RU2028705C1 - Multichannel system of power supply - Google Patents

Abstract

FIELD: radio engineering. SUBSTANCE: multichannel system includes D C power supply source, clock generator, commutation unit with K information inputs according to number of users, K power supply channels which incorporate section of M storage cells, K input OR gate and (K=1) key elements. System provides for connection of control equipment only when request to charge sections of storage cells of power supply channels and to maintain them arrives. EFFECT: increased reliability of protection. 1 dwg

Description

 The invention relates to electrical engineering, in particular to DC power supply systems of consumer complexes (loads) with various values of rated voltage, power or requiring galvanic isolation.

 A device is known for powering a load with direct current, comprising a series of battery sections charged from an electric energy source (direct current source) through two controlled key cells having two opposite-polarity power inputs and outputs. The device also includes: a battery condition monitoring unit, a switching unit (made in the form of a register), a clock generator, and power channels (charge-discharge units) according to the number of groups of electricity consumers. Managed key cells are introduced into each of the power channels. Moreover, each power channel has three control outputs. The first control terminal is connected to a common clock generator, and the second and third control terminals are connected to the corresponding counting output of the switching unit (register) and its clock input [1].

 The known device has the following disadvantages. In the process of functioning of the device, all the equipment of the switching unit, power channels, and also a clock generator are constantly in the on state. The energy consumption graphs of the objects on which the known device is installed are determined by the cyclograms of the operation of the electricity consumer systems, and, as a rule, they have an uneven change in each of the power supply channels. The unevenness in time of energy consumption schedules increases significantly with the multivariance of the modes of operation of objects. Therefore, the constant inclusion of all the equipment of the switching unit, power channels and a clock generator leads to unreasonably high energy consumption along the power circuits of these elements and a decrease in the operational life of the device.

 Also known is a multi-channel power supply system (MSEP), containing a direct current source, a clock generator, a switching unit with a clock input, K inputs and K outputs according to the number of loads K power channels with two input power, two output power and three control outputs in each, including a section of M batteries connected to a direct current source through M controlled key cells, each of which has two input power bipolar, two output power bipolar and one control terminals, a battery monitoring system with two input and one output control terminals, two pulse shapers, a pulse distributor, an AND circuit for two inputs and a NOT circuit, while the input power terminals of each power channel are connected to a direct current source, and the output power terminals are connected to the load , the first control conclusions of the power channels are connected to the output of the clock generator, the second control conclusions are connected to the corresponding outputs, and the third control conclusions are connected to the corresponding information inputs of the com utilization, and in each power channel, the first control output is connected to the first input of the And circuit, the second control output is connected to its second input, and the output of this circuit is connected to the clock input of the pulse distributor, the mth output of which is connected to the control input of the corresponding controlled key cell and the last output of the pulse distributor is connected to the input of the first pulse shaper, the output of the clock generator is connected to the clock input of the switching unit, which is made in the form of a set of information paths , each of which contains an OR circuit for two inputs, a first AND circuit for two inputs, a charge request trigger and a second AND circuit with a number of inputs equal to the path number in each path, the first input of the first circuit And is connected to a single output of the request trigger charge, its output is connected to the first input of the OR circuit, the second input of which is connected to the clock input of the switching unit, and the output to the clock input of the charge request trigger [2].

 The disadvantage of this system is also the increased energy consumption in the power supply circuits of the components of the MESP and the reduction of the operational life with a continuous, long-term order of 5-9 years of operation of the MESP.

 Closest to the proposed one is a multi-channel power supply system containing a direct current source, a clock generator, a switching unit with K information inputs for the number of loads, K power channels with two input, two output power and three control outputs in each, including a section of M batteries, connected to the direct current source through the control unit of the power channel, which has two input, two output power bipolar and two control pins, forming the control pins of the channel power supply, a battery monitoring device with two input and one output control terminal connected to the third output of the power channel, the output power terminals of the power channel are connected to the input control terminals of the battery and load monitoring device, the first control terminals of the power channels are connected to the output of the clock generator, the second control conclusions to the corresponding information outputs of the switching unit, and the third control conclusions to the corresponding information inputs of the block and switching, power circuits of the elements of the switching unit, clock generator, elements of the control unit, power channels with one bus are connected to the corresponding terminals of the DC source, and the power circuits of each device for monitoring the state of the batteries with two buses are directly connected to the corresponding terminals of the DC source [3].

 The disadvantages of this system are the increased power consumption of the control circuits and the reduced operational life of the MSEP elements.

 The purpose of the invention is to increase the operational resource and reduce energy consumption of the equipment of the control circuits of a multi-channel power supply system.

 This is achieved in that in a multi-channel power supply system containing a direct current source, a clock generator, a switching unit with K information inputs for the number of loads, K power channels with two input, two output power and three control outputs in each, including a section of M batteries connected to the DC source through the control unit of the power channel, having two input, two output power bipolar and two control pins, forming the control pins of the power channel, your control of the condition of the batteries with two input and one output control terminal connected to the third output of the power channel, the output power terminals of the power channel are connected to the input control terminals of the battery condition and load monitoring device, the first control terminals of the power channels are connected to the output of the clock generator, the second control conclusions - to the corresponding information outputs, and the third control conclusions - to the corresponding information inputs of the switching unit, power supply circuit The components of the switching unit, the clock generator, the elements of the control unit for the power supply channels with one bus are connected to the corresponding terminals of the direct current source, and the power circuits of each device for monitoring the state of the batteries with two buses are directly connected to the corresponding terminals of the direct current source, new connections and elements are introduced.

 In particular, an additional OR circuit for K inputs and (K + 1) key elements having one control and two power outputs is additionally introduced in the MSEP, the third control outputs of the power channels are connected to the corresponding channel number by the inputs of the OR circuits, the output connected to the control output (K + 1) a key element, the first power output of which is connected to a direct current source, and the second with another bus of the power circuits of the elements of the switching unit and the clock generator, in addition, the third control terminals of each power channel are connected to to the control inputs of the corresponding key cells, the first power terminals of which are connected to a direct current source, the second - with another bus of the power supply circuit of the power channel control unit.

 Comparative analysis with the prototype shows that the claimed system is fundamentally different by the presence of an OR circuit for K inputs and (K + 1) key cells, as well as their connection.

 This set of connections and elements ensures the execution of the MEPC functioning algorithm with the switching elements, the clock generator, and the corresponding power channel included in the operation only if there is a request signal for the charge of this channel and their inclusion in its absence, which reduces energy consumption in the power supply circuits and save operational resource.

 The introduction of a set of distinctive features allows to reduce the time spent in the on state of the elements in the MESP, which ensures an increase in the operational resource.

 The drawing shows a functional diagram of a multi-channel power supply system for three channels (K = 3). In the general case, when K loads, there should be K channels and, depending on the load parameters, there should be M batteries and M managed key cells in the battery section of each power channel.

The multi-channel power system contains a DC source 1, a switching unit 2 with 3k information inputs (K + 1 (1) 3) and 4k outputs for the number of loads, 5k power channels with two input 6k, 7k, two output 8k, 9k power and three control terminals 10k, 11k, 12k each, including a section of M 13k batteries, the batteries are connected to a direct current source 1 through a control unit 14k of the 5k power channel, having two input power unipolar 15k, 16k, two output power unipolar 17k, 18k and two control 19k, 20k output, about generators control power output channel. The battery condition monitor 21k has two input 22k, 23k and one output control terminal, which is connected to the 12k terminal of the 5k power channel. A 24k load is connected to the output power terminals 8k and 9k of the power channel. The first control terminals 10k of the 5k power supply channels are connected to the output of the clock generator 25, the second control terminals 11k to the corresponding information outputs 4k of the switching unit 2, and the third control terminals 12k to the corresponding information inputs 3k of the switching unit 2, and the control inputs corresponding to the channel number power supply of the key cells 27k, as well as the inputs of the OR circuit 26, the output connected to the control terminal of the key cell 27 _{to + 1} , the first power output of which is connected to a constant current source 1, and the second output to the second oh the power bus 28 elements of the switching unit 2 and the clock generator 25, the first power terminals of all the key cells 27k are connected to the DC power source 1, and the second ones to the second power buses 29k of the power channel elements 5k, the first buses 30k of which, as well as the first and second the power bus of the 21k battery condition monitoring devices is connected directly to source 1.

The system operates as follows. Load 24 is the most important (has the highest priority), load 24z is the least important (least priority). The priority of the load, its change during operation determines the signal supplied to the input code buses of setting the priority 31 of switching unit 2. In the initial state, all sections of the batteries are 13 _km charged, the voltage of the DC source 1 is applied to the power buses of all battery condition monitoring devices 21k, priority load set. In this case, the low-level signal (logical "0") is on the control terminals of all battery condition monitoring devices 21 ₁ -21 ₃ . This signal comes from the control pins 12 ₁ -12 ₃ power channels 5 ₁ -5 ₃ respectively to the information 3 ₁ -3 ₃ switching blocks 2, the control pins of the key elements 27k and three inputs of the OR circuit 26. The second power bus of the elements of the switching block 2, a clock generator 25, control units 14 ₁ -14 ₃ power channels 5 ₁ -5 _{3 are} disconnected from the direct current source 1. Thus, the direct current source 1 is not connected to 13 km batteries.

When the battery section in a power supply channel, for example 5 ₂ , is discharged to a certain extent, this is indicated by the battery monitoring device 21 ₂ by issuing a potential signal in the form of a logical "1" (high level potential).

The signal of a single level through the output 12 _{2 of} the power supply channel 5 ₂ enters the second input of the OR circuit 26, input 3 ₂ of the switching unit 2, and to the control terminal of the key cell 27 ₂ , which connects the second power supply lines of the control unit 14 ₂ power channels with its power outputs 5 ₂ to the DC source 1. In addition, a single signal from the output of the OR circuit 26 is supplied to the control terminal of the key cell 27 ₄ , the latter connects the second power buses of the elements of switching unit 2 and the clock generator 25 with its power terminals, providing m its start and the issuance of clock pulses to the control 10 ₁ -10 ₃ inputs of the power channels 5k and, accordingly, to the control inputs 20 ₁ -20 _{3 of} their control units 14 ₁ -14 ₃ .

The outputs 4 ₂ of the switching unit 2 (the logic of the operation of the switching unit 2 may be similar to the work in (3)) there is a high potential, which corresponds to the permission to connect the battery sections 13 ₂₁ -13 _2m power supply channel 5 ₂ to the DC source 1. At the same time the power channels 5 ₁ and 5 _{3 are} blocked by zero logic signals from the outputs 4 ₁ and 4 ₃ of the switching unit 2, applied to the terminals 11 ₁ and 11 ₃ and, respectively, 19 ₁ and 19 ₃ and the clock pulses of the generator 25 do not cause their operation. High potential from the output 4 ₂ of the switching unit 2 is supplied to the second control input 11 _{2 of} the power channel 5 ₂ and, accordingly, to the second control input 19 _{2 of} its control unit 14 ₂ . The control unit 14 ₂ in the presence of a control signal at 11 ₂ input and clock pulses at 20 ₂ input provides sequential connection of the battery sections 13 ₂₁ -13 _{2 m} to the DC source 1 in a circular cycle until the output of the battery monitoring device 21 ₂ a low potential does not appear, signaling the end of the battery charge of section 13 ₂ (logical “0”). Logical signal "0" is supplied through output 12 ₂ to the information input 3 ₂ of switching unit 2 (and through output 4 ₂ to the second control input 11 _{2 of} the power channel and, accordingly, to 19 ₂ input of its control unit 14 ₂ , which corresponds to the lack of permission to charge sections of accumulators 13 ₂₁ -13 _{2 m of} the power channel 5 ₂ ) and through the second input of the OR circuit 26 to the control output of the key cell 27 ₄ , which provides disconnection of the second power bus of the elements of switching unit 2, the clock generator 25, and the key cell 27 _{2 of the} block control 14 ₂ power channels 5 ₂ from DC source 1, which corresponds to the lack of permission to charge the battery section 13 ₂₁ -13 _2m .

When the battery section is discharged of a more important (more priority) load during battery charging of a less important (less priority) load, for example 24 ₁ and 24 ₂ , a signal will be sent to information input 3 ₁ of switching unit 2, the first input of OR circuit 26 and the control input of the key element 27 ₁ , which by its power terminals connects the second power bus 28 _{1 of} the power channel 5 ₁ to the constant current source 1, thereby ensuring the preparation and inclusion of the elements of the power channel 5 ₁ into operation. In addition, the switching unit 2, by this signal, disconnects the batteries 13 _{2 of the} less important load 24 ₂ from the direct current source 1 by issuing zero potential at the output 4 ₂ of the switching unit 2. The battery charge 13 _{2 of the} less important power channel 5 _{2 will} resume only after the battery is charged sections of the more important power channel 5 ₁ .

 Thus, the use of the invention will increase the operational resource and reduce the power consumption of the control circuit equipment, which is ensured by the technical implementation of disconnecting the control circuit equipment in the absence of requests for battery charge.

Claims (1)

 MULTI-CHANNEL POWER SUPPLY SYSTEM, containing a direct current source, a clock generator, a switching unit with K information inputs for the number of loads, K power channels with two input, two output power and three control outputs in each, including a section of M batteries connected to a direct current source through the control unit of the power channel, which has two input, two output power bipolar and two control pins, forming the control pins of the power channel, a device for monitoring the state of acc mulators with two input and one output control terminal connected to the third output of the power channel, the output power terminals of the power channel are connected to the input control terminals of the battery and load monitoring device, the first control terminals of the power channels are connected to the output of the clock generator, the second control terminals are connected to the corresponding information outputs of the switching unit, and the third control outputs to the corresponding information inputs of the switching unit, the power supply circuit of the unit elements switching, a clock generator, elements of the control unit of the power supply channels with one bus are connected to the corresponding terminals of the DC source, and the power circuit of each device for monitoring the state of the batteries with two buses are directly connected to the corresponding terminals of the DC source, characterized in that, in order to increase the operational life and To reduce the power consumption of the control circuit equipment, an OR circuit for K inputs and K + 1 key elements has been introduced into the power supply system one control and two power inputs, the third control terminals of the power channels are connected to the corresponding channel number by the inputs of the OR circuit, the output connected to the control terminal K + 1 of the key element, the first power terminal of which is connected to a direct current source, and the second to another circuit bus power supply of the switching unit and the clock, in addition, the third control terminals of each power channel are connected to the control inputs of the corresponding key cells, the first power terminals of which are connected to a direct current source, the second - with another bus power circuits of the elements of the power channel control unit.

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