RU2189603C2 - Device testing insulation resistance and protecting electrotechnical installation with suppression of field of electric energy generator - Google Patents

Abstract

FIELD: electrical engineering. SUBSTANCE: device has network generator with connected measurement circuit, measurement circuit rectifier, D C voltage source and actuator. One lead of measurement circuit is connected to phases of network, the other lead is connected to frame. Voltage source comes in the form of parametric stabilizer connected to network voltage, diodes of assembly forming three-phase rectifier are connected to phases of network, elements of measurement circuit (light emitter of optron shunted by noise-suppressing capacitor, adjusting and limiting resistor) are connected in series to common point of said diode assembly. Second lead of resistor is connected to frame. Photodetector of said optron is connected in series with actuator and to output of parametric stabilizer. Device is supplemented with commutation unit connected to phases of network, closing contact of actuator is placed in series with commutation unit, breaking and blocking contact of commutation unit is placed in parallel with resistor connected in series with key excitation winding of generator. Other leads of resistor and winding are connected to excitation voltage. full-wave rectifier which output is connected to input of parametric stabilizer is incorporated in auxiliary power supply source. Photodetector can come both in the form of phototransistor or photothyristor. EFFECT: simplified design, improved functional reliability and sensitivity of device. 2 cl, 2 dwg

Description

 The invention relates to electrical engineering and can be used in devices for protecting electrical installations and humans in three-phase (multiphase) networks with isolated neutral.

 Known devices for monitoring and protection of the electrical system [1], containing a sensor for monitoring insulation resistance, made in the form of a capacitive zero sequence sensor connected to each of the phases, the output of which is connected to an actuating control element connected to an actuating control body, an indication device and a power source providing power to electronic components of the control and protection system.

 The main disadvantage of such a device is the lack of response to a symmetrical decrease in insulation in a circuit with isolated neutral.

 The known principle of constructing a system of protective tripping device (RCD) using operational direct current [2, 3]. The principle of operation [2] is that an artificial zero point according to the "star" scheme is formed using a choke-transformer, in series with a common point of which a choke, a current relay and a DC source are connected, one of the terminals of which is connected to the housing ("ground" "). In this case, the current flowing along the above circuit is the operational control current, the value of which depends on the insulation resistance.

 The disadvantage of this device is the reduced sensitivity: at certain ratios, due to the lack of adjustments, the protection and control system may be inoperative.

 In addition, all of the above devices turn off the voltage at the load. In this case, the source of electricity - the generator - remains energized, which can lead to electric shock to a person in case of touching the live parts of the generator.

 The aim of the invention is to simplify the device, expand the functionality, increase its reliability.

 This goal is achieved by the fact that in a device containing a network generator with a connected measuring circuit, a rectifier of the measuring circuit, a DC voltage source and an actuating element, one output of the measuring circuit is connected to the phases of the network, the other to the case, which diodes are connected to the phases of the network by anodes the cathodes of which are interconnected, forming a rectifier of the measuring circuit, the DC voltage source is made in the form of a parametric stabilizer connected by one output to any of the phases of the network, etc. ogim - to the junction point of the cathodes of the said diodes, the measuring circuit is made in the form of a serial connection of the light emitter of the optocoupler shunted by an interference suppression capacitor, regulating and limiting resistors, and one terminal of the said light emitter of the optocoupler is connected to a common junction of the cathodes of the said diodes, the second terminal of the limiting resistor is connected to the housing, the photodetector of said optocoupler is connected in series with the actuating element to the output of the parametric bilizer, the device is characterized in that a switching device is introduced, connected to the phases of the network, in series with which the closing contact of the actuating element is connected, the opening and locking contact of the switching device is connected in parallel with the resistor, connected in series with the main excitation winding of the generator, the other terminals of the mentioned resistor and winding connected to the excitation voltage.

 In addition, the device is characterized in that a half-wave rectifier is included in the DC voltage source, the output of which is connected to the input of the parametric stabilizer, and in that the photodetector of the optocoupler can be made in the form of a photo thyristor or phototransistor.

 Figure 1 shows a schematic diagram of a device, figure 2 - options for execution.

 The device (Fig. 1) contains a network generator 1 (can be located outside the device), a rectifier 2 of the measuring circuit (two diodes, the anodes of which are connected to the phases of the network, the cathodes are combined into a common point), a DC voltage source 3 connected by one output to any of the phases of the network, the other - to the common connection point of the rectifier 2 of the measuring circuit to which the light emitter 4 of the optocoupler 5 is connected, the photodetector of which 6 is connected in series with the actuating element 7 to the output of the DC voltage source 3, the sequence 4 but with the light emitter includes an adjusting resistor 8 and the current limiting resistor 9 is connected to the other terminal of the housing ( "ground") 10. The closing contact actuating member 7 'is connected, e.g., to one or more network phases, performs a control function.

 The switching device 11 contains an opening and blocking contact 11 ', which returns the electrical installation to its original state and prepares it for the next manual or remote switching on after troubleshooting (for example, an RCD; not shown in Fig.).

 The DC voltage source 3 can be made, for example, in the form of a parametric stabilizer on a zener diode 12 and a quenching resistor 13 with a smoothing output filter 14. The insulation resistance (real) of each phase 15 is connected to the housing ("ground") 10. The light emitter 4 is shunted noise suppression capacitor 16.

The opening and blocking contact 11 'is connected to a resistor 17 connected in series with the main excitation winding of the generator 18 connected to the voltage V _exc - the excitation voltage of the main winding.

 A circuit comprising a serially connected make contact 7 'of the actuating element 7 and the switching device 11 is connected to a phase or line voltage of the network.

 The DC voltage source 3 can be connected (Fig. 2) directly to the phases of the network through a rectifier, made, for example, according to the Grets scheme.

 Figure 1 - photothyristor 5, its light emitter 4, the photodetector 6.

 In FIG. 2 - a phototransistor 5, its light emitter 4, a photodetector 6, a half-wave rectifier for a DC voltage source 19. In this case, one of the terminals of the phototransistor - a collector - is connected to one of the terminals of the actuator 7, the other terminal of which is connected to one of the outputs of the parametric stabilizer on the zener diode 12, the emitter of the phototransistor 6 is connected through the second limiting resistor 20 to the second output of the parametric stabilizer, to which the base is connected through the base resistor 21 th phototransistor 5. The measuring circuit includes series-connected light emitter 4 optocouplers 5, shunted by a noise suppressing capacitor 16, an adjustment resistor 8 and a limiting resistor 9.

The device shown in FIG. 1, works as follows. In normal operation, i.e. if there is insulation resistance within the established norms, the current I _о flowing through the light emitter 4 of the optocoupler 5 is insufficient to turn on the photodetector 6, the actuator 7 is in the off state, the contact of the actuator 11 is open, the generator 1 is on, on and (if necessary ) indication of normal operation. Operational current (for example, for phase "A") flows along the circuit: "A" - diode 2 of phase "A" - light emitter 4 - regulation resistor 8 - limiting resistor 9 - r _from (element 15) phases "B" and "C ", r _of - insulation resistance of the phase of the network in relation to the housing (" ground ").

In emergency modes, both asymmetric (i.e., a change in the insulation resistance of each phase is different) and a symmetric mode (change in the resistance of all phases are the same) are possible. Unlike the known devices, the measuring circuit, consisting of elements 4, 16, 8, 9, has a very large resistance (hundreds of ohms), and therefore its connection does not significantly affect the insulation resistance of the controlled network. Therefore, when any of the insulation resistances r _of 15 is reduced, both symmetric and asymmetric, the device is triggered, the sensitivity of which is determined by the very small input current of the light emitter 4 of the optocoupler 5.

 The insulation control at any point of a three-phase network with an isolated neutral is carried out by a circuit of elements 5, 8, 9, 16, 7. When the insulation level decreases or a person touches the current-carrying part of any phase, the actuating element 7 closes its contact 7 ', including switching device 11. It With its contact 11 ', a significant resistance 17 is introduced into the circuit of the main excitation winding 18 of the generator 17. The magnetic field of the generator is rapidly damped, and therefore its EMF decreases. Thus, the entire installation is quickly deenergized (L / R is very small), and the electrical safety of a person is ensured regardless of where in the circuit the phase (current-carrying part) touched.

 Contact 11 'is opening and blocking, i.e. it ensures the normal operation of the generator (the resistor 17 is shunted by the contact 11 'during operation) and, in emergency mode, the resistor 17 is inserted in series with the winding 18 and is blocked when disconnected, i.e. contact 11 'closes again for the next connection. The electrical installation is returned to its original state (resistor 17 is shorted by contact 11 '). Re-enable is carried out manually or remotely. If the problem persists, the process repeats.

 Depending on the network voltage, both thyristor (for example, ZOU103G) and transistor (for example, AOT110A) can be used as optocouplers. In the latter case, to operate in a wide temperature range, it is possible to control not only the light flux, but also electric means (second limiting resistor 18 and base resistor 19).

The authors tested the model of the proposed device at a network voltage of 220 V with r _o (limiting resistor 9) up to 180 kOhm, the insulation resistance was simulated within 100-150 kOhm, KD226V were used as diodes 2, 17, AOT110A optocouplers, 12 KS527A1 zener diodes, 12 relay actuator - RES-10, capacitor 14-K50-38-100V-22 uF. As a residual current device (node 11), UZO-M 304-2 was used, other UZOs of a similar type can be used.

 Thus, the proposed device provides not only a load shedding, but also a decrease in the voltage of the generator itself, which increases electrical safety when touching live parts of any point in the circuit, including the generator.

 The above data and information confirm the feasibility of the invention.

Sources of information
1. RF patent 2115986, cl. H 02 H 3/20, 7/08, publ. 1998, BI 20.

 2. Dolin P.A. Fundamentals of safety in electrical installations. - M .: Energy, 1979, p.274.

 3. Nayfeld M.R. Protective grounding in electrical installations. - M.-L.: SEI, 1959, p.194.

Claims (3)

 1. A device for monitoring insulation resistance and protecting an electrical installation with damping the field of an electric power generator, comprising a network generator with a connected measuring circuit, a rectifier for the measuring circuit, a DC voltage source and an actuating element, one terminal of the measuring circuit is connected to the phases of the network, and the other to the housing, diodes are connected to the network phases by anodes, the cathodes of which are interconnected, forming the rectifier of the measuring circuit, the DC voltage source is made in the form of a parameter of a stabilizer connected by one output to any phase of the network, and the other to the connection point of the cathodes of the said diodes, the measuring circuit is made in the form of a serial connection of the optocoupler light emitter, shunted by a noise suppressing capacitor, regulation and limiting resistors, and the other output of the optocoupler light emitter is connected to a common point connection of the cathodes of said diodes, the second terminal of the limiting resistor is connected to the housing, the photodetector of said optocoupler is connected is connected in series with the actuator to the output of the parametric stabilizer, characterized in that a switching device is introduced, connected to the phases of the network, in series with which the closing contact of the actuating element is connected, the opening and locking contact of the switching device is connected in parallel with the resistor connected in series with the main excitation winding of the generator, moreover, the other conclusions of the aforementioned resistor and windings are connected to the excitation voltage.  2. The device according to claim 1, characterized in that a half-wave rectifier is included in the DC voltage source, the output of which is connected to the input of the parametric stabilizer.  3. The device according to any one of paragraphs. 1 and 2, characterized in that the photodetector of the optocoupler can be made in the form of a photo thyristor or photo transistor.

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