Balance temperature switch

Usually we have seen in this type of equipment, consisting of thermistor or temperature sensor in variations. Around this time, found sensor which will that is new it that new, will be old it is old, Actually, because is known, and then some, I will explain it to someone who knows only
Temperature sensor with a semiconductor devices.
-It is actually, all the semiconductor resistance within. Which decreased when heated, will be very or least it is up to the agents used in the doping process. This includes a semiconductor, resistor, integrated circuit, transistor, etc..
-A diode is a semiconductor device at inexpensive, as compared to other devices, then select is temperature sensor in this circuit.

 
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Video amplifier splitter by transistor BD137-BC547-BC557

This is the video amplifier circuit or the video splitter circuit, it is designed to take video signal is stronger. Compensate for the loss of signal, and is video splitter video, which can connect up to three outputs. so is suitable for display on several television screens, or video tapes recording at the same time too. (Now may will no video tape.)
The advantage of this circuit is cheap, easy and the results are detailed in the circuit below.
How it works
Technical specifications
- Increasing rate Typically, the circuit video amplifier is designed to have low amplifier rates. (it different with the common pre-amp circuit) For our the circuit has the maximum gain ratio is only 4 times.
- Impedance is 75 ohms on both the input and output.
- Bandwidth of this circuit wide is 5 Mhz.
It can be seen that the circuit contains only three transistors. By Q1 (BC547), Q2 (BC557) acts as a signal amplifier, and Q3 (BD139 or BD137) serves as the output circuit of common emitter follower.
The input impedance of circuit is determined by the value of R1. The input signal entered through C2 to the base of Q1. By the VR1 is the set the level of the signal swing.

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Heat Sensor by IC 741

Click to View circuit Heat Sensor

DC Motor Control Circuit

Notes:
Here, S1 and S2 are normally open , push to close, press button switches. The diodes can be
red or green and are there only to indicate direction. You may need to alter the TIP31 transistors
depending on the motor being used. Remember, running under load draws more current. This
circuit was built to operate a small motor used for opening and closing a pair of curtains. As an
advantage over automatic closing and opening systems, you have control of how much, or how
little light to let into a room. The four diodes surriunding the motor, are back EMF diodes. They
are chosen to suit the motor. For a 12V motor drawing 1amp under load, I use 1N4001 diodes.

Frost Alarm or Cold Activated Switch by IC 741

Circuit : Andy Collinson
Email: anc@mitedu.freeserve.co.uk

Description:
A simple thermistor triggered cold switch with adjustable threshold.


Notes:
The thermistor used has a resistance of 15k at 25 degrees and 45k at 0 degrees Celsius. A suitable bead type thermistor can be found in the Maplin catalogue. The 100k pot allows this circuit to trigger over a wide range of temperatures.

If using a different thermistor then the control should match the new thermistor at its highest resistance, or be higher in value. The op-amp in this circuit is the ubiquitous 741. It may be catalogued as LM741, CA741 etc, all types will work. In this circuit it is used as a comparator. The non-inverting input (pin 3) is biased to half the supply voltage. The non-inverting input is connected to the junction of the thermistor and potentiometer. The control is adjusted so that the circuit is on when the thermistor is at the required temperature range. Once the thermistor is outside the temperature range its resistance alters and the op-amp output changes from near full supply to around 1 or 2 volts dc. There is insufficient voltage to turn on the transistor and the relay will not energise.

A slight amount of hysteresis is provided by inclusion of the 270k resistor. This prevents rapid switching of the circuit when the temperature is near to the switching threshold.

Voltage Controlled Switch using 555 Timer

Source :: http://www.zen22142.zen.co.uk/Circuits/Switching/vcs555.htm

Circuit : Miroslav Adzic - Serbia & Montenegro

Description:
In this circuit the 555 timer is used in a novel way, as a voltage controlled switch.

Notes:
The old and omnipresent NE555 can be very good at something it was not meant for: driving relays or other loads up to 200 mA. The picture shows an example circuit: if the input level rises over 2/3 of the supply voltage - it will turn on the relay, and the relay will stay on until the level at the input drops below one third of the supply voltage.

If the relay and D1 were connected between pin 3 and ground, the relay would be activated when the input voltage drops below one third, and deactivated when the input voltage goes over two thirds of the supply voltage.

It is also a nice advantage that the input requires only about 1 uA, which is something bipolar transistors can't compete with. (This high impedance input must not be left open.) A large hysteresis makes the circuit immune to noise. The output (pin 3) can only be either high or low (voltage-wise), and it changes its state almost instantenously, regardless of the input signal shape.

The voltage drop across the NE555's output stage (at 35-100 mA) is 0.3-2.0 V, depending on the way the relay is connected and the exact current it draws. D1 is absolutely vital to the safety of the integrated circuit.

Circuit Video Amplifier by transistor BC547 & BC557

Circuit Video Amplifier by transistor BC547 & BC557

PCB Video Amplifier by transistor BC547 & BC557

Circuit Sound SCR Swith by IC 1458 & SCR C106D

Circuit Sound SCR Swith by IC 1458 & SCR C106D


PCB Sound SCR Swith by IC 1458 & SCR C106D

Circuit Light Relay Switch By BC547 & BC337

Circuit Light Relay Switch By BC547 & BC337

PCB Light Relay Switch By BC547 & BC337

Water Alarm with LM350

Circuit Water Alarm with LM350

Touch Switch By IC 4001 & 4020

Circuit Touch Switch By IC 4001 & 4020

Dfferential Temperature Relay Switch by IC 741

Circuit Dfferential Temperature Relay Switch by IC 741

D.M.M. To Stopclock Converter with CA3140

Circuit D.M.M. To Stopclock Converter with CA3140

555 IC Timer control relay Switch

Circuit 555 IC Timer control relay Switch

Opto-Thermo Control Relay Switch with IC 741

Circuit Opto-Thermo Control Relay Switch with IC 741

Infrared Intruder Alarm

circuit Infrared Intruder Alarm

12V DC Motor Speed Controller by 4011

this is circuit 12V DC Motor Speed Controller by 4011.

Remote and Touch Volume Controls by MC3340P

circuit Remote and Touch Volume Controls by MC3340P

Electronic car ignition

Description:
This scheme is for 4 cylinder motor. This will make your car spent less fuel, be a little bit faster and you won�t have to frequently open your distributor cap to change the contact buttons thus wasting less money.

T1/T2 create one monostable multivibrator in which C2 and R5 determine the length of impulse which is 1,5 msec. Next in line are T3 and then T4 which is Darlington transistor specially developed for electronic ignition which is used as a switch to turn on/off primary coil. Impulses from switch P turn on monostable multivibrator T1/T2. You need to un-connect capacitor that is in distributor cap because it is not needed anymore. While switch P is closed T1 is in off state but T2 is in on state, also T3 and T4 which enables current to flow trough primary coil. When switch P is opened, T1 gets in on state for a moment causing C2 to charge over R6 which makes T2 go to off state because of voltage drop on R6. When T2 is off also T3 and T4 are off and current that was flowing trough primary coil is stopped. Because T2 is in off state, voltage on R8 is increased which is passed trough R5 on T1 base which is still in on state and C2 is still charging. After 1,5 msec. C2 value reaches the level where T2 goes to on state again and T1 goes to off state. Now T2, T3 and T4 are in on state, again, and current flows trough primary coil again. R2 and D1 are used to neutralize the effect of impulses caused from «jumping» of switch P which could turn on monostable multivibrator when it shouldn't.

Zener diodes Z5 and Z6 are together with R10 limit overcharged voltage impulses that are caused by self induction of primary coil which could damage T4. They should be connected as close as possible to T4.
D7 protects device from wrong polarity.

Coil should have ratio of 1:80 or 1:100 with external resistor Rv which is used for better cooling. Total resisting value (Rp) of primary coil and Rv resistor shouldn't be under 1,6 ohm's so current trough T4 wouldn�t be bigger than 10A.
Depending on Rp, R9 have different values:

120Ω/2W for Rp tot > 2,2Ω
100Ω/2W for 1,8Ω <>Parts:
D1-D4 = 1N4148
D5-D6 = BZX85C � 180 (replicable with all equivalent types with power of 1,3W)
D7 = 1N4001
R1 = 470 - 1W
R2 = 22k
R3 = 2,2k
R4 = 1k
R5 = 4,7k
R6 = 39k
R7 � R10 = 100
R8 = 680
C1 � C2 = 47nF (ceramic)
C3 = 0,22uF 400V (ceramic)
C4 = 100uF (electrolytic)
T1 � T2 = BC327 (BC327-25, BC327-40)
T3 = BC237B (BC547B, BC547C)
T4 = BUX37 (BU323, BU920, BU921, BU922, BUV37B (u TOP3), BUW29, BUW81, MJ10012, MJ10013, MJ10014, TIP662, TIP665, 2SD683)

Touch 'N Flip

Ever wonder how a touch plate, like the kind you see on some elevators and lamps work? This circuit will give you a feel for how the touch plate works in a circuit and you can expand on the circuit to suit your project needs. The touch plate can be a small piece of metal or aluminum foil. Start the circuit by moving S2 to the set position and then back to the previous position. Now press S1. One of the LED's will light. Now touch the touch plate and the LED's will flip on the opposite way. The sensitivity of the plate will vary depending on the humidity. Adjust the VR and capacitor that is connected to S2 to adjust the sensitivity.

From : http://home.maine.rr.com/randylinscott/apr21.htm