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SENSITRON SEMICONDUCTOR
TECHNICAL DATA DATASHEET 5002, Rev B
SPDPXXD28 SERIES
DC Solid State Power Controller Module
Description:
These Solid State Power Controller (SSPC) Modules are designed to operate without any heatsink requirements. They are microcontroller-based Solid State Relays rated up to 40A designed to be used in high reliability 28V DC applications. These modules have integrated current sensing with no derating over the full operating temperature range. These modules are the electronic equivalent to electromechanical circuit breakers with isolated control and status. This series is supplied in 4 SSPC families, with each family being programmable over a 2:1 current range: SPDP05D28: Programmable from 2.5A to 5A SPDP12D28: Programmable from 6A to 12A SPDP25D28: Programmable from 12.5A to 25A SPDP40D28: Programmable from 20A to 40A
Compliant Documents & Standards:
MIL-STD-1275B, Notice1 MIL-STD-704F MIL-STD-217F, Notice 2 Characteristics of 28 Volt DC Electrical Systems in Military Vehicles-4/20/04 Aircraft Electrical Power Characteristics 12 March 2004 Reliability Prediction of Electronic Equipment 28 Feb 1995
* * * * * * *
Module Features:
No additional heat sinking or external cooling required! Extremely Low Power, No Derating Over the Full Temperature Range Low Weight (20 gms up to 25A and 40 gms for SPDP40D28) Same Pin Out as Industry Standard SSPCs in a Smaller Outline Epoxy Shell Construction Solid State Reliability High Power Density
Electrical Features (SPDPxxD28 Series):
* * * * * * * * * * * * * 28VDC Input with Very Low Voltage Drop; 76mV, typ. @15A for SPDP25D28 True I2t Protection up to 10X rating with Nuisance Trip Suppression Instant Trip Protection (50 sec typ) for Loads Above 10X rating Unlimited Interrupt Capability; Repetitive Fault Handling Capability Thermal Memory Internally Generated Isolated Supply to Drive the Switch Low Bias Supply Current: 25 mA typ @ 5V DC High Control Circuit Isolation: 750V DC Control to Power Circuit Soft Turn-On to Reduce EMC Issues EMI Tolerant Module Reset with a Low Level Signal; Reset Circuit is Trip-Free TTL/CMOS Compatible, Optically Isolated, Input and Outputs Schmitt-Trigger Control Input for Noise Immunity * 221 West Industry Court Deer Park, NY 11729-4681 Phone (631) 586 7600 Fax (631) 242 9798 * * World Wide Web - http://www.sensitron.com * E-Mail Address - sales@sensitron.com * Page 1
SENSITRON SEMICONDUCTOR
TECHNICAL DATA DATASHEET 5002, Rev B
SPDPXXD28 SERIES
Table 1 - Electrical Characteristics (at 25 oC and Vbias = 5.0V DC unless otherwise specified) Control & Status (TTL/CMOS Compatible)
BIAS (Vcc) BIAS (Vcc) Current GATE Status, Load Status Signals CONTROL Signal VT+ (Positive-going input threshold voltage) VT- (Negative-going input threshold voltage) VT Hysteresis (VT+ VT-) Reset 5.0V DC Nominal, 6.5V DC Absolute Maximum 4.5V to 5.5 VDC 25 mA typ 30 mA, max Voh=3.7V, min, at Ioh=-20mA Vol=0.4V, max, at Iol=20mA 2.0V, min, 3.5V, max 1.2V, min, 2.3V, max 0.6V, min, 1.4V, max Cycle CONTROL Signal
Power
Input Voltage - Continuous - Transient Power Dissipation Current Max Voltage Drop Max current without tripping Trip time Output Rise Time (turn ON) Output Fall Time under normal turn-off Output Fall Time under Fault Min Load Requirement 0 to 40V DC, 50V DC Absolute Maximum +600V or -600V Spike (< 10 uS) See Table 5 See Table 5 See Figure 1, Trip Curve See Table 5 110% min See Figure 1, Trip Curve 110 sec typ 110 usec typ 50 usec typ Nil
Protection
Short Circuit Protection Instant Trip Unlimited 800%, min; 1200%, max
Table 2 - Physical Characteristics Temperature
Operating Temperature Storage Temperature TA = -55 C to +100 C TA = -55 C to +125 C
Environmental
Altitude Case Dimensions Operating Orientation Weight MTBF (Estimate: MIL STD 217F) Up to 30,000 ft Can be installed in an unpressurized area 1.825"L x 1.25"W x 0.38"H for SPDP05D28, SPDP12D28 and SPDP25D28 1.825"L x 1.25"W x 0.70"H for SPDP40D28 Any 20 grams typ (40 grams typ for SPDP40D28) 1.1 Mhrs at 25C Full load for SPDP05D28, SPDP12D28 and SPDP25D28 0.8Mhrs at 25C for SPDP40D28
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SENSITRON SEMICONDUCTOR
TECHNICAL DATA DATASHEET 5002, Rev B
SPDPXXD28 SERIES
Figure 1 - Trip Curve
Figure 2 - Timing Diagram
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SENSITRON SEMICONDUCTOR
TECHNICAL DATA DATASHEET 5002, Rev B
SPDPXXD28 SERIES
Table 3 - Signal Timing - (-55 oC to 100 oC @ LINE = 28V DC)
Parameter CONTROL to GATE Status Delay for Turn On Turn ON Delay Load Current Rise Time Turn ON to LOAD Status Delay CONTROL to GATE Status Delay for Turn Off Turn OFF Delay Load Current Fall Time Turn OFF to LOAD Delay Symbol t0 t1 t2 t3 t4 t5 t6 t7 Min Max 1 200 200 1 1 200 200 1 Units ms s s ms ms s s ms
50
50
Note: Current Fall Time from trip dependent on magnitude of overload
Figure 3 - Mechanical Dimensions for SPDP05D28, SPDP12D28 and SPDP25D28
All dimensions are in inches
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SENSITRON SEMICONDUCTOR
TECHNICAL DATA DATASHEET 5002, Rev B
SPDPXXD28 SERIES
Figure 4 - Mechanical Dimensions for SPDP40D28
All dimensions are in inches
Table 4 - Pin Definitions
Pin Number 1 2 3 4 5 6 7 8 9 10 Pin Name BIAS GND GATE Status LOAD Status CONTROL Input LINE GAINRET PWRGND GAIN LOAD Function +5V DC Supply 5V Return Switch Status Load Current Detection On/Off Control +28V DC Supply Internally connected to LOAD (pin 10) 28V Return Gain Adjust Load Connection
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SENSITRON SEMICONDUCTOR
TECHNICAL DATA DATASHEET 5002, Rev B
SPDPXXD28 SERIES
Table 5 - Individual Model Ratings
SPDP05D28 Current Rating @ 100OC Power Dissipation Max Voltage Drop
SPDP05D28 Set for 2.5 Amp Rating
2.5A 0.20W typ @ 1.5A 25OC 0.24W max @ 2.5A 25OC 0.26W max @ 2.5A 100OC 17mV typ @ 1.5A 25OC 28mV max @ 2.5A 25OC 34mV max @ 2.5A 100OC
SPDP05D28 Set for 5 Amp Rating
5A 0.27W typ @ 3A 25OC 0.45W max @ 5A 25OC 0.51W max @ 5A 100OC 33mV typ @ 3A 25OC 55mV max @ 5A 25OC 68mV max @ 5A 100OC
SPDP12D28 Current Rating @ 100OC Power Dissipation Max Voltage Drop
SPDP12D28 Set for 6 Amp Rating
6A 0.28W typ @ 3.6A 25OC 0.47W max @ 6A 25OC 0.55W max @ 6A 100OC 29mV typ @ 3.6A 25OC 49mV max @ 6A 25OC 63mV max @ 6A 100OC
SPDP12D28 Set for 12 Amp Rating
12A 0.59W typ @ 7.2A 25OC 1.34W max @ 12A 25OC 1.69W max @ 12A 100OC 58mV typ @ 7.2A 25OC 97mV max @ 12A 25OC 126mV max @ 12A 100OC
SPDP25D28 Current Rating @ 100OC Power Dissipation Max Voltage Drop
SPDP25D28 Set for 12.5 Amp Rating
12.5A 0.58W typ @ 7.5A 25OC 1.31W max @ 12.5A 25OC 1.62W max @ 12.5A 100OC 45mV typ @ 7.5A 25OC 76mV max @ 12.5A 25OC 97mV max @ 12.5A 100OC
SPDP25D28 Set for 25 Amp Rating
25A 1.31W typ @ 15A 25OC 3.32W max @ 25A 25OC 4.21W max @ 25A 100OC 76mV typ @ 15A 25OC 126mV max @ 25A 25OC 162mV max @ 25A 100OC
SPDP40D28 Current Rating @ 100OC Power Dissipation Max Voltage Drop
SPDP40D28 Set for 20 Amp Rating
20A 0.45W typ @ 12A 25OC 0.93W max @ 20A 25OC 1.14W max @ 20A 100OC 23mV typ @ 12A 25OC 38mV max @ 20A 25OC 48mV max @ 20A 100OC
SPDP40D28 Set for 40 Amp Rating
40A 1.26W typ @ 24A 25OC 3.19W max @ 40A 25OC 4.02W max @ 40A 100OC 45mV typ @ 24A 25OC 75mV max @ 40A 25OC 96mV max @ 40A 100OC
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SENSITRON SEMICONDUCTOR
TECHNICAL DATA DATASHEET 5002, Rev B
SPDPXXD28 SERIES
Figure 5 - Electrical Block Diagram
GAIN
GAIN RTN
Description
Figure 5 shows the block diagram of the SPDPXXD28 SSPC Series. It uses a SN74LVC3G14 device for digital I/O. This TTL compatible device has a Schmitt-Trigger input to minimize the effects of noise on the input. Its outputs can each drive more than 10 standard TTL loads. It's also compatible with CMOS inputs and outputs. The SN74LVC3G14 is isolated from the remainder of the module circuitry by three optocouplers. The block labeled "Control & Protection Circuitry" gets power from the DC-DC converter and is referenced to the output of the SSPC. This block contains an amplifier to gain up the voltage developed across the sense resistor. It also contains a microcontroller with on-board timers, A/D converter, clock generator and independent watchdog timer. The microcontroller implements a precision I2t protection curve as well as an Instant Trip function to protect the wiring and to protect itself. It performs all of the functions of multiple analog comparators and discrete logic in one high-reliability component. The "Control & Protection Circuitry" block also has the ability to adjust the current rating of each model of the SPDPXXD28 Series over a 2:1 range. If the "Gain" terminal is left open, the SSPC will be set for maximum rating which is 25 Amps for the SPDP25D28, 12 Amps for the SPDP12D28 and 5 Amps for the SPDP05D28. If the "Gain" terminal is connected directly to the "Gain Return" terminal, the SSPC will be set for 1/2 of the maximum rating. Furthermore, a resistor connected between the "Gain" terminal and the "Gain Return" terminal will set a rating between maximum and 1/2 of maximum. See Figures 10 - 12 for the relationship between rating and resistor value for each model. * 221 West Industry Court Deer Park, NY 11729-4681 Phone (631) 586 7600 Fax (631) 242 9798 * * World Wide Web - http://www.sensitron.com * E-Mail Address - sales@sensitron.com * Page 7
SENSITRON SEMICONDUCTOR
TECHNICAL DATA DATASHEET 5002, Rev B
SPDPXXD28 SERIES
The code programmed in the microcontroller acquires the output of the internal A/D converter, squares the result and applies it to a simulated RC circuit. It checks the output of the simulated circuit to determine whether or not to trip (turn off the power Mosfets). Because the microcontroller simulates an analog RC circuit, the SSPC has `thermal memory'. That is, it trips faster if there had been current flowing prior to the overload than if there hadn't been current flowing. This behavior imitates thermal circuit breakers and better protects the application's wiring since the wiring cannot take as much an overload if current had been flowing prior to the overload. The watchdog timer operates from its own internal clock so a failure of the main clock will not stop the watchdog timer. The code programmed in the microcontroller will periodically reset the watchdog timer preventing it from timing out. If the code malfunctions for any reason, the watchdog timer is not reset and it times out. When the watchdog timer times out, it resets the microcontroller. Since the code is designed to detect levels and not edges, the output of the module, and therefore the output of the SPDPXXD28, immediately reflects the command on its input. The Power Mosfets used in the SPDPXXD28 Series have been selected for very low Rds(on) and results in low voltage drop and low power dissipation. In most applications, the SPDPXXD28 will be operated at 50 - 60% of rated current to provide a safety margin. As can be seen in Table 1, when the SPDP25D28 is operated at 15 Amps, 60% of rated current, it only dissipates 1.0 Watt at room temperature. No heatsinking is required for this condition. However, if the SPDP25D28 is to be operated at maximum rating and/or at elevated temperatures, the dissipation can exceed 4 Watts and heatsinking is required. Some heatsinking can be accomplished by adding copper area to the LINE and LOAD pins, a heatsink can be epoxied to the surface of the module or a flat copper or aluminum heatsink can be sandwiched between the SPDP25D28 and the printed circuit board using a thermal pad to maximize heat transfer. Each application should be evaluated at maximum expected constant current. The lower current models in the SPDPXXD28 Series do not require heat sinking under all conditions. For overloads, no heatsinking is required provided the SPDPXXD28 Series is allowed some time to cool down. The SPDPXXD28 has sufficient thermal mass that the temperature will rise only a few degrees under the worstcase overload. Repetitive overloads should be avoided. When the SPDPXXD28 reports a trip condition, the controller driving the SPDPXXD28 should allow no more than four repetitions and then allow thirty seconds to cool down before trying to turn on again. The SPDPXXD28 will trip on overloads in the ALWAYS TRIP region shown in Figure 1 and will never trip when in the NEVER TRIP region. The SPDPXXD28 can be reset by bringing the CONTROL pin to a logic low. When the CONTROL pin is brought back to logic high, the SPDPXXD28 will turn back on. If the overload is still present, the SPDPXXD28 will trip again. Cycling the 5 Volt BIAS power will also reset the SPDPXXD28. If the CONTROL pin is at logic high when the BIAS power is cycled, the SPDPXXD28 will turn back on when the BIAS power is re-applied.
Status Outputs
The LOAD and GATE status outputs of the SPDPXXD28 show whether or not the load is drawing current and Power Mosfet switch is on. A logic high on the LOAD status output shows that the load draws < 5% of rated load and a logic low shows that the load draws > 15% of rated current. A load that draws between 5% and 15% of rated current could result in either a high or low logic level on the LOAD status output. Logic high on the GATE output indicates that the Power Mosfet switch is on while a logic low indicates that the switch is off. As can be seen in Table 6, of the 8 possible states for the combination of CONTROL, LOAD and GATE, only 3 states represent valid SSPC operation. The other 5 states indicate either a failed SSPC or, more likely, a short to ground or a short to the BIAS supply of one of the logic outputs. By comparing the CONTROL input with the LOAD and GATE outputs, the user can determine whether or not the load is supposed to be ON (GATE), whether or not it's drawing current (GATE) and whether or not the LOAD and GATE outputs are valid responses to the CONTROL input. * 221 West Industry Court Deer Park, NY 11729-4681 Phone (631) 586 7600 Fax (631) 242 9798 * * World Wide Web - http://www.sensitron.com * E-Mail Address - sales@sensitron.com * Page 8
SENSITRON SEMICONDUCTOR
TECHNICAL DATA DATASHEET 5002, Rev B
SPDPXXD28 SERIES
Table 6 - CONTROL, LOAD & GATE Truth Table
State 1 2 3 4 5 6 7 8 CONTROL L L L L H H H H LOAD L L H H L L H H GATE L H L H L H L H Comments SSPC failure or shorted LOAD output to ground SSPC failure Normal OFF condition SSPC failure or shorted GATE output to BIAS supply SSPC failure or shorted GATE output to ground Normal ON condition with load current > 15% rated current Tripped Normal ON condition with load current < 5% rated current
Wire Size
MIL-W-5088L has a chart the shows wire size as a function of wire temperature and current. This chart is for a single copper wire in free air. For an ambient temperature of 70 oC, the chart allows an 18-gauge wire to handle 25 Amps continuously at a wire temperature of 200 oC - a wire temperature rise of 130 oC. For a wire temperature limited to 150 oC, the chart requires a 16-gauge wire and for a wire temperature of 105 oC, the chart requires a 14-gauge wire. Amendment 1 of MIL-W-5088L has a table for copper wire in a bundle, group or harness with condition on the number of wires, percent of total harness capacity, etc. This table shows that a 12 gauge wire is necessary for 200 oC operation, 10-gauge for 150 oC and 8-gauge for 105 oC. MIL-W-5088L has various figures showing derating for harnesses as a function of the number of current carrying conductors for different altitudes. MIL-W-5088L only specifies wire for DC or RMS AC conditions, not for transient or overload conditions. MIL-W-5088L and its amendment should be consulted to determine minimum wire sizes for other currents and conditions. For transient or overload conditions, the transient or overload happens so quickly that heat is not transferred from the wire to the surroundings. The heat caused by the I2R heating of the wire causes the temperature to rise at a linear rate controlled by the heat capacity of the wire. The equation for this linear rise in temperature, with respect to time, can be solved as: I2t = constant. Every wire has an I2t rating that's dependent on the temperature rise allowed and the diameter of the wire. If the I2t rating of the SSPC or circuit breaker is less than the I2t rating of the wire, then the SSPC or circuit breaker can protect the wire. The maximum I2t rating for the SPD2P05D28 is 7.45 x 103 Amp2-Seconds. Every wire size in the paragraphs above has an I2t rating that exceeds the SPDP25D28 I2t rating for the temperature rises stated. Therefore, to select a wire size, it's simply a matter of determining the maximum temperature rise of the application and deciding whether or not the wire will be in a bundle and use the information above. Similarly, the I2t ratings for the SPDP12D28 and SPDP05D28 are 1.72 x 103 Amp2-Seconds and 300 Amp2-Seconds, respectively.
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SENSITRON SEMICONDUCTOR
TECHNICAL DATA DATASHEET 5002, Rev B
SPDPXXD28 SERIES
Application Connections
The SPDPXXD28 Series may be configured as a high-side or low-side switch and may be used in positive or negative supply applications. Figure 6 shows the connections as a high-side switch with a positive power supply.
Figure 6 - High-Side Switch, Positive Supply
GAIN
GAIN RTN
Figure 7 - Low-Side Switch, Positive Supply
Figure 7 shows a low-side switch with a negative power supply. Note that the PWRGND pin is now connected to the LINE pin (see Rise/Fall Time paragraph below for more information on the PWRGND pin).
GAIN
GAIN RTN
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SENSITRON SEMICONDUCTOR
TECHNICAL DATA DATASHEET 5002, Rev B
SPDPXXD28 SERIES
Figures 8 and Figure 9 show negative supply high-side switch and low-side switch implementations. Again, note the connection of the PWRGND pin.
Figure 8 - High Side Switch, Negative Supply
GAIN
GAIN RTN
Figure 9 - Low Side Switch, Negative Supply
GAIN
GAIN RTN
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SENSITRON SEMICONDUCTOR
TECHNICAL DATA DATASHEET 5002, Rev B
SPDPXXD28 SERIES
Rise Time & Fall Time The rise and fall times of the SPDPXXD28 are pre-set at the factory for a nominal 100S with a LINE supply of 28VDC (see Table 3 for min/max limits). The rise and fall times will vary linearly with supply voltage. The PWRGND pin is used to control the rise and fall times. If the PWRGND pin is left open, the rise and fall times will be about 50uS. Leaving the PWRGND pin open can be useful when a faster rise or fall time is desirable. With the PWRGND pin connected as in Figures 6 through 9, the SPDPXXD28, when set for a 25 Amp rating, can turn on into a capacitive load of 440uF, min, 880uF, typ, without tripping for any power supply voltage within the ratings. The capacitive load capability is proportional to current rating and can be therefore easily calculated for each model and setting in the SPDPXX28 Series.
Wiring and Load Inductance Wiring inductance can cause voltage transients when the SPDPXXD28 is switched off due to an overload. Generally, these transients are small but must be considered when long wires are used on either the LINE or LOAD pins or both. A 10 foot length of wire in free air will cause a transient voltage of about 10 Volts when the SPDP25D28 trips at an Instant Trip level of 250 Amps. At the rated load current of 25 Amps, the voltage transient will be about 1 Volt. If longer wire lengths are used, a transient suppressor may be used at the LINE pin and a power diode may be used at the LOAD pin so that the total voltage between the LINE and LOAD pins is less than 50 Volts. When powering inductive loads, the negative voltage transient at the LOAD pin can cause the voltage between LINE and LOAD to exceed the SPDPXXD28 rating of 50 Volts and a power diode from the LOAD pin to ground must be used. The cathode of the power diode is connected to the LOAD pin with the anode connected to ground. The power diode must be able to carry the load current when the SPDPXXD28 switches off. Voltage transients due to wiring or load inductance are proportional to the operating current. Therefore, transients are less of a problem for the SPDP12D28 and SPDP05D28 Models and even the SPDP25D28 Model when set to a 12.5 Amp rating.
Paralleling For example, putting two SPDP25D28s in parallel will not double the rating to 50 Amps. Due to differences in the Rds(on) of the Power Mosfets in the SSPCs, the current will not share equally. In addition, there are unit-tounit differences in the trip curves so that two SPDP25D28s in parallel may possibly trip at 35 Amps. Also, both SPDP25D28s will not trip together; the SPDP25D28 carrying the higher current will trip first followed by the other SPDP25D28. Multiple SPDP25D28s may be used in parallel as long as these complexities are appreciated. Due not parallel different models of this series as the current sharing will not be predictable.
Board Layout The current-carrying power circuit should be kept well away from the control circuit and other low-level circuits in the system. It's unlikely, but possible, that magnetic coupling could affect the control circuit when turning normal loads on and off. However, in the case of an overload, the magnetic coupling could be 10 times greater than with normal loads. Effects of such coupling could cause `chattering' when turning on and off, oscillation, and the possibility of turning the SPDPXXD28 back on after an overload. The SPDPXXD28 Series is a Trip-Free device. Once tripped it will not turn back on until reset and commanded on again. Reset is accomplished by bringing the CONTROL pin low and turning the SSPC back on is accomplished by bringing the CONTROL pin high. Sufficient magnetic coupling between the current-carrying power circuit and the control circuit can negate the Trip-Free characteristic.
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SENSITRON SEMICONDUCTOR
TECHNICAL DATA DATASHEET 5002, Rev B
SPDPXXD28 SERIES
MIL-STD-704F and MIL-STD-1275B These standards cover the characteristics of the electrical systems in Military Aircraft and Vehicles. The SPDPXXD28 Series meets all of the requirements of MIL-STD-704F including Normal, Emergency, Abnormal and Electric Starting conditions with the Ripple, Distortion Factor and Distortion Spectrum defined in the standard. The SPDPXXD28 Series also meets all of the requirements of MIL-STD-1275B including operation with Battery and Generator, Generator Only and Battery Only for all of the conditions described in the standard including Cranking, Surges, Spikes and Ripple. In addition, the SPDPXXD28 Series can withstand + 600 V spikes for 10S. This capability is beyond that required by the standards cited above.
Figure 10 - SPDP25D28
Rating vs. Resistance Between "Gain" and "Gain Return" Terminals
25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10
0 50 10 0 0 15 0 0 20 0 0 25 0 0 30 0 00 35 0 40 0 0 45 0 0 50 0 0 55 0 0 60 0 0 65 0 0 70 0 0 75 0 0 80 0 0 85 0 0 90 0 0 95 0 10 0 0 0 10 00 50 11 0 0 11 00 5 12 00 00 0
Current Rating (Amps)
Rating
Resistance Between Terminals (Ohms)
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SENSITRON SEMICONDUCTOR
TECHNICAL DATA DATASHEET 5002, Rev B
SPDPXXD28 SERIES
Figure 11 - SPDP12D28
Rating vs. Resistance Between "Gain" and "Gain Return" Terminals
12 Current Rating (Amps) 11 10 9 8 7 6 5
0 50 10 0 0 15 0 0 20 0 0 25 0 0 30 0 00 35 0 40 0 0 45 0 0 50 0 0 55 0 0 60 0 0 65 0 0 70 0 0 75 0 0 80 0 0 85 0 0 90 0 0 95 0 10 0 0 0 10 00 5 11 00 0 11 00 5 12 00 00 0
Rating
Resistance Between Terminals (Ohms)
Figure 12 - SPDP05D28
Rating vs. Resistance Between "Gain" and "Gain Return" Terminals
5 Current Rating (Amps) 4.5 4 3.5 3 2.5 2
0 50 10 0 0 15 0 0 20 0 0 25 0 0 30 0 0 35 0 0 40 0 0 45 0 0 50 0 0 55 0 0 60 0 0 65 0 0 70 0 0 75 0 0 80 0 0 85 0 0 90 0 0 95 0 10 00 0 10 00 5 11 00 0 11 00 5 12 00 00 0
Rating
Resistance Between Terminals (Ohms)
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SENSITRON SEMICONDUCTOR
TECHNICAL DATA DATASHEET 5002, Rev B
SPDPXXD28 SERIES
Figure 13 - SPDP40D28
Rating vs. Resistance Between "Gain" and "Gain Return" Terminals
40 Current Rating (Amps) 36 32 28 24 20 16
0 50 10 0 0 15 0 0 20 0 0 25 0 0 30 0 0 35 0 0 40 0 0 45 0 0 50 0 0 55 0 0 60 0 0 65 0 0 70 0 0 75 0 0 80 0 0 85 0 0 90 0 0 95 0 10 00 0 10 00 5 11 00 0 11 00 5 12 00 00 0
Rating
Resistance Between Terminals (Ohms)
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