MII 53248

PRELIMINARY DATA SHEET
53248
28 VDC SOLID STATE POWER CONTROLLER
Features:
Applications:
•
•
•
•
•
•
•
•
•
•
Isolated Controls
Isolated Status Outputs
Fault Protection
Thermal Shutdown
Undervoltage & Overvoltage Shutdown
Current Limitation
Short Circuit Protection
•
Mii
HYBRID MICROELECTRONICS
PRODUCTS DIVISION
Power Distribution In Land/Air/Launch Vehicles
Motor Switch
Displays/Lamps/Controls
Industrial Automation
Switching Heaters
Test Equipment
Machine Control Equipment
Medical Lab Equipment
DESCRIPTION
The 53248 is a 28 VDC Solid State High Side Power Controller (SSPC) that is designed to replace electromagnetic
circuit breakers rated at 10 amperes. It is a high side switch utilizing N-channel vertical power FET technology with
integral charge pump. The SSPC provides a status output that signals a variety of conditions including over
temperature shutdown, overvoltage or undervoltage, over-current or short circuit. It will trip off for any of the above
conditions and automatically (based on an internal thermal time constant) cycle On/Off until the fault or the control
signal is removed.
Using vertical MOSFET technology, the SSPC offers extremely low “ON” resistance. This results in very low power
dissipation, which allows operation over the temperature range of –40°C to +85°C with minimal heat sinking.
ABSOLUTE MAXIMUM RATINGS
(@ TC = 25°C unless otherwise specified)
Input Control Current......................................................................................................................................................10 mA
Reverse Input Voltage (Control to Signal Ground)..................................................................................................... - 5 VDC
Pins to Case Isolation.............................................................................................................................................. 1000 VDC
Input-Output Isolation .............................................................................................................................................. 1000 VDC
Lead Temperature........................................................................................................................................................ +300°C
Junction Temperature .................................................................................................................................................. +150°C
Micropac Industries cannot assume any responsibility for any circuits shown or represent that they are free from patent infringement.
Micropac reserves the right to make changes at any time in order to improve design and to supply the best product possible.
MICROPAC INDUSTRIES, INC. HYBRID MICROELECTRONICS PRODUCTS DIVISION • 905 E. Walnut St., Garland, TX 75040 • (972) 272-3571 • Fax (972) 494-2281
www.micropac.com
E-MAIL: [email protected] 05/16/01
53248
PRELIMINARY DATA SHEET
28 VDC SOLID STATE HIGH SIDE SELF-PROTECTED POWER CONTROLLER
Package Configuration
PIN #
1
2
3
4
5
6
7
8
9
10
FUNCTION
CONTROL
STATUS
SIGNAL GND
OUTPUT
OUTPUT
POWER IN
POWER IN
POWER GND
POWER GND
NC
Dimensions: inches
Functional Block Diagram
POWER
IN
VOLTAGE
REGULATOR
ISOLATION/
CONTROL
CONTROL
STATUS
ISOLATION/
STATUS
LOGIC
O/V
U/V
CURRENT
LIMIT
CHARGE
PUMP
GATE
PROTECTION
OUTPUT
DETECTION
OUTPUT
TEMP
SENSE
LOAD
SIGNAL GND
(POWER GND)
Micropac Industries cannot assume any responsibility for any circuits shown or represent that they are free from patent infringement.
Micropac reserves the right to make changes at any time in order to improve design and to supply the best product possible.
MICROPAC INDUSTRIES, INC. HYBRID MICROELECTRONICS PRODUCTS DIVISION • 905 E. Walnut St., Garland, TX 75040 • (972) 272-3571 • Fax (972) 494-2281
www.micropac.com
E-MAIL: [email protected] 05/16/01
PRELIMINARY DATA SHEET
53248
28 VDC SOLID STATE HIGH SIDE SELF-PROTECTED POWER CONTROLLER
SPECIFICATIONS
(@ TC 25°C unless otherwise specified)
Control Function
Input Type.........................................................................................................1.5 kΩ resistor in series with 1.3 V drop LED
Turn-on Control Current ..........................................................................................................................................2 mA (min)
Turn-off Control Current ....................................................................................................................................... 10 µA (max)
Status Function
Open Collector transistor, VCC = +40 VDC (max)
Output High is VCC , Output Low is +0.4 V (max) @ ICC = 10 mA (max)
Status output transistor off (logic high) indicates unit is off.
Status output transistor on (V ≤ 0.4 VDC) indicates unit is on.
Power Circuit
Supply Voltage (for normal operation)................................................................. 5 VDC (min), 28 VDC(typ), 33 VDC (max)
Continuous Current ........................................................................................................................................................... 10 A
On-state Resistance, Tj @ 25°C (IL ≥ 5A) .....................................................................................................................35 mΩ
On-state Resistance, Tj @ 150°C (IL ≥ 5A)....................................................................................................................70 mΩ
Minimum Output Voltage Drop (IL = 0.5A).....................................................................................................................50 mV
Power Dissipation at TC = 25°C and Full Load.................................................................................................................. 4 W
Power Output Leakage Through Load ...........................................................................................................................15 µA
Trip Reset Time ................................................................................................................................ Temperature Dependent
Body Diode Current Capacity .......................................................................................................................................... 10 A
Quiescent Current (@ No load) ...................................................................................................................................... 8 mA
Temperature Range
Operating (Case) ..............................................................................................................................................-40°C to +85°C
Storage .......................................................................................................................................................... -55°C to +150°C
Thermal Resistance
Junction to Case.........................................................................................................................................................2.5 °C/W
Case to Ambient ...................................................................................................................................................... TBD °C/W
Physical Characteristics
See Package Configuration
Timing at 28 VDC (IL =1A)
Turn-on Time ................................................................................................................................................... 200 µsec (max)
Status Turn-on Delay ...................................................................................................................................... 200 µsec (max)
Turn-off Time ................................................................................................................................................... 250 µsec (max)
Status Turn-off Delay ...................................................................................................................................... 300 µsec (max)
Micropac Industries cannot assume any responsibility for any circuits shown or represent that they are free from patent infringement.
Micropac reserves the right to make changes at any time in order to improve design and to supply the best product possible.
MICROPAC INDUSTRIES, INC. HYBRID MICROELECTRONICS PRODUCTS DIVISION • 905 E. Walnut St., Garland, TX 75040 • (972) 272-3571 • Fax (972) 494-2281
www.micropac.com
E-MAIL: [email protected] 05/16/01
PRELIMINARY DATA SHEET
53248
28 VDC SOLID STATE HIGH SIDE SELF-PROTECTED POWER CONTROLLER
FUNCTIONAL DESCRIPTION
The 53248 SSPC is a fully protected switch that offers a wide range of features. These include overvoltage and
undervoltage shutdown with automatic reset, overcurrent and short circuit protection provided by temperature
sensing with automatic reset when temperature drops to safe levels, built in transient protection and fully optically
isolated control and status lines. The overcurrent and short circuit protection are achieved through the
temperature-sensing feature of the controller. Overcurrent is sensed through the increasing RDS(ON) causing
increase power dissipation in the pass element, which additionally causes a further increase in RDS(ON). As
junction temperature approaches +150°C, drive to the pass element is decreased, causing VDS to increase. When
the pass element temperature is between +150°C and +175°C, the drive to the pass element is removed and
current flow ceases. When the temperature is reduced approximately 10°C the device will resume operations.
This will continue until the overcurrent/short circuit is removed or the control is turned off. Status will indicate the
overcurrent condition until the fault is removed.
Peak Current Limits vs. Junction Temperature*
Junction Temperature Min
Typ
Max Unit
-40°C
48
56
65
A
+25°C
40
50
58
A
+150°C
31
37
45
A
Overvoltage and Undervoltage Limits
Overvoltage
+34 VDC to +43 VDC
Undervoltage
+3.4 VDC to +5.0 VDC
Overvoltage hysteresis
Typical +1.0 VDC
Undervoltage hysteresis
Typical +0.5 VDC
(Tj = –40°C to +150°C)
*Peak Duration - Typical Waveform
Short Circuit Protection:
Short-While-On Peak Duration @ 25°C
70
Output Current (A)
60
50
40
30
20
10
0
-10
-20
0
20
40
60
80
100
Time (ms)
Micropac Industries cannot assume any responsibility for any circuits shown or represent that they are free from patent infringement.
Micropac reserves the right to make changes at any time in order to improve design and to supply the best product possible.
MICROPAC INDUSTRIES, INC. HYBRID MICROELECTRONICS PRODUCTS DIVISION • 905 E. Walnut St., Garland, TX 75040 • (972) 272-3571 • Fax (972) 494-2281
www.micropac.com
E-MAIL: [email protected] 05/16/01
PRELIMINARY DATA SHEET
53248
28 VDC SOLID STATE HIGH SIDE SELF-PROTECTED POWER CONTROLLER
APPLICATION INFORMATION
The cable harness occupies an important position in the total network to be protected. The wide variety and in
some cases considerable length and packing density used makes them particularly susceptible to persistent
overloads and overheating. The maximum current carrying capacity of a cable depends on its resistance, type of
insulation material and the ambient temperature. A cable, including insulation, generally consists of at least two
materials with different thermal capacitance and thermal resistance. The maximum temperatures of most cables
are at least +150°C (depending on the insulation properties) which is very close to the maximum junction
temperature of the SSPC (Shutdown). Since under overcurrent or short circuit conditions, the unit resistance per
unit length for the cable is much less than the RDS of the SSPC, the unit heating will also be much less. Under
these conditions, it is apparent that the SSPC can adequately protect properly selected cabling.
The following formulas provide methods for calculating the primary parameters.
Trip Current
Itrip = {(Tj max – Ta)/[R θja ][RON (Tj max)]}1/2
Tj max
=
Maximum Trip Temperature
R θja
Ta
=
Ambient Temperature
RON (Tj max) = On-state resistance at Trip Temperature
= Thermal Resistance, Junction to Ambient
On-state Resistance
RON(T) = {(Y2 – Y1)T2 + (300)(Y2 – Y1)T + (67500)Y1 – (8125)Y2} / 59375
Y1 = RON at +25°C
Y2 = RON at +150°C
T = Tj at temperature of interest in °C
With the above information, the temperature and current trip can be determined based upon the type of mounting
chosen and the ambient temperatures of operation.
Precaution
When a short circuit causes turn-off of the SSPC, precautions must be taken to limit transient voltages generated by
any inductance in the load. External protection is recommended, either across the switch or across the load, should
the application result in energies beyond this level.
Micropac Industries cannot assume any responsibility for any circuits shown or represent that they are free from patent infringement.
Micropac reserves the right to make changes at any time in order to improve design and to supply the best product possible.
MICROPAC INDUSTRIES, INC. HYBRID MICROELECTRONICS PRODUCTS DIVISION • 905 E. Walnut St., Garland, TX 75040 • (972) 272-3571 • Fax (972) 494-2281
www.micropac.com
E-MAIL: [email protected] 05/16/01
PRELIMINARY DATA SHEET
53248
28 VDC SOLID STATE HIGH SIDE SELF-PROTECTED POWER CONTROLLER
Truth Table
Control
Output
Status
Normal Operation
L
H
L
H
H
L
Current Limitation
L
H
H
**
Short circuit to Power Ground
L
H
Over-Temperature
L
H
L
H
L
L
L
L
Short circuit to Power In
L
H
H
H
L
L
Undervoltage
L
H
L
L
H
H
Overvoltage
L
H
L
L
H
H
H
**
H
**
Note: L = “Low” Level
H = “High” Level
** Status output will cycle between H and L while SSPC is in auto-reset mode.
Loads
The 53248 SSPC is designed to handle low side loads from +5 VDC to +33 VDC. Any combination of inductive,
resistive and capacitive may be used. This includes lamps and DC motors.
Inductive loads require protecting the SSPC from voltage transients as pointed out in the precaution section above.
Charging Capacitive loads is generally not a problem due to the auto-reset feature of the current limit function. For
capacitive loads, the user must assure that junction temperatures are not exceeded and at turn off if the VCC drops
below the voltage charge on the capacitor, any current will flow through the body diode of the FET switch. Since this
is a normal PN junction, the power dissipated for a given current can be many times that of the forward current
through the FET.
Incandescent lamps must be treated much like capacitive loads in that in-rush currents at turn-on can cause an
overcurrent condition.
DC motors must be treated like capacitive loads because in-rush currents can be very high. Should a machine
continue to rotate after power is removed, reverse currents due to back EMF need to be addressed.
Heatsinking
The SSPC is designed to take advantage of the relationship between junction temperatures and heat sink thermal
impedance. As described in the section discussing current trip characteristics, the thermal impedance of the heat sink
utilized can determine the magnitude of over current or short circuit current expected in a system.
Micropac Industries cannot assume any responsibility for any circuits shown or represent that they are free from patent infringement.
Micropac reserves the right to make changes at any time in order to improve design and to supply the best product possible.
MICROPAC INDUSTRIES, INC. HYBRID MICROELECTRONICS PRODUCTS DIVISION • 905 E. Walnut St., Garland, TX 75040 • (972) 272-3571 • Fax (972) 494-2281
www.micropac.com
E-MAIL: [email protected] 05/16/01
PRELIMINARY DATA SHEET
53248
28 VDC SOLID STATE HIGH SIDE SELF-PROTECTED POWER CONTROLLER
Offset voltage
The Power MOSFETs used in Micropac’s SSPC have very low on resistance and therefore low power dissipation.
Typical on-state resistance at 25°C is only 27 mΩ. Due to internal design the typical VDS at 0.5 A is 50 mV. This stays
relatively constant until the current reaches approximately 2 amperes when VDS is 60 mV. For higher currents, the
RDS is constant at Tj of +25°C. Maximum RDS at +150°C is 70 mΩ.
Since the design of SSPC current limit is temperature dependent, there is no need for a current sensing resistor and
therefore no additional voltage drop which would add to the RDS.
Isolation of Control and Status
The SSPC was designed to utilize optical isolation both on the input/control and the status feed back. The only input
power required is that necessary to drive a control LED and provide pull up power for the open collector status
transistor. The SSPC derives its energy for operation from the 28 VDC load supply. As a result, the power in and
power out are completely isolated.
Micropac Industries cannot assume any responsibility for any circuits shown or represent that they are free from patent infringement.
Micropac reserves the right to make changes at any time in order to improve design and to supply the best product possible.
MICROPAC INDUSTRIES, INC. HYBRID MICROELECTRONICS PRODUCTS DIVISION • 905 E. Walnut St., Garland, TX 75040 • (972) 272-3571 • Fax (972) 494-2281
www.micropac.com
E-MAIL: [email protected] 05/16/01