the input terminal and
power terminal
Impulse withstand voltage ±1.2 x 50 μs, 4,500 V between the entire electric circuitry and external case
±1.2 x 50 μs, 3,000 V between power terminals
Vibration resistance Destruction: 10 to 25 Hz, 2-mm double amplitude (2G max.) for 2 hrs each in 3 directions
Malfunction: 16.7 Hz, 1-mm double amplitude for 10 min each in 3 directions
Shock resistance Destruction: 294 m/s2 (30G)
Malfunction: 98 m/s2 (10G)
Weight Approx. 290 g Approx. 350 g Approx. 310 g
SDV
5
Timing Function
Note: The time setting range when the startup lock is selected for the operating mode is approximately 1 to 30 s.
Nomenclature
Item SDV-FH@T
Setting time 0.5 to 30.0 s (see note)
Operating time accuracy ±5% FS max.
Setting error ±15% FS max.
Reset time 5 s min.
Influence of temperature ±10% FS max.
Operating mode (set via DIP switch) ON-delay, OFF-delay, Startup lock
SDV-F@/-FH@T
Location of DIP switch to
set operating modes
Setting Operating
Value
Operation Indicator (LED)
Function Sticker
Voltage Multiplying
Factor Sticker
Setting Reset Value
Setting Operating Time
Setting Intermediate
Voltage of Dead Band Setting Dead
Band Voltage
Operation Indicator
SDV-D@
The diagram on
the right shows
the SDV-FH6T
when used for
undervoltage
detection for
DC input.
Function Sticker Voltage Multiplying
Factor Sticker
Location of DIP switch to
set operating modes
The diagram above shows the
SDV-DH3 when used for AC input
in the range 100 to 300 V.
Note: The SDV-F@ is not equipped with a time setting knob.
SDV
6
Operation
■Timing Charts
Single-function Models
Overvoltage Detection Undervoltage Detection
Operating
value
Input
Reset value
Output relay
Input
Reset value
Operating
value
Output relay
ON
OFF ON
OFF
Note
The reset time must be 5 s or longer to ensure accuracy of the timing operation.
Single-function Model with Timing Function
SDV-FH@T
ON-delay Overvoltage Detection
Operating
value
Input
Output relay
Setting timeSetting time Setting time
Reset value
Output relay
Input
Operating
value Reset value
Reset time
(5 s min.)
ON-delay Undervoltage Detection
Output relay
Input
Operating
value
Reset value
Reset time
(5 s min.)
Setting timeSetting time Setting time
Input
Operating
value
Output relay
Reset value
ON
OFF
ON
OFF
ON
OFF
Setting time
Setting time
SDV
7
Note: The output relays will be forced OFF from the control power supply is turned ON until the set time has expired.
OFF-delay Overvoltage Detection
OFF-delay Undervoltage Detection
Output relay
Input
Operating
value
Reset value
Reset time
(5 s min.)
Operating
value
Input
Output relay
Setting timeSetting time Setting time
Reset value
Operating
value
Input
Output relay
Setting timeSetting time Setting time
Reset value
Output relay
Input
Operating
value
Reset value
Reset time
(5 s min.)
Startup Lock
Power
Output operation
Setting time
Power
Reset time
(5 s min.)
ON
OFF
ON
OFF
ON
OFF
ON
OFF
ON
OFF
ON
OFF
Setting time
Setting time
Dual-function Models
SDV-D
Input
Intermediate
voltage of
dead band
Dead band voltage
Dead band voltage
Undervoltage
relay
Overvoltage
relay
ONON
H
L
SDV
8
■Setting
(Refer to Examples of Mode Settings for details on individual models.)
Set the desired values using the DIP switch and setting knobs on the front panel.
Opening the DIP Switch Cover
Remove the cover of the compartment containing the DIP switch for various mode settings, and then set the DIP switch according to the SWITCH
SELECTION table affixed to the side of the voltage sensor.
Setting the DIP Switch
Set the DIP switch on the front panel for the required functions, operation inputs, and voltages. Set the switch to the top for ON settings and to the
bottom for OFF settings.
•Function (SDV-F): Set to either overvoltage or undervoltage detection.
•Input: Set to either AC or DC input.
•Polarity (SDV-FL@ only): Set polarity or not to specify polarity.
“8(+), 7(–)”: Use polarity as shown for pin number.
“FREE”: Do not use polarity.
•Multiplying Factor: Set the voltage scale multiplying factor for the required operating voltage setting range.
•TIMER (SDV-FH@T): Select the timing function.
Set ON-delay, OFF-delay, lock timer (start lock timer), or TIMER OFF.
If TIMER OFF is set, the timing function will not be effective, and the single-function operation will be performed.
Setting of Time (SDV-FH@T Only)
Use the time setting knob to set the desired time.
Closing the DIP Switch Cover
Attach the cover to the compartment housing the DIP switch. Select the stickers for the settings that have been made and attach them to the cover.
Setting Flowchart
Cover
Flat-blade
screwdriver
Flat-blade screwdriver
Cover
Select model based on operation and type of input.
Single-function Model Dual-function Model
Determine detection method, polarity setting, operating value,
and reset value.
Determine intermediate voltage of dead band and dead band
voltage.
Determine reset value according to dead band voltage.
Obtain the PICK UP index scale value, HOLD index scale
value, and voltage multiplying factor.
Set the knob and the DIP switch, and attach stickers.
Set the desired operating mode for the SDV-FH@T.
Obtain the BALANCE index scale value, BAND WIDTH index
scale value, and voltage multiplying factor.
Set the knob and the DIP switch, and attach stickers.
SDV
9
SDV-FL@
Switch Selection Table
Accessory Labels
SDV-FM@
Switch Selection Table
Accessory Labels
SDV-FH@
Switch Selection Table
Note: “NO USE” indicates that DIP switch setting is not required and
the positions of these switches are irrelevant to the operation of
the voltage sensor.
Accessory Labels
Switch
Function Under
Over
Polarity 8 (+) 7 (–)
Free
Multiplying
factor
x 4 mV →
x 10 mV →
x 20 mV →
x 40 mV →
x 80 mV →
ON ●1234 5 6
OFF
●
●
●
●
●
●
OVER
POL FREE
×4 mV
×
10 mV
×
20 mV
×
40 mV
×
80 mV
OVER
8 (+)
POL7 (−)
UNDER
8 (+)
POL7 (−)
UNDER
POL FREE
Switch
Function Under
Over
Input AC (20 to 500 Hz)
DC
Multiplying
factor
x 0.2 V →
x 0.5 V →
x 1 V →
x 2 V →
x 4 V →
ON ●1234 5 6
OFF
●
●
●
●
●
●
OVER
INPUT DC
INPUT DC
INPUT AC
INPUT AC
×0.2 V
×0.5 V
×
1 V
×
2 V
×
4 V
OVER
UNDER
UNDER
Switch
Function Under
Over
Input AC (20 to 500 Hz)
DC
Multiplying
factor
x 10 V →
x 25 V →
x 50 V →
x 100 V →
ON ●1234 5 6
OFF
●
NO USE
(see note)
●
●
●
●
OVER
INPUT DC
INPUT DC
INPUT AC
INPUT AC
×10 V
×25 V
×50 V
×
100 V
OVER
UNDER
UNDER
SDV
10
SDV-FH@T
Switch Selection Table
Note: “NO USE” indicates that DIP switch setting is not required and the positions of these switches are irrelevant to the operation of the voltage
sensor.
SDV-DM@
Switch Selection Table
Accessory Labels
SDV-DH@
Switch Selection Table
Note: “NO USE” indicates that DIP switch setting is not required and
the positions of these switches are irrelevant to the operation of
the voltage sensor.
Accessory Labels
Switch
Function Under
Over
Input AC (20 to 500 Hz)
DC
Multiplying
factor
x 10 V →
x 25 V →
x 50 V →
x 100 V →
Timer ON-delay →
OFF-delay →
Lock timer →
Timer OFF →
Accessory Labels
OVER
INPUT DC
INPUT DC
INPUT AC
INPUT AC
×10 V
×25 V
×50 V
×
100 V
OVER
UNDER
UNDER
ON ●1234 5 6 7 89 10
OFF
●
NO USE
(see note)
NO USE
(see note)
●
●
●
●
● ● ●
● ●
●
Switch
Input AC (20 to
500 Hz)
DC
Multiplying
factor
x 0.2 V →
x 0.5 V →
x 1 V →
x 2 V →
x 4 V →
ON ●1234 5
OFF
●
●
●
●
●
OVER&
UNDER
OVER&
UNDER
INPUT DC
INPUT AC
×0.2 V
×0.5 V
×
1 V
×
2 V
×
4 V
Switch
Input AC (20 to
500 Hz)
DC
Multiplying
factor
x 10 V →
x 25 V →
x 50 V →
x 100 V →
ON ●1234 5
OFF
●
NO USE
(see note)
●
●
●
OVER&
UNDER
OVER&
UNDER
INPUT DC
INPUT AC
×10 V
×25 V
×50 V
×
100 V
SDV
11
■Examples of Mode Setting
Example 1
Example 2
For the single-function SDV-FH6, the setting method given below would be used to detect overvol-
tages with a DC voltage input. The operating value is 15 V and the reset value is 12 V.
Step 1. To set the detection method and type of input on the DIP switch.
Turn OFF pin 1 (function) to specify overvoltage detection.
Turn OFF pin 2 (input) to specify a DC input.
Attach the OVER INPUT DC stickers.
Voltage multiplying factor setting: The voltage multiplying factor is selected according to the
maximum and minimum factors and a sticker is attached.
The calculation method is as follows:
The PICK UP index scale value is between 1.0 and 3.0, so calculate the voltage multiplying
factor for both 1.0 and 3.0.
15 V (Operating value)/1 (PICK UP index scale value) = 15 (Maximum multiplying factor)
15 V (Operating value)/3 (PICK UP index scale value) = 5 (Minimum multiplying factor)
In this example, pins 3 to 5 are turned OFF and the x10V sticker is attached.
PICK UP index scale value setting: The calculation method is as follows (X = index scale):
10 (Voltage multiplying factor) x X = 15 V (Operating value)
Therefore, X = 1.5
Turn the PICK UP knob to 1.5.
12 V (reset value) = 15 V (operating value) x (1 − Y) Therefore, Y = 0.2
Set the HOLD knob to 20 (%).
SDV-F@@
Step 3. To set the reset value (Y = HOLD index scale value): Calculate the HOLD percentage as
follows:
Step 2. To set the operating value according to the voltage multiplying factor and the PICK UP
index scale value.
For the single-function SDV-FH6T, the setting method given below would be used to detect undervol-
tages with a DC voltage input. The operating value is 20 V and the reset value is 20.4 V. An ON-delay
operation is specified and the setting time is 30 s.
Step 1. To set the detection method and type of input on the DIP switch.
Turn ON pin 1 (function) to specify undervoltage detection.
Turn OFF pin 2 (input) to specify a DC input.
Attach the UNDER INPUT DC stickers.
Step 2. To set the operating value according to the voltage multiplying factor and the PICK UP
index scale value.
Voltage multiplying factor setting: The multiplying factor is selected according to the maxi-
mum and minimum factors and a sticker is attached. The calculation method is as follows:
The PICK UP index scale value is between 1.0 and 3.0, so calculate the voltage multiplying
factor for both 1.0 and 3.0.
20 V (Operating value)/1 (PICK UP index scale value) = 20 (Maximum multiplying factor)
20 V (Operating value)/3 (PICK UP index scale value) = 6.7 (Minimum multiplying factor)
In this example, pins 3 to 5 are turned OFF and the x10V sticker is attached.
PICK UP index scale value setting: The calculation method is as follows (X = index scale):
10 (Voltage multiplying factor) x X = 20 V (Operating value)
Therefore, X = 2
Turn the PICK UP knob to 2.0.
Step 3. To set the reset value (Y = HOLD index scale value): Calculate the HOLD percentage as
follows:
20.4 V (reset value) = 20 V (operating value) x (1 + Y) Therefore, Y = 0.02
Set the HOLD knob to 2 (%).
Step 4. To set setting time and operating mode.
Set the time setting knob to 30 s and turn the pins 7 to 9 ON to specify ON-delay operation.
SDV-FH@T
SDV
12
Example 3
■Shunts (Order Separately)
A shunt is a resistor to convert a DC current into a DC voltage. Use
the shunt in combination with SDV-FL to detect undercurrent, reverse
current and overcurrent in DC circuits.
Note: Select a shunt whose rated current is more than 120% of the
current normally flowing in a circuit. The characteristics of the
shunt may change or fusing of a resistor element may occur if
an overload that is 1,000% of the rated current is applied.
Therefore, determine the rated current of the shunt to be used,
by taking the circuit conditions into account.
For the dual-function SDV-DH3, the setting method given below would be used to detect over and
undervoltage with an AC voltage input. The intermediate voltage of dead band is 250 V and the dead
band voltage is 20 V.
Step 1. To set the detection method and type of input on the DIP switch.
Turn ON pin 1 (input) to specify a AC input.
Attach the OVER and UNDER INPUT AC stickers.
Step 2. To set the intermediate voltage of dead band according to the BALANCE index scale
value and the voltage multiplying factor.
Voltage multiplying factor setting: The voltage multiplying factor is selected according to the
maximum and minimum factors and a sticker is attached. The calculation method is as fol-
lows:
250 V (Intermediate voltage of dead band)/1 (BALANCE index scale value)
= 250 (maximum multiplying factor)
250 V (Intermediate voltage of dead band)/3 (BALANCE index scale value)
= 83.3 (maximum multiplying factor)
In this example, pins 2 and 3 are turned OFF and pins 4 is turned ON, and the x100V sticker
is attached.
BALANCE index scale value setting: The calculation method is as follows for the BALANCE
index scale value (X = index scale):
100 (Voltage multiplying factor) x X = 250 V (intermediate voltage of dead band)
Therefore, X = 2.5
Turn the BALANCE knob to 2.5.
Step 3. To set dead band voltage according to the voltage multiplying factor and BAND WIDTH
index scale value.
BAND WIDTH index scale value setting:
Z (BAND WIDTH index scale value) x 100 V (voltage multiplying factor) = 20 V (dead band
voltage) Therefore, Z = 0.2
Set the DEAD WIDTH knob to 0.2.
Step 4. Reset value for each detection setting: Automatically set according to the dead band
voltage setting.
Reset values are calculated for overvoltage detection and undervoltage detection.
Overvoltage detection: Reset value = (250 V + 20 V) − (20 V x 2/3) = 256.7 min.
Undervoltage detection: Reset value = (250 V − 20 V) + (20 V x 2/3) = 243.3 max.
SDV-D@@
The BALANCE index scale value is between 1.0 and 3.0, so calculate the voltage multiply-
ing factor for both 1.0 and 3.0.
Output voltage (mV)
Input current (A)
Characteristics
SDV-SH5A (Rated Current: 5 A)
Shunt rated
at 60 mV
60
5
SDV
13
■Application Example
Current Detection Using the Shunt (SDV-FL)
Voltage Detection (SDV-FM/FH/FH@T/-DM/-DH)
Overload Detection (A) Overload Detection (B)
Example: Overload detection in a distribution switch
board installed in a power substation.
Example: Overload detection in equipment such as a motor in a
rolling mill when the polarity of the applied voltage to
the motor is reversed.
DC power
supply for
distribution
board
SDV-SH
shunt
SDV-FL
(with or without polarity)
Distribution
switchboard
SDV-SH
shunt
DC motor
SDV-FL
(without polarity)
(−)
(+)
or
(+) (−)
(−) (+)
M
_
Power
supply
Reverse Current Detection (A) Reverse Current Detection (B)
Example: Detection of an output current from a transmitter on
a control panel.
SDV-FL
(with or without polarity)
Power supply
for transmitter
4 to 20mA
Quantity of
low, airflow,
wattage, etc.
Transmitter
10 Ω or more
(−)
(+)
SDV-SH
shunt
DC motor
SDV-FL
(with polarity)
M
_
(−)
(+)
DC power
supply
Example:
Detection when a DC motor is used
as a generator (or a generator is
used as a motor).
Voltage Regulation Operation Lock Due to Voltage Drop (Alarm)
Example: Voltage regulation of a power supply unit in the dis-
tribution switchboard installed in a power substation.
Example: Function lock due to voltage drop in a machine or
equipment (alarm).
Thyristor
power
supply
Distribu-
tion
switch
board
Command
signal for
regulation
3 dia.
Machine
or equip-
ment
Command
signal for
operation
lock
SDV-FH/SDV-FH@T
with ON-delay operation
(undervoltage detection)
SDV-DH
(+)
(−)
SDV
14
Non-utility generator
Detection of
power failure
Engine
Drive command
(Starts/Stop)
Exciter
Voltage regula-
tion (rotation
control)
Power supply
Detection of power failure or trans-
former trouble (for the DC lighting
command in emergency illumination)
Detection of battery
overdischarge
Distribution board for general illumination
Detection of partial power
failure (for the lighting
command in emergency
illumination)
Distribution board for
emergency illumination Emergency illumination
output
SDV-FH (undervol-
tage detection)
SDV-FH (undervoltage
detection)
SDV-FH/SDV-FH@T
with ON-delay operation
(undervoltage detection)
SDV-FH (undervoltage
detection)
Emergency Power Supply (e.g. Standard Power Receiving/Distributing Facility)
SDV-DH
G
SDV
15
Three-phase AC Current Detection Using Current Converter
Current Converters (Order Separately)
Voltage Monitoring in Rectifiers (Chargers) with ON-delay Operation
Example: To detect only overvoltage and not detect voltages for instantaneous load changes (ON/OFF).
Example: Machine motor control, overload detection,
undercurrent detection.
SET Current Converter
SDV-DH
SDV-FH
SDV-FH@T
SDV-FM
Model Current range
SET-3A 1 to 80 A
SET-3B 64 to 160 A
Three-phase AC Current Detection with Startup Lock Operation
(When Using Same Power Supply for Motor and Control Power Supply)
SET Current Converter
Control power supply
SDV-FH@T
Load
Load
SDV-FH@T
undervoltage detection
Rectifier
SDV-FH@T
overvoltage detection
Note: Detection of excessive or insufficient charge in rectifiers (chargers).
SDV
16
■Q&A
Q: What is necessary to detect undervoltages when using the same power supply for the input voltage and the control
power supply?
A: The NO contact of the output relay is used for undervoltage detection. Even if the control voltage drops to 85% of
the rated voltage (AC power), the operation of the relay can be maintained. Set the mode setting on the DIP switch
to overvoltage detection and set the reset value to the value to be detected. Set the operating value of the SDV to
a value higher than the reset value.
Q: Will the SDV be damaged if the input setting (AC/DC) is incorrect. If not, what will happen?
A: The SDV will not be damaged, but the operating value and reset value will not be accurate. These values will be
about 10% less than the set values if DC is input for an AC setting and about 10% off to the positive side if AC is
input for a DC setting.
Q: Can the negative pole of a DC voltage be input to the SDV?
A: Yes. An absolute rectifier circuit is used in the SDV-F to enable negative pole input. The SDV-FL has a polarity
setting, which can be set to (+)(–) to disable operation with negative voltages. Positive/Negative settings cannot
be used for the dual-function SDV-D even if the intermediate voltage of dead band is set to 0. Negative inputs can-
not be used for the SDV-D.
Q: Is instantaneous detection faster than 0.5 s possible?
A: Use the S87A Power Interruption Detector for instantaneous detection (10 ms or 20 ms).
SDV-F (undervoltage detection)
Load
SDV
17
Dimensions
Note: All units are in millimeters unless otherwise indicated.
■Main Body
■Shunts
SDV-F@@/SDV-FH@T
SDV-D@@
Connecting Socket
3.5
5
60 89
7
100
7291
8.5
8PFA1 (order separately)
SDV-F
119
PL08 (order separately)
100
16
SDV-F
89 7
100
8.5
5
3.5
6079
72
14PFA (order separately)
SDV-D
128.5
PL15 (order separately)
100
16
SDV-D
Model A B C D E F G
SDV-SH75 140 120 25 10.5 6 18 36
SDV-SH100 140 120 25 10.5 6 18 36
SDV-SH150 140 120 25 10.5 6 18 43
SDV-SH200 140 120 25 10.5 6 18 43
SDV-SH5 to SDV-SH50 (60-mV Rating)
Current terminal: M6 screw
Voltage terminal: M4 screw
SDV-SH75 to SDV-SH200 (60-mV Rating)
Current terminal: M8 screw
Voltage terminal: M4 screw
10.5 dia.
5.5
dia. 5.5
dia.
140
120
25
18
6
33
A
B
C
F
G
D
E
SDV
18
Note: Inquire about models with a rated current of 1,500 A or larger.
■Accessories (Order Separately)
Front Connecting Socket
Model A B C D E Resistor
SDV-
SH300
130 30 110 4 36 4
SDV-
SH500
160 40 120 6 41 5
SDV-SH300/-SH500 (60-mV Rating)
Current terminal: M10 screw (SDV-SH300),
M12 screw (SDV-SH500)
Voltage terminal: M4 screw
A
B
C
D
E
Model A B C D E
SDV-
SH750
175 45 130 15 30
SDV-
SH1000
175 60 135 18 30
SDV-SH750/-SH1000 (60-mV Rating)
Current terminal: M12 screw
Voltage terminal: M5 screw
A
B
C
DE
5
8PFA1
Terminal Arrangement
(Top View)
Mounting Holes
Two, M4 or 4.5-dia. holes
Eight, M3.5 x 7
sems
Two, 4.5-dia.
holes
93 max.
51 max.
24 max.
130 max.
14PFA
Fourteen,
M3.5 x 7 sems
81 max.
72 max.
Two,
4.5-dia.
holes
33.5 max.
118 max.
Two, M4 or 4.5-dia. holes
Terminal Arrangement
(Top View)
Mounting Holes
SDV
19
Back Connecting Socket (Solder Terminal)
PL08
Terminal Arrangement
(Bottom View)
Mounting Holes
PL15
Terminal Arrangement
(Bottom View)
Mounting Holes
Two, 3.5-dia. or
two, M3 socket
mounting holes
50.5 max.
35 max.
30 dia.
Approx. 20.5
Two, 2-dia. holes
Two, M3 or two, 3.5-dia.
voltage sensor mounting
holes
Two, M3 or Two, 3.5-dia.
socket mounting holes
42-dia. hole
22 max.
66 max. 41 max.
Two, 2-dia. holes
31-dia.
hole
45 max.
Mounting Track
PFP-100N
PFP-50N
4.5
15 25 25 25 25
10 10
1,000 (500)*
7.3+0.15
35+0.3 27+0.15
1
15 (5)*
*PFP-50N
4.5
15 25 25 25 25 15
10 10
1,000
35+0.3 27 24
16
29.2
1 1.5
PFP-100N2
End Plates
PFP-M
50
11.5
M4 x 8 pan
head screw
10
6.2 1.8
135.5 35.3
1.8
1.3
4.8
M4 spring
washer 5
16
12
44.3 34.8
16.5
Spacers
PFP-S
SDV
20
Installation
■Internal Circuit
Input and power supply circuits are electrically isolated as protection against mutual interference.
SDV-F@@/SDV-FH@T
SDV-D
Note: 1. There is no polarity setting for the SDV-FM or SDV-FH/-FH@T.
2. There is no power supply polarity setting when using a DC control power supply for the SDV.
3. The polarity selection switch (SW2) is on the SDV-FL.
4. The AC/DC switch (SW2) is on the SDV-FM and SDV-FH/-FH@T.
Note: 1. There is no power supply polarity setting when using a DC control power supply for the SDV.
2. There is no polarity setting for DC inputs.
voltage circuit
Reference
Range selector switches
Polarity selector switch
(SW2)
(see note 3)
Power
supply
circuit
Power
supply
circuit
To
each
circuit Chopper
circuit
Overvoltage/
Undervoltage
selector switch
SW1
Output relay
Comparator
circuit
Power circuit
Inverter circuit
Amplifier circuit
Releasing value
setting circuit
Timer time
setting circuit
Buffer circuit
Absolute value
rectifier circuit
Operating value
setting circuit
AC/DC selector
switch SW2
(see note 4)
Startup lock
reference
voltage circuit
Inverter circuit
Comparator
circuit
Buffer circuit
DC Power supply circuit
AC Power supply circuit
Input
Quick charge/
discharge circuit
To
each
circuit
Reference
voltage circuit
Power
supply
circuit
Power
supply
circuit
To
each
circuit
To
each
circuit
Dear band
setting circuit
Range selector switches
AC/DC selector
switch SW1
Amplifier circuit
Chopper
circuit
AC Power supply circuit
DC Power supply circuit
Smoothing
circuit
Power circuit
voltage circuit
Reference
Power circuit
voltage circuit
Reference
Input
Output relay for
overvoltage
detection
Addition circuit
Comparator
circuit(High)
Power
supply
Power
supply
Output relay for
overvoltage
detection
Output relay for
undervoltage
detection
Comparator
circuit(Low)
Absolute value
rectifier circuit
Note: The SDV-FH@T contains
the circuit outlined with the
dotted line.
SW6
SW7
SW9
SW5 SW4 SW3
X/c
8
7
5
X
4
2
1
3
SW8
VR
2
1
Power
supply
Power
supply
SW5 SW4 SW3 SW2
XL/a
XL/b
XH/b
XH/a
15
XL
10
12
5
4
2
1
2
1
3
6
7
8
9
XH
SW1
Smoothing
circuit
SDV
21
Safety Precautions
Approximately 0.5 s is required for operation. When confirming the
operating value, gradually change the input voltage while checking
the value.
Power supply voltage fluctuations and the ambient operating temper-
ature must be maintained within the allowable ranges. Be particularly
careful not to apply an overvoltage beyond the specified range for the
voltage detection.
Do not use the SDV in locations subject to corrosive or explosive
gases.
The SDV cannot be used to detect momentary power interruptions
because of its response time. Use the S87A to detect momentary
power interruptions.
An SDV cannot be used with a circuit containing thyristors, or VVVF
inverters, because these elements can change the output waveform
to the point that the SDV will malfunction.
Mounting
When mounting with the PL08 or PL15 Back Connection Socket,
insert the Socket into a 1- to 4-mm panel from the back and secure it
with screws. Do not mount the SDV until the Socket has been
mounted firmly. Be sure that the key groove on the Socket is
mounted on the bottom, and also secure the SDV to the panel with
screws.
When mounting with the 8PFA or 14PFA Back Connection Socket,
insert the SDV into the Socket and secure it with the hooks. Leave
approximately 30 mm or more between Sockets to allow enough
space for the hooks.
When mounting more than one SDV, allow at least 30 mm or more
between them.
S87A Power Interruption Detector
In the interest of product improvement, specifications are subject to change without notice.
ALL DIMENSIONS SHOWN ARE IN MILLIMETERS.
To convert millimeters into inches, multiply by 0.03937. To convert grams into ounces, multiply by 0.03527.
Read and Understand This Catalog
Please read and understand this catalog before purchasing the products. Please consult your OMRON representative if you have any questions or
comments.
Warranty and Limitations of Liability
WARRANTY
OMRON's exclusive warranty is that the products are free from defects in materials and workmanship for a period of one year (or other period if specified)
from date of sale by OMRON.
OMRON MAKES NO WARRANTY OR REPRESENTATION, EXPRESS OR IMPLIED, REGARDING NON-INFRINGEMENT, MERCHANTABILITY, OR
FITNESS FOR PARTICULAR PURPOSE OF THE PRODUCTS. ANY BUYER OR USER ACKNOWLEDGES THAT THE BUYER OR USER ALONE HAS
DETERMINED THAT THE PRODUCTS WILL SUITABLY MEET THE REQUIREMENTS OF THEIR INTENDED USE. OMRON DISCLAIMS ALL OTHER
WARRANTIES, EXPRESS OR IMPLIED.
LIMITATIONS OF LIABILITY
OMRON SHALL NOT BE RESPONSIBLE FOR SPECIAL, INDIRECT, OR CONSEQUENTIAL DAMAGES, LOSS OF PROFITS OR COMMERCIAL LOSS
IN ANY WAY CONNECTED WITH THE PRODUCTS, WHETHER SUCH CLAIM IS BASED ON CONTRACT, WARRANTY, NEGLIGENCE, OR STRICT
LIABILITY.
In no event shall the responsibility of OMRON for any act exceed the individual price of the product on which liability is asserted.
IN NO EVENT SHALL OMRON BE RESPONSIBLE FOR WARRANTY, REPAIR, OR OTHER CLAIMS REGARDING THE PRODUCTS UNLESS
OMRON'S ANALYSIS CONFIRMS THAT THE PRODUCTS WERE PROPERLY HANDLED, STORED, INSTALLED, AND MAINTAINED AND NOT
SUBJECT TO CONTAMINATION, ABUSE, MISUSE, OR INAPPROPRIATE MODIFICATION OR REPAIR.
Application Considerations
SUITABILITY FOR USE
OMRON shall not be responsible for conformity with any standards, codes, or regulations that apply to the combination of products in the customer's
application or use of the products.
At the customer's request, OMRON will provide applicable third party certification documents identifying ratings and limitations of use that apply to the
products. This information by itself is not sufficient for a complete determination of the suitability of the products in combination with the end product,
machine, system, or other application or use.
The following are some examples of applications for which particular attention must be given. This is not intended to be an exhaustive list of all possible
uses of the products, nor is it intended to imply that the uses listed may be suitable for the products:
Outdoor use, uses involving potential chemical contamination or electrical interference, or conditions or uses not described in this catalog.
Nuclear energy control systems, combustion systems, railroad systems, aviation systems, medical equipment, amusement machines, vehicles,
safety equipment, and installations subject to separate industry or government regulations.
Systems, machines, and equipment that could present a risk to life or property.
Please know and observe all prohibitions of use applicable to the products.
NEVER USE THE PRODUCTS FOR AN APPLICATION INVOLVING SERIOUS RISK TO LIFE OR PROPERTY WITHOUT ENSURING THAT THE
SYSTEM AS A WHOLE HAS BEEN DESIGNED TO ADDRESS THE RISKS, AND THAT THE OMRON PRODUCTS ARE PROPERLY RATED AND
INSTALLED FOR THE INTENDED USE WITHIN THE OVERALL EQUIPMENT OR SYSTEM.
PROGRAMMABLE PRODUCTS
OMRON shall not be responsible for the user's programming of a programmable product, or any consequence thereof.
Disclaimers
CHANGE IN SPECIFICATIONS
Product specifications and accessories may be changed at any time based on improvements and other reasons.
It is our practice to change model numbers when published ratings or features are changed, or when significant construction changes are made.
However, some specifications of the products may be changed without any notice. When in doubt, special model numbers may be assigned to fix or
establish key specifications for your application on your request. Please consult with your OMRON representative at any time to confirm actual
specifications of purchased products.
DIMENSIONS AND WEIGHTS
Dimensions and weights are nominal and are not to be used for manufacturing purposes, even when tolerances are shown.
PERFORMANCE DATA
Performance data given in this catalog is provided as a guide for the user in determining suitability and does not constitute a warranty. It may represent the
result of OMRON’s test conditions, and the users must correlate it to actual application requirements. Actual performance is subject to the OMRON
Warranty and Limitations of Liability.
ERRORS AND OMISSIONS
The information in this document has been carefully checked and is believed to be accurate; however, no responsibility is assumed for clerical,
typographical, or proofreading errors, or omissions.
2011.12
In the interest of product improvement, specifications are subject to change without notice.
OMRON Corporation
Industrial Automation Company
http://www.ia.omron.com/
(c)Copyright OMRON Corporation 2011 All Right Reserved.
