LM1921

LM1921 1 Amp Industrial Switch February 1995 LM1921 1 Amp Industrial Switch General Description The LM1921 Relay Driver incorporates an integrated power PNP transistor as the main driving element The advantages of this over previous integrated circuits employing NPN power elements are several Greater output voltages are available off the same supply for driving grounded loads typically 4 5 volts for a 500 mA load from a 5 0 volt supply The output can swing below ground potential up to 57 volts negative with respect to the positive power supply This can be used to facilitate rapid decay times in inductive loads Also the IC is immune to negative supply voltages or transients The inherent Safe Operating Area of the lateral PNP allows use of the IC as a bulb driver or for capacitive loads Familiar integrated circuit features such as short circuit protection and thermal shutdown are also provided The input voltage threshold levels are designed to be TTL CMOS and LSTTL compatible over the entire operating temperature range If several drivers are used in a system their inputs and or outputs may be combined and wired together if their supply voltages are also common Features Y Y Y Y Y Y Y Y Y Y Y Y 1 Amp output drive Load connected to ground Low input-output voltage differential a 60 volt positive transient protection b 50 volt negative transient protection Automotive reverse battery protection Short circuit proof Internal thermal overload protection Unclamped output for fast decay times TTL LSTTL CMOS compatible input Plastic TO-220 package 100% electrical burn-in Applications Y Y Y Y Y Y Relays Solenoids Valves Motors Lamps Heaters Typical Application Circuit Required for stability TL H 5271 – 1 FIGURE 1 Test and Application Circuit Connection Diagram TL H 5271 – 2 Front View Order Number LM1921T See NS Package Number T05A C1995 National Semiconductor Corporation TL H 5271 RRD-B30M115 Printed in U S A Absolute Maximum Ratings If Military Aerospace specified devices are required please contact the National Semiconductor Sales Office Distributors for availability and specifications Supply Voltage Operating Range Overvoltage Protection (100 ms) 4 75V to 26V b 50V to a 60V Internal Power Dissipation Operating Temperature Range Maximum Junction Temperature Storage Temperature Range Lead Temp (Soldering 10 seconds) Internally Limited b 40 C to a 125 C 150 C b 65 C to a 150 C 230 C Electrical Characteristics (VCC e 12V Parameter Supply Voltage Operational Survival Transient Supply Current VON OFF e 0 VON OFF e 2V Conditions IOUT e 500 mA TJ e 25 C VON OFF e 2V unless otherwise specified ) Tested Limits (Note 1) Min 4 75 Max 26 60 Design Limits (Note 2) Min 6 Max 24 V VDC V mA mA mA mA A V V 75 01 13 08 10 20 08 15 32 30 26 36 20 30 50 A A mA V V mA V CW CW b 120 b 45 Typ Units 100 ms 1% Duty Cycle 06 6 285 575 13 05 10 14 6VsVCCs24V VON OFF e 0 6VsVCCs24V b 15 b 50 15 10 350 700 15 08 10 20 IOUT e 0 mA IOUT e 250 mA IOUT e 500 mA IOUT e 1A IOUT e 500 mA IOUT e 1A Input to Output Voltage Drop Short Circuit Current Output Leakage Current ON OFF Voltage Threshhold ON OFF Current Overvoltage Shutdown Thermal Resistance junction-case case-ambient Inductive Clamp Output Voltage Fault Conditions Output Current ON OFF Floating Ground Floating Reverse Voltage Reverse Transient Overvoltage Supply Current ijc ica VON OFF e 0 IOUT e 100 mA 3 50 b 60 V Pin 5 Open Pin 3 Pin 4 Open VCC eb15V VCC eb50V VCC e a 60V Pin 1 Pin 2 Short No load 01 01 b 0 01 b 100 0 01 10 50 50 b1 1 40 mA mA mA mA mA mA Note 1 Guaranteed and 100% production tested Note 2 Guaranteed not necessarily 100% production tested Not used to calculate outgoing AQL Limits are for the temperature range of b 40 C s Tj s 150 C 2 Typical Performance Characteristics Output Voltage Drop Device Operating Current Peak Output Current (VOUT) TL H 5271–3 TL H 5271 – 4 TL H 5271 – 5 Output Voltage Drop Output Voltage (VOUT) Maximum Power Dissipation (TO-220) TL H 5271–6 TL H 5271 – 7 TL H 5271 – 8 ON OFF Current vs Junction Temperature Threshold Voltage vs Supply Voltage ON OFF Current vs ON OFF Voltage TL H 5271–13 TL H 5271 – 14 TL H 5271 – 15 Equivalent Block Diagram TL H 5271 – 12 FIGURE 1 3 Circuit Schematic TL H 5271 – 9 4 Application Hints HIGH CURRENT OUTPUT The 1 Amp output is fault protected against overvoltage If the supply voltage rises above approximately 30 volts the output will automatically shut down This protects the internal circuitry and enables the IC to survive higher voltage transients than would otherwise be expected The 1921 will survive transients and DC voltages up to 60 volts on the supply The output remains off during this time independent of the state of the input logic voltage This protects the load The high current output is also protected against short circuits to either ground or supply voltage Standard thermal shutdown circuits are employed to protect the 1921 from over heating FLYBACK RESPONSE Since the 1921 is designed to drive inductive as well as any other type of load inductive kickback can be expected whenever the output changes state from on to off (see waveforms on Figure 1 ) The driver output was left unclamped since it is often desirable in many systems to achieve a very rapid decay in the load current In applications where this is not true such as in Figure 2 a simple external diode clamp will suffice In this application the integrated current in the inductive load is controlled by varying the duty cycle of the input to the driver IC This technique achieves response characteristics that are desirable for certain automotive transmission solenoids for example For applications requiring a rapid controlled decay in the solenoid current such as fuel injector drivers an external zener and diode can be used as in Figure 3 The voltage rating of the zener should be such that it breaks down before the output of the LM1921 The minimum output breakdown voltage of the IC output is rated at b57 volts with respect to the supply voltage Thus on a 12 volt supply the combined zener and diode breakdown should be less than 45 volts The LM1921 can be used alone as a simple relay or solenoid driver where a rapid decay of the load current is desired but the exact rate of decay is not critical to the system If the output is unclamped as in Figure 1 and the load is inductive enough the negative flyback transient will cause the output of the IC to breakdown and behave similarly to a zener clamp Relying upon the IC breakdown is practical and will not damage or degrade the IC in any way There are two considerations that must be accounted for when the driver is operated in this mode The IC breakdown voltage is process and lot dependent Clamp voltages ranging from b 60 to b 120 volts (with respect to the supply voltage) will be encountered over time on different devices This is not at all critical in most applications An important consideration however is the additional heat dissipated in the IC as a result This must be added to normal device dissipation when considering junction temperatures and heat sinking requirements Worst case for the additional dissipation can be approximated as Additional PD e I2 x L x f (Watts) where I e peak solenoid current (Amps) L e solenoid inductance (Henries) f e maximum frequency input signal (Hz) For solenoids where the inductance is less than ten millihenries the additional power dissipation can be ignored Overshoot undershoot and ringing can occur on certain loads The simple solution is to lower the Q of the load by the addition of a resistor in parallel or series with the load A value that draws one tenth of the current or DC voltage of the load is usually sufficient TL H 5271 – 10 TL H 5271 – 11 FIGURE 2 Diode Clamp FIGURE 3 Zener clamp for rapid controlled current decay 5 LM1921 1 Amp Industrial Switch Physical Dimensions inches (millimeters) 5-Lead TO-220 Power Package (T) Order Number LM1921T NS Package Number T05A LIFE SUPPORT POLICY NATIONAL’S PRODUCTS ARE NOT AUTHORIZED FOR USE AS CRITICAL COMPONENTS IN LIFE SUPPORT DEVICES OR SYSTEMS WITHOUT THE EXPRESS WRITTEN APPROVAL OF THE PRESIDENT OF NATIONAL SEMICONDUCTOR CORPORATION As used herein 1 Life support devices or systems are devices or systems which (a) are intended for surgical implant into the body or (b) support or sustain life and whose failure to perform when properly used in accordance with instructions for use provided in the labeling can be reasonably expected to result in a significant injury to the user National Semiconductor Corporation 1111 West Bardin Road Arlington TX 76017 Tel 1(800) 272-9959 Fax 1(800) 737-7018 2 A critical component is any component of a life support device or system whose failure to perform can be reasonably expected to cause the failure of the life support device or system or to affect its safety or effectiveness National Semiconductor Europe Fax (a49) 0-180-530 85 86 Email cnjwge tevm2 nsc com Deutsch Tel (a49) 0-180-530 85 85 English Tel (a49) 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