SU1181043A1 - Device for non-summetric under-load operation protection in three-phase power network - Google Patents

Abstract

A DEVICE FOR PROTECTION FROM A NON-SYMMETRIC LOAD MODE IN A THREE-PHASE ELECTRIC NETWORK, containing a source of rectified voltage, made in the form of three semiconductor diodes, each of which is connected to the corresponding phase of the network, connected to a star, connected to a star, connected to a star, connected to a star, connected to a voltage, connected to a star, connected to a voltage, connected to a voltage, connected to a voltage, connected to a voltage, connected to a voltage source, connected to a voltage source, connected to a network the zero point of the controlled load, and the capacitors connected in parallel to them, as well as the reacting body, so that, in order to expand the functionality of From the device, by determining the state of each phase of the load, the response organ is fulfilled in the form of a serially connected logical analysis unit having six output buses and a display unit, the logical analysis unit consisting of three identical groups containing two parallel connected circuits, one of which is formed a series connection of a diode connected with one polarity and a relay, and the other with the inclusion of a diode with another polarity and a relay, each group is connected to the cathodes of the respective diodes and each relay has two closing contact systems, the first and second fixed contacts of the relay of the first group and the second fixed contacts of the relay of the second group are united in a common point and connected to the first phase of the mains supply, the first moving contact of the first relay of the first group is connected to the first the fixed contact of the first relay of the third group, the second movable contact of the first relay of the first group is connected to the first fixed contact of the second relay of the second group, the first moving contact (L of the second relay of the first group is connected to the first fixed contact of the second relay of the third group, the second moving contact of the second relay of the first group is connected to the first fixed contact of the first relay of the second (Group, the second moving contact of the second relay of the second group is connected to the second fixed contact of the second relay of the third group, second moving contact the first relay of the second group is connected to the second fixed contact of the first relay of the third & 0 group, the second moving contact of the second relay of the third group is connected to the first bus e, the second movable con tact first relay of the third group is connected to the second bus, the first movable contact of the first switch of the second group is connected to the third bus, the first movable contact of the second switch of the second group is connected to fourth bus pVrvy movable contact of the first relay is connected to a third group of n

Description

That bus, the first moving contact of the third relay of the third group is connected to the sixth bus, the display unit consists of six alarm elements, one ends of which are connected to the corresponding output buses of the logic analysis unit, while others are interconnected and connected to the second phase of the three-phase network.

The invention relates to electrical engineering and can be used to protect an asynchronous crane motor with a phase-rotor from an unbalanced load in the rotor circuit. The purpose of the invention is to expand the functionality of the device by determining the state of each phase of the load. FIG. 1 shows a diagram of the device; in fig. 2 and 3, respectively, electrical circuits of the logic analysis unit, and the display unit. The device contains three semiconductor diodes 1, each of which is connected to the corresponding phase of the network to which the controlled load 2 is connected. Resistors 3 connected to the cathodes of the diodes are connected in a star, the zero point of which is connected to the zero point of the controlled load 2. Parallel to the resistors 3 are connected capacitors 4. To the cathodes of diodes 1 are connected input bus with | B C block 5 logical analysis, the output of which is connected to the first input of the display unit 6, the second input of which is connected to the phase of the network. Block 5 of the logical analysis consists of six electromagnetic relays 7–12, each of which has, respectively, two closing contacts, designated by the positions 13–24. Each pair of contacts is connected in series and connected to separate buses 25–30. The relay coils are connected via diodes 31-36 to the cathodes of diodes 1. (buses a, b, c). The relays vk are specified as follows: bus a, diode 31 in the forward direction, relay 7, bus b; bus Of, diode 32 in the opposite direction, relay 10, bus b; bus b, diode 33 in the forward direction, relay 8, bus C; bus, diode 34 in the opposite direction, relay 11 ,. O tire; bus C, diode 35 in the opposite direction, relay 9, bus a; bus C, diode 36 in the forward direction, relay 12, bus D. The display unit consists of six 3.7-42 light signaling elements, one ends of which are connected to the corresponding output buses of the 5th logic analysis unit, while others are united in a common point and connected to second phase network. The device works as follows. In the absence of defects in the controlled load 2, the same currents flow through the resistors 3, the pulsations of which are smoothed by the capacitors 4, and the voltages on the resistors 3 in this case are equal to each other. Thus, the potential differences between the points H, L, C (Fig. 1) are respectively equal to zero, and the relay of the logical analysis unit 5 is in a de-energized state. Accordingly, its output bus 2-5--30 does not apply voltage from phase A, i.e. elements 37-42 light alarm unit 6 display de-energized. When the closure of one of the resistors controlled load 2, for example, in phase a, the device operates as follows. The voltage drop across resistors 3 connected to phases B and C is proportional to the voltage drops across the respective resistors of the load to be controlled 2 and are equal to each other. The voltage drop across the resistor 3 connected to the phase A of the network is, in this case, zero. This combination of voltages goes to the input buses of the logical analysis unit 5, which triggers its relays 10 and 12, which connect the phase A of the network to its output bus 25 with their closing contacts 19 and 23. The voltage from the phase A of the network goes to block 6 of the display, causing the fire element 37 of the light alarm system. If one of the phases of controlled load 2, such as phase A, breaks, the voltage on the resistors 3 is proportional to the voltage drop on the corresponding phases 434 of the controlled load 2. The voltage on the resistors that are connected to phases B and C is equal to between each other and less voltage across a resistor connected to phase A. Therefore, in logic analysis block 5, relays 7 and 9 are triggered, which connect the phase A of the network to the output bus 26 with their short circuits contacts 13 and 17. The voltage from the phase A of the network arrives at block 6 indicative and causing the illumination of the light element 38 signaling. In the event of the occurrence of these defects in other phases of the controlled load, the device operates in the same way,

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Claims (1)

DEVICE FOR PROTECTED FROM ASYMMETRIC LOAD MODE IN A THREE PHASE ELECTRIC NETWORK, containing a rectified voltage source made in the form of three semiconductor diodes, each of which is connected to the corresponding phase of the network, to whose cathodes are connected resistors ^ connected to the star, the zero point controlled load, and capacitors connected in parallel to them, as well as a reacting organ, which is connected with the fact that, in order to expand the functional capabilities of the device In order to determine the state of each phase of the load, the reacting organ is made in the form of series-connected logical analysis unit having six output buses and an indication unit, and the logical analysis unit consists of three identical groups containing two parallel-connected circuits, one of which is formed in series by connecting a diode connected by one polarity and a relay, and the other by turning on a diode of a different polarity and a relay, each group is connected to the cathodes of the corresponding source diodes, and Each relay has two closing contact systems, the first and second fixed contacts of the relay of the first group and the second fixed contacts of the relay of the second group are combined into a common point and connected to the first phase of the supply network, the first movable contact of the first relay of the first group is connected to the first fixed contact of the first relay of the third group, the second movable contact of the first relay of the first group is connected to the first fixed contact of the second relay of the second group, the first movable contact of the second relay of the first group is connected to the first the stationary contact of the second relay of the third group, the second movable contact of the second relay of the first group is connected to the first fixed contact of the first relay of the second ^ group, the second movable contact of the second relay of the second group is connected to the second fixed contact of the second relay of the third group, the second movable contact of the first relay of the second group connected to the second fixed contact of the first relay of the third group, the second movable contact of the second relay of the third group is connected to the first bus, the second movable contact of the first relay the third group is connected to the second bus, the first movable contact of the first relay of the second group is connected to the third bus, the first movable contact of the second relay of the second group is connected to the fourth bus, the first movable contact of the first relay of the third group is connected to the fifth bus, the first movable contact of the second relay of the third the group is connected to the sixth bus, the display unit consists of six light signaling elements, one ends of which are connected to the corresponding output buses of the logical analysis unit, while others are interconnected This turns and under a second phase of the threephase ce · ti.