Showing posts with label power. Show all posts

Friday, December 12, 2014

Plus and Minus DC Power Supply

This is a classic example of a regulated DC power supply that produces both a positive 15v and a negative 15v from a 20vac wall adapter.

Power Amplifier

    300w Sub-woofer Power Amplifier - High power amps are not too common as projects, since they are by their nature normally difficult to build and are expensive.
    LM3886 Power Amplifier - The LM3886 is a high-performance audio power amplifier capable of delivering 68W of continuous average power to a 4 ohm load and 38W into 8 ohm load.
    2.3 GHz Power Amplifier - 2 schematic which contains prototype and real one.
    20 Watt Class-A Power Amplifier - This amp uses the basic circuitry of the 60W power amp but has been modified for true Class-A operation.
    20 Watt / Channel Stereo Power Amplifier - This project is based almost directly on the typical application circuit in the National Semiconductor specification sheet.
    Simple Audio Power Amp - This simple audio power amplifier was originally designed for a circuit board workshop conducted by the OSU IEEE Student Group.
    Death of Zen (DoZ) - A New Class-A Power Amp - This project design specifically for headphones.
    Simple Current Feedback Power Amplifier - The first version of the amp uses a single power supply and capacitor coupled speaker.
    Single Chip 50 Watt / 8 Ohm Power Amplifier - This project is based almost directly on the typical application circuit in the National Semiconductor specification sheet.
    Soft-Start Circuit For Power Amps - The circuit presented in the website is designed to limit inrush current to a safe value.
    170W Audio Power Amplifier - Suitable for self-powered speakers, sub-woofers and quality car boosters.

Wednesday, November 19, 2014

Simple Power Supply with 2 transistors

Power Supply in this post is using a regulator which is composed of 2 pieces of NPN transistor. A transistor acts as a power regulator and a transistor again serves as a controller output voltage. Power Supply has an adjustable output with a range of 6-12 VDC. The part that serves as a power regulator is Q1 TIP31. Then the controller output voltage is a voltage divider composed of R3, R4, VR1 and R2 provide bias to the base of Q2 to control the power regulator Q1. In a series of power supply is mounted 5.1 V zener diode which serves to make the minimum limit the output voltage with Q2.

Power Supply With transistor circuit is quite simple and can be made with the PCB holes, so for those who want to try to directly mempraktikannya. May the power supply circuit can be useful for readers, especially for friends who need a power supply circuit with the regulator transistor.

Thursday, November 13, 2014

3 30V 3A Adjustable Regulated DC Power Supply

This power supply is meant as an auxiliary or as a permanent power supply for all common circuits based on a stabilized DC voltage between 3 and 30V provided that the consumption does not exceed 3A. Of course this power supply unit can also be used for other purposes. Be replacing the trimmer by a potentiometer, it may even be used as an adjustable power supply unit. A good quality heatsink must be used.
[...]
Parts list:
R1 = 8.2K
R2 = 2.2K
R3 = 680R
R4 = 1K
R5 = 82K
R6 = 0.18R/5W
C1 = 470p
C2 = 100nF-63V
C3 = 100nF-63V
C4 = 100uF-63V
C5 = 10KuF-60V
D1-D6 = 6.6A
Q1 = MJ3001 (Darligton)
IC1 = UA723D

Specifications:
* Overload protected
* Sshort-circuit stable
* Output current: max. 3A
* Output ripple voltage: 0.5mV
* Output voltage: adjustable from 3 to 30V, stabilized
* Input voltage: 9 to 30V AC (depending on the desired output voltage)

Source: http://www.extremecircuits.net/2010/02/3-30v-3a-adjustable-regulated-dc-power.html

Universal Features TDA2030 Power Amplifiers

This chip amplifier NCH TDA2030A company ST Microelectronics enjoys well-deserved popularity among radio amateurs. It has a high electrical performance and low cost, which allows for the least cost to collect her high UNCH capacity of up to 18 Watts. But not everyone is aware of its hidden virtues: it turns out at the IMS can collect a number of other useful devices. TDA2030A chip is a 18 W Hi-Fi class AB power amplifier or a driver for UNCH capacity of up to 35 W (with strong external transistor) . It provides high output current, has a small harmonic and intermodulation distortion, wide bandwidth reinforced signal, a very low level of own noise, built protection against short circuits output, an automatic system for limiting the power dissipation, holding a working point of output transistors IMS in a safe area. This chip implemented in the shell Pentawatt and has a 5 findings. At first, a brief look at several standard charts IMS application - bass amplifiers. The model scheme to include TDA2030A shown in Figure 1.

The

This chip is included on the scheme neinvertiruyuschego amplifier. Gain is determined by the ratio of resistance resistors R2 and R3, forming a chain of OOS. It is calculated by the formula Gv = 1 + R3/R2 and can be easily changed by selecting the resistance of a resistor. Usually this is done through the resistor R2. As can be seen from the formula, reducing resistance of the resistance increasing the gain (sensitivity) UNCH. Capacity capacitor C2 light of the fact that its capacitance Hs = 1 / 2? FS at a lower operating frequency was lower than R2 for at least 5 times. In this case, at a frequency of 40 Hz Hs _{2 = 1} / 6, 28 * 40 * 47 * 10 ^-6 = 85 ohms. Input resistance is determined by the resistors R1. As VD1, VD2 can use any silicon diodes with a current I _OL 0.5 ... 1 A and U _OBR more than 100, for example KD209, KD226, 1N4007. Hook-IMS in the case of a unipolar power source is illustrated in Figure 2.

Divisor R1R2 and resistor R3 form a chain of shifting to get at the outlet of IMS (conclusion 4) voltage equal to half the supply. This is necessary to strengthen both symmetrical poluvoln input. The parameters of this scheme at Vs = +36 V correspond to the scheme shown in Figure 1, when the power source of ± 18 V. Example of chips as a driver for UNCH with powerful external transistor is shown on Fig.3.

When Vs = ± 18 V at 4 ohm load amplifier power 35 Watts. In the food chain IMS includes resistors R3 and R4, a drop which is opening for transistors VT1 and VT2, respectively. In a small output (input voltage) current consumed IMS, low and the voltage drop on resistor R3 and R4 not enough to open the transistors VT1 and VT2. As the input voltage increases output and consumption current of IMS. In pursuing its value 0.3 ... 0.4 A voltage drop on resistor R3 and R4 will be 0.45 ... 0.6 V. begin to open transistors VT1 and VT2, while they will be included alongside the internal transistors IMS. As VT1 and VT2 can use any pair of complementary transistors respective capacities, for example KT818, KT819. Square scheme incorporating IMS is illustrated in Figure 4.

The signal from a commercial IMS DA1 via divider R6R8 at inverting input DA2, which provides chips in the opposite. At the same time increasing the voltage at the load and, consequently, increased power output. When Vs = ± 16 V at 4 ohm load power output reaches 32 Watts. For fans of the two-, three-UNCH this IMS - an ideal solution, because it can directly collect active LPF and HPF. The scheme of three-UNCH shown on Fig.5.

Low channel (NCH) is made on the scheme with powerful output transistors. At the entrance IMS DA1 included LPF R3C4, R4C5, the first link LPF R3C4 included in the chain of OOS amplifier. Such designs allows simple control (without increasing the number of links) get high enough slope recession ACHH filter. Medium (SCH) and high-frequency (HF) channel amplifier assembled on a model scheme for IMS DA2 and DA3 respectively. At the entrance SCH channel includes FHP C12R13, C13R14 and LPF R11C14, R12C15, which together provide the bandwidth of 300 ... 5000 Hz. The filter frequency channel assembled in the cell C20R19, C21R20. The cutoff frequency of each link, or LPF HPF can be calculated by the formula f = 160/RC, where the frequency f expressed in Hz, R - in kiloohm, S - in mikrofarad. These examples do not exhaust the possible application of IMC TDA2030A as a bass amplifier. For example, instead of feeding dvuhpolyarnogo Products (Fig.3, 4), you can use a unipolar power. To do this, minus the power source should zazemlit at neinvertiruyuschy (output 1) input file offset, as shown in Figure 2 (elements R1-R3 and S2). Finally, the output IMS between 4 and load the conclusion should include electrolytic capacitor, a blokirovochnye capacitors on the chain-Vs from the scheme should be deleted.

TDA2030A IMS represents nothing more than an operational amplifier with a powerful weekend cascade and a very good performance. Based on this, have been designed and tested with several non-standard inclusion. Some schemes has been tested "live" on the breadboard, some - modeled in the Electronic Workbench.

Powerful repeater signal.

The signal at the output device Fig.6 repeats in shape and amplitude of the input, but has great power, that is scheme can work at low pressures. Repeater can be used, for example, umoschneniya power supplies, increasing the output of low-frequency generator (so you can immediately feel the head speaker or acoustic systems). The band working frequency repeater is linear from dc to 0.5 ... 1 MHz, more than enough for the generator NCH.

Umoschnenie power sources.

This chip is included as a repeater signal, output voltage (output 4) is the input (output 1), and the output current can reach values of 3.5 A. Thanks to the built-protection scheme is not afraid of short circuits in the load. The stability of output voltage stability is determined by reference, that is stabilitrona VD1 Fig.7 and integral stabilizer DA1 Fig.8. Naturally, the pattern shown in Fig.7 and Fig.8, you can collect stabilizers and other stress, just need to keep in mind that the total (full) power dissipated by the chip should not exceed 20 Watts. For example, you need to build a stabilizer at 12 V and current 3 A. There is a ready source of food (transformer, rectifier and filter capacitor), which gives U _IP = 22 V, with the necessary current load. Then on the chip occurs voltage drop U _{IMS IP} = U - U _VYH = 22 -12 V = 10V and a current load 3 A dissipated power reaches values of R = U _{RAS IMS} * I * _N = 10B = 3A W 30, that exceeds the maximum value for TDA2030A. The maximum permissible voltage drop in the IMS can be calculated using the formula:

U _IMS = R _RAS.MAH / I _N. In our example, U _IMS = 20 W / 3 A = 6.6 V, thus the maximum voltage rectifier must be U = U _{new IP} + U _IMS = 12V + 6.6 V = 18.6 B. The number of turns of the transformer secondary windings will diminish. Resistance ballast resistor R1 in the pattern shown in Fig.7, you can count on the formula:

R1 = (U _IP - U _CT) / I _ST, where U _ST and _ST I - respectively voltage and current stabilization stabilitrona. The limits of the current stabilization can be found in the handbook, in practice for low stabilitronov his choosing within 7 ... 15 mA (typically 10 mA). If the current in the above formula to express in milliampere, the amount of resistance to get in kiloomah.

A simple laboratory power supply.

By varying the voltage at the entrance of IMS using potentiometer R1, produced a smooth adjustable output voltage. The maximum current, given a chip, depending on the output voltage and restricted the same maximum dissipated power at IMS. Calculate it could be the formula:

I _MAX = R _RAS.MAH / U _IMS

For example, if the output voltage U billed _VYH = 6, the chip is happening voltage drop U _{IMS IP} = U - U _VYH = 36 - 6 = 30, therefore, the maximum current is I _MAX = 20 W / 30 = 0.66 A. When U _VYH = 30 V maximum current can reach a maximum of 3.5 A, as well as a drop in the IMS slightly (6).

Stabilized laboratory power supply.

Source stabilized reference voltage - chip DA1 - powered by Parametric stabilizer at 15, collected at stabilitrone VD1 and resistor R1. Should IMS nurture DA1 directly from the source +36 V, it can be easily damaged (the maximum input voltage for IMS 7805 is 35 V). IMS DA2 included on the scheme neinvertiruyuschego amplifier gain which is defined as 1 + R4/R2 and is 6. Consequently, the output voltage adjustment potentiometer R3 can take the value from nearly zero to 5 * 6 = 30 V. With regard to the maximum output current, for this scheme true all this for a simple laboratory power supply (Fig.9). If it is less regulated output voltage (for example, from 0 to 20 in the U _IP = 24), elements VD1, S1 can be excluded from the scheme, but instead R1 set the jumper. If necessary, the maximum output voltage can change the selection of resistance resistor R2 and R4.

An adjustable current source.

At the entrance inverting IMS DA2 (concludes 2), thanks to the OOS through resistance load, supported by tension _U BX. As can be seen from the formula, load current does not depend on the resistance loads (of course, up to certain limits, due to end-voltage IMS). Therefore, changing the _U BX from zero to 5 V using potentiometer R1, with the fixed value of resistance R4 = 10 ohms, can be controlled through the current strain of 0 ... 0.5 A. The device can be used for charging batteries and electroplating elements. Charging current stable throughout the cycle of charging and does not depend on the amount of discharge of the battery or the instability of the supply network. The maximum charging current, displayed using potentiometer R1, you can change, increasing or decreasing resistance resistor R4. For example, when R4 = 20 ohms, it has a value of 250 mA, and with R4 = 2 ohms reaches 2.5 A (see formula above). For the scheme are fair restrictions on the maximum output current, both for stabilizing voltage circuits. Another application of a powerful inhibitor of current - measuring small resistance through voltmetra on a linear scale. Indeed, if the value of a current exhibit, for example, 1 A, is connected to the scheme resistor 3 ohms resistance, Ohms law to get the voltage drop its U = l * R = l A * 3 ohms = 3 V, and connecting, say, resistor resistance 7.5 ohms, we get a drop 7.5 V. Of course, this current can be measured only powerful Low resistors (3 V at 1 A - is 3 W, 7.5 V * 1 A = 7.5 W) But you can reduce the measured current and use the voltmeter to the lower limit of measurement.

A powerful generator of rectangular pulses.

Plans powerful generator of rectangular pulses are shown in Fig.12 (with bipolar diet) and Fig.13 (with unipolar meals). Plans can be used, for example, the device alarm. This chip includes a Schmitt trigger, and the whole scheme is a classic relaxation RC-oscillator. Consider the job figures. 12. Lets assume that at the time of the power output of IMS is moving towards a positive level of saturation (U _VYH = + U _IP). Capacitor C1 begins to be charged through resistor R3 with a constant time-Cl R3. When the voltage on C1 will reach half a positive voltage power source (+ U _IP / 2), IMS DA1 switch to a negative saturation (U _VYH =-U _IP). Capacitor C1 will discharged through resistor R3 at the same time Cl R3 to the voltage (-U _IP / 2) when the IMS again switches into a positive state of saturation. The cycle will be repeated with a 2,2 C1R3, regardless of the power supply voltages. Frequency pulses can count on the formula:

f = l / 2,2 * R3Cl. If the resistance to express kiloomah and capacity in mikrofaradah, the frequency will get in kilohertz.

A powerful low-frequency generator harmonic oscillations.

An electric circuit powerful low-frequency generator harmonic oscillations is shown in Fig.14. The generator gathered on a bridge Wines, formed by elements of DA1 and S1, R2, C2, R4, providing the necessary phase shift in the chain of PIC. Gain voltage IMS, with the same values of Cl, C2 and R2, R4 should be exactly equal to 3. With less importance Ku fluctuations fade, and an increased - dramatically increasing distortion of the output signal. Gain voltage determined resistance filament bulbs ELI, EL2 and resistors Rl, R3 and is _Ky = R3 / Rl + R EL1, _2. Lamps ELI, EL2 serve as elements with variable resistance in the chain of OOS. When increasing the output voltage resistance of the filament lamp by heating increases, causing a decrease gain DA1. Thus, stabilizing the amplitude of the output signal generator, and minimize distortions of form sinusoidalnogo signal. Minimum distortion at the maximum possible output amplitude sought through podstroechnogo resistor R1. To exclude the impact of stress on the frequency and amplitude of the output signal at the output of the generator includes a chain R5C3, frequency oscillations generated can be determined by the formula:

f = 1/2piRC. Generator can be used, for example, in the repair and inspection heads speaker or speakers.

In conclusion, the chips must be installed on the radiator with ohlazhdaemoy surface area of not less than 200 ^cm 2. When razvodke agents of the printed circuit board for the amplifier must be Bass track to "earth" tires for input, as well as the power source and output summed with the different parties (conductors to these terminals should not be a continuation of one another, and assembled together to form stars "). This is necessary to minimize the background of the AC and eliminate possible self-amplifier with output power close to the maximum.

13 8V 20A DC Power Supply

The following DC Power supply circuit is a linear power supply (using transformer). The voltage output of 13.8V power supply is highly regulated, can be adjusted in the moderate range, at up to 20A continuous current. This power supply is suitable for use for amateur radio equipment. DC Power supply is easily constructed and suitable for heavy duty because it is very efficient, small and lightweight.

In the DC power supply presented here, the pass transistors are located in the negative rail and connected in common-emitter configuration rather than as emitter-followers. Thanks to this, the regulator’s minimum voltage drop is extremely low, only about 0.1V for the transistors plus 0.5V for the equalizing resistors.

DC Power Supply Circuit

The other advantage is that the collectors are directly connected to the negative pole of the power supply’s output, which in most applications is grounded. That means that no insulation is required between the transistors and the grounded power supply cabinet! This eases the cooling very considerably. Thanks to the low regulator drop, a low cost 25V filter capacitor can be used.

Some Notes of DC Power Supply Circuit

Use a transformer for the primary voltage you need. The 3A fuse is for 220 or 240V primaries. If you use something in the neighborhood of 110V, use a 6A fuse.
The rather high transformer rating of 35A accounts for the losses that occur due to the capacitive input filter. If your transformer is rated for capacitive input, then a 25A value is enough.
Of course you can make up C1 by placing several smaller capacitors in parallel. Likewise, the 0.1 Ohm, 5 Watt resistors can be made up by several in parallel, for example by 5 resistors of 0.5 Ohm, 1 Watt each.
The LM336Z-5.0 voltage reference IC should not be replaced by a zener diode. Zeners are not nearly as stable. A different voltage reference IC can of course be used, if R2 and R3 are modified for the different voltage.
D1 and Q2 through Q6 need heatsinking. Only Q2 needs insulation. D1 dissipates up to 60W, Q2 up to 25W, while the pass transistors dissipate up to 30W each in normal use, but may reach a level of 130W during short circuit! Take this into account when choosing the heat sink!
R5 exists only to make sure that the transistors can actually be driven off. The 741 is not a single-supply operational amplifier, so it cannot drive its output very low. If a true single-supply opamp is used, then R5 becomes unnecessary.

Monday, November 3, 2014

Power Amplifier with 2N3055

Simple and low cost. The optimal supply voltage is around 50V, but this amp work from 30 to 60V. The maximal input voltage is around 0.8 – 1V. As you can see, in this design the components have a big tolerance, so you can build it almost of the components, which you find at home. The and transistors can be any NPN type power transistor, but do not use Darlington types… The output power is around 60W.
Some comments:

- capacitor C1 regulates the low frequencies (bass), as the capacitance grows, the low frequncies are getting louder.

– capacitor C2 regulates the higher frequencies (treble), as the capacitance grows, the higher frequencies are getting quiter.

– this is a class B amplifier, this means, that a current must flow through the end transistors, even if there is no signal on the input. This current can be regulated with the 500? trimmer resistor. As this current incrases, the sound of the amplifier gets better, but the end transistors are more heating. But if this current decrases, the transistors are not heating so much, but the sound gets worse…

Friday, October 31, 2014

Operational Amplifiers with Power Supply

The single feed mode has become very important in systems powered from a single power supply, because it reduces the cost of circuits with operational amplifiers and also makes it easier to use on mobile devices. In this series of articles will look at various ways that can power amplifiers circuits using operational amplifiers with single power supply (single rail).

The diagram of a sound amplifier, which operates with a single power supply shown in Figure 16. In this circuit one end of the signal source connected to the right input terminal of the operational amplifier, and the other end connected to the bias voltage VBias.

The load resistance (RL) and R1 also associated with the bias voltage. The voltage at the right input terminal, VP, is equal to:

Vp = VBias + Vin

The voltage at the reverse input terminal VN, is equal to:

VN = VD + VP but because,

Vd = 0 we have:

VN = VP = Vin + VBias

without an input signal

Vin = 0, so therefore

Vn = Vp = VBias

Figure 16. Amplifier with single power supply.

Figure 17. Input and output waveforms of the amplifier of Figure 16.

The bias voltage (VBias) is typically equal to half the voltage of the power supply. The output voltage of this amplifier can be calculated as follows:

The current I1, which flows through the resistor R1, is approximately equal to the current I2, which flows through the resistor R2, and thus I1 = I2. The current flowing through R1 is equal to the difference voltage across R1 divided by the value of R1, ie

In this circuit VB is the voltage applied to the right end of R1, and VA is the voltage applied to the left end of R1.

From the figure 16 we see that:

VB = VP but VP = VBias + VIN, thus:

VB = VBias + VIN

We also have VA = VBias so:

Similarly, the current I2 flowing through the resistor R2, is equal to the difference voltage across the R2.

i.e. VR2 = VO - VB divided by the value of R2

We also have VB = VBias + VIN, thus:

Figure 18a. AC amplifier with simple power supply.

Since I1 = I2, we obtain:

Rearranging we get:

By multiplying both sides of this equation with R2 we get:

So in the absence of an input signal, ie when VIN = 0, the above equation becomes

or VO = VBias

So in the absence of an input signal, the input terminals and the output terminal of the operational amplifier have the same voltage (VBias).

If an input voltage 2 volts peak to peak, is applied to the amplifier shown in Figure 16, R1 = R2, and VCC = 10V, then when the input signal is at the positive peak value of +1V, the output voltage will be:

When the input signal changes is at its highest negative value -1V, then the output voltage equals:

So when the input signal changes from -1V to +1V, the output voltage varies from +3V to +7V.

Figure 17 shows waveforms of the input and output. Notice that the first term in equation 1 represents the voltage gain of a conventional amplifier using a double power supply. The voltage gain is given by the following relationship:

In a conventional non-inverting amplifier, which operates with double supply, the bias voltage VBias is equal to 0 volts, and the output voltage is given by the following equation:

300 Watt Power Amplifier Elektor 11 1995

Taken by themselves, the properties of the PA300 amplifier are not revolutionary. But taken in combination, they show something special: a robust 300 watt hi-fi power amplifier that is not too difficult to build.
There are several starting points to the design of a power amplifier: pure hi-fi without any compromise; simplicity and reliability; high output power. The design of the present amplifier is a mixture of these. The result is a unit that does not use esoteric components, is not too complex, and is fairly easily reproduced. In fact, it could well be named a Hi-fi public address amplifier.
There will be a few eyebrows raised at the power output of 300 watts (into 4Ohm); it is true, of course, that in the average living room 30–40 W per channel is more than sufficient. However, peaks in the reproduced music may have a power of 10–20 times the average level. This means that some reserve power is desirable. Also, there are loudspeakers around with such a low efficiency that a lot more than 30–40W is needed. And, last but not least, there are many people who want an amplifier for rooms much larger than the average living room, such as an amateur music hall.

Fig. 1. With the exception of an IC at the input, the circuit of the PA300 amplifier is conventional.

Straightforward designSince every amplifier contains a certain number of standard components, the circuit of Fig.1 will look pretty familiar to most audio enthusiasts. Two aspects may hit the eye: the higher than usual supply voltage and the presence of a couple of ics. The first is to be expected in view of the power output. One of the ics is not in the signal path and this immediately points to it being part of a protection circuit. What is unconventional is an IC in the input stage. Normally, this stage consists of a differential amplifier followed by a voltage amplifier of sorts, often also a differential amplifier, to drive the predriver stages. In the PA300, the entire input stage is contained in one ic, a Type NE5534 (IC1).
The internal circuit of IC1 is shown in the box on further on in this article. It may also be of interest to note that the NE5534 is found in nine out of every ten cd players(as amplifier in the analogue section). This is reflected in its price which is low. Its only drawback is that its supply voltage is far below that of the remainder of the amplifier.
This means an additional symmetrical supply of ±15 V. Moreover, it restricts the drive capability of the input stage. The supply requirement is easily met with the aid of a couple of zener diodes and resistors. The drive restriction means that the amplifier must provide a measure of voltage amplification after the input stage.

Circuit description
The input contains a high-pass filter, C5-R3 and a low-pass filter, R2-C6. The combination of these filters limits the bandwidth of the input stage to a realistic value: it is not necessary for signals well outside the audio range to be amplified – in fact, this may well give rise to difficulties.
Opamp IC1 is arranged as a differential amplifier; its non-inverting (+) input functions as the meeting point for the overall feedback. The feedback voltage, taken from junction D7-D8, is applied to junction R4-R5 via R9. Any necessary compensation is provided by C9, C12 and C14. The voltage amplification is determined by the ratio R9:R5, which in the present circuit is x40.
The output of IC1 is applied to drive stages T1 and T3 via R6. These transistors operate in Class A: the current drawn by them is set to 10 mA by voltage divider R10- R13 and their respective emitter resistors. Their voltage and current amplification is appreciable, which is as required for the link between the input and output stages. The output amplifier proper consists of drive stages T6 and T7 and power transistors T8, T9, T14, T15. which have been arranged as symmetrical power darlingtons. Because of the high power, the output transistors are connected in parallel. The types used can handle a collector current of 20 A and have a maximum dissipation of 250 W.
The output stages operate in Class AB to ensure a smooth transition between the n-p-n and p-n-p transistors, which prevents cross-over distortion. This requires a small current through the power transistors, even in the absence of an input signal. This current is provided by zener transistor T2, which puts a small voltage on the bases of T6 and T7 so that these transistors just conduct in quiescent operation. The level of the quiescent current is set accurately with P1.
To ensure maximum thermal stability, transistors T1–T3 and T6–T7 are mounted on and the same heat sink. This keeps the quiescent current within certain limits. With high drive signals, this current can reach a high level, but when the input signal level drops, the current will diminish only slowly until it has reached its nominal value.
Diodes D7, D8 protect the output stages against possible counter voltages generated by the complex load. Resistor R30 and capacitor C17 form a Boucherot network to enhance the stability at high frequencies. Inductor L1 prevents any problems with capacitive loads (electrostatic loudspeakers). Resistor R29 ensures that the transfer of rectangular signals are not adversely affected by the inductor.

Protection circuitsAs any reliable amplifier, the PA300 is provided with adequate protection measures.
These start with fuses F1 and F2, which guard against high currents in case of overload or short-circuits. Since even fast fuses are often not fast enough to prevent the power transistors giving up the ghost in such circumstances, an electronic short-circuit protection circuit, based on T4 and T5, has been provided. When, owing to an overload or short-circuit, very high currents begin to flow through resistors R25 and R27, the potential drop across these resistors will exceed the base-emitter threshold voltage of T4 and T5. These transistors then conduct and short-circuit or reduce drive signal at their bases. The output current then drops to zero. If a direct voltage appears at the output terminals, or the temperature of the heat sink rises unduly, relay Re1 removes the load from the output. The loudspeakers are also disconnected by the relay when the mains is switched on (power-on delay) to prevent annoying clicks and plops.
The circuits that make all this possible consist of dual comparator IC2, transistors T10–T13, and indicator diodes D13 and D14. They are powered by the 15 V line provided by zener diode D10 and resistor R42.
The ac terminal on the PCB is linked to one of the secondary outputs on the mains transformer. As soon as the mains is switched on, an alternating voltage appears at that terminal, which is rectified by D12 and applied as a negative potential to T12 via R50. The transistor will then be cut off, so that C20 is charged via R36 and R44. As long as charging takes place, the inverting (+) input of comparator IC2b is low w.r.t. the non-inverting (–) input. The output of IC2b is also low, so that T13 is cut off and the relay is not energized. This state is indicated by the lighting of D13. When C20 has been charged fully, the comparator changes state, the relay is energized (whereupon D13 goes out) and the loudspeakers are connected to the output. When the mains is switched off, the relay is deenergized instantly, whereupon the loudspeakers are disconnected so that any switch-off noise is not audible.
The direct-voltage protection operates as follows. The output voltage is applied to T10 and T11 via potential divider R32-R34. Alternating voltages are short-circuited to ground by C18. However, direct voltages greater than +1.7 V or more negative than –4.8V switch on T10 or T11 immediately. This causes the +ve input of IC2a to be pulled down, whereupon this comparator changes state, T13 is cut off, and the relay is deenergized. This state is again indicated by the lighting of D13.
Strictly speaking, temperature protection is not necessary, but it offers that little bit extra security. The temperature sensor is R39, a ptc (positive temperature coefficient) type, which is located on the board in a position where it rests against the rectangular bracket. Owing to a rising temperature, the value of R39 increases until the potential at the –ve input of IC2a rises above the level at the +ve input set by divider R45-R46, whereupon the output of IC2a goes low. This causes IC2b to change state, whereupon T13 is cut off and the relay is deenergized. This time, the situation is indicated by the lighting of D14. The circuit has been designed to operate when the temperature of the heat sink rises above 70 °C. Any relay clatter may be obviated by reducing the value of R48.
The terminal marked CLIP on the PCB is connected to the output of IC1 via R31. It serves to obtain an external overdrive indication, which may be a simple combination of a comparator and LED. Normally, this terminal is left open.

Power supply
As with most power amplifiers, the ±60 V power supply need not be regulated. Owing to the relatively high power output, the supply needs a fairly large mains transformer and corresponding smoothing capacitors—see Fig. 2. Note that the supply shown is for a mono amplifier; a stereo outfit needs two supplies.

Fig. 2. The power supply is straightforward, but can handle a large current. Voltage acserves as drive for the power-on delay circuit.

The transformer is a 625 VA type, and the smoothing capacitors are 10 000 µF, 100 V electrolytic types. The bridge rectifier needs to be mounted on a suitable heat sink or be mounted directly on the bottom cover of the metal enclosure.. The transformer needs two secondary windings, providing 42.5 V each. The prototype used a toroidal transformer with 2x40 V secondaries. The secondary winding of this type of transformer is easily extended: in the prototype 4 turns were added and this gave secondaries of 2x42.5 V.
The box Mains power-on delay provides a gradual build-up of the mains voltage, which in a high-power amplifier is highly advisable. A suitable design was published in 305 Circuits (page 115).
The relay and associated drive circuit is intended to be connected to terminal ac on the board, where it serves to power the power-on circuit. If a slight degradation of the amplifier performance is acceptable, this relay and circuit may be omitted and the PCB terminal connected directly to one of the transformer secondaries.

Fig. 3. Component layout of the printed-circuit board for the 300 W power amplifier.

Fig. 4. Track layout of the printed-circuit board for the 300 W power amplifier.

ConstructionBuilding the amplifier is surprisingly simple. The printed-circuit board in Fig. 4 is well laid out and provides ample room. Populating the board is as usual best started with the passive components, then the electrolytic capacitors, fuses and relay. There are no difficult parts.
Circuits IC1 and IC2 are best mounted in appropriate sockets. Diodes D13 and D14 will, of course, have to be fitted on the front panel of the enclosure and are connected to the board by lengths of flexible circuit wire. Inductor L1 is a DIY component; i consists of 15 turns of 1 mm. dia. enamelled copper wire around R29 (not too tight!). Since most of the transistors are to be mounted on and the same heat sink, they are all located at one side of the board. However, they should first be fitted on a rectangular bracket, which is secured to the heat sink and the board—see Fig. 3. Note that the heat sink shown in this photograph proved too small when 4 Ohm loudspeakers were used. With 8 Ohm speakers, it was just about all right, but with full drive over sustained periods, the temperature protection circuits were actuated. If such situations are likely to be encountered, forced cooling must be used. As already stated, temperature sensor R39 should rest (with its flat surface) against the rectangular bracket. On the board, terminals A and B terminals to the left of R39 must be connected to A and B above IC2 with a twisted pair of lengths of insulated circuit wire as shown in Fig. 3. The points where to connect the loudspeaker leads and power lines are clearly marked on the board. Use the special flat AMP connectors for this purpose: these have large-surface contacts that can handle large currents. The loudspeaker cable should have a cross-sectional area of not less than 2.5 mm2.

FinallyHow the amplifier and power supply are assembled is largely a question of individual taste and requirement. The two may be combined into a mono amplifier, or two each may be built into a stereo amplifier unit. Our preference is for mono amplifiers, since these run the least risk of earth loops and the difficulties associated with those. It is advisable to make the 0 of the supply the centre of the earth connections of the electrolytic capacitors and the centre tap of the transformer.
The single earthing point on the supply and the board must be connected to the enclosure earth by a short, heavy-duty cable. This means that the input socket must be an insulated type. This socket must be linked to the input on the board via screened cable.
To test the amplifier, turn P1 fully anticlockwise and switch on the mains. After the output relay has been energized, set the quiescent current. This is done by connecting a multimeter (direct mV range) across one of resistors R25–R28 and adjusting P1 until the meter reads 27 mV (which corresponds to a current of 100 mA through each of the four power transistors). Leave the amplifier on for an hour or so and then check the voltage again: adjust P1 as required.

Wednesday, October 29, 2014

Collection Scheme Audio Power Amplifier High Power MOSFETs

200W Audio Amplifier with Mosfet BUZ905P-BUZ900P

This project is develop from the MOSFET Power amplifier 100W that posted which it take to use in many activity such as Guitar amp,Mic,or Home theater and you will be to apply it.
As many people prefer because of its robustness MOSFET legendary. Altronics had a MOSFET amplifier with 200W, the product in a 4Ω, and we have decided to take a look at is.
It turns out that on the basis of the Pro One “, as described above, even if this version of Altronics and to the various MOSFETs. He has a rated output of 140W to 200W into 4Ω and 8W. Frequency range of 1 dB 20Hz up to 80kHz (Fig. 1). THD is less than 0.1% at full power (Fig. 2) and signal to noise ratio when compared to 200W is better than -100 dB unweighted.

Performance of the prototype
Output power (RMS ):… 140W into 8 ohms, 200W into 4 ohms
Frequency Response:. 20Hz – 80kHz-1dB points (see Figure 1)
Input sensitivity: ………… 830mV for 200W into 4 ohms
Distortion: … <0.1% (20 Hz – 20 kHz) (see Fig.2)
Signal-to-Noise Ratio:. > 102dB unweighted, 105dB A-weighted with respect to 200W into 4 ohms
Stability :…………………….. Unconditional
Originally, the “Pro Series One” was developed by Hitachi MOSFET A-3 metal containers. They are no longer available, and their counterparts from plastics are very difficult to obtain. Altronics on this situation and have essentially the same circuits designed for Plastic MOSFET corresponds Exicon by the United Kingdom. This required a re-design of the computer, so that all MOSFET and the pilot for all transistors on a plate are vertically mounted on the radiator.
Besides the use of plastic in the power transistors, which greatly simplifies the assembly of the metal in comparison with A-3 power transistors, have Altronics spring clips in the proximity of the pairs of transistors, so things were still simple. The spring clips, just what the voltage for transistors and there is no harm in a transistor due to struggle more screws.
The heat sink is a black anodized aluminum extrusion with fins on one side. It measures 300 mm long and has a lid that a 80mm fan cooled 24V DC. The fan runs constantly, which means that the radiator is always cool (or at least slightly above the ambient temperature).

100W Audio Amplifer Circuit With MOSFET IRFP240

MOSFET amplifier with MOSFET for your build in electronic hobby.
I would like to show you here a basic MOSFET amplifier or power Amp which Output power is plus/minus 100 Watt/RMS with
8 Ohms or ohter plus/minus 160 Watts /RMS with 4 ohms.
Regarding this circuit simplicity, The distortion is plus/minus 0.1 %.
For band-width -3 db(decibel) is gain for 4 Hz to 96 Khz, it is limited by C1, R1, C2 and R2.
In the two transistors are T1 and T2 makes a first differential stage part, So,current source(I) of +/- one mA is set with resistor R3.

For the upgraded project, The current source(I) is more efficient in stability. Coil P1 allows a fine tuning of direct current voltage at amplifier’s output. Place the Coil P1 with it’s half value for first power up, then turn it slowly for a lowest DC output voltage. Use a first quality compoment.
Electronic Part
C1 = 2,2 µF MKP, MKT 100 V
C2 = 330 pF céramique 50 V
C3 = 100 nF MKP, MKT 100 V
C4 = 100 µF 40 V électro-chimique
C5, C6 = 18 pF céramique 50 V
C7 = 100 nF MKP, MKT 250 V (C8 = 47 µF 100 V)
R1, R3 = 47 K (R3 = 330 -> 470 Ohms)
R2 = 2K2
R4, R5 = 3K9
R6 = 1 K
R7 = 27 K
R8, R9, R11 = 100 ohms
R10 = 10 K
R12, R13 = 470 ohms
R14, R15 = 0.33 ohms 5 watts
R16 = 10 ohms 3 watts (R17 = 1 K R18, R19 = 10K)
T1, T2, T9,T10 = 2SD756A,2SD716A, BC556B (attention au brochage différent – take care for pin layout)
T7 = IRFP240, 2SK1530, 2SJ162, BUZ900DP, BUZ901DP (attention au brochage different – take care for pin layout : GDS GSD)P1 = 100 ohms (25 tours – 25 turns)

230W Audio Amplifer Circuit With MOSFET IRFP240,9240

230 W MOSFET Audio Amplifer Circuit Here is simple LED-power audio amplifier circuit with MOSFET amplifier TL071C and 2 may be up to 45 W into 8 ohms.

For MOSFET IRFP240 and IRFP9240 are used safety with device can now be these modification.
The scheme is at the request SILICONIX and the voltage change of 2 serial resistances from suppliers operating voltage amplifier driver was inserted.
MOSFET must be mounted on at least one condenser 1K / W.
Amplifier efficiency is 70%, the reduction in the frequency distortion in more than 0.2% at 20 Hz at 8 ohms and 10W.
With a supply voltage in the range of + – 30V, can supply audio amplifier MOSFET 45W into 8 ohms and 70W into 4 ohms.
Remember that the sound amplifier is short, so all you can check the radio button is protected, whether the speaker is connected.

400Watt Audio Power Amplifier with Mosfet BUZ902DP

If you like in the sound system or sound this circuit will should like you , This amplifier has two completely separate mono amplifiers with each channel has its own power supply to the order of zero channel crosstalk, a common phenomenon in amplifiers have the same food.
To view the full performance of each supply transformer should be evaluated at 40VAC – 0 – 40VAC at 640VA.
Unlike many models of capacitors is a reservoir to supply the peak currents, I prefer the power transformer in a much faster transient. BUZ902DP Although the specifications are rather modest,
if they can hear you now to experience a large reserve of power available and never any reason to worry that something to do than drive a large number of amplifiers aloud. You do not hear nothing but the truth without distortion at all levels, and I can assure you that this amplifier is required to provide the best features coupled.

800 Watt Audio Amplifer circuit with MOSFET

800W audio amplifier circuit
The audio power amplifier ideal for home user or PA work or for use as a general-purpose subwoofer or hi-fi amplifier. There are many people like to prefer MOSFET as their legendary ruggedness.
This circuit project had the Mosfet amplifier module which produced 800 Watt into 4 Ohm speaker load and so we decided to take a look it.
It was turned out to be based on the “Pro Series One” as mentioned above, although this version by Altronics has had derated and adapted to different MOSFET. It has a power output rate with 700W into 8W and 800W into 4 Ohm. For frequency response is within 1dB from 20Hz to 80kHz. Total harmonic distortion is rated at less than 0.1% up to full power and signal-to-noise ratio with respect to 800W is better than 100dB unweighted.
For circuit using MOSFET number BUZ902DP ,BUZ907DP which is popula take to build amplifer, If you see the circuit ,It seen 2 same circuits in the project which one circuit can gen power output at 400 Watt.

1000W MOSFET Audio Amplifier Circuit

Welcome to Hobby Electronics ,Today i’m still present the audio amplifier circuit ,I like the supper amplifier .
So,I would like to show you the 1000Watts MOSFET amplifier circuit for your build sound system.
Click the picture left side to open the Circuit in PDF file.
I include full schemaatic chart and film; pattern of the 1000-watt amplifier and a step by step instructions for setting the construction of the amplifier is a true full 1000 watts per channel.
I have been building and playing very well goood can drive a 18 Bring with inch subwoofer dual magnet high performance at UA smooth clear and crisp sound that I used for outdoor event and mobile services when building you will, said this amp I can only contact me gave my email Mail on how to get this project … I assure you his powerful …. You could, but I have to return it a full program of 20 band equalizer can be difficult to find on the net …

Automatic Switch For Audio Power Amplifier

Circuit of an automatic switch for audio power amplifier stage is presented here. The circuit uses stereo preamplifier output to detect the presence of audio to switch the audio power amplifier on only when audio is present. The circuit thus helps curtail power wastage. IC1 is used as an inverting adder. The input signals from left and right channels are combined to form a common signal for IC2, which is used as an open loop comparator. IC3 (NE556) is a dual timer. Its second section, i.e., IC3(b), is configured as monostable multivibrator. Output of IC3(b) is used to switch the power amplifier on or off through a Darlington pair formed by transistors T1 and T2. IC3(a) is used to trigger the monostable multivibrator whenever an input signal is sensed.

Circuit diagram:

Automatic Switch For Audio Power Amplifier Circuit Diagram

Under ‘no signal’ condition, pin 3 of IC2 is negative with respect to its pin 2. Hence the output of IC2 is low and as a result output of IC3(a) is high. Since there is no trigger at pin 8 of IC3(b), the output of IC3(b) will be low and the amplifier will be off. When an input singal is applied to IC1, IC2 converts the inverted sum of the input signals into a rectangular waveform by comparing it with a constant voltage which can be controlled by varying potentiometer VR1. When the output of IC2 is high, output pin 5 of IC3 goes low, thus triggering the monostable multivibrator. As soon as the audio input to IC1 stops, pin 5 of IC3 goes high and pin 1 of IC3 discharges through capacitor C3, thus resetting the monostable multivibrator.

Hence, as long as input signals are applied, the amplifier remains ‘on.’ When the input signals are removed, i.e., when signal level is zero, the amplifier switches off after the mono flip-flop delay period determined by the values of resistor R8 and capacitor C3. If no input signals are sensed within this time, the amplifier turns off—else it remains on. Power supply for the circuit can be obtained from the power supply of the amplifier. Hence, the circuit can be permanently fitted in the amplifier box itself. The main switch of the amplifier should be always kept on. Resistors R1 and R2 are used to divide single voltage supply into two equal parts.

Capacitors C1 and C2 are used as regulators and also as an AC bypass for input signals. Diode D1 is used so that loading fluctuations in power amplifier do not affect circuit regulation. Transisitor T2 acts as a high voltage switch which may be replaced by any other high voltage switching transistor satisfying amplifier current requirements. Value of resistor R10 should be modified for large current requirement. The LED glows when the amplifier is on. The circuit is very useful and relieves one from putting the amplifier on and off every time one plays a cassette or radio etc.

Source : EFY