CS268077B1 - Pulse source wiring - Google Patents

Abstract

The solution relates to the field of computer technology, where it is applicable to power supplies of central units and peripheral devices. It provides a simple wiring arrangement, which is manifested by low energy consumption, its essence lies in the fact that the auxiliary voltage source of the pulse source is connected by the output of the first supply voltage to the input of the first supply voltage of the converter and to the input of the first supply voltage of the remote control circuits. In this case, the control output of the auxiliary voltage source is connected to the input of the rectifier and the output of the second supply voltage of the auxiliary voltage source is connected to the input of the second supply voltage of the converter and simultaneously to the input of the second supply voltage of the level monitoring circuit and to the input of the second supply voltage of the remote control circuits. Furthermore, the first input of the auxiliary voltage source is connected to the output of the internal power supply circuits

Description

The invention relates to a pulse source with remote control and protection in the field of computer technology for power supplies of central units and specific devices.

To supply the computer equipment is often used pulsed sources Besides the basic functions, it is creating the necessary voltage levels, they must zdvw,) _{e S} t pift _Ova other requirements, such as monitoring the state level, the drive to start and stop doubling, »

Some pulse source connections are known to serve this purpose. For example, one of them involves connecting the mains voltage to an auxiliary voltage source and a rectifier. The rectifier is connected to an inverter which is controlled from the control circuit by the outputs of a known monolithic circuit and also supplied by an auxiliary source. M \ _mo | _{The 0} output of the inverter is connected to the output power section, connected by feedback _{3 to the} control circuit. In this connection, the remote control function of the source is performed by a monolithic nbvod with a control input. However, the known connection and in fact also others similar to it are of a relatively more complex design, it is necessary to adjust them, while the most significant disadvantage is their energy intensity.

These disadvantages are eliminated by the connection of a pulse source according to the invention comprising an auxiliary voltage source connected to the mains input, a rectifier connected to the auxiliary source via the mains input and a converter connected to the auxiliary source, the internal voltage circuit by the output level circuit and the control circuits. connected to the control circuits and the group of inputs to the level monitoring circuit and in addition provided with a group of power outputs. However the circuit of the internal power supply is connected to the auxiliary source, whereas the circuit monitoring levels is associated with the circuitry of the remote control and _{the secretarial} damage to property source circuit of the remote control is connected to an auxiliary source, a control ol> y _Qc sive and moreover is provided with control input connection. The invention is characterized 'z «YY _{T up} the first power voltage of the auxiliary voltage source is connected to the input ₀ prvnth supply voltage of the auxiliary voltage source is connected to the ^R input of the first power converter and napětf input to the first power supply circuit of the remote control. The control output of the auxiliary power supply is connected to the control input of the rectifier and the output of the second supply voltage of the auxiliary power supply is connected to the input of the second supply voltage of the inverter and at the same time to the input of the second supply voltage of the level monitoring circuit and the input of the second supply voltage of the remote control circuits. input pomocnpj, _o power supply is connected to the output of internal power supply circuits. Furthermore, the second supply input of the storage member simultaneously forms the operating input of the auxiliary voltage source and the excitation output of the DC voltage source is connected to the input of the delay circuit, the first control output of which is connected to the input of the first switching circuit. The second control output of the delay circuit is connected to the input of the second switching circuit, the output of which simultaneously forms the control output of the auxiliary voltage source. The output of the first switching circuit is arranged

-Jc jji iμυ jc> i to the switching input of the internal power supply stabilizer, the output of which is souftat, _n g output of the second supply voltage of the auxiliary voltage source, in addition to the blocking input of the level converter, the output of which is simultaneously the first blocking output of the remote control circuits. The supply input of the level converter is connected to the supply input of the control circuit and at the same time forms the input of the first supply voltage of the remote control circuits. Furthermore, the supply input of the level converter is connected to the supply input of the monitoring control circuit, to the supply input of the evaluation _{0 O} outlet> “.? and simultaneously forms the input of the second voltage supply circuit of the remote control, the D ~ Uhy inhibit output control circuit is connected to the blocking input of the control circuit hl by being added whose control input the same time forms the evaluating circuit input remote ovi _dl j _s _ _F output control circuit monitoring is connected to the input of the evaluation circuit, the output of which simultaneously forms the second blocking output of the remote control circuits.

The advantage of connecting a pulse source according to the invention is its simple connection to _it . _kc „and energy saving in the state switched off in the remote control mode.

_w · KG'ť e low power input transformer can be used.

268 077 Bl

An example of the connection of a pulse source according to the invention is shown in the accompanying drawings, where Fig. 1 is an overall block diagram of a pulse source, Fig. 2 is a block diagram of an auxiliary voltage source and Fig. 3 is a block diagram of remote control circuits.

The mains input 11 of the auxiliary voltage source £ is connected to the mains input 81 of the rectifier £ and at the same time forms the mains input 91 of the mains connection (Fig. 1). The output 011 of the first supply voltage of the auxiliary voltage source £ is connected to the input 33 of the first supply voltage of the converter 3 and to the input 7 of the first supply voltage of the remote control circuits £, the first interlock output 071 of which is connected to the first interlock input 22 of the control circuits. The control output 012 of the auxiliary voltage source £ is connected to the control input 82 of the rectifier £, the output 081 of which is connected to the input 31 of the third supply voltage of the converter £. The output 013 of the second supply voltage of the auxiliary voltage source £ is connected to the input 24 of the second supply voltage of the control circuits £, to the input 34 of the second supply voltage of the converter £, to the input 62 of the second supply voltage of the level monitoring circuit 6 and to the input 73 of the second supply voltage of the circuits £. remote control, their second blocking output 072 is connected to the second blocking input 23 of the control circuits 2. The control output 021 of the control circuits £ is connected to the control input 32 of the converter £, the first excitation output 031 of which is connected to the excitation input ££ around the output levels. whose feedback output 041 is connected to the feedback input 21 of the control circuit 2. The second drive output 032 of the converter £ is connected to the drive input 51 of the internal power supply leads, the output 051 of which is connected to the operating input 12 of the auxiliary voltage source. The group of power outputs 042 of the output level circuit 6 simultaneously forms a group of power outputs 091 of connection for connection to a load (not shown), the group of control outputs 043 of the output level circuit is connected to a group of control inputs 61 of the level monitoring circuit, the evaluation output 061 input 72 remote control £ circuits. The control input 71 of the remote control circuitry simultaneously forms a control input 92 of the circuit for connection to a control unit (not shown). '

The input 101 of the DC voltage source 100 (Fig. 2) simultaneously forms the network input 11 of the auxiliary voltage source 6. The supply output 0101 of the DC power supply 100 is connected to the first supply input 111 of the storage member 110, the output 0111 of which is connected to the supply input 151 of the internal power stabilizer 150 and simultaneously forms the output 011 of the first supply voltage of the auxiliary power supply. The second supply input 112 of the storage member 110 simultaneously forms the operating input 12 of the auxiliary voltage source. The excitation output 0102 of the DC power supply 100 is connected to the input 121 of the delay circuit 120, the first control output 0121 of which is connected to the input 131 of the first switching circuit 130. The second control output 0122 of the delay circuit 120 is connected to the input 141 of the second switching circuit 140 0141 simultaneously forms the control output 012 of the auxiliary voltage source £. The output 0131 of the first switching circuit 130 is connected to the switching input 152 of the internal supply stabilizer 150, the output 0151 of which simultaneously forms the output 013 of the second supply voltage of the auxiliary voltage source.

The input 701 of the control circuit 700 (Fig. 3) simultaneously forms the control input 71 of the remote control circuit 6. The first blocking output. 071 of the control circuit 700 is connected to the blocking input 711 of the level converter 710, the output 0711 of which simultaneously forms the first blocking output 071 of the remote control circuit 7. The power input 712 of the level converter 710 is connected to the power input 702 of the control circuit 700 and simultaneously forms the input 74 of the first supply voltage of the remote control circuit 6. The supply input 713 of the monitoring control circuits 720 to the supply input 732 of the evaluation circuit 730 and at the same time form the input 73 of the second supply voltage of the remote control circuit e. The second blocking output 0702 of the control circuit 700 is connected to the blocking input 721 of the monitoring control circuit 720, the control input 722 of which simultaneously forms the evaluation input 72 of the remote control circuit 6. The output 0721 of the monitoring control circuit 720 is connected to the input 731 of the evaluation circuit 730, the output 0731 of which simultaneously forms the second blocking output 072 of the remote control circuit £.

268 077 Bl

A mains voltage is applied to the input of the auxiliary voltage source £ and to the input of the rectifier £, which, after rectification and filtering, is supplied as a third supply voltage to the converter £ (Fig. 1). In order to avoid a large current surge from the mains, the capacitors of the mains filter are charged first after switching on the power supply via a large internal impedance in the rectifier £. Simultaneously with the charging of the line filter capacitor, the energy required for starting the converter £ accumulates in the auxiliary voltage source £ and the first supply voltage is applied, which is fed to the converter £ and to the remote control circuit £. When the required power level is reached, the second supply voltage is connected to the control circuits £, to the converter £, to the level monitoring circuit £ and to the remote control circuit £, thereby actuating the control circuits £ which start the converter £. As a result of the operation of the converter £, the output levels of the output level circuit 6 are generated and a group of outputs 042 connected to a unit (not shown) is connected, the internal supply circuits £ are put into operation, the operating voltage is connected to the auxiliary voltage source. the power of the auxiliary voltage source £ is supplied from the internal supply circuit £ and a control signal is generated which switches the charging circuit in the rectifier £ to a low impedance, so that the line filter capacitors continue to be charged without | current limitation. The control circuits £ are controlled by a feedback signal derived from the output levels of the output level circuit 6, thus ensuring their necessary stability when the mains voltage changes and when the load changes. The control signals supplied to the level monitoring circuit 6 are also derived from the state of the output levels. If a level fails, the state of the evaluation signal supplied to the remote control circuit E will change. These generate a first □ second blocking signal fed to the control circuits £ and distinguish whether the output level has dropped due to a fault or due to the source being put into standby by an external remote control signal at the input 71 of the remote control circuit.

The auxiliary power supply circuit (Fig. 2) provides the energy required for the start-up of the inverter and introduces the necessary start-up delay, which allows the mains filter capacitors to be fully charged via an established internal resistance to reduce current surge. from the mains after switching on the source. The circuit further provides power supply to the evaluation logic circuits and the control circuit when the remote control signal is activated at the input 71 of the remote control circuit £. After connecting the mains voltage to the DC voltage source 100, the storage member 110 is charged from its supply output 0101 and at the same time the excitation voltage is supplied to the delay circuit 120. After the expiration. ‘Of the set delay, the first switching circuit 130 is closed, which connects the stabilizer 150 of the internal supply to the storage member 110, in which the energy needed to start the converter £ has accumulated so far. The voltage at the output 0111 of the storage member 110 supplies the excitation and evaluation circuits. After the start-up of the converter £, the required energy is already supplied from the internal supply circuit £ to the accumulator member 110. If, during the operation of the pulse source, the remote control signal is activated at the input ££ of the remote control circuit £ or a fault is indicated at one of the output voltages of the pulse source, the control circuits £ and thus the converter £ are blocked. The power supply interrupts the supply of power to the storage member 110, so that all power for the control circuits 6 of the evaluation and logic circuits must be paid from the DC voltage source 100.

After applying the remote control signal to input 701 (Fig. 3), the signal fed to the converter 710 and from there to the control circuits £ blocks the inverter £, thereby lowering the output voltages of the pulse source and subsequently generating a fault signal from the circuit £. for monitoring levels to control input 722 of the control circuit 720. Given that in this case, not a failure, it is necessary first to bring this circuit signal output from the second blocker 072 watches in this case is' • _4,268,077 01 activated signal for evaluation circuit 730, as well as the signal is activated when a fault is reported during operation of the pulse source. The signal at the output 0731 of the evaluation circuit 730 controls the control circuits 2. After the signal at the input 71 is canceled, both the control circuits 2 and the monitoring control circuit 720 are unlocked.

The invention can be used in computer technology for power supplies of central units and peripheral devices, for example in devices for data preparation and preprocessing.

Claims (3)

Object of the invention A pulse source connection comprising an auxiliary voltage source connected to a power input, a rectifier connected to a mains input and a converter connected to an internal voltage circuit, an output level circuit and control circuits, the output level circuit being connected to control circuits and a group of inputs to a monitoring circuit. levels and in addition is provided with a group of power outputs, while the level monitoring circuit is connected to the remote control circuits, the remote control circuit is connected to the control circuits and in addition is provided with a control control input, characterized in that the first supply voltage output (011) the auxiliary voltage source (1) is connected to the input (33) of the first supply voltage of the remote control circuits (7), while the control output (012) of the auxiliary voltage source (1) is connected to the control input / 82) of the rectifier (8) and (013) of the second supply voltage of the auxiliary voltage source (1) is connected to the input (34) of the second supply voltage of the converter (3) and at the same time to the input (62) of the second supply voltage of the remote control circuits (7), the operating input (12) of the auxiliary voltage source (1) being connected to the output (051) of the internal power supply circuits (5). 2. The connection of a pulse source according to item 1, wherein the auxiliary voltage source is connected by its mains input to a DC voltage source further connected by a first power input to a storage member which is further connected to an internal power stabilizer, characterized in that the second power input (112) of the storage member (110) simultaneously form an operating input. (12) auxiliary .sources. (100) a DC voltage source (1002) is connected to the input (121) of the delay circuit (120), the first control output (0121) of which is connected to the input (131) of the first switching circuit. (130), the second control output (0122) of the delay circuit (120) is connected to the input (141) of the second switching circuit (140), the output (0141) of which simultaneously forms the control output (12) of the auxiliary voltage source (1) and the output ( 0131) of the first connection circuit (130) is connected to the switching input (152) of the internal power supply stabilizer (150), the output (0151) of which simultaneously forms the output (013) of the second supply voltage of the auxiliary voltage source (1). 3. Connecting a pulse source according to item 1, wherein the remote control circuit is connected to a control input, characterized in that said control input (71) simultaneously forms an input (701) of the control circuit (700) and a first interlock output (0701) of the control circuit. (700) is connected to the blocking input (711) of the level converter (710), the output (0711) of which simultaneously forms the first blocking output (071) of the remote control circuits (7), the power input (712) of the level converter (710) being connected to the supply input (702) of the control circuit (700) and simultaneously forms the input (74) of the first supply voltage of the remote control circuits (7), the supply input (713) of the level converter (710) is connected to the supply input (723) of the control circuit (720) monitoring, the supply input (713) of the level converter (710) is connected to the supply input (723) of the monitoring control circuit (720), to the supply input (732) of the evaluation circuit (730) and simultaneously forms the input (73) of the second supply voltage of the circuits (7) remote control, second blocking output 268 077 B1 (0702) of the control circuit (700) is connected to the blocking input (721) of the monitoring control circuit (720), the control input (722) of which forms the simultaneous evaluation input (72) of the remote control circuits (7), output (0721) The monitoring control circuit (720) is connected to the input (731) of the evaluation circuit (730), the output (0731) of which simultaneously forms the second blocking output (072) of the remote control circuits (7).