Linkworld 200w CHEM power supply. Schemes

Telephone

Utilities and reference books.
- Directory in format.chm. The author of this file - Kucheryavhenko Pavel Andreevich. Most of the source documents were taken from the Pinouts.ru website - brief descriptions and cuts of more than 1000 connectors, cables, adapters. Descriptions of tires, slots, interfaces. Not only computer equipment, but also cell phones, GPS receivers, audio, photo and video equipment, game consoles, etc. Technique.

The program is designed to determine the capacitance of the condenser in color marking (12 types of capacitors).

Database for transistors in Access format.

Power supplies.

Wiring for ATX Standard Power Connectors (ATX12V) with Nominal Wiring Nominations and Color Marking:

Table of contacts of the 24-pin power supply unit connector ATX standard (ATX12V) with ratings and color marking of wires

CONT	Own	Color	Description
1	3.3V.	Orange	+3.3 VDC.
2	3.3V.	Orange	+3.3 VDC.
3	Com.	The black	Land
4	5V	Red	+5 VDC.
5	Com.	The black	Land
6	5V	Red	+5 VDC.
7	Com.	The black	Land
8	Pwr_ok.	Grey	Power OK - all voltages within the normal range. This signal is formed when the BP is turned on and is used to reset the motherboard.
9	5VSB.	Purple	+5 VDC standby voltage
10	12V	Yellow	+12 VDC.
11	12V	Yellow	+12 VDC.
12	3.3V.	Orange	+3.3 VDC.
13	3.3V.	Orange	+3.3 VDC.
14	-12V.	Blue	-12 VDC.
15	Com.	The black	Land
16	/ PS_ON.	Green	POWER SUPPLY ON. To turn on the power supply, you need to shorten this contact to the ground (with a black wire).
17	Com.	The black	Land
18	Com.	The black	Land
19	Com.	The black	Land
20	-5V.	White	-5 VDC (this voltage is used very rarely, mainly to power the old extension boards.)
21	+ 5V.	Red	+5 VDC.
22	+ 5V.	Red	+5 VDC.
23	+ 5V.	Red	+5 VDC.
24	Com.	The black	Land

ATX-300P4-PFC power supply circuit (ATX-310T 2.03).

ATX-P6 power supply circuit.

Power supply diagram API4PC01-000 400W manufactured by AcBel Politech Ink.

Alim ATX 250Watt SMEV J.M. power supply circuit. 2002.

Type diagram of a 300W power supply circuit marked on the functional purpose of individual parts of the circuit.

Typical Power Block Scheme for 450W with Active Power Factor Correction (PFC) Modern Computers.

API3PCD2-Y01 450W APBEL Electronic (Dongguan) CO. Ltd.

ATX 250 SG6105, IW-P300A2 power supply circuits, and 2 schemes of unknown origin.

BP NUITEK (Colors IT) 330U (SG6105).

BP Nuitek (Colors IT) 330U on the SG6105 microcircuit.

BP NUITEK (Colors IT) 350U SCH.

BP Nuitek (Colors IT) 350T scheme.

BP NUITEK (Colors IT) 400U scheme.

Scheme BP Nuitek (Colors IT) 500T.

BP Nuitek (Colors IT) Scheme ATX12V-13 600T (Colors-IT - 600T - PSU, 720W, Silent, ATX)

Circuit BP Chieftec Technology GPA500S 500W Model Gpaxy-Zz Series.

Codegen 250W MOD circuit. 200xa1 MOD. 250xa1.

BP Codegen 300W MOD Scheme. 300x.

CWT Model PUH400W BP Scheme.

DELTA ELECTRONICS INC. Model DPS-200-59 H Rev: 00.

DELTA ELECTRONICS INC. Model DPS-260-2A.

DTK Computer BP Scheme Model PTP-2007 (it is Macron Power Co. model ATX 9912)

BP DTK PTP-2038 200W scheme.

Scheme of EC MODEL 200X.

FSP GROUP Inc. Model FSP145-60SP.

FSP GROUP INC Power Supply Source Scheme ATX-300GTF model.

FSP GROUP INC Power Supply Source Scheme Model FSP Epsilon FX 600 GLN.

Scheme of BP Green Tech. Model MAV-300W-P4.

HiPer HPU-4K580 power supply circuits. The archive is a file in the SPL format (for SPLAN) and 3 files in GIF format - simplified schema: Power Factor Corrector, PWM and power chain, autogenerator. If you have nothing to view files.spl, use patterns in the form of drawings in format.gif - they are the same.

INWIN IW-P300A2-0 R1.2 power supply circuits.

Power block diagrams inwin IW-P300A3-1 Powerman.
The most common malfunction of the inwin power supply blocks, the schemes of which are presented above - failure of the diagram of formation of the duty voltage + 5VSB (duty). As a rule, it is required to replace the electrolytic capacitor C34 10 MCF X 50V and the protective stabilion D14 (6-6.3 V). In the worst case, R54, R9, R37, microcircuit U3 (SG6105 or IW1688 (full analog SG6105)) are added to the faulty elements (SG6105)) for the experiment, tried to put the C34 with a capacity of 22-47 microfa - perhaps it will increase the reliability of the duty room.

Powerman IP-P550DJ2-0 Power Block Scheme (IP-DJ Rev: 1.51). Available in the document forming scheme of the duty voltage is used in many other models of POWER MAN power supplies (for many power supplies with a capacity of 350W and 550W differences only in the nominal elements).

JNC Computer Co. Ltd LC-B250ATX

JNC Computer Co. Ltd. SY-300ATX Power Supply Scheme

Presumably manufacturer JNC Computer Co. Ltd. SY-300ATX power supply. The scheme is drawn by hand, comments and recommendations on improvement.

Power Supply Schemes Key Mouse Electroniks Co Ltd Model PM-230W

Power Supply L & C Technology Co. LC-A250ATX model

LWT2005 Power Supply Schemes on KA7500B and LM339N chip

M-Tech Kob AP4450XA BP scheme.

BP Macron Power Co. Scheme ATX 9912 model (it is DTK Computer model PTP-2007)

BP MaxPower PX-300W Scheme

Maxpower PC ATX SMPS PX-230W VER.2.03

PowerLink power supply circuits Model LP-J2-18 300W.

Power Master Power Power Schemes Model LP-8 VER 2.03 230W (AP-5-E V1.1).

Power Master Power Power Schemes Model FA-5-2 VER 3.2 250W.

MICROLAB 350W BP Scheme

MICROLAB 400W BP Scheme

POWERLINK LPJ2-18 300W BP Scheme

Power Efficiency Electronic Co Ltd Model PE-050187

ROLSEN ATX-230 BP Scheme

Scheme SEVENTEAM ST-200HRK

BP Scheme Seventeam ST-230WHF 230Watt

Scheme BP Seventeam ATX2 V2

The power supply is the most important part of any device, especially when it comes to a power supply for a computer. At one time I was engaged in repairs, so some schemes were accumulated, which can help you figure out and repair them if necessary.

For a start, a small educational program on BP:

BP for a computer is based on a two-stroke converter with a tranformator input. It is safe to say that interest 95 of all power supplies for computers are based on this principle. The output voltage cycle contains several steps: the input voltage is straightened, smoothed and fed to the strength keys of the two-stroke converter. The operation of these keys is engaged in a specialized microcircuit, commonly called the PWM controller. This controller is engaged in the generation of pulses supplied to the power elements, usually power bipolar transistors, but recently there are interest in powerful field transistors, so they can occur in BP. Since the transforming diagram is two-stroke, we have two transistors, which should be switched alternately with each other if they are turned on simultaneously, it is safe to believe that the power elements are ready to repair - in this case, power elements are burned, sometimes a pulse transformer can burn and still Something in the load. The task of the controller is that such a situation does not occur in principle, it also monitors the output of the voltage, usually this is the power supply chain + 5V, i.e. This voltage is used for the feedback circuit and it is stabilized by all other stresses. By the way, in the Chinese BP of additional stabilization over the + 12V, -12B chains, + 3.3B is not provided.
Voltage regulation is carried out by the pulse method: usually changes the pulse filling coefficient, i.e. Log width. 1 to the width of the entire impulse. The larger log.1, the higher the output voltage. All this can be found in special literature on power rectifier.
After the keys there is a pulsed transformer that transfers energy from the primary chain into secondary and simultaneously performs electroplating junction from the 220V power circuit. Next, an alternating voltage is removed from the secondary windings, which is straightened, smoothes and fed to the output for powering the motherboard and all components of the computer. This is a general description that is not devoid of flaws. For power electronics, it is worth contacting specialized textbooks and resources.

Below is the layout of wires for power supplies AT and ATX:

AT.

ATX


Output	Description
1	+ 3.3V.
2	+ 3.3V.
3	Land
4	+ 5V.
5	Land
6	+ 5V.
7	Land
8	Power OK (+ 5V and + 3.3B normally)
9	+ 5V Standby Voltage (MAX 10MA) powered duty
10	+ 12V.
11	+ 3.3V.
12	-12V.
13	Land
14	Power Supply ON control signal including the main sources + 5V, + 3.3B, + 12V, -12V, -5B, active level - low.
15	Land
16	Land
17	Land
18	-5V.
19	+ 5V.
20	+ 5V.

To start the ATH power supply, you must connect the Power Supply ON wire with the Earth (black wire). Below are the diagrams of power supplies for a computer:

ATX Power Supplies:

№	File	Description
1		The diagram of the ATX power supply is presented on the basis of the TL494 chip.
2		ATX POWER SUPPLY DTK PTP-2038 200W.
3

Best Scheme of Standard BP ATH

ATX POWER SUPPLY DTK PTP-2038 200W

TL494.

Features:

Full set of PWM control functions
Output flowing or flowing current of each exit 200mA
It is possible to work in a two-stroke or one-step
Built-in dual pulse suppression scheme
Wide range adjustment
Outlet reference voltage 5V + -05%
Just organized synchronization

general description:

Specially created for the construction of IVP, the TL493 / 4/5 chips provide the developer advanced possibilities when designing IVP control schemes. TL493 / 4/5 devices include an error amplifier, a built-in adjustable generator, a dead-time adjustment comparator, a control trigger, a precision ion by 5V and an output cascade control circuit. The error amplifier issues a simphanist voltage in the range from -0.3 ... (VCC-2) V. The dead time adjustment comparator has a constant displacement that limits the minimum duration of the dead time of the value of about 5%.

It is allowed to synchronize a compared generator, using the connection of R output R to the output of the reference voltage and supply the input sawtooth voltage to the output C, which is used when synchronous operation of several IVP schemes.

Independent outputers on transistors provide the ability to operate the output cascade according to a circuit with a common emitter or by an emitter repeater scheme. The output cascade of the TL493 / 4/5 microcircuit works in one-way or two-stroke mode with the ability to select the mode using a special input. The built-in scheme controls each output and prohibits the issuance of a dual pulse in the two-stroke mode.

The devices having suffix L guarantee normal operation in the temperature range --5 ... 85C, with a suffix with a normal operation in the temperature range of 0 ... 70c.

Structural scheme:

Cocolevka case:

Parameter limit values:

Supply voltage ......................................................................41v

Input voltage amplifier ............................................. ... (VCC + 0.3)

Output voltage collector ................................................ ... ... 41v

Output current collector ........................................................................ ... 250mA

The total dispersion capacity in continuous mode ........................... .1W

Operating range of ambient temperatures:

With suffix L ........................................................................ -25..85С

With a suffix with ........................................................................ ..0..70c

Range of storage temperatures ................................................- 65 ... + 150c

How to make a full-fledged power supply with a range of adjustable voltage 2.5-24 volts, it can be very simple, can repeat each without having a radio amateur experience.

We will do from the old computer unit, TX or ATH without a difference, good, over the years of the PC, each house has already accumulated enough of the old computer iron and the BP probably there is also there, therefore the cost of homemade will be insignificant, and for some masters equal to zero rubles .

I got for the alteration of which AT block.

The more powerful will be used by the BP, the better the result, my donor is only 250W with 10 ampere on the tire + 12V, and in fact, with a load of only 4 and it does not cope, there is a complete output drawdown.

See what is written on the case.

Therefore, look at what current you are planning to receive from your adjustable BP, such a donor potential and lay down immediately.

The options for finalizing the standard computer BP set, but they are all based on the change in the blocking of the IC-TL494CN chip (its analogues of DBL494, ka7500, IR3M02, A494, MV3759, M1114EU, MPC494C, etc.).

Figure No. 0 TL494CN chip and analogs.

Let's see several options The execution of computer BP schemes, perhaps one of them will be your and deal with the strapping will be much easier.

Scheme number 1.

We will start work.
First, it is necessary to disassemble the BP housing, unscrew the four bolts, remove the lid and look inside.

We are looking for on the board the chip from the list above, if it does not turn out to be, then you can search the version of the Internet for your IS.

In my case, the KA7500 chip was discovered on the board, which means you can begin to study the strapping and the location of unnecessary parts to us that you want to delete.

For the convenience of work, first completely unscrew the entire board and take out from the case.

In the photo 220V power connector.

Disconnect the power and fan, drop or whining the output wires so that you do not interfere with us to understand in the scheme, leave only the necessary, one yellow (+ 12V), black (general) and green * (Start ON) if there is such.

There is no green wire in my AT block, so it starts immediately when turning on the outlet. If the ATH block, then it should have a green wire, it must be soldered to the "common", and if you wish to make a separate power on the case, then simply put the switch to the break of this wire.

Now we need to look at how much Volts are weekend large capacitors, if less than 30V is written on them, then it is necessary to replace them with similar, only with a working voltage at least 30 volts.

In the photo - black capacitors as a replacement option for blue.

This is done because our final block will not give out +12 volts, but to +24 volts, and without replacing the capacitors will simply explode at the first 24V test, after a few minutes of work. When selecting a new electrolyte, it is not desirable to reduce the container, it is always recommended to increase.

The most responsible part of the work.
We will delete everything excess in the IC494 strapping, and solder other nominal details so that the result is such a blockage (Fig. No. 1).

Fig. №1 Change in the strapping of the IC 494 chip (refinement scheme).

We will need only these legs of chips №1, 2, 3, 4, 15 and 16, do not pay for other attention.

Fig. №2 Option of refinement on the example of scheme number 1

Decoding designations.

It is necessary to do about so, we find the leg number 1 (where the point is on the case) of the chip and study that it is connected to it, all chains must be removed, disconnect. Depending on how you have in a specific modification of the board, the tracks will be located and the parts are created, the optimal finalization option is selected, it can be dropping and lifting one feet of the part (breaking the chain) or it will be easier to cut the track with a knife. Deciding with the plan of action, we begin the process of reworking according to the refinement scheme.

In the photo - replacement of resistors to the desired nominal.

In the photo - raising the legs of unnecessary parts, tearing chains.

Some resistors who are already in the scheme of the strapping can approach without replacing them, for example, we need to put a resistor on R \u003d 2.7K with a connection to "common", but there is already a R \u003d 3K connected to "general", it is quite suitable for us. And we leave it there without change (an example in fig. No. 2, green resistors do not change).

On the picture- Curl tracks and added new jumpers, old nominal nominations are written by a marker, it may be necessary to restore everything back.

Thus, we look at and remake all the chains on six legs of the chip.

It was the most difficult point in the alteration.

We make voltage and current controls.

We carry out variable resistors on the 22k (voltage regulator) and 330Ω (current regulator), we solder two 15 cm wires to them, other ends are soldered according to the circuit (Fig. No. 1). Install on the front panel.

Voltage control and current.
For control, we will need a voltmeter (0-30V) and an ammeter (0-6a).

These devices can be purchased in Chinese online stores at the best price, my voltmeter cost me with the delivery of only 60 rubles. (Voltmeter :)

Ammeter I used my own, from the old stocks of the USSR.

IMPORTANT - inside the device there is a current resistor (current sensor), which we need according to the scheme (Fig. No. 1), therefore, if you use an ammeter, then the current resistor is additionally not necessary, it is necessary to install without an ammeter. Usually it is done homemade, the wire d \u003d 0.5-0.6 mm, the turn to the turn to the entire length is wound on the 2-won't resistance of MLT, the ends are screwed to the conclusions of the resistance, that's all.

The body of the device will be done for themselves.
You can leave completely metallic, cutting holes for regulators and control devices. I used the trimming of the laminate, they are easier to drill and cut down.

Let us give a full description of the concept for one of the 200-watt pulse power supplies (PS6220C, the production of Taiwan).

The variable voltage of the network is fed through the PWR SW power switch through the F101 4A network fuse, the interference filters formed by the elements C101, R101, L101, C104, C103, C102 and chokes L102, L103 on:

the output three-pin connector to which the display power cable may be pretended;
two-contact jp1 connector, the response part of which is on the board.

From the JP1 connector, the variable voltage of the network enters:

bridge scheme of straightening BR1 through thermistor THR1;
primary winding of the start transformer T1.

At the outlet of the rectifier, the smoothing containers of the filter C1, C2 are included. The thermistor THR limits the initial throw of the charging current of these capacitors. Switch 115 V / 230 V SW provides the ability to power the UPS from both the network of 220-240 V and from the network 110/127 V.

High-moving resistors R1, R2, shunting capacitors C1, C2 are symmetrging (equalize the voltages on C1 and C2), and also ensure the discharge of these capacitors after turning off the UPS from the network. The result of the input circuits is the appearance of the rectified voltage voltage of the UEP constant voltage network on the tire, equal to +310 V, with some ripples. This UPS uses a start-up scheme with a forced (external) excitation, which is implemented on a special start transformer T1, on the secondary winding of which, after switching on the UPS, an alternating voltage appears in the network with a frequency of the supply network. This voltage is straightened by diodes D25, D26, which form a two-flowing diagram of straightening with an average point with a secondary winding of T1. C30 - the smoothing capacity of the filter on which a constant voltage used to power the U4 control chip is formed.

As a control chip in this UPS, the TL494 is traditionally used.

The supply voltage from the C30 condenser is fed to the output 12 U4. As a result, on the output 14 U4, the output voltage of the internal support source UREF \u003d -5 B is appeared, the internal saw-shaped voltage generator of the chip is launched, and control voltages appear on the outputs 8 and 11, which are sequences of rectangular pulses with negative front fronts, shifted relative to each other half a period. The C29, R50 elements connected to the conclusions 5 and 6 of the U4 chips determine the frequency of the saw-shaped voltage produced by the internal generator of the chip.

The coercive cascade in this UPS is made on a delimitory scheme with separate management. The supply voltage from the C30 capacitor is fed to the average points of the primary windings of control transformers T2, T3. Output transistors IC U4 perform the functions of transistors of the matching cascade and included according to the OE scheme. Emitters of both transistors (9 and 10 chip conclusions) are connected to the "case". The collector loads of these transistors are primary half-type control transformers T2, T3 connected to the outputs 8, 11 of the U4 chips (open output transistors). Other half of primary windings T2, T3 with diodes connected to them D22, D23 form chains of demagnetization of cores of these transformers.

T2, T3 transformers control powerful transistors of the half-lit-up inverter.

The switching of the output transistors of the chip causes the appearance of pulsed control EMFs on the secondary windings of control transformers T2, T3. Under the action of these EDS, power transistors Q1, Q2 alternately open with adjustable pauses ("dead zones"). Therefore, through the primary winding of the power pulse transformer T5, an alternating current in the form of saws-like current pulses proceeds. This is explained by the fact that the primary winding of T5 is included in the diagonal of an electric bridge, one shoulder of which is formed by the transistors Q1, Q2, and the other - C1, C2 condensers. Therefore, when opening any of the transistors Q1, Q2, the primary T5 winding is connected to one of the capacitors C1 or C2, which causes the flow through it throughout the time the transistor is opened.

D1, D2 damper diodes provide a refund of the energy stored in the inductance of the scattering of the primary winding T5 during the closed state of the transistors Q1, Q2 back to the source (recovery).

The C3 condenser included in sequentially with the primary winding T5 eliminates the constant current component through the primary winding of T5, thereby eliminating the unwanted applied of its core.

Resistors R3, R4 and R5, R6 form basic dividers for powerful transistors Q1, Q2, respectively and provide the optimal mode of switching them from the point of view of dynamic power loss on these transistors.

The flow of AC through the primary winding T5 causes the presence of alternate rectangular pulse EMFs on the secondary windings of this transformer.

The power transformer T5 has three secondary windings, each of which has an output from the midpoint.

The IV winding provides the output voltage of +5 V. The SD2 diode assembly (semi-edible) forms with a winding of the IV bipoperiodic impact circuit with an average point (the average point of the IV winding point is grounded).

The SD2 assembly diodes are diodes with the Schottky barrier than the necessary speed is achieved and the efficiency of the rectifier is increased.

Winding III in conjunction with winding IV provides the output voltage of +12 in along with a diode assembly (semi-mounted) SD1. This assembly forms with a winding of the III bipoperiodic straightening scheme with an average point. However, the average point of the winding III is not grounded, but is connected to the output voltage bus +5 V. This will give the opportunity to use Schottki diodes in the channel of production +12 V, because The reverse voltage applied to the rectifier diodes with such an inclusion, decreases to the Schottky level allowed for diodes.

Elements L1, C6, C7 form a smoothing filter in the channel +12 V.

Resistors R9, R12 are designed to accelerate the discharge of the output capacitors of tires +5 V and +12 in after the UPS is turned off from the network.

Winding II with five removal provides a negative output voltage -5 V and -12 V.

Two discrete diodes D3, D4 form a two-fiber rectifier semicircle in the channel of production -12 B, and d5, d6 diodes - in channel -5 V.

Elements L3, C14 and L2, C12 form smoothing filters for these channels.

Winding II, as well as the winding III, is inserted by the reassuring RC chain R13, C13.

The average point of the winding II is grounded.

Stabilization of output voltages are carried out in different ways in different channels.

Negative output voltages -5 V and -12 in stabilize using linear integral three-water stabilizers U4 (type 7905) and U2 (type 7912).

To do this, the inputs of these stabilizers serves output voltages of rectifiers with C14 capacitors, C15. On the weekend capacitors C16, C17, stabilized output voltages are obtained -12 V and -5 V.

D7, D9 diodes provide the discharge of the output capacitors C16, C17 through resistors R14, R15 after turning off the UPS from the network. Otherwise, these capacitors would discharge through the scheme of stabilizers, which is undesirable.

Through resistors R14, R15, C14, C15 condensers are discharged.

D5, D10 diodes perform a protective function in case of breakdown of rectifying diodes.

If at least one of these diodes (D3, D4, D5 or D6) will be "punched", then in the absence of d5, d10 to the input of the integral stabilizer U1 (or U2) would be applied a positive pulse voltage, and through electrolytic capacitors C14 or C15 A variable current would occur, which would lead to their failure.

The presence of D5, D10 diodes in this case eliminates the possibility of such a situation, because The current closes through them.

For example, if the "breaks" diode D3, the positive part of the period, when D3 must be closed, the current will be closed on the chain: K-A D3 - L3 D7-D5- "Case".

Stabilization of the output voltage +5 V is carried out by the PWM method. To do this, a measuring resistive divider R51, R52 is connected to the output voltage bus. The signal proportional to the output voltage in the +5 V channel is removed from the R51 resistor and is fed to the inverting input of the DA3 error amplifier (output 1 of the control chip). On the direct input of this amplifier (output 2) fed by the reference voltage level, removed from the R48 resistor, which is included in the VR1, R49, R48 divider, which is connected to the output of the inner reference source of the U4 uref \u003d + 5 V. with changes in the voltage level of the tire + 5 B under the influence of various destabilizing factors, a change in the magnitude of mismatch (errors) between the reference and controlled voltage levels at the inputs of the DA3 error amplifier is changed. As a result, the width (duration) of the control pulses at the conclusions 8 and 11 of the U4 chip changes in such a way as to return the rejected output voltage +5 to the nominal value (with a decrease in the voltage on the tire +5 in the width of the control pulses increase, and with an increase in this voltage - decreases).

Output voltage +12 V in this UPS does not stabilize.

Adjusting the output voltage level This UPS is performed only for channels +5 V and +12 V. This adjustment is carried out by changing the level of reference voltage at the direct input of the DA3 error amplifier with the help of a VR1 trimmed resistor.

When the position of the VR1 engine is changed, during the UPS setting, the voltage level on the bus is +5 V, which means the +12 V bus, because Tire voltage +5 B is supplied to the middle point of the winding III.

Combined sewn of this UPS includes:

limiting control circuit control pulse width;
incomplete control of the output overvoltage (only on the +5 V bus).

Consider each of these schemes.

Limiting control circuit uses the T4 current transformer as a sensor, the primary winding of which is enabled sequentially with the primary winding of the power pulse transformer T5.

The R42 resistor is the load of the secondary winding T4, and D20, D21 diodes form a two-speech diagram of straightening the alternate pulse voltage removed from the load R42.

Resistors R59, R51 form a divider. Part of the voltage is smoothed by the C25 capacitor. The voltage level on this condenser proportionally depends on the width of the control pulses on the bases of the power transistors Q1, Q2. This level via the R44 resistor is supplied to the inverting input of the DA4 error amplifier (output 15 U4 chip). Direct input of this amplifier (output 16) grounded. D20, D21 diodes are included in such a way that the C25 capacitor when current flows through these diodes is charged to a negative (relative to the total wire) of the voltage.

In normal operation, when the width of the control pulses does not go out for the permissible limits, the output potential 15 is positive, due to the connection of this output through the R45 resistor with the UREF bus. With an excessive increase in the width of control pulses for any reason, the negative voltage on the C25 condenser increases, and the output potential 15 becomes negative. This leads to the appearance of the output voltage of the DA4 error amplifier, which before that was 0 B. Further increase in the width of the control pulses leads to the fact that the DA2 PWM-comparator shifts is transmitted to the DA4 amplifier, and the subsequent increase in the width of control pulses no longer occurs (restriction mode), because The width of these pulses ceases to depend on the feedback signal level on the direct input of the DA3 error amplifier.

The protection circuit from the KZ in loads can be conditionally divided into protection of the channels for the production of positive stresses and the protection of channels for the development of negative stresses, which are scheduled for approximately the same.

The sensor of the protection circuit from the KZ in the loads of the positive stress production channels (+5 V and +12 V) is a diode-resistive divider D11, R17, connected between the output tires of these channels. The voltage level on the anode diode D11 is a controlled signal. In normal mode of operation, when the voltages on the output tires of the channels +5 V and +12 V are nominal values, the potential of the diodine diodine D11 is about +5.8 V, because Through the divider-sensor flows from the tire +12 to the bus +5 in the chain: tire +12 V - R17-D11 - Tire +5 V.

The controlled signal from the anode D11 is fed to the resistive divider R18, R19. Some of this voltage is removed from the R19 resistor and is fed to the direct input of the comparator 1 of the U3 type LM339N chip. The inverting input of this comparator is supplied to the reference voltage level from the R27 resistor R26, R27 connected to the output of the uref \u003d + 5 reference source in the U4 control chip. The reference level is selected so that with normal operation mode, the potential of the direct input of the comparator 1 would exceed the potential of the inverse input. Then the output transistor of the comparator 1 is closed, and the UPS scheme is normally functioning in PWM mode.

In the case of a KZ in the load of the channel +12 in, for example, the potential of the diodine diode D11 becomes equal to O in, so the potential of the inverting input of the comparator 1 will become higher than the potential of the direct input, and the output transistor of the comparator will open. This will cause the closing of the transistor Q4, which is normally opened by a current base flowing through the chain: Upom bus - R39 - R36 B-E Q4 - "Case".

Opening the output transistor of the comparator 1 connects the R39 resistor to the "body", and therefore the Q4 transistor is passively closed by zero offset. Closing the transistor Q4 entails charging C22 condenser, which performs the function of the protection delay link. The delay is necessary from those considerations that in the process of the UPS output on the mode, the output voltages on the tires +5 V and +12 in appear not immediately, but as the output capacitors of the high capacity are charging. The reference voltage from the UREF source, on the contrary, appears almost immediately after turning on the UPS to the network. Therefore, in the start-up, the comparator 1 switches, its output transistor opens, and if there was no delaying capacitor C22, it would lead to the triggering of protection immediately when the UPS is turned on to the network. However, the C22 is included in the scheme, and the triggering of protection occurs only after the voltage on it reaches the level determined by the R37 resistor rates, the divisor connected to the UPOM bus and being the base for the transistor Q5. When this happens, the transistor Q5 opens, and the resistor R30 turns out to be connected through the small internal resistance of this transistor to the "case". Therefore, a way to flow the current of the base of the transistor Q6 by chain is appearing: uref - e-b Q6 - R30 - K-E Q5 "Case".

The transistor Q6 opens with this current to saturation, as a result of which the voltage uref \u003d 5 V, which is subtracted by the emitter, the transistor Q6 is applied through its small internal resistance to the output 4 of the U4 control microcircuit. This, as shown earlier, leads to the stopping of the digital microcircuit path, the disappearance of the output control pulses and the termination of the switching transistors Q1, Q2, i.e. To protective disconnection. The KZ in the load of the channel +5 V will lead to the fact that the potential of the diodine diodine D11 will be only about +0.8 V. Therefore, the output transistor of the comparator (1) will be open, and a protective shutdown will occur.

Similarly, a protection from the KZ in the loads of the negative stresses of the negative stresses (-5 V and -12 V) on the comparator 2 of the U3 chip is built. Elements D12, R20 form a diode-sized divider sensor, connected between the output tires of channels of negative stresses. The controlled signal is the potential of the diode diode cathode. When the CW in the load of the channel -5 B or -12 B, the potential of the cathode D12 increases (from -5.8 to 0 V to the CW in the load of the channel -12 V and to -0.8 V to the CZ in the load of the channel -5 B) . In any of these cases, a normally closed output transistor comparator 2 is opened, which causes the triggering of protection according to the above mechanism. In this case, the support level from the R27 resistor is supplied to the direct input of the comparator 2, and the potential of the inverting input is determined by the R22 resistors rates, R21. These resistors form a bipolarly populated divider (the R22 resistor is connected to the UREF \u003d + 5 V bus, and the R21 resistor to the diode cathode D12, the potential of which in the normal operation of the UPS, as already noted, is -5.8 V). Therefore, the potential of the inverting logger of the comparator 2 in the normal mode of operation is supported by smaller than the potential of the direct input, and the output transistor of the comparator will be closed.

Protection against output overvoltage on the +5 bus is implemented on ZD1, D19, R38, C23 elements. Stabilitron ZD1 (with a punching voltage of 5.1 V) is connected to the output voltage bus +5 V. Therefore, while the voltage on this bus exceeds +5.1 V, the stabilion is closed, and the transistor Q5 is closed. In case of increasing the voltage on the bus +5 above +5.1 V stabilitron "breaks through", and an unlocking current flows into the base of the transistor Q5, which leads to the opening of the transistor Q6 and the appearance of the UREF \u003d + 5 V voltage at the output 4 of the U4 control microcircuit, those. To protective disconnection. The R38 resistor is ballast for ZD1 stabitron. Capacitor C23 prevents the protection of protection in case of random short-term voltage emissions on the +5 V bus (for example, as a result of the voltage setting after a jump-shaking reduction of the load current). Diode D19 is unleashing.

The PG signal formation scheme in this UPS is a two-function and assembled on comparators (3) and (4) U3 microcircuits and a transistor Q3.

The scheme is constructed on the principle of controlling the presence of alternating low-frequency voltage on the secondary winding of the T1 starting transformer, which acts on this winding only in the presence of supply voltage on the primary winding T1, i.e. While the UPS is enabled in the feed network.

Almost immediately after turning on the UPS, the UPOM auxiliary voltage appears on the C30 capacitor, which is powered by the U4 control microcircuit and the U3 auxiliary microcircuit. In addition, the alternating voltage from the secondary winding of the T1 start transformer through the diode D13 and the current-limiting resistor R23 charges the C19 capacitor. With voltage with C19, the resistive divider R24, R25 is powered. From the R25 resistor, part of this voltage is fed to the direct input of the comparator 3, which leads to the closure of its output transistor. Appearing immediately following this, the output voltage of the internal support source of the U4 UREF \u003d + 5 chip in powers the R26, R27 divider. Therefore, a support level from the R27 resistor is supplied to the inverting input of the comparator 3. However, this level is selected smaller than the level of direct input, and therefore the output transistor of the comparator 3 remains in the closed state. Therefore, the process of charging the delayed capacity of C20 by chain begins: UPOM - R39 - R30 - C20 - "Case".

Growing as charging capacitor C20 The voltage is fed to the inverse input 4 of the U3 chips. On direct input of this comparator, voltage from the R32 R32 resistor R31, R32 connected to the UPOM bus is fed. While the voltage on the charging capacitor C20 does not exceed the voltage on the R32 resistor, the output transistor of the comparator 4 is closed. Therefore, the transistor base Q3 flows the opening current according to the chain: UPOM - R33 - R34 - B-E Q3 - "Corpus".

The transistor Q3 is open to saturation, and the PG signal, removed from its collector, has a passive low level and prohibits the start of the processor. During this time, during which the level of voltage on the C20 condenser reaches the level on the R32 resistor, the UPS has time to reliably exit the nomapsy mode of operation, i.e. All its output voltages appear in full.

As soon as the C20 voltage exceeds the voltage removed from R32, the comparator 4 will switch, and its output transistor will open. This entails the closing of the transistor Q3, and the PG signal, removed from its collector load R35, becomes active (n-level) and allows the start of the processor.

When the UPS is turned off from the network on the secondary winding of the T1 start transformer, the alternating voltage disappears. Therefore, the voltage on the C19 condenser is rapidly reduced due to the low capacity of the latter (1MKF).

As soon as the voltage drop on the R25 resistor will become less than on the R27 resistor, the comparator 3 switches, and its output transistor will open. This will entail a protective disconnection of the output voltages of the U4 control chip, because The transistor Q4 opens. In addition, through an open output transistor of the comparator 3, the process of accelerated discharge of the C20 condenser will begin: (+) C20 - R61 - D14 - K-E output transistor of the comparator 3 - "Case". As soon as the voltage level on C20 becomes smaller than the voltage level on R32, the comparator 4 will switch, and its output transistor closes. This will entail the Opening of the transistor Q3 and the transition of the PG signal into an inactive low level before it is unacceptable to decrease the voltage at the UPS output tires. This will lead to the initialization of the computer reset signal and to the initial state of the entire digital part of the computer.

Both comparators 3 and 4 schemes for generating a PG signal are covered by positive feedback using R28 and R60 resistors, respectively, which speeds up their switching.

Smooth output to the mode in this UPS is traditionally provided by the forming chain C24, R41 connected to the output 4 of the U4 control chip. The residual voltage at the output 4, which determines the maximum possible duration of the output pulses, is given by the divider R49, R41.

The fan motor power is carried out by voltage from the C14 condenser in the voltage generation channel -12 v via an additional unleashing M-shaped filter R16, C15.