RU2335055C1 - Vehicle independent power supply system - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: invention relates to electric power distribution systems. The proposed system incorporates the main and standby power supplies, the first and second external power distribution devices, the first and second transit cable lines, four power circuit switching units, the main and standby power inputs, the first and second transit power inputs, a switcher assembly made up of the first switch consisting of the first and second switching units with make contacts and the switcher assembly switching unit control unit, a power take-off electrical unit (PTOU), its generator being driven by the vehicle engine, a PTOU channel switching unit, a control signal reception and transmission unit, an input voltage control unit, the first and second power circuit protection circuit breakers, a power circuit switching units control unit, the first, second and third loads' switching units, a loads' channels switching unit, the first and second voltage converters, main and secondary firm power supply loads' DC distribution units with, secondary nonfirm power supply loads' DC and AC distribution units, main and secondary loads, a storage battery charging unit, a storage battery operation control unit, a storage battery, a line input, a centralised automated control unit and three communication lines.

EFFECT: shortened time intervals of power supply interrupts and higher-quality power supply.

3 cl, 3 dwg

Description

The invention relates to power distribution systems and can be used for power supply of electronic complexes operating away from stationary electrical networks.

Known power supply systems containing primary and backup sources of electricity connected through switchgears and cable lines to mobile objects, each of which contains primary and secondary consumers of electricity connected to consumer switching devices and an automatic control unit for consumer switching devices, power take-off installation, main and backup power inputs [1, 2].

In the normal mode of power supply to the facilities, the sources of the system have a low coefficient of utilization of installed capacity, which affects their fuel efficiency. An increase in the utilization rate and an improvement in fuel economy can be achieved by increasing the number of sources (with a corresponding decrease in their rated power), but this will lead to a decrease in the reliability of power supply, an increase in the cost of the system and the number of staff. At the same time, despite the correct operation of the main and backup sources, frequent switching of the power supply from the main power input to the backup input and vice versa may occur due to short-term voltage drops during the start-ups of asynchronous motors of auxiliary consumers, for example, air conditioners operating in short-term mode repeatedly. In addition, the electrical installations of objects cannot be used in the hot standby mode in the absence of a backup mobile source.

Closest to the technical nature of the present invention is an autonomous power supply system for mobile objects containing primary and backup power sources, remote distribution devices, primary and backup cable lines, centralized automated control device, primary, backup and transit power inputs, switching devices for switching sources power and control unit named switching devices, input control unit power supply, power take-off with a generator drive from the vehicle’s engine of a mobile unit and a switch with switching devices for connecting it to the network, a channel switching unit, switching devices for connecting main consumers, switching devices for connecting auxiliary consumers and a control unit for said switching devices, unit receiving and transmitting control commands, a communication line with a centralized automated network management device e ktrosnabzheniya [3].

The main disadvantage of the power supply system, selected as a prototype [3], is that when the main power source is switched to standby and the auxiliary consumers are disconnected from the last one, short-term (up to 200 ms) power outages of the main consumers and long (over 10 minutes) interruptions power supply auxiliary consumers.

In addition, when switching sources of electricity at the time of connecting consumers to them with full load, transients occur, associated with a significant deviation of voltage and frequency, the value of which exceeds the specified (required) values established by regulatory documents for power supply systems, which worsen the quality of electricity.

The aim of the invention is to reduce the break time and improve the quality of power supply to consumers.

This goal is achieved by the fact that in an autonomous power supply system for mobile objects containing a series-connected main power source, a first remote switchgear, a main cable line, a main power input, a first power circuit breaker and a first power circuit breaker, a redundant power source is connected in series , second remote switchgear, redundant cable line, redundant power input, second switching a power circuit apparatus and a second power circuit breaker, first and second transit power inputs, third and fourth switching apparatuses of power circuits, first and second transit cable lines, a switch consisting of a control unit, a first switching device with its make contacts and a second switching device with its make contacts, power take-off installation (EUU), EUU channel switching unit, control command receiving and transmitting unit, input voltage control unit, control unit switching power circuit switching devices, first and second consumer switching devices, linear input, first communication line, centralized automated control system of the power supply network, second and third communication lines, wherein the output of the first switching power device circuit is connected to the input of the third switching device of power circuits, the output of which is connected to the input of the first transit power input, to which the first transit cable line is connected, the output of the second switching of the power circuit apparatus is connected to the input of the fourth power circuit switching apparatus, the output of which is connected to the input of the second transit power input, to which the second transit cable line is connected, the EUOM output is connected to the first input of the EUOM channel switching unit, whose control output is connected to the control input of the unit control switching devices of the switch, the first and second control outputs of which are connected to the control inputs of the first and second switching ap the switch leads, the output of the first switching apparatus of the power circuits is connected to the second terminal of the closing contacts of the first switching apparatus of the switch, the first terminal of which is connected to the first terminal of the closing contacts of the second switching apparatus of the switch, the second terminal of which is connected to the output of the second switching apparatus of the power circuits, the input of the first circuit breaker power circuits connected to the first input of the input voltage control unit, the second input of which is connected to the input of the second car power circuit protection mat, the output of the control command reception and transmission unit is connected to the second input of the EUOM channel switching unit, the output of which is connected to the connection point of the first conclusions of the closing contacts of the first and second switching devices of the switch, the first output of the input voltage control unit is connected to the input of the switching control unit devices of power circuits, the first, second, third, fourth, fifth and sixth control outputs of which are connected to the control inputs of the first, second, the third and fourth switching apparatuses of power circuits, the first and second switching apparatuses of consumers, the second output of the input voltage control unit is connected to the input of the control unit for receiving and transmitting commands, the input-output of which is connected to the first input-output of the linear input, the second input-output of which the first communication line is connected to the first input-output device of a centralized automated control of the power supply network, the second input-output of which is connected via a second line connection with the main source of electricity, a backup source of electricity through a third communication line is connected to the third input-output device of a centralized automated control of the power supply network, characterized in that it includes a consumer channel switching unit, the first and second voltage converters, the DC distribution unit of the main consumers with guaranteed power supply, DC distribution unit for auxiliary consumers with guaranteed electric equipment, main direct current consumers with guaranteed power supply, auxiliary direct current consumers with guaranteed power supply, direct current distribution unit for auxiliary consumers with non-guaranteed power supply, alternating current distribution unit for auxiliary consumers with non-guaranteed power supply, auxiliary DC consumers with non-guaranteed power supply, auxiliary AC consumers with unwarranted power supply, battery charge unit, battery mode control unit, third consumer switching device with make contacts and a battery, while the outputs of the first and second power circuit breakers are connected to the first and second inputs of the consumer channel switching unit, third and fourth whose inputs are connected to the outputs of the first and second consumer switching devices, respectively, the first output of the consumer channel switching unit Iteli is connected to the input of the first voltage converter, the first output of which is connected to the first input of the DC consumers distribution unit with guaranteed power supply, the outputs of which are connected to the main DC consumers with guaranteed power supply, the second output of the consumer channel switching unit is connected to the inputs of the second voltage converter and unit AC distribution of auxiliary consumers with non-guaranteed power supply, to the outputs of which о auxiliary AC consumers with guaranteed power supply are connected, the first output of the second voltage converter is connected to the first input of the DC distribution unit of auxiliary consumers with guaranteed power supply, to the outputs of which auxiliary DC consumers with guaranteed power supply are connected, the second output of the second voltage converter is connected to the input of the unit DC distribution of auxiliary consumers with non-garan by the power supply, the second output of the first voltage converter is connected to the input of the battery charge unit, the first input-output of which is connected to the input-output of the battery operation mode control unit, the information input of which is connected to the information output of the battery, the input-output of which is through the third switching the consumer device is connected to the second input-output of the battery charge unit, the first and second outputs of the third switching device are consumer of the consumers are connected respectively to the second inputs of the DC distribution block of the main consumers with guaranteed power supply and the DC distribution block of auxiliary consumers with guaranteed power supply, the control input of the third switching device of consumers is connected to the control output of the control unit for operating modes of the battery, the information input-output of which is connected to additional information input-output block receiving and transmitting control commands eniya.

Comparative analysis with the prototype shows that the claimed autonomous power supply system for mobile objects is characterized by the presence of new units: a switching unit for consumer channels, two voltage converters, a DC distribution unit for main consumers with guaranteed power supply, a DC distribution unit for auxiliary consumers with guaranteed power supply, main and auxiliary DC consumers with guaranteed power supply, unit distribution of direct current of auxiliary consumers with non-guaranteed power supply, auxiliary distribution unit of alternating current with non-guaranteed power supply, auxiliary DC consumers with non-guaranteed power supply, auxiliary AC consumers with non-guaranteed power supply, battery charge unit, control unit for operating modes of the battery, third switching device with make contacts and battery, as well as a change in the relationship between the known other elements of the circuit.

Thus, the claimed system meets the criteria of the invention of "novelty." Comparison of the proposed solutions with other technical solutions shows that the introduced blocks are widely known [4, 5].

However, when they are introduced in this connection with the other elements of the circuit into the inventive autonomous power supply system for mobile objects, the above blocks exhibit new properties, which leads to a reduction in interruption time and an improvement in the quality of power supply to consumers. At the same time, the proposed system practically eliminates interruptions in the power supply of consumers in the event of a loss of the main and backup sources of electricity and, thereby, significantly improves the quality of power supply. This allows us to conclude that the technical solution meets the criterion of "significant differences".

Figure 1 presents a structural diagram of an autonomous power supply system for mobile objects, and Figures 2 and 3 show structural diagrams of a control unit for operating modes of a battery and a centralized automated control system for a power supply network.

An autonomous power supply system for mobile objects contains (see Fig. 1) main 1 (network 1) and backup 2 (network 2) power sources, the first 3 and second 4 remote distribution devices, the main 5 and backup 6 cable lines, the main 7 and backup 8 power inputs, the first 9 and second 10 transit power inputs, the first 11, second 12, third 13 and fourth 14 switching devices of power circuits, the first 15 and second 16 transit cable lines between mobile objects, respectively, in the main 1 (network 1) and standby 2 (network 2) networks, ne a switch 17, consisting of a control unit 18 of the switching apparatus of the switch, the first 19 of the switching apparatus with its make contacts 21 and the second 20 of the switching apparatus with its make contacts 22, power take-off 23 (ECM) with a generator drive from the vehicle’s vehicle engine, block switching 24 channels of EUOM, a block for receiving and transmitting 25 control commands, a control unit 26 for the input voltage, the first 27 and second 28 circuit breakers for power circuits, the control unit 29 works oh switching devices of power circuits, first 30 and second 31 switching devices of consumers, switching unit of 32 consumer channels, first 33 and second 34 voltage converters, distribution block of 35 direct current of main consumers with guaranteed power supply, distribution block of 36 direct current of auxiliary consumers with guaranteed power supply , the main consumers of direct current 37 with guaranteed power supply, auxiliary consumers of 38 direct current with guaranteed power power supply, DC distribution unit 39 of auxiliary consumers with non-guaranteed power supply, distribution unit 40 of alternating current of auxiliary consumers with non-guaranteed power supply, auxiliary consumers of 41 direct current with non-guaranteed power supply, auxiliary consumers 42 AC with non-guaranteed power supply, charge unit 43 of the battery, control unit 44 battery modes, third 45 switching device otrebiteley make contact, the battery 46, input line 47, a first link 48, the device 49 automated power management of a network, the second link 50 and third link 51.

The battery operation mode control unit 44 (Fig. 2) comprises a battery status data receiving unit 52, a display panel 53, a control command generator 54, an information transmitting and receiving unit 55, and a line adapter 56.

The centralized automated control device 49 contains (Fig. 3) a computer complex 57 consisting of a central processor module 58, a system bus 59, a hard disk drive 60, a standalone magnetic disk drive unit 61, a keyboard 62, a printer 63, and a controller module 64 input / output and video monitor 65, and also contains a block 66 for the exchange of information, which includes a module 67 mathematical accelerator and block 68 linear adapters.

The AC voltage from the output of the main 1 source of electricity through the first 3 remote switchgear using the main 5 cable line is connected to the input of the main 7 power input, the output of which through the closed contacts of the first 11 switching device and the first 27 circuit breaker is connected to the first input of the unit 32 switching consumer channels. A backup 2 source of electricity through a second 4 remote switchgear, a backup 6 cable line, a backup 8 power input, closed contacts of the second 12 switching apparatus of the power circuits and the second 28 circuit breaker for power circuits are connected to the second input of the block 32 switching consumer channels.

The output of the first 11 switching apparatus of the power circuits is also connected to the input of the third 13 switching apparatus of the power circuits, the output of which is connected to the input of the first 9 transit power input, the output of which is connected to the first 15 transit cable line through which AC voltage can be output from the output of the electrical installation 23 to another mobile object. The output of the second 12 switching apparatus of the power circuits is also connected to the input of the fourth 14 switching apparatus of the power circuits, the output of which is connected to the input of the second 10 transit power input, the output of which is connected to the second 16 transit cable line for supplying alternating current voltage to another mobile object.

The output of the electrical installation 23 is connected to the first input of the EUUOM channel switching unit 24, the second input of which is connected to the output of the unit 25 for receiving and transmitting control commands. The control output of the EUOM channel switching unit 24 is connected to the control input of the switching device control unit 18 of the switch 17, the first and second output of which is connected to the control inputs of the first 19 and second switching devices of the switch 17, and the power output of the EUOM channel switching unit 24 is connected to the connection point the first conclusions of the make contacts 21 and 22, respectively, of the first 19 and second 20 switching devices of the switch 17. The second conclusion of the make contacts of the first 19 switching of the first apparatus of the switch 17 is connected to the output of the first 11 switching apparatus of the power circuits, and the second output of the make contacts 22 of the second 20 switching apparatus of the switch 17 is connected to the output of the second 12 switching apparatus of the power circuits. The input of the first 27 circuit breaker is connected to the first input of the input voltage control unit 26, the second input of which is connected to the input of the second 28 circuit breaker. The first output of the input voltage control unit 26 is connected to the input of the power circuit switching apparatus control unit 29, the first, second, third, fourth, fifth and sixth control outputs of which are connected to the control inputs of the first 11, second 12, third 13 and fourth 14 switching devices, respectively power circuits, the first 30 and second 31 switching devices of consumers, and the second output of the input voltage control unit 26 is connected to the input of the control unit 25 for receiving and transmitting control commands, the input-output of which is is single with the first input-output of the linear input 47. The second input-output of the linear input 47 is connected via the first 48 communication lines to the first input-output of the device 49 for centralized automated control of the power supply network, the second input-output of which is connected via the second 50 communication line to the main 1 a source of electricity, and a backup source 2 of electricity through a third 51 communication lines connected to the third input-output device of a centralized automated control of the power supply network.

The outputs of the first 27 and second 28 power circuit breakers are connected respectively to the first and second inputs of the consumer channel switching unit 32, the third and fourth inputs of which are connected to the outputs of the first 30 and second 31 consumer switching devices, respectively. The first output of the consumer channel switching unit 32 is connected to the input of the first 33 voltage converter, the first output of which is connected to the first input of the DC distribution unit 35 of the main consumers with guaranteed power supply, to which the main DC consumers 37 with guaranteed power supply are connected. The second output of the consumer channel switching unit 32 is connected to the inputs of the second 34 voltage converter and the alternating current distribution unit 40 of the auxiliary consumers with non-guaranteed power supply, to which the auxiliary 42 consumers of alternating current with non-guaranteed power supply are connected. The second output of the first voltage converter 33 is connected to the input of the battery charge unit 43, the first output of which is connected to the input-output of the battery operation mode control unit 44, the information input of which is connected to the information output of the battery 46. The second input-output of the battery charge unit 43 the battery is connected to the first input-output of the third 45 switching device of consumers, the second input-output of which is connected to the battery 46. The first and second outputs of the third about the consumer switching device are connected to the second inputs of the DC distribution unit 35 of the main consumers with guaranteed power supply and the DC distribution unit 36 of auxiliary consumers with guaranteed power supply, the control input of the third consumer switching device is connected to the control output of the battery operating mode control unit 44, information the input-output of which is connected to an additional information input-output Ohm block 25 receiving and transmitting control commands.

The first and second outputs of the battery state data receiving unit 52 of the battery operating mode control unit 44 are connected to inputs of a display board 53 and a control command generator 54, the first control output of which is connected to a control input of the information reception and transmission unit 55, the output of which is connected with the first input of the battery status receiving unit 52. The input-output of the information receiving and transmitting unit 55 is connected to the first input-output of the linear adapter 56, while the second input of the battery status data receiving unit 52 is an information input of the battery operation mode control unit 44, the input-output of which is the third input of the block 52 receiving data on the state of the battery and the second control output of the driver 54 of the control commands, the second input-output of the linear adapter 56 is the information input-output of the mode control unit 44 the operation of the battery, the control output of which is the third control output of the shaper 54 control commands.

The first, second, third, fourth and fifth inputs and outputs of the central processor module 58 of the centralized automated control network 49 of the power supply device 49 are connected respectively to the first input-output of the system bus 59, to the inputs and outputs of the hard disk drive 60, of the autonomous drive unit 61 of the drives floppy magnetic disks, keyboard 62 and printer 63. The second input-output of the system bus 59 is connected to the first input-output of the I / O controller module 64, the second input-output of which is connected to the input-output of the video monitor 65, the third input-output of the system bus 59 is connected to the first input-output of the mathematical accelerator module 67 of the information exchange unit 66, and the second input-output of the mathematical accelerator module 67 is connected to the first input-output of the linear adapter unit 68, to the second, third and the fourth inputs and outputs of which are connected, respectively, the first 48, second 50 and third 51 communication lines.

The main 1 and backup 2 sources of electricity can be used industrial network of three-phase alternating current with a rated voltage of 380/220 V, rated frequency of 50 Hz or mobile power plants of three-phase alternating current of the specified nominal voltage and frequency mounted in a box body mounted on a car chassis all terrain type Ural-375 or KAMAZ.

The first 3 and second 4 remote switchgears are structurally complete units made in a housing protected from dust and precipitation, incorporating connecting elements for connecting a power cable from the above-mentioned three-phase alternating current power sources.

The main 5 and backup 6 cable lines, the first 15 and second 16 transit cable lines can be performed using various field power distribution cables used for the deployment of power supply networks, for example, distribution hose special cable type KRSHS-4x6 square. mm

The main 7 and backup 8 power inputs, the first 9 and second 10 transit power inputs are designed to connect power cables and receive (transmit) voltage from them from the main 1 and backup 2 AC power sources. All of the mentioned power inputs are made of the same type of design in a rigid case with front-panel connectors of the “C” series (power), for example, connectors designed for a current of 40 or 63 amperes.

The first 11, second 12, third 13 and fourth 14 switching devices of power circuits are intended for connecting and switching power circuits from the main 1 and backup 2 power sources to the inputs of the first 27 and second 28 power circuit breakers. As such switching devices, various switching devices and contactors for power circuits can be used, for example, switching devices of the KM-10 or KM-25 type [5].

Electrical installation 23 is intended for additional backup of the main 1 and backup 2 sources of electricity in the event of failure. The presence of electrical installation 23 allows for hot backup of power supply due to the automatic activation of EUU 24 instead of the failed main 1 or backup 2 sources of electricity, which contributes to uninterrupted power supply to consumers and increase the reliability of power supply to mobile objects.

The EUOM channel 24 switching unit is designed for switching the output of the EUOM 23 to the channel of network 1 or channel of network 2, to the first 13 and second 14 transit power inputs for transmitting electricity to external consumers. Block 24 also provides the transmission to the block 18 of the control signals of the switching devices 19 and 20 of the switch 17 and the reception from the block 25 of the signals of the remote on (off) electrical installation 23.

Block 25 is intended for reception and transmission through line input 47 and the first 48 line of communication control commands to the device 49 centralized automated control of the power supply network.

The input voltage control unit 26 is designed to control the AC voltage supplied through the main 7 and standby 8 power inputs from the main 1 (network 1) and backup 2 (network 2) power sources, as well as coming from the output of electrical installation 23 through channel switching unit 24 EUU and switch 17 with closed contacts 21 of the first 19 switching device or closed contacts 22 of the second 20 switching device.

If the incoming AC voltage is within the specified norms, then the block 26 provides a signal to the control unit 29, which includes the first 30 and second 31 consumer switching devices. The latter are also triggered by closing their contacts, which are part of the consumer channel switching unit 32, and provide AC voltage transmission from the outputs of the first 27 and second 28 power circuit breakers respectively through the first input and output of the consumer channel switching unit 32 to the input of the first 33 voltage converter and through the second input and output of the block 32 switching consumer channels to the input of the second 34 voltage Converter. From the second output of the block 32 switching consumer channels, the AC voltage from the backup 2 of the electric power source is supplied to the input of the block 40 of the distribution of alternating current auxiliary consumers with unwarranted power supply.

Power circuit breakers 27 and 28 are designed for current protection of power circuits of the main 1 and backup 2 power sources during overload and short circuit in the power circuits of the main and auxiliary consumers.

Block 32 switching consumer channels is designed to connect power circuits from the main 1 and backup 2 sources of electricity, from the electrical installation of the EUOM 23, receiving and switching three-phase alternating current with a rated voltage of 380/220 V, rated frequency of 50 Hz, transmitting alternating current electricity to the inputs of the first 33 and the second 34 AC converters, to the input of the unit 40 for distribution of alternating current of auxiliary consumers with non-guaranteed power supply, as well as for automatic switching sources of electricity from the main 1 to the backup 2 source when the voltage of the main 1 source of alternating current electricity disappears and the automatic switching back from the backup 2 to the main 1 source occurs when the voltage of the main source 1 of the alternating current is restored.

The first 33 and second 34 converters are designed to connect power circuits from alternating current power sources, direct current and battery consumers, signal circuits, converting three-phase alternating current electric power with a rated voltage of 380/220 V, rated frequency of 50 Hz into direct current electricity with a nominal voltage of 28.5 V and the required indicators of the quality of electricity, the return of rated power when working from autonomous AC sources, you block overload without tripping sources and consumers. Blocks 33 and 34 also automatically control the magnitude of the output DC voltage and the magnitude of the load current.

As such converters, a rectifier unit (VU) can be used, developed and mass-produced by the closed joint-stock company (CJSC) of the Sigma research and production company (Russia, 248000, Kaluga, 11/1 Lunacharsky St., Kaluga, Russia) NPF ZAO "Sigma". Product catalog, p.22, 2006).

The DC distribution block 35 of the main consumers 37 with guaranteed power supply is designed to connect to the first input of a DC power source of unwarranted power supply (first 33 voltage converters), a guaranteed DC power source of guaranteed power (battery 46) to the second input and the main DC consumers 37 with guaranteed power supply, transit circuits of guaranteed power supply, switching and distribution of electric power WGIG DC sources guaranteed power consumers. Block 35 also provides automatic continuous monitoring of the state of switching bodies (on / off) of the block, the magnitude of the voltage at the inputs and outputs, the magnitude of the consumed currents at the inputs and outputs, the presence of voltage at the outputs to consumers 37.

The DC distribution unit 36 of auxiliary consumers 38 with guaranteed power supply is intended for connecting to the first input of a non-guaranteed power source of direct current DC (second 34 voltage converters), a guaranteed power supply of direct current DC power (battery 46) to the second input and auxiliary DC consumers 38 with guaranteed power supply, transit circuits of guaranteed power supply, switching and distribution electric power supply of direct current sources of guaranteed power to consumers 38. Unit 36 also provides automatic continuous monitoring of the state of switching bodies (on / off) of the unit, the voltage at the inputs and outputs, the magnitude of the consumed currents at the inputs and outputs, the presence of voltage at the outputs to consumers 38 .

The distribution unit 39 of direct current of auxiliary consumers with non-guaranteed power supply 41 is intended for connecting to the first input of a non-guaranteed power supply of direct current (second 34 voltage converters) and auxiliary consumers of direct current 41 with non-guaranteed power supply, switching and distribution of power of non-guaranteed power direct current sources to consumers 41. Block 39 also provides automatic continuous monitoring with -being switching organs (on / off) of the block, the voltage values at inputs and outputs, the values of currents consumed by the inputs and outputs, the voltage at the outputs availability to consumers 41.

The distribution unit 40 of alternating current of auxiliary consumers with unguaranteed power supply 42 is intended for connecting to the input of an electric power source of non-guaranteed power supply (from block 32 of switching consumer channels) and auxiliary consumers 42 alternating current with non-guaranteed power supply, switching and distribution of electric power of non-guaranteed power sources of alternating current consumers 42. Unit 40 also provides automatic continuous monitoring of the area of switching bodies (on / off) of the unit, the voltage at the inputs and outputs, the magnitude of the consumed currents at the inputs and outputs, the presence of voltage at the outputs to consumers 42.

The battery charge unit 43 in conjunction with the battery mode control unit 44 is designed to automatically charge the battery 46 using a DC voltage coming from the output of the first 33 voltage converter. It provides the operator with a preliminary setting of the charge mode (charge current and charge time), automatically switches to charge mode when a certain acceptable voltage level is reached on a discharged battery, and automatically disconnects from charge mode when a specified time is reached, protects the unit from improper power supply connection and protection from short circuit, continuous signaling of power-up and operating modes, intermittent signaling of unit operation modes when current disappears in the circuit acc battery and the end of the charge mode, a digital indication of the current charge time.

As the rechargeable battery 46, alkaline rechargeable batteries of the type NKTB-80 (nickel-cadmium tabletless without capacity, with a capacity of 80 ampere-hours) or KNB-15 and KNB-32 (cadmium-nickel tabletless without capacity of 15 and 32 ampere-hours) can be used [6].

The device 49 for centralized automated control of the power supply network is designed to solve the problems of choosing the optimal operating modes of the power supply system based on information received from the control unit 25 for receiving and transmitting control commands, the main 1 and backup 2 power sources, and processing data for monitoring the technical condition of the power supply system elements.

Computing complex 57 of device 49 is intended for receiving information from block 25, main 1 and backup 2 sources of electricity, processing data for monitoring the technical condition of the main elements of the power supply system, and the amount of electricity consumption. The presence of these data will allow timely measures to be taken to ensure uninterrupted power supply to the main 37, auxiliary 38, 41 and 42 consumers of electricity of mobile objects.

Computing complex 57 can be implemented using the basic and additional modules of electronic computers (computers) of the Baguette family for specialized applications and software for them. The Baget family of computers includes a set of standard modules and allows you to install additional modules to solve a wide range of problems of input, collection, storage, processing, display on a video monitor and data transfer [4].

Block 66 information exchange is designed to receive, process and transmit data on the technical condition of the power supply system and its elements. It includes a math accelerator module 67 and a block of linear adapters 68. The mathematical accelerator module 67 is a well-known element from the family of additional modules for the Baguette computer system. As such a block 67, a mathematical accelerator of the BTO1-206 type can be used. It is designed to interface with ISA type 59 system bus and provide high-speed processing of large volumes of homogeneous information. Block 68 linear adapters is designed to exchange data on physical communication lines, including the first 48, second 50 and third 51 communication lines between the device 49 and block 25, the main 1 and backup 2 power sources. It also provides the transmission of signals and control commands for remote turning on (turning off) the electrical installation 23, depending on the scheme of the power supply system installed during this period of operation.

The system is characterized by several modes of operation, the main of which are:

1) power supply to consumers in a two-beam scheme from the main 1 and backup 2 sources of electricity;

2) power supply to consumers according to a two-beam scheme from the main source 1 of electric power and electrical installation of EUM 23 of a mobile object;

3) power supply to consumers according to a single-beam scheme;

4) the issuance of AC electricity to external consumers through the transit 9 and 10 power inputs.

The first of these modes is ensured in the presence of alternating current voltage at the power inputs 7, 9 and 8, 10 of a mobile unit, provided that the voltage deviation at the main 7 and first 9 transit power inputs, as well as at the backup 8 and second 10 transit power inputs, are not out of range. In this case, separate power is supplied to the main consumers 37 with guaranteed power supply, auxiliary consumers 38 with guaranteed power supply, auxiliary consumers 39 and 40 with non-guaranteed power supply via cable lines 5, 15 and 6, 16 from the main 1 and backup 2 AC power sources. Electrical installation 23 in this case is an unloaded reserve.

In this mode, the contacts of the switching devices of the power circuits 11, 13 (on the main network) and 12, 14 (on the backup network) are in the closed position, the contacts (are in the 32 switching unit of the consumer channels) of the switching devices 30 and 31 consumers, and the contacts 21 of the first switching apparatus 19 and the contacts 22 of the second 20 switching apparatus of the switch 17 are in the open state. When the voltage deviates at the main 7 power input beyond the permissible limits, the control unit 29 automatically responds to the switching devices 30 and 31 under the action of a signal generated by the input voltage control unit 26. At the same time, in block 32 of switching consumer channels, the second input, which receives AC voltage from backup 2 of the electric power source, automatically switches to the first output of block 32 and then to the input of the first 33 AC voltage to DC voltage converter, which is fed to the input of the block 35 DC distribution of consumers with guaranteed power supply. Opening the contacts of the switching apparatus of 31 consumers disconnects auxiliary consumers 38, 41 and 42 from the backup 2 source of electricity. When restoring the main 1 source of electricity in block 32, the reverse automatically switches the main consumers to power from source 1 and auxiliary consumers from backup 2 of the source of electricity. So there is a backup of power supply for alternating current.

The uninterrupted (uninterrupted) power supply of the main 37 and auxiliary 38 consumers with guaranteed power supply during the first operation mode in the proposed power supply system is achieved by direct current backup using a rechargeable battery 46, which is constantly connected to the main and auxiliary DC distribution units 35 and 36 consumers with guaranteed power supply. This is done as follows. In the normal position, when the battery 46 is fully charged, the voltage from it is supplied through the first pair of closed contacts of the third 45 switching device of the consumers to the second inputs of the DC power distribution units 35 and 36. If the AC voltage of the main 1 source of electricity disappears, the main consumers of direct current 37 are supplied with power from the battery 46. In the event of a long interruption and discharge of the battery 46 is less than acceptable, the battery 46 is disconnected from consumers by opening the first pair of contacts of the third 45 consumer switching device . In this case, the signal about the discharge of the battery 46 from its output is fed to the information input of the unit 44 for controlling the operating modes of the battery. Simultaneously with the output of the battery charge unit 43, a signal indicating the presence of voltage at its output is also supplied to the control unit 44. Based on these data, unit 44 generates a control signal, which is fed to the control input of the third 45 switching device of consumers. Under the influence of this signal, the switching device 45 is activated, which opens the first pair of its contacts and closes the second pair. Closing the second pair of contacts of the third 45 switching device of the consumers, the battery is connected to the input-output of the battery charge unit 43 and the battery 46 is charged through it to the required level by the voltage from the second output of the first 33 voltage converter to the battery input 46 through a charge unit 43 and a second pair of closed contacts of the third 45 switching device of consumers. Information about the state of the battery 46 and the charging process from the information input-output of the control unit 44 of the operating modes of the battery through the block 25 of the reception and transmission of control commands, line input 47 and the first 48 communication line is supplied to the device 49 for centralized automated control of the power supply network.

Power supply in the second mode is provided from the main 1 source of electricity through power inputs 7, 9 and from the electrical installation 23 of the mobile object. In this case, centralized power is supplied to the main consumers of direct current 37 from the main power source 1 according to the above scheme and power is supplied to auxiliary consumers 38, 41 and 42 from a working electrical installation 23, the start of which is provided by the operator manually or remotely by command from the centralized automated control device 49 through the first 48 communication line, line input 47 and block 25 of the reception and transmission of control commands. The command adopted by block 25 through the EUUOM channel 24 switching unit is sent to the switching device control unit 18 of the switch 17, under the action of which the second 20 switching device is triggered and with its closed contacts 22 supplies AC voltage from the output of the electrical installation 23 to the input of the second 28 circuit breaker (to the network 2) and to the second input of the input voltage control unit 26. When the voltage level of the corresponding level is supplied to the input unit 26, it starts the consumer switchgear control unit 29, which, when activated, turns on the switching device 31. With its closed contacts in the block 32, the switching device 31 provides the power circuit breaker 28 from the output through the second input and output of the power supply unit 32 of auxiliary consumers 38, 41 and 42 from the electrical installation 23. With this mode of operation of the power supply system is also uninterrupted (without cw) power consumers auxiliary power supply 36 with a guaranteed by the use of the battery 46 similarly as described above for the first mode of the system.

The third mode of power supply occurs when there is only one external source of electricity or electrical installation 23, when both external sources of electricity are absent. This mode can be implemented if high reliability of power supply to consumers of mobile objects is not required.

The fourth mode of power supply is carried out by means of electrical installation 23 of his mobile object. In this case, the AC voltage from the output of the electrical installation 23 through the EUUOM channel 24 switching unit is supplied to the connection point of the first terminals of the make contacts 21 of the first 19 switching apparatus of the power circuits and the making contacts 22 of the second 20 switching apparatus of the power circuits of the switch 17. Closing the contacts 21 or 22 of the switching apparatus 19 or 20, the voltage from the output of the electrical installation 23 through the channel switching unit 24 is supplied to the inputs of the third 13 or fourth 14 switching devices of the power circuits, from the output to voltage through the first 9 transit or second 10 transit power inputs enters the first 15 transit or second 16 transit cable lines and then to the transit power inputs of other mobile objects.

To implement a particular operating mode of the power supply system, it provides data collection on the state of the system and its elements along the first 48, second 50 and third 51 communication lines to the centralized automated control device 49, in which the received data are processed using the computer complex 57. Based on the data processing results, the operator determines the most optimal scheme of the power supply system.

The positive effect of the proposed power supply system is to reduce the time outages and improve the quality of power supply to consumers. This is achieved by introducing a rechargeable battery 46, which is the second backup source of direct current, providing remote switching on of the electrical installation 23, which allows for hot backup of power supply due to their automatic switching on instead of a failed primary or backup source, which contributes to uninterrupted power supply to consumers.

In the proposed autonomous power supply system due to the introduction of the block 43 of the charge of the battery 46 and the block 44 of the control modes of the battery eliminates transient processes in the sources of electricity, which helps to improve the quality of electricity of consumers. At the same time, the DC voltage supplied to the main 37 and auxiliary 38 consumers with guaranteed power supply does not decrease less than the limit of the nominal value of the battery used to maintain uninterrupted power supply (without interruption of power supply), and thereby ensures uninterrupted power supply to consumer equipment.

In addition, it also achieves the preservation of 100 percent capacity of the battery 46 and the extension of its technical resource, which helps to extend the life of the battery, the total service life of the battery and the power supply system of mobile objects as a whole.

The advantage of the proposed power supply system is also that it provides the ability to connect electrical installation 23 not only to network 1 or network 2, but also to transit power inputs 9 and 10, which makes it possible to use electrical installation 23 for supplying consumers with alternating current as its mobile object , as well as consumers of other mobile objects through transit 15 and 16 cable lines. This helps to expand the functionality of the proposed power supply system.

Information sources.

1. SU, copyright certificate No. 681501, cl. H2O 3/04, 1977.

2. SU, copyright certificate No. 843090, cl. H2O 3/04, 1981.

3. RU, patent No. 2125331, class. H02J 3/04, 9/06, 1999.

4. The family of computers "Baguette-M", Design Bureau "Corund-M", PO Box 10.

5. Domoratsky O.A. Energy military communications installations. - M .: Military Publishing House, 1974, p. 174-197.

6. Romanov V.V., Khashev Yu.M. Chemical current sources. - M .: Soviet Radio, p. 79-80, 1978.

Claims (3)

1. An autonomous power supply system for mobile objects, containing a series-connected main power source, a first remote switchgear, a main cable line, a main power input, a first power circuit breaker and a first power circuit breaker, a redundant power source connected in series, a second remote distribution device , redundant cable line, redundant power input, the second switching apparatus of the power circuits and the second machine protection of power circuits, first and second transit power inputs, third and fourth switching apparatuses of power circuits, first and second transit cable lines, a switch consisting of a control unit, a first switching device with its make contacts and a second switching device with its make contacts, electrical installation power take-off (EUOM), an EUOM channel switching unit, a control command receiving and transmitting unit, an input voltage control unit, a switching apparatus control unit with main circuits, the first and second switching devices of consumers, linear input, the first communication line, the device for centralized automated control of the power supply network, the second and third communication lines, while the output of the first switching device of the power circuits is connected to the input of the third switching device of the power circuits, the output of which is connected with the input of the first transit power input, to which the first transit cable line is connected, the output of the second switching apparatus of the power circuits is connected to the input of the fourth switching apparatus of the power circuits, the output of which is connected to the input of the second transit power input, to which the second transit cable line is connected, the output of the EUOM is connected to the first input of the channel switching unit of the EUOM, the control output of which is connected to the control input of the control unit of the switching switching devices, the first and the second control outputs of which are connected to the control inputs of the first and second switching devices of the switch, the output of the first the switching circuit of the power circuits is connected to the second terminal of the make contacts of the first switching apparatus of the switch, the first terminal of which is connected to the first terminal of the closing contacts of the second switching apparatus of the switch, the second terminal of which is connected to the output of the second switching apparatus of the power circuits, the input of the first circuit breaker is connected to the first the input of the input voltage control unit, the second input of which is connected to the input of the second circuit breaker, the output of the unit the reception and transmission of control commands is connected to the second input of the EUU channel switching unit, the output of which is connected to the connection point of the first conclusions of the closing contacts of the first and second switching devices of the switch, the first output of the input voltage control unit is connected to the input of the control unit of the switching devices of the power circuits, first, second , the third, fourth, fifth and sixth control outputs of which are connected to the control inputs of the first, second, third and fourth switching units of power circuits, first and second switching devices of consumers, the second output of the input voltage control unit is connected to the input of the control reception and transmission unit, the input-output of which is connected to the first input-output of the linear input, the second input-output of which is connected via the first communication line with the first input-output device for centralized automated control of the power supply network, the second input-output of which is connected via a second communication line to the main source of electric power rgii, a backup source of electricity through a third communication line is connected to the third input-output of the centralized automated control system of the power supply network, characterized in that it includes a consumer channel switching unit, first and second voltage converters, a DC distribution unit of the main consumers with guaranteed power supply, DC distribution unit for auxiliary consumers with guaranteed power supply, main consumers guaranteed current supply, auxiliary DC consumers with guaranteed power supply, DC distribution unit for auxiliary consumers with non-guaranteed power supply, AC distribution unit for auxiliary consumers with non-guaranteed power supply, auxiliary DC consumers with non-guaranteed power supply, auxiliary AC consumers with non-guaranteed power supply, battery charge unit a battery, a control unit for operating modes of the battery, a third consumer switching device with make contacts and a battery, while the outputs of the first and second circuit breakers of the power circuits are connected respectively to the first and second inputs of the switching unit of the consumer channels, the third and fourth inputs of which are connected to the outputs of the first and second consumer switching devices, respectively, the first output of the consumer channel switching unit is connected to the input of the first pre a voltage generator, the first output of which is connected to the first input of the DC power distribution unit with guaranteed power supply, to the outputs of which the main DC consumers with guaranteed power supply are connected, the second output of the consumer channel switching unit is connected to the inputs of the second voltage converter and the AC distribution unit of auxiliary consumers with non-guaranteed power supply, to the outputs of which auxiliary power is connected ate AC with unguaranteed power supply, the first output of the second voltage converter is connected to the first input of the DC distribution unit of auxiliary consumers with guaranteed power supply, the outputs of which are connected auxiliary DC consumers with guaranteed power supply, the second output of the second voltage converter is connected to the input of the DC distribution unit auxiliary consumers with non-guaranteed power supply, the second in the course of the first voltage converter is connected to the input of the battery charge unit, the first input-output of which is connected to the input-output of the battery operation mode control unit, the information input of which is connected to the information output of the battery, the input-output of which is connected to the consumer’s third switching device the second input-output of the battery charge unit, the first and second outputs of the third switching device of the consumers are connected respectively to W direct inputs of the DC distribution unit of the main consumers with guaranteed power supply and the DC distribution unit of auxiliary consumers with guaranteed power supply, the control input of the third switching device of the consumers is connected to the control output of the control unit for operating modes of the battery, the information input-output of which is connected to an additional information input - the output of the block receiving and transmitting control commands. 2. The stand-alone system according to claim 1, characterized in that the control unit for operating modes of the battery contains a unit for receiving data on the state of the battery, a display panel, a command shaper, a unit for receiving and transmitting information, and a line adapter, the first and second outputs unit for receiving data on the state of the battery are connected to the inputs, respectively, of the display panel and the command generator, the first control output of which is connected to the control input of the receive and transmit unit information, the output of which is connected to the first input of the battery status data receiving unit, the input-output of the information receiving and transmitting unit is connected to the first input-output of the line adapter, while the second input of the battery status data receiving unit is the information input of the mode control unit the operation of the battery, the input-output of which is the third input of the data receiving unit about the state of the battery and the second control output of the control command generator, second The th input-output of the linear adapter is the information input-output of the battery operating mode control unit, the control output of which is the third control output of the control command generator. 3. The stand-alone system according to claim 1, characterized in that the centralized automated control system for the power supply network comprises a computer complex consisting of a central processor module, a system bus, a hard disk drive, an autonomous floppy disk drive unit, a keyboard, a printer, a module of input / output controllers and a video monitor, and an information exchange unit including a mathematical accelerator module and a linear adapter unit, wherein the first, second, third, h the fourth and fifth inputs and outputs of the central processor module are connected respectively to the first input-output of the system bus, to the inputs and outputs of a hard disk drive, an autonomous block of floppy disk drives, a keyboard and a printer, the second system bus input-output is connected to the first the input-output of the controller module, the second input-output of which is connected to the input-output of the video monitor, the third input-output of the system bus is connected to the first input-output of the mathematical accelerator module of the information exchange unit math, and the second input-output of the mathematical accelerator module is connected to the first input-output of the linear adapter unit, while the first, second and third input-output of the centralized automated power supply network control device are the second, third and fourth inputs and outputs of the linear adapter block, which are connected, respectively, the first, second and third communication lines.

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