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Self powered Fast Battery Tester
This schema runs a fast battery test without the need of power supply or expensive moving-coil voltmeters. It features two ranges: when SW1 is set as shown in the schema diagram, the device can test 3V to 15V batteries. When SW1 is switched to the other position, only 1.5V cells can be tested.
Parts:
R1______________2K2 1/4W Resistor R2______________3R3 1/4W Resistor R3_____________10R 1/4W Resistor R4______________4K7 1/4W Resistor R5_____________33K 1/4W Resistor R6,R7_________100K 1/4W Resistors R8____________220K 1/4W Resistor R9____________330K 1/4W Resistor R10___________500K Trimmer Cermet C1,C2__________10nF 63V Polyester Capacitors C3-C7_________100nF 63V Polyester Capacitors C8____________220µF 35V Electrolytic Capacitor D1,D7___________LEDs Red 5mm. (see Notes) D2-D6________1N4148 75V 150mA Diodes Q1___________2N3819 General purpose FET Q2,Q3_________BC337 45V 800mA NPN Transistors IC1,IC2________7555 or TS555CN CMos Timer ICs P1_____________SPST Pushbutton SW1____________DPDT Switch BUT____________Battery under test Holder or clips to connect the Battery under test to the schema Testing 3V to 15V batteries: 1. Switch SW1 as shown in the schema diagram. 2. Place the battery under test in a suitable holder or clip it to the schema. 3. Wait some seconds in order to let C8 reach its full charge. 4. LED D1 illuminates at a constant intensity, independent of battery voltage. 5. If D1 illuminates very weakly or is completely off the battery is unusable. 6. If D1 has a good illumination, press P1 and keep an eye to LED D7. If D7 remains completely off, the battery is in a very good state. 7. If D7 illuminates brightly for a few seconds, the battery is weak. This condition is confirmed by a noticeable weakening in D1 brightness. 8. If D7 illuminates weakly for a few seconds but D1 maintain the same light intensity, the battery is still good but is not new. Testing 1.5V batteries: 1. Switch SW1 in the position opposite to that shown in the schema diagram. 2. Place the battery under test in a suitable holder or clip it to the schema. 3. Wait some seconds in order to let C8 reach its full charge. 4. LED D1 illuminates very weakly only in presence of a new battery, otherwise is off. 5. Press P1 and keep an eye to LED D7. If D7 remains fully off the battery can be in very good state. 6. If D7 illuminates brightly for a few seconds, the battery is weak. 7. If D7 illuminates weakly for a few seconds, the battery is still good but is not new. 8. If you are suspecting a 1.5V cell to be completely discharged, a better test can be made wiring two 1.5V batteries in series, then running the 3V test. Circuit operation: FET Q1 provides a constant current generator biasing LED D1 and Q2 Base. In this manner D1 illuminates at a constant intensity, independent of battery voltage from 3 to 15V and Q2 (when P1 is closed) applies a constant current load of about 120mA to the battery. IC1 is a square wave generator oscillating at about 3KHz. IC2 acts as an inverter and drives, together with IC1 but in anti-phase, Diodes D2-D6 and Capacitors C4-C7, obtaining a voltage multiplication. C8 is charged by this raised voltage and R8-R10 form a voltage divider biasing the Base of Q3. When P1 is open, a very light load is applied to the battery under test and Q3 Base is biased in order to maintain LED D7 in the off state. Closing P1, a 120mA load is applied to the battery under test. If the battery is not fully charged, its output voltage starts reducing: when this voltage falls 0.6V below the battery nominal voltage, Q3 Emitter becomes more negative than the Base, the transistor is hard biased and D7 illuminates. Obviously, this state of affairs will last a few seconds: the time spent by C8 to reduce its initial voltage to the new one, proportional to the voltage of the loaded battery. If the battery under test is in a good charging state, its output voltage will not fall under a 120mA loading current, so LED D7 will stay off. When testing 1.5V batteries, the schema formed by Q1, Q2, D1, R1 & R2 does not work well at this supply voltage, so a 150mA load current is applied to the BUT by means of the 10 Ohm resistor R3 after switching SW1A. Q3 bias is also changed via SW1B. Notes: * To set-up this schema apply a 6 to 7.5V voltage source to the input and trim R10 until LED D7 is completely off (without pushing on P1). * 1.5V test position needs no set-up. * CMos 555 ICs must be used for IC1 & IC2 because they are the only cheap devices able to oscillate at 1.5V supply or less.
Self powered Fast Battery Tester
This schema runs a fast battery test without the need of power supply or expensive moving-coil voltmeters. It features two ranges: when SW1 is set as shown in the schema diagram, the device can test 3V to 15V batteries. When SW1 is switched to the other position, only 1.5V cells can be tested.
Parts:
R1______________2K2 1/4W Resistor R2______________3R3 1/4W Resistor R3_____________10R 1/4W Resistor R4______________4K7 1/4W Resistor R5_____________33K 1/4W Resistor R6,R7_________100K 1/4W Resistors R8____________220K 1/4W Resistor R9____________330K 1/4W Resistor R10___________500K Trimmer Cermet C1,C2__________10nF 63V Polyester Capacitors C3-C7_________100nF 63V Polyester Capacitors C8____________220µF 35V Electrolytic Capacitor D1,D7___________LEDs Red 5mm. (see Notes) D2-D6________1N4148 75V 150mA Diodes Q1___________2N3819 General purpose FET Q2,Q3_________BC337 45V 800mA NPN Transistors IC1,IC2________7555 or TS555CN CMos Timer ICs P1_____________SPST Pushbutton SW1____________DPDT Switch BUT____________Battery under test Holder or clips to connect the Battery under test to the schema Testing 3V to 15V batteries: 1. Switch SW1 as shown in the schema diagram. 2. Place the battery under test in a suitable holder or clip it to the schema. 3. Wait some seconds in order to let C8 reach its full charge. 4. LED D1 illuminates at a constant intensity, independent of battery voltage. 5. If D1 illuminates very weakly or is completely off the battery is unusable. 6. If D1 has a good illumination, press P1 and keep an eye to LED D7. If D7 remains completely off, the battery is in a very good state. 7. If D7 illuminates brightly for a few seconds, the battery is weak. This condition is confirmed by a noticeable weakening in D1 brightness. 8. If D7 illuminates weakly for a few seconds but D1 maintain the same light intensity, the battery is still good but is not new. Testing 1.5V batteries: 1. Switch SW1 in the position opposite to that shown in the schema diagram. 2. Place the battery under test in a suitable holder or clip it to the schema. 3. Wait some seconds in order to let C8 reach its full charge. 4. LED D1 illuminates very weakly only in presence of a new battery, otherwise is off. 5. Press P1 and keep an eye to LED D7. If D7 remains fully off the battery can be in very good state. 6. If D7 illuminates brightly for a few seconds, the battery is weak. 7. If D7 illuminates weakly for a few seconds, the battery is still good but is not new. 8. If you are suspecting a 1.5V cell to be completely discharged, a better test can be made wiring two 1.5V batteries in series, then running the 3V test. Circuit operation: FET Q1 provides a constant current generator biasing LED D1 and Q2 Base. In this manner D1 illuminates at a constant intensity, independent of battery voltage from 3 to 15V and Q2 (when P1 is closed) applies a constant current load of about 120mA to the battery. IC1 is a square wave generator oscillating at about 3KHz. IC2 acts as an inverter and drives, together with IC1 but in anti-phase, Diodes D2-D6 and Capacitors C4-C7, obtaining a voltage multiplication. C8 is charged by this raised voltage and R8-R10 form a voltage divider biasing the Base of Q3. When P1 is open, a very light load is applied to the battery under test and Q3 Base is biased in order to maintain LED D7 in the off state. Closing P1, a 120mA load is applied to the battery under test. If the battery is not fully charged, its output voltage starts reducing: when this voltage falls 0.6V below the battery nominal voltage, Q3 Emitter becomes more negative than the Base, the transistor is hard biased and D7 illuminates. Obviously, this state of affairs will last a few seconds: the time spent by C8 to reduce its initial voltage to the new one, proportional to the voltage of the loaded battery. If the battery under test is in a good charging state, its output voltage will not fall under a 120mA loading current, so LED D7 will stay off. When testing 1.5V batteries, the schema formed by Q1, Q2, D1, R1 & R2 does not work well at this supply voltage, so a 150mA load current is applied to the BUT by means of the 10 Ohm resistor R3 after switching SW1A. Q3 bias is also changed via SW1B. Notes: * To set-up this schema apply a 6 to 7.5V voltage source to the input and trim R10 until LED D7 is completely off (without pushing on P1). * 1.5V test position needs no set-up. * CMos 555 ICs must be used for IC1 & IC2 because they are the only cheap devices able to oscillate at 1.5V supply or less.
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