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POWER_ON_DELAY_CIRCUIT

Published:2009/6/15 22:06:00 Author:May

POWER_ON_DELAY_CIRCUIT
Using an IC to count ac mains pulses, the circuit produces 16 various delay times,where ac power is applied to a load after a preset interval.   (View)

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AUTOMATIC_TR_SWITCH

Published:2009/6/15 21:11:00 Author:May

AUTOMATIC_TR_SWITCH
A pair of diodes and a quarter-wave transmission line are used as an automatic TR switch. D1 and D2 conduct during transmit periods, short-circuiting the scanner input. In th 1/4-wave line appears as an open circuit. In receive, the circuit acts as a Wilkinson power divider.   (View)

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SILENT_ALARM

Published:2009/6/14 23:10:00 Author:May

SILENT_ALARM
A sensor switch triggers a set-reset flip flop and lights an LED.   (View)

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BURGLAR_CHASER

Published:2009/6/14 23:07:00 Author:May

BURGLAR_CHASER
BZ..................... Mtai Horn Buzzer C1 ..............5μF 250 volts Capactto C2.............022μF Green Cap(223 K5K)D1..........................1N4O07 DiodeFT.......... Micro Strobe Tube/ReflectorL1.............................Neon Lamp Q1.................. C174O SW Transistor Q2...............................106 SOP R1......................200 ohm Resistor R2......................820 ohm Resistor R3.......................10 meg ReststorT1...................Invener TransformerT2.................... 4 kV Trtgger Coil The burglar chaser makes a great accessory for any alarm system. It creates brilliant flashes of white light and a loud, irritating sound from a metal horn buzzer. Transformer T1 is connected to Q1, R1, and R2 to formablocking oscillator. This createsaG-Vac signal on the primary ofT1. Because of T1's large ratio of turns frorn primary to secondary, the 6-Vac signal is stepped up to a level of over 200 Vac, which is then rectified by D1. The resultant dc voltage is applied to storage capacitor C1 and the neon relaxation oscillator made up of R3, C2, and L1. Each time C2 charges up to a sufficient level, it ionizes L1, which causes SCR Q2 to fire. The firing SCR causes the charge on C2 to be applied to the trigger coil. The trigger coil converts the 200 V into the 4000-V pulse that is needed to fire micro xenon strobe tube/reflector FT. The cycle repeats itself after the strobe tube flashes.   (View)

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ALARM_SOUNDER_FOR_FLEX_SWITCH

Published:2009/6/14 23:02:00 Author:May

ALARM_SOUNDER_FOR_FLEX_SWITCH
This is a cross-sectional diagram of a flex switch. They can be used as pushbutton or even posi-tion sensors. This schematic diagram shows an oscillator, which is used as an alarm sounder, trig-gered by a flex switch.   (View)

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SELF_LATCHING_LIGHT_ALARM_WITH_TONE_OUTPUT

Published:2009/6/14 23:00:00 Author:May

SELF_LATCHING_LIGHT_ALARM_WITH_TONE_OUTPUT
A decrease in the resistance of the CDS cell when light strikes it activates latch a and b, enabling Lone oscillator c and d which produces an output of about 1000 Hz. RA sets the trip level. S1 resets Lhe circuit.   (View)

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HIGH_OUTPUT_PULSED_TONE_LIGHT_ACTIVATED_ALARM

Published:2009/6/14 22:58:00 Author:May

HIGH_OUTPUT_PULSED_TONE_LIGHT_ACTIVATED_ALARM
This circuit can produce up to 1 W of audio power to drive a speaker or horn. When the CDS cell is struck by light, its resistance decreases thus activating NOR gate(a) thereby causing(a) and(b) to produce a low-frequency(10-Hz) square wave. This pulses the 1-kHz oscillator(c) and(d), caus-ing it to generate a pulsed 1-kHz tone at a 10-Hz rate. Q1 and Q2 amplify this signal. Q2(2N3055) drives the speaker.   (View)

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PRECISION_LIGHT_ALARM_WITH_HYSTERESIS

Published:2009/6/14 22:57:00 Author:May

PRECISION_LIGHT_ALARM_WITH_HYSTERESIS
The TL081 is used as a comparator in a Wheatstone bridge circuit. When the CDS cell resistance decreases due to exposure to light, the output from IC2 cause the low-frequency osciLator(a) and(b) to generate a 10-Hz square wave, gating the 1000 Hz oscillator(c) and(d) on and off. This signal dri-ves an amplifier. R3 controls hysteresis, which reduces on-off triggering near the threshold set by R4.   (View)

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PRECISION_LIGHT_ACTIVATED_ALARM

Published:2009/6/14 22:55:00 Author:May

PRECISION_LIGHT_ACTIVATED_ALARM
The light-sensitive CDS cell R8 conftgured In a bridge circuit with IC1 as a comparator causes IC1's output to go high when light strikes the CDS cell R8,triggering SCR1 This lights LED1 andturns on opto isolator IC2,which switches the load   (View)

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LIGHT_ACTIVATED_ALARM_WITH_LATCH

Published:2009/6/14 22:55:00 Author:May

LIGHT_ACTIVATED_ALARM_WITH_LATCH
In this circuit, light causes R5 to conduct forward-biasing Q1. R6 sets sensitivity. SCR1 is triggered from the emitter voltage on LQ1, sounding the alarm bell. When 51 is depressed, SCR1 un-latches. Be sure that a self-interrupting alarm (electromechanical buzzer or bell) is used.   (View)

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LIGHT_BEAM_ALARM_PREAMPLIFIER

Published:2009/6/14 22:53:00 Author:May

LIGHT_BEAM_ALARM_PREAMPLIFIER
This circuit can be used for light beams to 20 kHz .The gain of the operational amplifier is set for a 40-dB gain.   (View)

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DARK_ACTIVATED_ALARM_WITH_PULSED_TONE_OUTPUT

Published:2009/6/14 22:51:00 Author:May

DARK_ACTIVATED_ALARM_WITH_PULSED_TONE_OUTPUT
DARK_ACTIVATED_ALARM_WITH_PULSED_TONE_OUTPUT

NOR gates a and b form a low-frequency oscillator that is activated when the CDS cell,underdark conditions,causes NOR gate ato see alogic zero at one input This low-frequency (10 Hz) gates a high-frequency oscillator (c and d) to oscillate at around 1000 Hz.R1 can be varied to change the pulse rate and R2 to change the tone.R3 sets the trigger point.   (View)

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LIGHT_BEAM_ALARM_FOR_INTRUSION_DETECTION

Published:2009/6/14 22:46:00 Author:May

LIGHT_BEAM_ALARM_FOR_INTRUSION_DETECTION
When the light beam that falls in the CDSphotocell is interrupted,transistor(EN3904) conducts thereby triggering SCR1 (C106) and activating alarm bell. S1 resets the SCR. The alarm bell should be a self-interrupttng electromechanical type.   (View)

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555_BASED_ALARM

Published:2009/6/14 22:43:00 Author:May

555_BASED_ALARM
555_BASED_ALARM

The alarm circuit has a single 555。scillator/timer(U1)performing double duty;serving both in the alarm-trigger circuit and the entry-delay circuit. In this application,the trigger mput of U1 at ptn 2 iS held high via R1,A normally-closed sensor switch,S1,supplies a positive voltage to the junction of R2 and C1,and lights LED1.With both ends of C1 tied high,there is no charge on C1 But when S1 opens,C1(initially acting as a short) momentarny pulls pm 2 of U1 low, triggering the timed delay circle At the beginning of the timing cycle,U1 produces a positive voltage at put 3,which charges FAUito near the positive voltage at put 3,which charges C4 to near the positive supply voltage Transistor Q1 is heavily biased on by R3,keeping its collector at near ground level With Qt on,SCR1’s gate lOclamped to ground,holding it off. When the delay circuit times out,pin 3 of U1 goes low and ties thepositive end of C4 to ground,That turns Q1 offWhen Q1 turns off,the voltage at the gate of SCR goes positive,turning on the SOP and sounding the alarm,The delay time is adjustable from just a few seconds(R6 set to its minimum resistance) to about one minute(R6 adjusted to its maximum resistance)   (View)

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THERMOSTAT_SWITCH_FOR_AUTOMOTIVE_ELECTRIC_FANS

Published:2009/6/14 22:25:00 Author:May

THERMOSTAT_SWITCH_FOR_AUTOMOTIVE_ELECTRIC_FANS
The circuit is based on a commercial temperature sensor(TS6178) and an MC3334P ignition chip. When the radiator temperature increaser,the sensor pulls the base of Q2 low via Q1, which is wired as a diode.Q2's collector thus goes high and riggers IC1,which switches its pin 7 output high and turns on the fan motor via Q3.   (View)

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EXIT_DELAY_FOR_BURGLAR_ALARMS

Published:2009/6/14 22:16:00 Author:May

EXIT_DELAY_FOR_BURGLAR_ALARMS
Depressing S1 charges C1 to the supply voltage. This biases Q1 on via bias resistors R2 and R3. A voltage is available for the duration of the delay period, to hold off the alarm circuit.C1 can be increased or decreased in value to al-ter the delay times.   (View)

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PIEZOELECTRIC_ALARM

Published:2009/6/14 22:13:00 Author:May

PIEZOELECTRIC_ALARM
01,C2...............047 Disc Capacitor Q1,Q2.......... ... 2N3906 Transistor R1................ 6.8K Resistor R2..................33K Resistor R3................. 200 ohm Resistor R4..................75K Resistor XDC.................Piezoelectric transducer The alarm uses a fixed-frequency piezoelectric buzzer in conjunction with the cadmium-sulfide (CDS) cell and the two-transistor circuit to provide a unique effect. Whenever light reaches the CDS photo-electric cell, the alarm is silent. But when no light strikes the cell, transistor Q1 tums on, and the circuit emits a high-pitched tone.The alarm consists of a piezoelectric disk that oscillates at the fixed frequency of 3. 137 kHz, cre-ated by transistor Q2, capacitor C1 and C2, and resistors R1 through R3. Transistor Q1 is used as a switch. It is forward-biased on by R4; however, the CDS cell turns Q1 off when the light is strik-ing it.A CDS photo cell is made from cadmium sulfide, a semiconductor material that changes resis-tance when the light strikes it. The greater the amount of light, the lower the resistance. The low re-sistance conducts positive voltage to the base of pnp transistor Q1, keeping it turned off' when the light shines on the CDS cell. As soon as the light is removed, the CDS cell provides a resistance of over 100 kQ. That causes Q1 to tum on, allowing a positive voltage to reach the emitter lead of Q2, which then begins to oscillate. That then causes the piezoelectric element (transducer) to produce a loud signal.   (View)

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HEAT_OR_LIGHT_ACTIVATED_ALARM

Published:2009/6/14 22:06:00 Author:May

HEAT_OR_LIGHT_ACTIVATED_ALARM
The tone generated by a 555 oscillator can be turned on (activated) by heat or light. That causes Q1 to conduct transistor W2 (TIP 3055).Q2 (TIP 3055) acts as an audio amplifier and speaker driver.   (View)

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NO_DOZE_ALARM

Published:2009/6/14 22:00:00 Author:May

NO_DOZE_ALARM
This circuit sends out a loud tone if the input switch(S2) is not retriggered at pre-set intervals. If you fall asleep and miss re-triggering the circuit, it will sound until you press S2.   (View)

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AUDIO_ALARM

Published:2009/6/14 21:59:00 Author:May

AUDIO_ALARM
In the circuit, UI amplifies the audio picked up by the condenser microphone. Resistor RI limits current, while R2 and R3 center the output of the amplifier to 1/2 B+ to allow a singleended sup-ply to be used. Diodes Dl and D2 rectify the output of U1, and C3 filters the resulting pulsing dc.Thus, a dc voltage that is proportional to the ambient sound level is produced.That voltage is presented to the noninverting input of U2. The inverting input is provided with a reference voltage of between 0 and 1/2 B+, which is set by R11.As long as the noise level is low enough to keep the voltage at pin 3lower than the voltage at pin 2, the output of U2 stays low (approximately 1V). That is enough to bias Q1 partially on. A voltage divider, formed by R8/RIO and Q1 (when it's partially on), prevents Q2 from turning on.When the noise level is high enough to bring the voltage at pin 3 higher than the voltage at pin 2, the output of U2 goes high. That turns Q1 fully on and drives Q2 into saturation. The piezo buzzer then sounds until the power is cut off.   (View)

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