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GS-R1005
50W STEP-DOWN SWITCHING REGULATOR
Type GS-R1005 Vi 12 to 36 V Vo 5V Io 10 A
FEATURES Wide input voltage range (12 to 36V) High efficiency (80% min.) Parallel operation with current sharing Synchronization Remote inhibit/enable Remote load voltage sense Output short-circuit protection Soft-start PCB or chassis mountable DESCRIPTION The GS-R1005 is a step-down switching voltage regulator suitable to provide 5V/10Aoutput voltage from a wide input voltage range (12 to 36V).
ABSOLUTE MAXIMUM RATINGS
Symbol Vi Viinh Tcop Tstg DC Input Voltage High Inhibit voltage Operating Case Temperature Range Storage Temperature Range Parameter Value 40 28 0 to +75 - 20 to +105 Unit V V C C
June 1994
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ELECTRICAL CHARACTERISTICS (Tamb = 25C unless otherwise specified)
Symbol Vi li lir Vien Viinh liinh Vo Vor VOL VOO Vo Io Iol Iosc Io Parameter Input Voltage Input Current Reflected Input Current Enable Input Voltage Inhibit Input Voltage Inhibit Input Current Output Voltage Output Ripple Voltage Line Regulation Load Regulation Total Remote Sense Compensation Output Current* Output Current Limiting Short-circuit Output Current Current Sharing Deviation Soft-start Time Line Transient Recovery Time Load Transient Recovery Time Switching Frequency Efficiency Thermal Resistance Case-to-ambient Test Conditions Vo = 5.05V Vi = 24V Io = 1.2 to 10A Io = 10A Min 12 Typ 24 2.5 200 0 2 0.3 4.9 5.05 100 220 1.2 24 0.5 5.2 120 0.5 1 0.5 Vo = 5.05V 0 12.5 10 13.7 16 10 Max 36 Unit V A mApp V V mA V mVpp % % V A A A %
Vi = 24V Io = 10A with external filter (C = 470F) Vi = 12 to 36V Io = 1.2 to 10A Vi = 12 to 36V Io = 1.2 to 10A Vi = 12 to 36V Io =1.2 to 10A Viinh = 5V Vi = 12 to 36V Io = 1.2 to 10A Vi = 24V Io = 10A Vi = 12 to 36V Io = 10A Vi = 24V Vi = 24V Io = 10A Vi = 12 to 36V Vi = 12 to 36V Vi = 24V Vi = 24V Io = 2 to 10A two modules in parallel Vi = 24V Io = 10A Io = 1.2 to 10A
tss tr1 tr2 fs R thc
15 60 100 100 80 83 7.5
ms s s kHz % C/W
Vi = 12 to 36V Io = 5A Vi = 24V Vi = 24V Io = 1.2 to 10A Io = 1.2 to 10A Io = 10A
Vi = 12 to 36V
* Note: when output current is less than 1.2A, output ripple voltage increases due to discontinuous operation.
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CONNECTION DIAGRAM AND MECHANICAL DATA
Package R. Dimensions in mm (inches).
PIN DESCRIPTION
Pin 1 2 3 4,5 6 7 8 9 10,11 Function GND Input Inhibit + Vin + Vout + Sense Sync Parallel - Sense GND Output Description Return for input voltage source. Internally connected to pin 10,11. The converter is ON (Enable) when this pin is unconnected or the voltage applied is lower than 1.2V. The converter is OFF (Inhibit) for a control voltage in the range of 2 to 24V. DC Input voltage; recommended maximum voltage is 36V. External capacitor between pin 3 and pin 1 is mandatory; recommended value is 470F/50V for switching application. +5V output voltage. Senses the remote load high side. To be connected to pin 4,5 when remote sense is not used. Synchronization output. See figures 1,2,3,4. Open when not used. Parallel output. See figures 1,2,3,4. Open when not used. Senses the remote load return. To be connected to pin 10,11 when remote sense is not used. In parallel configuration, take care to connect all -S pins together (see figures 1,2,3,4). Return for output current path. Internally connected to pin 1.
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USER NOTES Input Voltage The recommended operating maximum DC input voltage is 36V inclusive of the ripple voltage. The use of an external low ESR, high ripple current capacitor located as close the module as possible is mandatory; recommended value is 470F/50V. Softstart To avoid heavy inrush current the output voltage rise time is typically 15ms in any condition of load. Remote Sensing The remote voltage sense compensation range is for a total drop of 500mV equally shared between the load connecting wires. It is a good practice to shield the sensing wires to avoid oscillations. See the connection diagram on figures 1, 2, 3, 4. Parallel Operation To increase available output regulated power, the module features the parallel connection possibility with equal current sharing and maximum deviation of 10% (two modules in parallel). See the connection diagram on figures 1, 2, 3, 4. Module Protection The module is protected against occasional and permanent shortcircuits of the output pins to ground, as well as against output current overload. It uses a current limiting protection circuitry, avoiding latch-up problems with certain types of loads.
Figure 1.
Figure 2.
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Figure 3. Figure 4.
Thermal characterist ics: how to choose the heat-sink Sometimes the GS-R1005 requires an external heat-sink dependingon both operatingtemperature conditions and power. Before entering into calculations details, some basic concepts will be explained to better understand the problem. The thermal resistance between two points is represented by their temperature difference in front of a specified dissipated power, and it is expressed in Degree Centigrade per Watt (C/W). For GS-R1005 the thermal resistance case to ambient is 7.5C/W. This means that an internal power dissipation of 1W will bring the case temperature at 7.5C above the ambient temperature. The maximum case temperature, at which the module provides 10A, is 75C (see fig. 6). Let's suppose to have a GS-R1005 that delivers a load current of 10A at an ambient temperature of 40C.
The dissipated power in this operating condition is about 10.2W (at typical efficiency of 83%), and the case temperature of the module will be:
TCase = TAmb + Pd x Rth = 40 + 10.2 x 7.5 = 116.8 C
This value exceeds the maximum allowed temperature and an external heat-sink must be added. To this purpose four holes (see mechanical drawing) are provided on the metal surface of the module. To calculate this heat-sink, let's first determine what the total thermal resistance should be. Rth = TCaseMAX - Tamb = 75 - 40 = 3.42C / W Pd 10.2 This value is the resulting value of the additional heatsink thermal resistance.
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Figure 5. - Efficiency vs. Output Current.
Typ. eff. (%) 90 89 88 87 86 85 84 83 82 81 80 0 1 2 3 4 5 6 7 8 9 10 Vi= 36V Vi= 24V Vi= 12V
Figure 6. - Output Current vs. T case.
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The following list may help the designer to select the proper commercially available heat-sink. Sometimes it can be more convenient to use a custom made heat-sink that can be experimently designed and tested.
Manufacturers ALUTRONIC
Type PR139 PR140 PR159
Height (mm) 20 19 20 19 15 19 14 25.5 33.5 12 15 25.5 19 21 24 14 14 24 30
Rth (C/W) 3 2 2.5 3 2 2 4.5 1.5 3 3 2.5 1.5 2 3 3 4.5 5 4.5 1.5
ASSMAN
V5440 V5805 V5280
AAVID
60885 60660 62355
AUSTERLITZ
KS50 KS100.3
FISCHER
SK16 SK52
SGE BOSARI
L30 LZ50
THERMALLOY
6155 6601 6176 6320
Information furnished is believed to be accurate and reliable. However, SGS-THOMSON Microelectronics assumes no responsibility for the consequences of use of such information nor for any infringement of patents or other rights of third parties which may result from its use. No license is granted by implication or otherwise under any patent or patent rights of SGS-THOMSON Microelectronics. Specification mentioned in this publication are subject to change without notice. This publication supersedes and replaces all information previously supplied. SGS-THOMSON Microelectronics products are not authorized for use as critical components in life support devices or systems without express written approval of SGS-THOMSON Microelectronics. (c) 1994 SGS-THOMSON Microelectronics - All Rights Reserved SGS-THOMSON Microelectronics GROUP OF COMPANIES Australia - Brazil - China - France - Germany - Hong Kong - Italy - Japan - Korea - Malaysia - Malta - Morocco - The Netherlands Singapore - Spain - Sweden - Switzerland - Taiwan - Thailand - United Kingdom - U.S.A.
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