SU1700678A1 - Power supply system - Google Patents

Abstract

The invention relates to electrical engineering and can be used to power n loads. The purpose of the invention is to simplify the provision of alternating switching on and off of n loads. This is done by dividing n loads into m groups of loads, each of which contains k loads connected in parallel through one key and included in the first parallel circuit. Moreover, out of k loads in each of the m load groups, only one load can be connected to the main source at any time. The first terminals of each two parallel circuits are closed through a comparison block. The first and second keys of each of the contact groups are connected to the second terminals of each of the first and second parallel circuits, respectively. The common key point of each of the two contact groups is connected to the second output separately of either the main or auxiliary power sources. 1 il. cl

Description

The invention relates to electrical engineering and can be used to power n loads.

The purpose of the invention is to simplify the provision of alternating switching on and off of n loads.

The drawing shows the functional diagram of the power supply system.

The system contains the main 1 and auxiliary 2 power sources, the first 3 and second 4 controllers, the first 5 and second b contact key groups, the voltage meter 7, the sensitive elements 8 and 9 short circuit and breakage, the control key contact control unit 10 11 -13, keys 14-16, load simulator 17, third controller 18, comparing unit 19, first keys 20 and 21 of the first and

the second contact groups, the second keys 22 and 23 of the first and second contact groups, and the control signal channel 24.

Previously, all existing in the system and powered from the main source 1 n loads are divided into m groups of loads, each of which contains k loads connected in parallel through one key. In this case, k loads are selected so that of them at any moment only one load should be connected to the main source 1.

To simplify the depiction of the device, only three loads of any of the m load groups are represented in the drawing.

The system contains the main 1 and auxiliary 2 power supplies, some of which are through the first 3 and second 4

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The controllers, respectively, are connected via contact groups 5 and 6 to two parallel circuits, between which the voltage meter 7 is connected. The first circuit consists of a short-circuit sensing element 8 connected in series and an open sensing element 9, the outputs of which are connected to the inputs of the contact group control unit 10. Loads 11-13 are interconnected in parallel through keys 14-16. The second circuit includes serially connected load simulator 17 and a third controller 18, the input of which is connected to the first output of the current comparing device 19, the second output connecting to one of the inputs 10 contact group management. A current comparison unit 19 is connected between the short circuit sensing element 8 and the third regulator 18, i.e. between the first ends of two parallel chains. The first 20 and 21 and the second keys 22 and 23 of the contact groups 5 and 6 are connected respectively to the parallel connected loads 11-13 and the load simulator 17, i.e. to the second ends of the parallel circuits, with the common point of the keys 20 and 22 connected to the second terminal of the main source 1, and the common point of the keys 21 and 23 connected to the second terminal of the auxiliary source 2 of the power supply. To the input of the control unit 10 contact groups connected channel 24 control signals

The system works as follows.

If necessary, switch on the next load, for example, load 13 on the control signal received via the channel 24 to the control unit 10 of the contact keys. Cham, the latter switches the keys 16 and 21 connecting the load 13 to the auxiliary source 2 along the circuit: the first terminal of the source 2, the second regulator 4, the current comparison device 19, the short circuit and open circuit sensing elements 8 and 9, respectively, the load 13, the keys 16 and 21 and the second terminal of the source 2. According to the control signal, the switch 22 also switches the load simulator 17 to the main source 1 along the circuit: the first clamp of the source 1, the first regulator 3, which compares the current block 19, the third regulator 18, the load simulator 17 key 22 and sec The first terminal of the source 1. Due to the large value of the resistance of the third regulator 18, the current in the circuit of the load simulator 17 initially is almost zero. After the transient process at the auxiliary source 2 is completed, the second regulator 4 equalizes its voltage with the main source 1 About equality

voltages are judged by readings of voltage meter 7. At the same time, the input from the third regulator 18 receives a signal from one output of the current comparing unit 19, proportional to the difference of the currents of the auxiliary 2 and the main 1 sources. As a result, the current of the main source 1 will begin to smoothly increase until it is aligned with the current of the computational source 2. When the specified currents at the output of the third regulator 18 are equal, the signal of the comparison current block 19 is memorized from one of its outputs. Simultaneously from the second

5 of the output of the comparing unit 19, the signal acts on the control unit 10, which generates commands for simultaneously opening the switches 21 and 22 and closing the switch 20, which means connecting the load 13 to the main source 1 without causing disturbances on it. The load 13 is disconnected either after it has completed its tasks, or if a short circuit or open circuit occurs in its circuit. In the first case, the shutdown is carried out by the control unit 10 contact groups on the signal received through the channel 24, in the second case, the shutdown is performed by block 10

0 according to the signals of the sensitive elements 8 and 9 short circuit and breakage, respectively. On these signals, the control unit 10 generates commands to simultaneously open the key 20 and to close the key 22,

5 which means disconnecting from the main source 1 load 13 and connecting to it a simulator 17 load. Since the resistance of the third regulator 18 is memorized at the moment of connecting the load 13, its disconnection

0 will not cause significant interference on the tires of the main source 1 due to the approximate equality of the resistance of the simulator 17 load and the load 13. After switching, due to the lack of current of the auxiliary power supply source 2, through the comparison current block 19 the signal from its output acts on the third regulator torus 18 so that its resistance increases smoothly, which will lead to a smooth decrease to zero current

0 of the main source 1. The shutdown of the load simulator 17 is then carried out by the control unit 10 on the signal of the channel 24.

Similarly,

5 connection and disconnection of loads in any of the m load groups.

Thus, to connect (disconnect) n loads to the primary power source 1 in the proposed device, it is necessary (n-m) keys (in the known device 4, n), m load patterns, i.e. according to the number of groups of loads in the (known device p), i.e. according to the number of loads themselves, m comparative blocks (in the known device the same functions are performed by the Z p devices).

Claims (1)

The invention includes a power supply system containing n loads and n corresponding load simulators interconnected in parallel through 2p contact groups, each of which consists of two serially connected keys, the main and auxiliary power sources, the first outputs of which are through the first and second controllers respectively connected through the said groups to each two of the 2n parallel circuits, between which the voltage meter is connected, the first circuit including connected a short-circuit sensing element and a breakage sensing element, the outputs of which are connected to the inputs of the control unit of contact groups, and one of the n loads, and the second serially connected simulator of the corresponding load and the third controller, the input of which is connected to the first output of the comparison unit, the second output connected to one of the inputs of the control unit of contact groups, differing so that, in order to simplify the provision of alternating switching on and off of n loads, the latter are divided by m groups of loads, each of which includes k loads connected in parallel through k and connected to the first parallel circuit, the output of the control unit of contact groups is connected to one of the k loads, the first extreme terminals of two parallel circuits are interconnected through comparing unit, and the first and second keys of each contact group connected to the second extreme terminals of the first and second parallel circuits, respectively; in addition, the common point of the keys of each of the two contact groups is connected to the second terminal of the corresponding power source. | 2A YU 77 untlp / u Ljl jl