Friday, October 31, 2014

Best Performance Interruption Detector Schematic

Best Performance Interruption Detector Schematic Circuit, The circuit presented here detects interruption in security systems. Its features include no false triggering by external factors (such as sun-light and rain), easy relative positioning of the sensors and alignment of the circuit, high sensitivity, and reliability. The circuit comprises three sections, namely, transmitter, receiver, and power supply. The transmitter generates modulated IR signals and the receiver detects the change in IR intensity. Power supply provides regulated +5V to the transmitter and the receiver. 

The power supply and the speaker are kept inside the premises while the transmitter and the receiver are placed oppo site to each other at the entrance where the detection is needed. Three connections (Vcc, GND, and SPKR) are needed from the power supply/speaker to the receiver section, while only two connections (Vcc and GND) are required to the transmitter. The transmitter is basically an astable multivibrator configured around NE555 (IC3). Its frequency should match the frequency of the detector/sensor module (36 kHz for the module shown in figure) in the receiver. The transmitter frequency is adjusted by preset VR2. For making the duty cycle less than 50 per cent, di-ode 1N4148 is connected in the charging path of capacitor C7. 

The output of astable multivibrator modulates the IR signal emitted from IR LEDs that are used in series to obtain a range of 7 metres (maximum). To increase the range any further, the transmitted power has to be raised by using more number of IR LEDs. In such a case, it is advisable to use another pair of IR LEDs and 33-ohm series resistor in parallel with the existing IR LEDs and resistor R5 across points X and Y. The receiver unit consists of a monostable multivibrator built around NE555 (IC2), a melody generator, and an IR sensor module. The output of the IR sensor module goes high in the standby mode or when there is continuous presence of modulated IR signal.

Circuit diagram :

 
High-Performance Interruption Detector Circuit Diagram
 
When the IR signal path is blocked, the output of the sensor module still re-mains high. However, when the block is removed, the output of the sensor module briefly goes low to trigger monostable IC3. This is due to the fact that the sensor module is meant for pulsed operation. Thus interruption of the IR path for a brief period gives rise to pulsed operation of the sensor module. Once monostable IC2 gets triggered, its output goes high and stays in that state for the duration of its pulse width that can be controlled by preset VR1. The high output at pin 3 of the monostable makes the musical IC to function. Voltage divider comprising R2 and R3 reduces the 555 output voltage to a safer value (around 3V) for UM66 operation. The du-ration of the musical notes is set by pre-set VR1 as stated earlier. 

For proper operation of the circuit, use 7.5V to 12V power supply. A battery backup can be provided so that the circuit works in the case of power failure also. Potmeter VR3 serves as a volume control. The transmitter, receiver, and power supply units should be assembled separately. The transmitter and the receiver should have proper coverings (booster) for protection against rain. The length of the wire used for connecting the IR sensor module and IR LEDs should be minimum. 

Note. 
 
The heart of the circuit is the IR sensor module (usually used in VCRs and TVs with remote); the circuit works satisfactorily with various makes of sensors. The entire circuit can be fixed in the same cabinet if the connection wires to the sensors are smaller than 1.5 meters. The reflection property of IR signals can also be used for small distance coverage. 



Sourced By: www.streampowers.blogspot.com
ReadMore..
Posted by at No comments:
Labels: , , , ,

VW Passat 1 L 2001 Headlights Wiring Diagram

VW
Headlights Wiring Diagram VW Passat 1.L 2001 Look inside behind the fuse panel. You’ll see the relay panel and relay 173. A closer look at relay 173 installed. Pull relay 173 out to disable the daytime running, Second method: Modifying the light switch The pin connectors at the back of the light switch lights. The object here is to stop electrical current from traveling through these pins.

For MY 1998-2001 Passats (B5) tape over, bend, or break pin TFL to disable the DRL when the light switch is in the OFF position. For MY 2001.5-2003 Passats (B5.5) tape over, bend, or break pin B to disable the DRL when the light switch is in the OFF position.

Here VW Passat 1 L 2001 Headlights Wiring Diagram

ReadMore..
Posted by at No comments:
Labels: , , , , , , ,

Balancing LiPo Cells Circuit Diagram

Things change fast in the electronics world, and that’s also true for recharge- able batteries. The rate of development of new types of rechargeable batteries has been accelerated by the steadily increasing miniaturisation of electronic equipment. LiPo cells have conquered the market in a relatively short time. Their price and availability have now reached a level that makes them attractive for use in DIY circuits.

Balancing LiPo Cells Circuit diagram

BalancingBalancing LiPo Cells Circuit diagram

Unlike its competitors Elektor Electronics has already published several articles about the advantages and disadvantages of LiPo batteries. One of the somewhat less well-known properties of this type of rechargeable battery is that the cells must be regularly ‘balanced’ if they are connected in series. This is because no two cells are exactly the same, and they may not all have the same temperature. For instance, consider a battery consisting of a block of three cells. In this case the outer cells will cool faster than the cell in the middle. Over the long term, the net result is that the cells will have different charge states. It is thus certainly possible for an individual cell to be excessively discharged even when the total voltage gives the impression that the battery is not fully discharged. That requires action – if only to prolong the useful life of the battery, since LiPo batteries are still not all that inexpensive. 

One way to ensure that all of the cells have approximately the same charge state is limit the voltage of each cell to 4.1 V during charging. Most chargers switch over to a constant voltage when the voltage across the batter terminals is 4.2 V per cell. If we instead ensure that the maximum voltage of each cell is 4.1 V, the charger can always operate in constant-current mode. 

When the voltage of a particular cell reaches 4.1 V, that cell can be discharged until its voltage is a bit less than 4.1 V. After a short while, all of the cells will have a voltage of 4.1 V, with each cell thus having approximately the same amount of charge. That means that the battery pack has been rebalanced. 

The circuit (Figure 1) uses an IC that is actually designed for monitoring the supply voltage of a microcontroller circuit. The IC (IC1) normally ensures that the microcontroller receives an active-high reset signal whenever the supply voltage drops below 4.1 V. By contrast, the out-put goes low when the voltage is 4.1 V or higher. In this circuit the output is used to discharge a LiPo cell as soon as the voltage rises above 4.1 V. 

When that happens, the push-pull output of IC1 goes low, which in turn causes transistor T1 to con-duct. A current of approximately 1 A then flows via resistor R1. LED D2 will also shine as a sign that the cell has reached a voltage of 4.1 V. The function of IC2 requires a bit of explanation. The circuit built around the four NAND gates extends the ‘low’ interval of the signal generated by IC1. That acts as a sort of hysteresis, in order to prevent IC1 from immediately switching off again when the voltage drops due the internal resistance of the cell and the resistance of the wiring between the cell and the circuit. The circuitry around IC2 extends the duration of the discharge pulse to at least 1 s.
Balancing


Figure 2 shows how several circuits of this type can be connected to a LiPo battery. Such batteries usually have a connector for a balancing device. If a suit-able connector is not available, you will have to open the battery pack and make your own connections for it. The figure also clearly shows that a separate circuit is necessary for each cell.
ReadMore..
Posted by at No comments:
Labels: , , , ,

Adjustable Power Supply 1 2 – 30V 5A using LM338

If you want to a variable dc voltage power supply circuit during 1.2V to 30Vdc and can provide a current maximum to 5A.

We may be have the many ways such as: to be modified the LM317 Variable Regulator 0-30V 1A by add the power transistor MJ2955 in circuit following Power supply regulator 1.2V-20V and 3V-6V-9V-12V 3Amp or will build the Variable dc regulator 0-30V 5A circuit to be well as well, But these methods. Rather cumbersome and wasting too money.

Adjustable

However we can build this circuit easily and cheap, By using the packages IC No. LM338 only one, Similar to the LM317 IC number, but it can supply up to 5A, as the circuit shown in Fig.

How this circuit works
-The transformer T1 converts the AC 220V to 24 Vac, so be rectified the current by the bridge diode rectifier BD1 – 10A 400V. Until DCV has come out that the filter capacitor C1 is equal to 35 volt.
-The IC1 is the heart of the operation of this circuit. By the voltage output value obtained from the IC depends on the voltage value at the Adj pin of IC1, or can be varied by adjusting the VR1.
-However output voltage will be approximately equal to 1.25+1.25VR1/R1
The output voltage at the output pin of the IC1 is a more powerful filter with the capacitor C3.
ReadMore..
Posted by at No comments:
Labels: , , , , , , , , ,

Alarm LED Light Circuit

This circuit yearn for act the performance of the equipment,otherwise Check the fuse here the circuit.The circuit is diminutive and the power supply voltage of all kinds. It demonstrate with LED, 2-color in individual. Which is cathode universal kind,the anode has two separate terminals. If the circuit is functioning well LED, it revealed in wet behind the ears colour.The display is red, as the fuse into the circuit is damaged.The resistor R1 limits the current to gush through the LED is roughly 2 mA.This is an adequate amount to produce the LED light.If it lowers the R1 down, the LED light up.

Alarm
Alarm LED Light Circuit Diagram

In the conventional setup of the circuit and The fuse is not damaged. The zener diode to prevent the green and red LED illumination up in chorus.Zener diode prevents the LED is simple and red illumination all together.
The piercing efficiency LED, as soon as connected trendy like. The red LED uses high-pressure, so with the intention of single green LED illumination up only. Diodes D3 and D4 wish prevent dodgy instead of the LED. While the semi cycle downbeat voltage of the alternating current voltage.However, if the DC supply voltage.I act not retain to manage diode protection.

ReadMore..
Posted by at No comments:
Labels: , , ,

Automatic Fan Controller Circuit Diagram

This circuit will turn on/off 12V DC fan or CPU fan when temperature above normal temperature.You can set turn on temperature by adjust VR1. This circuit use an NTC (Negative temperature coefficient)which is a thermistor is one in which the zero-power resistance decreases with an increase in temperature. So If temperature increate the voltage at pin 3 on LM311 will decreated .The resistance of NTC is about 10K at 25c.

VR1 should be multi-turn potentiometer type such 10K/25 turn
ReadMore..
Posted by at No comments:
Labels: , , , ,

Thursday, October 30, 2014

Precision Headphone Amplifier Circuit Diagram

Designs for good-quality headphone amplifiers abound, but this one has a few special features that make it stand out from the crowd. We start with a reasonably conventional input stage in the form of a differential amplifier constructed from dual FET T2/T3. A particular point here is that in the drain of T3, where the amplified signal appears, we do not have a conventional current source or a simple resistor. T1 does indeed form a current source, but the signal is coupled out to the base of T5 not from the drain of T3 but from the source of T1. Notwithstanding the action of the current source this is a low impedance point for AC signals in the differential amplifier.

Precision Headphone Amplifier Circuit diagram:


Precision
Precision Headphone Amplifier Circuit Diagram

Measurements show that this trick by itself results in a reduction in harmonic distortion to considerably less than –80 dB (much less than 0.01 %) at 1 kHz. T5 is connected as an emitter follower and provides a low impedance drive to the gate of T6: the gate capacitance of HEXFETs is far from negligible. IC1, a volt-age regulator configured as a current sink, is in the load of T6. The quiescent current of 62 mA (determined by R11) is suitable for  an output power of 60 mWeff into an impedance of 32 Ω, a value typical of high-quality headphones, which provides plenty of volume.

Precision

Using higher-impedance headphones, say of 300 Ω, considerably more than 100 mW can be achieved. The gain is set to a useful 21 dB (a factor of 11) by the negative feedback circuit involving R10 and R8. It is not straightforward to change the gain because of the single-sided supply: this voltage divider also affects the operating point of the amplifier. The advantage is that excellent audio quality can be achieved even using a simple unregulated mains supply.  Given the relatively low power output the power supply is considerably overspecified. Noise and hum thus remain more than 90 dB below the signal (less than 0.003 %), and the supply can also power two amplifiers for stereo operation.

The bandwidth achievable with this design is from 5 Hz to 300 kHz into 300 Ω, with an output voltage of 10 Vpp. The damping factor is greater than 800 between 100 Hz and 10 kHz. A couple of further things to note: some-what better DC stability can be achieved by replacing D1 and D2 by low-current red LEDs (connected with the right polarity!). R12 prevents a click from the discharge of C6 when headphones are plugged in after power is applied. T6 and IC1 dissipate about 1.2 W of power each as heat, and so cooling is needed. For low impedance headphones the current through IC1 should be increased. To deliver 100 mW into 8 Ω, around 160 mA is required, and R11 will need to be 7.8 Ω (use two 15 Ω resistors in parallel).

To keep heat dissipation to a reasonable level, it is recommended to reduce the power supply volt-age to around 18 V (using a transformer with two 6 V secondaries). This also means an adjustment to the operating point of the amplifier: we will need about 9V between the positive end of C6 and ground. R4 should be changed to 100 Ω, and R8 to 680 Ω. The gain will now be approximately 6 (15 dB). The final dot on the ‘i’ is to increase C7 by connecting another 4700 µF electrolytic in parallel with it, since an 8 Ω load will draw higher currents.

Author : Hergen Breitzke - Copyright : Elektor
ReadMore..
Posted by at No comments:
Labels: , , , ,

Solar Hot Water Panel Differential Pump Controller Diagram Circuit

This circuit optimises the circulation of heated water from solar hot water panels to a storage cylinder. It achieves this by controlling a 12V DC pump, which is switched on at a preset temperature differential of 8°C and off at about 4°C. This method of control has distinct advantages over some systems that run the pump until the differential approaches 0°C. In such systems, the pump typically runs whenever the sun shines. A small 10W solar panel charging a 12V SLA battery is sufficient to run the controller. Most commercial designs use 230VAC pumps, which of course don’t work when there is a power outage or there is no AC power at the site.

SolarOperation:

Temperature sensors TS1 & TS2 are positioned to measure the highest and lowest water temperatures, with one at the panel outlet and the other at the base of the storage cylinder. The difference between the sensor outputs is amplified by op amp IC1d, which is configured for a voltage gain of about 47. As the sensors produce 10mV/°C, a difference of 8°C will produce about 3.76V at the op amp’s output (pin 14). The output from IC1d is fed into the non-inverting input (pin 10) of a second op amp stage (IC1c), which is wired as a voltage comparator. The op amp’s inverting input (pin 9) is tied to a reference voltage, which can be varied by trimpot VR3. When the voltage from IC1d exceeds the reference voltage, the output of the comparator (pin 8) swings towards the positive rail.

A 10MW resistor feeds a small portion of the output signal back to the non-inverting input, adding some hysteresis to the circuit to ensure positive switching action. A third op amp stage (IC1b) acts as a unity-gain buffer. When the comparator’s output goes high, the buffer stage switches the Mosfet (Q1) on, which in turn energises the pump motor. Mosfet Q1’s low drain-source on-state resistance means that in most cases, it won’t need to be mounted on a heatsink. The prototype uses a Davies Craig EBP 12V magnetic drive pump, which draws about 1A when running and is suitable for low-pressure hot water systems only (don’t use it for mains-pressure systems as it may burst!). For mains-pressure systems, the author suggests the SID 10 range of brass-body magnetic drive pumps from Ivan Labs USA.

Circuit diagram:Solar
Solar Hot Water Panel Differential Pump Controller Circuit Diagram
Setup:

Each LM335 temperature sensor and its associated trimpot is glued to a small copper strip using high-temperature epoxy. It is then waterproofed with silicon sealant and encapsulated in heatshrink tubing. Standard twin-core shielded microphone cable can be used for the connection to the circuit board. Before sealing the two units, adjust their trimpots to get 2.98V at 25°C [(ambient temperature x .01) + 2.73V] between the "+" and "-" terminals. When both have been adjusted, clamp them together and allow their temperatures to stabilise for a few minutes. Next, measure the output voltage from the differential amplifier (IC1d), which should be close to 0V. If not, tweak one of the pots until it is.

Separate the two and warm the panel sensor (TS1), monitoring the output of IC1d. You should see a marked increase in voltage, remembering that an 8°C difference between the sensors should give an output of about 3.76V. The pump switch-on point is set by VR3 and can be adjusted over a practical range of about 4-10°C differential (1.88-4.70V). Adjust VR3 to get about 3.8V on pin 9 of IC1c as a starting point. If set too low and the panels are located far from the cylinder, much of the heat will be lost in the copper connecting pipes. On the other hand, if set too high and the weather is mostly cloudy, then the pump will not switch on very often, as the panels will not get hot enough. For best results, use copper pipes for the panel plumbing and insulate them with tubes of closed-cell foam.

As the pipes cool down between pump operations, small diameter pipes of 15mm are more efficient than larger sizes as they contain less static water. In practice, the pump in the author’s setup switches on for about 30 seconds every 4-5 minutes. As the Davies pump shifts 13 litres/minute, it displaces the heated water from a single panel in about 14 seconds. There is a thermal lag in the sensor readings, so after the pump stops, the temperature difference will keep decreasing for 40 seconds or so as the panel sensor cools down and the cylinder sensor heats up.
Author: Mike Scaife - Copyright: Silicon Chip Electronics
ReadMore..
Posted by at No comments:
Labels: , , , , , , , , ,

Nmos Power Amplifier Series Part 3

 Nmos400
A power amplifier module capable of up to 400 watts into a 4 ohm load depending on power supply and the output mosfets used.  The layout makes use of older style TO3 mosfets.

Nmos400-TO3 Schematic
Nmos400-TO3 Layout

Nmos350 Mk2
This revised version yet to be built improves a few perfomance areas. I considered more complex ideas but this increased the component count and original idea of the amp would have been lost; that is a powerful high quality amplifier that used commonly available and cheap components.
  1. A LED as the voltage reference for the first stage constant current source tracks changes in temperature slightly better that than the old double diode setup.
  2. A cascode second stage makes it faster and more linear.
  3. Better clipping attributes
  4. The fuse has been shifted out of the voltage drive loop between the driver and output stages.

Nmos350 Mk2 Schematic



ReadMore..
Posted by at No comments:
Labels: , , , , ,

PCB Layout Power Amplifier LM4780

I get different boards for LM4780 based amplifier designed when I was several samples from National Semiconductor. I was one-sided copper board to bring in my market, so I created the board on one side only.

This is the first. I build them from scratch. Study the pin details of LM4780 and I draw on the paper presented, as well as the basic circuit schematic.

A little tuning of the power supply PCB for thicker tracks.

PCB
PCB Layout Power Amplifier LM4780
But there was a major obstacle – 6 nos of jumper wires connecting the IC. I wanted to avoid, so I designed the new board. A very good thing I came to know about from DiyAudio, was the use of n / c pins. So this was all new, third version. It turned out that the most compact and straight layout. I have about 10 PCBs of this one.

This is the latest. I tried two other bridges in V++ wiring systems and further thicken the power to remove traces. Mmm, still thinking to go for a different version, this time a little more spacious. Troubleshooting can be difficult to compact circuit boards.
ReadMore..
Posted by at No comments:
Labels: , , , ,

300 Watt Quasi with 2N3773

Nbip300 with transistor 2N3773
This amplifier was designed to provide a use for the otherwise useless TO3 power transistors that many hobbyists have in their junk pile.  With good construction the module is capable of high quality performance and is rated to 300 watts into a 4 ohm load depending on power supply.  With the driver and output transistors specified it is limited to DC rails of +/- 70 volts. 

Nbip300 Schematic


Nbip300 Layout

ReadMore..
Posted by at No comments:
Labels: , , , ,

Bass Guitar Amp Vocal Adaptor Circuit Diagram

This is where the technical problems arise not in terms of the .25” (6.3 mm)  jack, but in terms of the sound quality (the words  are barely understandable) and volume (the amp  seems to produce fewer decibels than for a guitar). What’s more, unpredictable feedback may cause damage to the speakers and is very unpleasant on the ear. This cheap little  easy-to-build project can help solve these technical  problems. 

Vocal Adaptor for Bass Guitar Amp Circuit diagram :



Vocal Adaptor for Bass Guitar Amp Circuit Diagram
 
A guitar (or bass guitar) amplifier is designed first and foremost to reproduce the sound of the guitar or bass as faithfully as  possible. The frequency response of the amp doesn’t need to be as wide or as flat as in hi-fi (particularly at the high end), and so this sort of amplifier won’t permit faithful reproduction of the voice. If you build an adaptor to compensate for the amp’s limited frequency response by amplifying in advance the frequencies that are  then attenuated by the amp, it’s possible to  improve the quality of the vocal sound. That’s  just what this circuit attempts to do. 

The adaptor is built around the TL072CN low-noise dual FET op-amp, which offers good value for money. The NE5532 can be used with almost the same sound quality, but at (slightly) higher cost. The circuit breaks  down into two stages. The first stage is used to match the input impedance and amplify the microphone signal. For a small 15 W guitar or bass amplifier, the achievable gain is  about 100 (gain = P1/R1). For more powerful amplifiers, the gain can be reduced to  around 50 by adjusting P1. The second stage amplifies the band of frequencies (adjustable using P2 and P3) that are attenuated by the guitar amp, so as to be able to reproduce the (lead)  singer ’s voice as clearly, distinctly, and  accurately as possible. To refine the adaptor and tailor it to your amplifier and speaker, don’t be afraid to experiment with the component values and the type  of capacitors. 

The circuit can readily be powered using a 9 V battery, thanks to the voltage divider R4/R5 which converts it into a symmetrical  ±4.5 V supply.
ReadMore..
Posted by at No comments:
Labels: , , , , , ,

Wednesday, October 29, 2014

Acoustic Distress Beacon Circuit Diagram

This is the Acoustic Distress Beacon Circuit Diagram. An ELT (Emergency Locator Transmitter, also known as a distress beacon) is an emergency radio transmitter that is activated either manually or automatically by a crash sensor to aid the detection and location of aircraft in distress. This acoustic ELT project is intended for radio control (RC) model aircraft, which every now and then decide to go their own way and disappear into the undergrowth. 

Acoustic Distress Beacon Circuit diagram :

 
Acoustic Distress Beacon Circuit Diagram

The audio locating device described here enables model aircraft that have landed ‘off limits’ to be found again and employs its own independent power supply. The small cam-era battery shown in the circuit activates an acoustic sounder when radio contact is lost and produces a short signal tone (bleep) every ten seconds for more than 25 hours. Current consumption in standby and passive (with jumper J1 set) modes is negligible. The timing generator for the alarm tone is the Schmitt trigger AND-gate IC1.B; its asymmetric duty cycle drives a 5 V DC sounder via MOSFET transistor T1. All the time that the RC receiver output is delivering positive pulses, the oscillator is blocked by IC1.A and diode D1. Setting jumper J1 parallel to C2 also disables the oscillator and serves to ‘disarm’ the distress beacon.
ReadMore..
Posted by at No comments:
Labels: , , , ,

Automatic AC Power Switch Circuit Diagram

Holiday Home Electrical appliances accidentally left on  in (holiday) homes left unoccupied for a  short or a long period consume power  unnecessarily and can present a fire hazard. Everyone will be familiar with those  nagging thoughts, a few miles down the  road from the house: “Did I remember  to switch off the coffee machine? The  lights? The oven?” 

Automatic AC Power Switch Circuit diagram :

Automatic
Automatic AC Power Switch Circuit Diagram

Hotel rooms are often equipped with a  switch near the main door which enables the power supply to everything in  the room only when the plastic card (which  might contain a chip or have a magnetic strip  or a pattern of holes) that serves as the room  key is inserted. The circuit idea given here  to switch off lights and other appliances is  along the same lines. The solution is surprisingly simple. 

A reed contact is fitted to the frame of the main entrance door, and a matching magnet  is attached to the door itself such that when  the door is closed the reed contact is also  closed. To enable power to the house, press  S1 briefly. Relay RE1 will pull in and complete  the circuit for all the AC powered appliances in  the house. The relay will be held in even after  the button is released via the second relay contact and the reed contact (‘latching’ function). 

As soon as the main entrance door is  opened, the reed contact will also open.  This in turn releases the latch circuit and  consequently the relay drops out. The  various connected appliances will thus  automatically and inevitably be switched  off as soon as the house is left. The circuit is principally designed for  small holiday homes, where this mode  of operation is particularly practical. Of course, for any circuit that deals in AC  powerline voltages, we must mention  the following caution. 

Caution:
shock hazard! Construction and connection of this circuit  should only be carried out by suitably-qualified  personnel, and all applicable electrical safety  regulations must be observed. In particular, it  is essential to ensure that the relay chosen is  appropriate for use at domestic AC grid volt-ages and is suitably rated to carry the required  current.
ReadMore..
Posted by at No comments:
Labels: , , , , ,

Flashing LED Battery status Indicator Circuit Diagram

Signals when an on-circuit battery is exhausted 5V to 12V operating voltage A Battery-status Indicator circuit can be useful, mainly to monitor portable Test-gear instruments and similar devices. LED D1 flashes to attire the users attention, signaling that the circuit is running, so it will not be left on by mistake. The circuit generates about two LED flashes per second, but the mean current drawing will be about 200µA. Transistors Q1 and Q2 are wired as an uncommon complementary astable multivibrator: both are off 99% of the time, saturating only when the LED illuminates, thus contributing to keep very low current consumption. 

Flashing-LED Battery-status Indicator Circuit diagram :

Flashing-LED Battery-status Indicator Circuit Diagram

The circuit will work with battery supply voltages in the 5 - 12V range and the LED flashing can be stopped at the desired battery voltage (comprised in the 4.8 - 9V value) by adjusting Trimmer R4. This range can be modified by changing R3 and/or R4 value slightly.

When the battery voltage approaches the exhausting value, the LED flashing frequency will fall suddenly to alert the user. Obviously, when the battery voltage has fallen below this value, the LED will remain permanently off. To keep stable the exhausting voltage value, diode D1 was added to compensate Q1 Base-Emitter junction changes in temperature. The use of a Schottky-barrier device (e.g. BAT46, 1N5819 and the like) for D1 is mandatory: the circuit will not work if a common silicon diode like the 1N4148 is used in its place.

Parts :
R1,R7__________220R  1/4W Resistors
R2_____________120K  1/4W Resistor
R3_______________5K6 1/4W Resistor
R4_______________5K  1/2W Trimmer Cermet or Carbon
R5______________33K  1/4W Resistor
R6_____________680K  1/4W Resistor
R8_____________100K  1/4W Resistor
R9_____________180R  1/4W Resistor
C1,C2____________4µ7  25V Electrolytic Capacitors
D1____________BAT46  100V 150mA Schottky-barrier Diode
D2______________LED  Red 5mm.
Q1____________BC547   45V 100mA NPN Transistor
Q2____________BC557   45V 100mA PNP Transistor
B1_______________5V to 12V Battery supply
Notes :
  • Mean current drawing of the circuit can be reduced further on by raising R1, R7 and R9 values.



Source : Red Circuits
ReadMore..
Posted by at No comments:
Labels: , , , , , ,

Motor Generator Stepper

Stepper motors are a subject that keeps recurring. This little circuit changes a clock signal (from a square wave generator) into signals with a 90-degree phase difference, which are required to drive the stepper motor windings. The price we pay for the simplicity is that the frequency is reduced by a factor of four. This isn’t really a problem, since we just have to increase the input frequency to compensate. The timing diagram clearly shows that the counter outputs of the 4017 are combined using inverting OR gates to produce two square waves with a phase difference. This creates the correct sequence for powering the windings: the first winding is negative and the second positive, both windings are negative, the first winding is positive and the second negative, and finally both windings are positive.

Circuit diagram:Stepper
Stepper Motor Generator Circuit Diagram

Internally, the 4017 has a divide-by-10 counter followed by a decoder. Output ‘0’ is active (logic one) as long as the internal counter is at zero. At the next positive edge of the clock signal the counter increments to 1 and output ‘1’ becomes active. This continues until output ‘4’ becomes a logic one. This signal is connected to the reset input, which immediately resets the counter to the ‘zero’ state. If you were to use an oscilloscope to look at this output, you would have to set it up very precisely before you would be able to see this pulse; that’s how short it is. The output of an OR gate can only supply several mA, which is obviously much too little to drive a stepper motor directly. A suitable driver circuit, which goes between the generator and stepper motor.
ReadMore..
Posted by at 1 comment:
Labels: , ,

Simple Amplifier with C945 MJE340 and TIP3055

This simple amplifier does sound good quality Power output about 10 - 14 Watts with Supply voltage about 34 - 36 Volt DC. It requires a preamp in the function of it hasnt got much advance. It requires cumbersome heat up sinks and a great transformer and a enormous power supply and alert wiring, but taking part in the bottom it is enormously regular and it sounds very good. The zener diode rubbish every wave future from the power supply, But you still barely aspire a ripple of 10mV be very successful. The swell triumph the input is enlarged, so the zener diode gets free of with the intention of, but whatever swell in attendance is wish still catch the power stage. The Buffer Stage using transistor C945 , Driver Stage Using MJE340 and Booster Stage using TIP3055 . The Transistor are using NPN transitor.

Simple Amplifier using with MJE340 TIP3055 Schematic Circuit Diagram
ReadMore..
Posted by at No comments:
Labels: , , , , , ,

Amplifier Output Delay with Relay

This is a minimal circuit which I built to individual of my audio amplifier projects to control the presenter output relay. The end of this circuit is to control the relay which turns on the speaker output relay within the audio amplifier. The impression of the circuit is time lag around 5 seconds ofter the power up until the speakers are switched to the amplifier output to circumvent grating “pound” sound from the speakers. an added appear of this circuit is so as to is disconnects the orator just now once the power within the amplifier is finish inedible, so avoiding every now and then nasty sounds as soon as you trip the equipments inedible.

Amplifier Output Delay with Relay Circuit Diagram
Followed by power is functional to the power input of the circuit, the categorical stage of AC voltage charges C1. Then C2 starts to charge little by little through R1. while the voltage in C2 rises, the emitter output voltage of Q1 rises concurrently with voltage on C2. as the output voltage of Q2 is anticyclone an adequate amount of (typically around 16..20V) the relay goes to on state and the relay witches associate the speakers to the amplifier output. It takes typically around 5 seconds in the same way as power up until the relay starts to conduct (next to absolute epoch depends on the size of C2, relay voltage and circuit input voltage). as the power is switched rotten, C1 force not tied up it’s energy quite quickly. and C2 will transpire charged quite quickly through R2. into excluding than 0.5 seconds the speakers are disconnected from the amplifier output.

ReadMore..
Posted by at No comments:
Labels: , , , ,

Amplifier Class A Headphone Circuit Diagram

This circuit is derived from the Portable Headphone Amplifier featuring an NPN/PNP compound pair emitter follower output stage. An improved output driving capability is gained by making this a push-pull Class-A arrangement. Output power can reach 427mW RMS into a 32 Ohm load at a fixed standing current of 100mA. The single voltage gain stage allows the easy implementation of a shunt-feedback circuitry giving excellent frequency stability.

Circuit diagram :
Amplifier
Class-A Headphone Amplifier Circuit diagram

The above mentioned shunt-feedback configuration also allows the easy addition of frequency dependent networks in order to obtain an useful, unobtrusive, switchable Tilt control (optional). When SW1 is set in the first position a gentle, shelving bass lift and treble cut is obtained. The central position of SW1 allows a flat frequency response, whereas the third position of this switch enables a shelving treble lift and bass cut.
Note:
  • Before setting quiescent current rotate the volume control P1 to the minimum, Trimmer R6 to zero resistance and Trimmer R3 to about the middle of its travel.
  • Connect a suitable headphone set or, better, a 33 Ohm 1/2W resistor to the amplifier output.
  • Connect a Multimeter, set to measure about 10Vdc fsd, across the positive end of C5 and the negative ground.
  • Switch on the supply and rotate R3 in order to read about 7.7-7.8V on the Multimeter display.
  • Switch off the supply, disconnect the Multimeter and reconnect it, set to measure at least 200mA fsd, in series to the positive supply of the amplifier.
  • Switch on the supply and rotate R6 slowly until a reading of about 100mA is displayed.
  • Check again the voltage at the positive end of C5 and readjust R3 if necessary.
  • Wait about 15 minutes, watch if the current is varying and readjust if necessary.


Parts List :
P1 : 22K Dual gang Log Potentiometer 
R1 : 15K 
R2 : 220K
R3 : 100K
R4 : 33K 
R5 : 68K 
R6 : 50K 
R7 : 10K 
R8,R9 : 47K 
R10,R11 : 2R2 
R12 : 4K7
R13 : 4R7
R14 : 1K2
R15,R18 : 330K
R16 : 680K
R17,R19 : 220K
R20,R21 : 22K
C1,C2,C3,C4 : 10µF/25V 
C5,C7 : 220µF/25V
C6,C11 : 100nF
C8 : 2200µF/25V
C9,C12 : 1nF
C10 : 470pF
C13 : 15nF
D1 : LED
D2,D3 : 1N4002 
Q1,Q2 : BC550C 
Q3 : BC560C 
Q4 : BD136 
Q5 : BD135 
IC1 : 7815
T1 : 15CT/5VA Mains transformer
SW1 : 4 poles 3 ways rotary Switch 
SW2 : SPST slide or toggle Switch
 
 



ReadMore..




Posted by



at





No comments:
      

















Labels:
,
,
,
,
,
















          

        

          

        

Tuesday, October 28, 2014


          

        










TDA2009 Stereo Hi Fi Class AB Power Amplifier









The IC TDA2009 Stereo Hi-Fi Class AB Power Amplifier circuit design with the intention of looks parallel to the IC 8W +8 W stereo amplifier circuits of the earlier tape.But it pray adjust the IC amplifier in the same way as a figure TDA2009.inside the IC in support of circuit amplifiers, Hi-Fi rank AB. And output terse circuit protection sectors as well.But nearby will be present changed according to the properties of the IC. The TDA2009 IC is to qualify from the power supply 8-24 volts, the current most of 1-2 amp.An output voltage watt 10 watt 24 volt load 4 ohms, 0.351% distortion by a frequency 1 kHz, frequency response from 10 Hz-50 kHz by -3 dB to 36 dB of grow and the strength. input make signs by 100 mV.

TDA2009 Stereo Hi-Fi Class AB Power Amplifier Circuit Diagram
While raising the power supply circuit and input into the audio input.The audio input gone channel and absolute channel. desire it perform the same.So I explained the values of the missing channel merely lone box.gesticulate through C1 meant for protection dc stimulating To interfere with IC.
at that time liveliness to the input signal to pin 5 of IC.The non inverting pin wish not reach to time signals. The output from pin 8. Through C8 and to prevent DC and raise the low frequency response the better,so therefore sent to the spokesman.The C10 and C11 act to filter the light to look after the smooth sound




ReadMore..




Posted by



at





No comments:
      

















Labels:
,
,
,
,
,
,
,

























Temperature Sensitive Switch For Solar Collector Diagram Circuit









This circuit can be used to turn the pump on and off when a solar collector is used to heat a swimming pool, for example. This way the water in the collector has a chance to warm up significantly before it is pumped to the swimming pool. A bonus is that the pump doesn’t need to be on continuously. The basis of operation is as follows. When the temperature of the water in the solar collector is at least 10 °C higher than that of the swimming pool, the pump starts up.

The warm water will then be pumped to the swimming pool and the temperature difference will drop rapidly. This is because fresh, cool water from the swimming pool enters the collector. Once the difference is less than 3 °C the pump is turned off again. R10/R1 and R9/R2 each make up a potential divider. The output voltage will be about half the supply voltage at a temperature around 25 °C. C7 and C8 suppress any possible interference.

The NTCs (R9 and R10) are usually connected via several meters of cable, which can easily pick up interference. Both potential dividers are followed by a buffer stage (IC1a/IC1b). IC1c and R3, R4, R5 and R6 make up a differential amplifier (with unit gain), which measures the temperature difference (i.e. voltage difference). When both temperatures are equal the output is 0 V. When the temperature of the solar collector rises, the differential amplifier outputs a positive voltage.

This signal is used to trigger a comparator, which is built round an LM393 (IC2a). R7 and P1 are used to set the reference voltage at which the comparator changes state. R8 and P2 provide an adjustable hysteresis. R11 has been added to the output of IC2a because the opamp has an open collector output. A power switch for the pump is created by R12, T1 and Re1. D1 protects T1 against voltage spikes from the relay coil when it is turned off.

A visual indication of the state of the controller is provided by IC4 (UAA170), a LED spot display driver with 16 LEDs. The reference voltage for the comparator is buffered by IC1d and fed to input VRMAX of the UAA170. R20/D21 and R23/D22 limit the input voltages of IC4 to 5.1 V, since the maximum permissible input voltage to the UAA170 is 6 V. When there is no temperature difference, LED D20 turns on.

Circuit diagram:
Temperature Sensitive Switch Circuit Diagram For Solar Collector

As the temperature difference increases the next LED turns on. The full scale of the LED bar is equal to the reference voltage of the comparator. This means that when the last LED (D5) of the UAA170 turns on, the comparator switches state. This is also indicated by D2. The power supply has been kept fairly simple and is built around a LM7812 regulator. The circuit is protected against a reverse polarity at the input by D3.

You have to make sure that the input to the regulator is at least 15 V, otherwise it won’t function properly. There are a few points you should note regarding the mounting of the NTCs. NTC R9 should be placed near the output of the solar collector. You should choose a point that always contains water, even when some of the water flows back a little. NTC R10 should be mounted inside the filter compartment (where it exists), which continually pumps the swimming pool water.

This will give a good indication of the temperature of the water. The way the circuit has to be set up depends how it has been installed and is very much an experimental process. To start with, set hysteresis potentiometer (P2) halfway. Then set the reference voltage to about 1.5-2 V with P1. On a sunny day you can measure the voltage difference to get an idea as to which reference voltage needs to be adjusted. The hysteresis setting determines how long the pump stays on for, which is until the minimum temperature difference has been reached.
Author: Tom Henskens - Copyright: Elektor Electronics Magazine



ReadMore..




Posted by



at





No comments:
      

















Labels:
,
,
,
,
,
,
,
,

























9 to 5 Volt DC Converter









9
9 to -5 Volt DC Converter
By using IC NE555, which causes wave clear the sector output allows the voltage nearly 6V after the signify on the output from a pulse plus C2 acts charge through D1 to ground and if the pulse harmful capacitor C2 desire discharge. through diode D1 and capacitor C3 to chage so as to negative voltage is about-6V, but being aloof to the run to of absent-5V zener diode ZD1 current output will happen approximately 12mA. To test the circuit or else circuits with the purpose of may well need various circuits, but we take refusal fire-5V power supply-5V, but if the battery 9V circuit can allow us to avail yourself of the volt-5V being desired. 




ReadMore..




Posted by



at





No comments:
      

















Labels:
,
,
,
,
,

























12v TRICKLE CHARGER









12v TRICKLE CHARGER

The 12v Trickle Charger circuit uses a TIP3055 power transistor to limit the current to the battery by turning off when the battery voltage reaches approx 14v or if the current rises above 2 amp. The signal to turn off this transistor comes from two other transistors - the BC557 and BC 547. 

Firstly, the circuit turns on fully via the BD139 and TIP3055. The BC557 and BC 547 do not come into operation at the moment. The current through the 0.47R creates a voltage across it to charge the 22u and this puts a voltage between the base and emitter of the BC547. The transistors turn on slightly and remove some of the turn-on voltage to the BD139 and this turns off the TIP3055 slightly. 

This is how the 2 amp max is created. 

As the battery voltage rises, the voltage divider made up of the 1k8 and 39k creates a 0.65v between base and emitter of the BC557 and it starts to turn on at approx 14v. This turns on the BC 547 and it robs the BD136 of "turn-on" voltage and the TIP3055 is nearly fully turned off. 

All battery chargers in Australia must be earthed. The negative of the output is taken to the earth pin.   
source : http://www.talkingelectronics.com.au/projects/200TrCcts/200TrCcts.html



ReadMore..




Posted by



at





No comments:
      

















Labels:
,
,

























STK465 Stereo Power Amplifier 2x30W









A amplifier of acoustic frequencies can be there manufactured with apparent supplies, despite is common so much the difficulties of conclusion of resources, I beg your pardon? the difficult of regulations. These difficulties are overcome relatively without difficulty if we locate amplifier modish form fulfilled.

Completed STK465 is an amplifier of acoustic frequencies to offers qualitative output, using nominal outdoor elements. Substantially he is lone of bulky complete force. Has a line pins and incorporated metal rise on behalf of adaptation in cooler. The provision pins in a line, facilitates the placement complete inwards the point printed and his support in cooler. The circuit functions in a big range of remuneration of catering, from 20V seeing that 60V, and it attributes 30WRMS, at what time the tendency of catering is higher than 50V and composer resistance of loudspeaker is the 4 or else 8 Ohm. The catering ought to be real symmetrically.

while it functions with tendency 56V it follows that the tendency self-control be ± 28V since meant for the ground. With this recommended tendency of catering, the attributed force is 30 WRMS hip charge 8W. The consequences of malformation is acceptable and oscillates around in the 0,08% for force of expense from 1W until 30W. Curve response his it is extended from 10Hz and reaches 100 KHz, with divergence 0dB and -3dB in that order, measured in force 1W. Using evolved techniques, concluded amplifier STK465, can minimise the deformities even in the field of highest levels of force. Other naturally to facilitate determines the finished circuit they are: the broad area and the exalted aid.

 STK465 is drawn to remain constant, whilst it functions in conjunction clogged bronchi with enormous collect. equally all the amplifiers, hence and this, under certified unfavourable conditions, can seizure happening oscillations. These oscillations say as answer of recurring in the same stage from the exit in the opening, or else from bad wily PCB, or else from bad superior of corridors in the circuits of entry. as soon as you entice a printed circuit, it is critical to return the current of charge and the current of show of entrance arrived the ground, via dissimilar corridors. usually, conclusive is the charge it is connected unswervingly in pin the catering and in meticulous in collective pin electrolytic the catering. If statement and charge are connected directly in the 0V via the same road, so therefore are produced retroactions, pardon? receive in the same way as consequence oscillations and the abnormality. To you we propose maintaining as much as potential slighter the cables of ground 0V and the capacitors of unharnessing, so with the aim of are some degree of the results of self-induction and resistance of outline of copper PCB. on occasion the oscillation is allocated during great time taken drivers involving way in and expense, particularly if these allow big length and the dense resistance of source are superior. Can anticipate the oscillation with the aim of is to be paid in extended wirings, accumulation capacitor from 50 - 500pf relating pins access. in favor of the low abnormality, of the essence role the stage furthermore the placement of conductors of catering. This be supposed to be present reserved the same as much as likely additional far from the wiring of entrance, so with the purpose of is deterred in this way the not linear catering stylish the entry of IC.  STK 465 does not boast technique of thermal protection, so to facilitate are avoided the thermal elations. If the hotness of JC reaches in from head to foot outlay, at that time the amplifier changes the polarisation of rung of expense. If the heat is increased, then in order to is ensured the business it ought to you grow cooler. The amplifier functions with catering of lookalike polarity. into form 1 we envision the electronic circuit of amplifier so as to Is based on the STK 465.


STK465


The circuit is stereo and has two channels of amplifier in a nutshell. It is a strict manipulative to facilitate develops positively all the particularities completing. Concretely, we observe that the not inverting access fulfilled (pins 2 and 15, pro all channel), is supplied from dividing wall of tendency, which ensures tendency from the tendency of expense completing. next to the same period with the application inwards apiece channel, exists a capacitor 470rF, which achieves the unharnessing, in to it concerns the AC components of climax frequency, while en line a capacitor 1mF allows in the amplifier to be situated supplied from advantageous show acoustic frequencies, fence simultaneous the unremitting piece. Bronchi unharnessing it is realised with the help of networking of two resistances 33KW and 330W and a capacitor 100mF, which to end with ensures dynamic of aid equal with 100. Finally, by the same occasion with the exit exists networking RC (0,1mF - 4,7 Ohm) to it attends to the minimisation of phenomenon  crossover.  The amplifier can survive supplied from a line of doppelganger polarity. Still it can function under a open region of tendencies (±10V for instance ±28V). The supplies of current depend from the force of expense and it can they instigate from 120mA up to 1A. It is very foremost the catering to stay adequately unharnessing, so with the aim of is avoided imports of maddening noises.

Parts :
R1= 1K C1= 1uF/35V R2= 3,3K C2= 470pF R3= 100 C3 = 100uF/60V R4 = 330 C4 = 100uF/60V R5 = 3,3K C5 = 10uF/60V R6 = 1K C6 = 47uF/60V R7 = 0,33 C7 = 8,2pF R8 = 33К C8 = 0,1uF R9 = 4,7 C9 = 1uF/35V R10 = 1К C10 = 470pF R11 = 3,3К C11 = 100uF/60V R12 = 100 C12 = 100uF/60V R13 = 330 C13 = 10uF/60V R14 = 3,3К C14 = 47uF/60V R15 = 1К C15 = 8,2pF R16 = 0,33 C16 = 0,1uF R17 = 33К R18 = 4,7 IC1 = STK465 LS1 = Speaker 40W 8 or 4 Ohm



ReadMore..




Posted by



at





No comments:
      

















Labels:
,
,
,
,

























Series electric circuit









Series electrical circuit is an electrical circuit, in which the input of a component derived from the output of other components. This has led to a series electrical circuit can save costs (fewer connecting cables used). In addition to own excess, a series electrical circuit also has a weakness, if one component is removed or damaged, then the other components will not function properly. Eg light bulbs strung together three series, the input of a single lamp light output will come from the other. If one lamp removed or damaged, then the other lights will go off. Consider the following series of three lights :


Series
Series electric circuit of three lights.
Replacement series resistance equation can be sought from the initial equation, in which a strong electric current on each of each hambaran is the same, while the potential difference across each distinct value of each barrier.



ReadMore..




Posted by



at





No comments:
      

















Labels:
,
,

























IC RD15HVF1 bassed RF amplifier electronic Circuit diagram 









This RF amplifier electronic project circuit is designed for 525MHz frequency band . This RF amplifier electronic project is based on the RD15HVF1 MOS FET type transistor specifically
designed for VHF/UHF High power amplifiers .
This RD15HVF1 rf amplifier circuit project can provide a maximum High power of 15 watts and a gain power more than 7dB using few external electronic parts . This amplifier circuit project must be powered from a 12 volts dc power supply .

C1 capacitance must have a value of 10uFand must be formed from 2200pf capacitors connected in parallel . C2 capacitor must be formed from two capacitors of 2200pf connected in parallel . C3 capacitance must have a value of 330uF and must be formed from 2200pf capacitors connected in parallel . L1 L2 and L3 coils must be formed from 1.6mm silver plateted copper wire on a diameter of 6mm . L1 must have 4 turns , L2 must have 2 turns and L3 must have 4 turns .
As you can see in schematic circuit , this electronic project based on MOS FET type transistor require few external electronic parts . 



ReadMore..




Posted by



at





No comments:
      

















Labels:
,
,
,
,
,
,
,
,
,
















          

        

          

        

Monday, October 27, 2014


          

        










Discharge the large electrolytic capacitor load









If the switching regulator fails to work or fail to start, then it is usually of the electrolytic capacitor is storing charge. There are habits of some engineers dumping electrolyte capacitor like this using solder. This is actually a poor habit. Because without them knowing things like this sometimes can lead to broken solder element.

Why this may happen?
Note that the voltage on the electric charge of the electrolyte capacitor is 300V. While working voltage 220v only solder element. If the charge on the electrolytic capacitors are still full and the 220u electrolytic capacitors or more then this electric charge can only damage the solder element.

Another bad habit of throwing of the electrolytic capacitor is to download shortkan legs electrolyte capacitor with a screwdriver. It is no possibility of damaging electrolytic capacitor itself, in which connection leg electrolyte capacitor is no risk in it will burn.

How should the dumping of the electrolytic capacitors?
  • Always provide a resistor with a value of about 30k ~ 50k/2w
  • If the correct power supply to the problem fails to work, then the resistor is normally for a while we solder directly on the legs of of the electrolytic capacitor. And if the problem is ok, the new resistor is removed.




ReadMore..




Posted by



at





No comments:
      

















Labels:
,
,
,
,
,

























Voltage to frequency converters LM231 LM331









The LM231/LM331 family of voltage-to-frequency converters are ideally suited for use in simple low-cost circuits for analog-to-digital conversion, precision frequency-to-voltage conversion, long-term integration, linear frequency modulation or demodulation, and many other functions
Voltage-to-frequency converters LM231/LM331
Features Voltage-to-frequency converters LM231/LM331:
- Guaranteed linearity 0.01% max
- Improved performance in existing voltage-to-frequency
conversion applications
- Split or single supply operation
- Operates on single 5V supply
- Pulse output compatible with all logic forms
- Excellent temperature stability, ±50 ppm/°C max
- Low power dissipation, 15 mW typical at 5V
- Wide dynamic range, 100 dB min at 10 kHz full scale
- Wide range of full scale frequency, 1 Hz to 100 kHz
- Low cost



ReadMore..




Posted by



at





No comments:
      

















Labels:
,
,
,
,
,

























USB Voltage Converter 5V to 12V









This is a 5Volt to 12Volt DC-DC step-up (boost) converter circuitry with the intention of is especially ideal pro the USB powered applications. primarily of all a USB harbor has two current supply modes. beforehand detecting the connected device, it food highest 100mA to the load. once recognizing the device, it increases the output current up to 500mA. 
USB Voltage Converter 5V to 12V Schematic Diagram

Taking part in this circuit, controller (LT1618) moreover provides two input current modes. 100mA and 500mA input modes can be there selected by the user. Output currents are narrow due to the increased the makings difference on the output. as soon as the demand of the load increases, output voltage pray start to decrease. representing paradigm, if the circuit operates within the 100 mA input mode, once the load is 35 mA, the output voltage will come to pass reserved on 12V. But if the load increases to 50 mA, output voltage strength of character reduce to 8V to preserve the constant 100 mA input current. 



ReadMore..




Posted by



at





No comments:
      

















Labels:
,
,
,
,
,

























Power supply with driver TEA1507









Power supply with driver TEA1507 is mostly used by TV branded PHILIPS. Power Supply has an efficiency rate of up to 90% - thus requiring less cooling, as well as stand-by power required is less than 1 watt.

Power Supply with TEA driver is equipped with a variety of surge protector that has a high reliability - not easily damaged if any part of a damaged power supply circuit and power transistor or FET heat is not easily damaged. Power supply circuits are dapatapat working on ac input voltage between 85 up to 275v. The way it works with the driver circuit power supply TEA 1507 is quite simple, so easy tracking of damage to the circuit.


The picture above is the basic power supply circuit with TEA1507



ReadMore..




Posted by



at





No comments:
      

















Labels:
,
,
,
,

























Workings of STR IC Regulator Power Supply









The meaning STR in this article for example is a Sanken regulator series and Fairchild series STR-F/G/W KA05Q Is an ic Quasy Resonant Flyback (QRF) Swiching Regulator comprising (a) control IC and (b) power MOSFETs that are packed into a single unit. The regulator is designed so that only requires a few external components.

How it works :
A. UVLO (under voltage lock out)
Regulators will start working when the voltage Vcc start-up on pin-4 reaches 16V. Once the power supply voltage Vcc further work will be reimbursed through a switching transformer supplied from a diode rectifier. At the time the circuit was working when the voltage Vcc is less than 15V, the regulator controls will still work. regulator will stop working (protectionism) if the supply voltage Vcc drops to less than 11V.
  
2. Feedback control (pin-1)

PWM regulators work using the system, wherein the output voltage B + to stable controlled by the feedback circuit of the output voltage B + >>> >>> photo-coupler pin-1. A capacitor mounted on the pin-1 is used to prevent noise disturbance if anyone does not interfere with the working system.

  
3. Soft start (pin-5)
When the power is turned on first, then the circuit has not been working behind the Uman because there is no output voltage B +. This causes a heavy current on the MOSFET start. To prevent this, the regulator is equipped with soft start circuit internally and an external filter kapasitr.
If the power supply is used to monitor for example, the frequency of the regulator needs to be synchronized. External synchronization signal can be input through pin-5s
  
4. Protectors
Regulators are equipped with all sorts protector.
  • Over-current protector (OCP) or Over Load protector (OLP). For example, if there is damage to flyback or def yoke, it will cause the load voltage B + over. If there is such a case the regulator will die protectionism so that IC is not damaged. For over current sensor is a resistor with a small value that is placed on pin-2 to the ground.
  • Short protector. If the output voltage B + short, the regulator turns off protectionism.
  • Over-voltage protectors (OVP). Regulators are not equipped with a surge protector so if the feedback path disconnected can cause the output voltage of the transformer switching regulator power up or damaged .. With OVP protectionist regulator will die if the voltage supply Vcc pin-4 rise above 22.5v.
  • Thermal protector. Regulators will stop working if the temperature reaches 140 degrees Celsius.
6. Auto start.
Regulators will start automatically if the auto turns itself (protectionism) after OVP or OCP


read also ->>>> Troubleshooting STR IC Regulator Power Supply



ReadMore..




Posted by



at





No comments:
      

















Labels:
,
,
,
,
,
,

























Home Theater Installation









Installation - This for many is probably the biggest reason to go with the prepackaged kit rather than a huge system of individual component—ease of installation. Most, if not all, of the prepackaged kits are very simple to install, which eliminates the need for professional installation and takes a great deal of hassle out of the installation process.
Home Theater Installation

The prepackaged systems are not however, the type of systems you will want to purchase if you intend to build a better system over time as they are not easily upgradeable and most true enthusiasts are often disappointed with the quality of the speakers and sounds that come with these systems. However if you have limited space and limited funds, these systems are often a great place to start when it comes to a home theater. You can always pass it on to your children if you decide to upgrade later.




ReadMore..




Posted by



at





No comments:
      

















Labels:
,
,
















          

        

          

        

Sunday, October 26, 2014


          

        










Adjustable Switching Regulator Circuit with LM2576









The Adjustable Switching Regulator Circuit with LM2576 are monolithic integrated circuits that provide all the active functions for a step-down (buck) switching regulator, capable of driving 3A load with excellent line and load regulation. These devices are available in fixed output voltages of 3.3V, 5V, 12V, 15V, and an adjustable output version.
LM2576 IC Package
Requiring a minimum number of external components, these regulators are simple to use and include internal frequency compensation and a fixed-frequency oscillator. The Adjustable Switching Regulator Circuit with LM2576 offers a high-efficiency replacement for popular three-terminal linear regulators. It substantially reduces the size of the heat sink, and in some cases no heat sink is required.


IC Switching Regulator Circuit with LM2576

A standard Adjustable Switching Regulator Circuit with LM2576 of inductors optimized for use with the LM2576 are available from several different manufacturers. This feature greatly simplifies the design of switch-mode power supplies.

Other features include a guaranteed ±4% tolerance on output voltage within specified input voltages and output load conditions, and ±10% on the oscillator frequency. External shutdown is included, featuring 50 μA (typical) standby current. The output switch includes cycle-by-cycle current limiting, as well as thermal shutdown for full protection under fault conditions.

Features Adjustable Switching Regulator Circuit with LM2576 :
- 3.3V, 5V, 12V, 15V, and adjustable output versions
- Adjustable version output voltage range,1.23V to 37V
- Guaranteed 3A output current
- Wide input voltage range, 40V up to 60V for HV version
- Requires only 4 external components
- 52 kHz fixed frequency internal oscillator
- TTL shutdown capability, low power standby mode
- High efficiency
- Uses readily available standard inductors
- Thermal shutdown and current limit protection
- P+ Product Enhancement tested



ReadMore..




Posted by



at





No comments:
      

















Labels:
,
,
,
,
,

























Digital control system applications









Digital Control System is a branch of the control system with continuous time processes in the region associated with the digital controller as the controller of the control elements that control systems and computing discrete time. Depending on requirements, a digital controller can be shaped microcontroller and ASIC to a standard desktop computer. Because the digital computer system is discrete, then the Laplace transform is used in the control system is replaced with the Z-transform. Therefore, you must understand about the concept of continuous time and discrete time concept.


Flow Chart - Digital Control system applications

Digital computer also has a limited precision (See quantization) extra care needed to ensure that errors in the coefficients, A / D conversion, D / A conversion, etc. do not produce unwanted effects or planned.

The application of digital control can easily be done when used in a feedback form. Since the creation of the first digital computer in the early 1940s the price of digital computers has dropped significantly. The reason this is one of the many reasons for the application of digital control systems for the control of the control system. Other reasons:

Flexibile: easy to configure and reconfigure through software
* Scalable: can be set up programs tailored to the limits of memory or storage space at no extra cost
* Adaptable: program parameters can be changed with the times
* Static operation: digital computers are much more susceptible to environmental conditions rather than of capacitors and inductors



ReadMore..




Posted by



at





No comments:
      

















Labels:
,
,
,
















        

      









Subscribe to:
Posts (Atom)