RU2242829C2 - Ground fault detecting and protecting device for electrical machines and apparatuses (alternatives) - Google Patents

Abstract

FIELD: electrical engineering; protection of electrical machines and installations.

SUBSTANCE: device has supply mains generator with metering circuit, actuating element connected to supply mains through rectifier, and final element connected to supply mains generator, load, and rectifier output. Rectifier supplies with power metering circuit and actuating element. Metering circuit output is connected to one of inputs of actuating element whose output is connected to control input of final element. Actuating element is made in the form of series-connected thyristor and final-element control winding.

EFFECT: simplified design, enlarged functional capabilities, improved metrological characteristics.

10 cl, 10 dwg

Description

The invention relates to electrical engineering and can be used in devices for protecting electrical apparatuses and installations in single-phase networks with terminals isolated from the housing (“earth”) and in three-phase (multiphase) networks with isolated neutral.

Known devices for monitoring and protection of electrical systems [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 actuator control element connected to an actuator, an indication device and a power source, providing power to electronic components of the protection and control system.

The main disadvantage of such a device is the lack of response to a symmetric decrease in insulation resistance in circuits with isolated neutral.

There is a known principle of constructing a system of protective tripping devices using operational direct current [2], the principle of which is that an artificial zero point according to the “star” scheme is formed using a choke indicator, in series with a common point of which a choke, a current relay and DC source, one of the terminals of which is connected to the chassis (“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 its considerable weight and dimensions due to the presence of a throttle transformer, as well as reduced sensitivity: at certain ratios, due to the lack of adjustments, the protection and control system may be inoperative.

Closest to the proposed device, which we adopted as a prototype, is a device [3] containing a network generator with a connected measuring circuit, a rectifier for the measuring circuit, a DC voltage source and an actuating element, a DC voltage source made in the form of a parametric stabilizer, the measuring circuit is made in the form of a series connection of a light emitter of an optocoupler shunted by an interference-suppressing capacitor, regulation and limiting resistors, one of Displayed limiting resistor connected to the housing, the switching device connected to the network phases, which is included in series with normally open contact actuating element, parallel to a resistor connected in series with the main field winding of the generator, and the other terminals of said resistor and a field winding connected to the excitation voltage.

The disadvantage of the device adopted for the prototype is the presence of optoelectronic elements having significant technological variations that are sensitive to ionization radiation; in addition, it uses a voltage relay, which is less accurate than the current relay and requires a voltage stabilizer, as a rule, to increase the accuracy of the threshold. In addition, the requirement of international and domestic standards of a certain amount of resistance between power and measuring circuits (in particular, at least 1 MΩ) does not provide the device that we adopted as a prototype, as well as a number of devices for similar purposes. In complex generators, in which there is not one but several excitation windings, turning off one of them does not lead to a complete disappearance of the voltage at the load.

The aim of the invention is to simplify the device, improve its metrological characteristics, expand the functionality. This goal is achieved by the fact that in the device containing the network generator with a measuring circuit, an actuator connected to the network through a rectifier, an actuator is inserted, connected in series with the load, the actuator is made in the form of a thyristor and an actuator control winding connected in series, and the control the thyristor electrode is connected through the relay contact of the measuring circuit to the midpoint of the resistive voltage divider connected to the power electrodes of the thyristor, with which the RC circuit is connected in parallel, the connection point of the RC circuit capacitor, one of the power electrodes of the thyristor and the resistive divider is connected to one of the outputs of the rectifier, the second output of which is connected to the free terminal of the control coil of the actuator, and the measuring circuit is made in the form of a relay coil measuring circuit shunted by a capacitor, one of the terminals of the mentioned winding is connected to one of the outputs of the rectifier, the second - through the limiting resistor - add to the other output nogo rectifier, said second output winding simultaneously connected to a circuit comprising a series connection of a second current limiting resistor, a diode and a varistor, a second terminal connected to said varistor body ( "ground").

In addition, a device for monitoring the insulation resistance and protection of electrical machines and apparatuses is proposed, comprising a network generator with a measuring circuit, an actuator connected through a rectifier, into which an actuator is inserted, connected in series with the load, and an additional rectifier connected to the network phases by an input, the actuating element is made in the form of series-connected thyristor and control winding by the executive body, and the thyristor control electrode is connected through to the relay contact of the measuring circuit to the midpoint of the resistive voltage divider connected to the power electrodes of the thyristor, to which the RC circuit is connected in parallel, the connection point of the capacitor of the RC circuit, one of the power electrodes of the thyristor and the resistive divider is connected to one of the terminals of the said rectifier, the second output which is connected to the free terminal of the control winding by the executive body, and the measuring circuit is made in the form of a relay winding of the measuring circuit shunted by a capacitor, one of the terminals omyanutoy winding connected to the output of an additional rectifier, the second terminal of winding simultaneously connected to a circuit comprising series-connected limiting resistor and a second varistor, a second terminal connected to said varistor body ( "ground").

A device for monitoring and protecting the insulation resistance of electrical machines and apparatuses is also provided, comprising a network generator with a measuring circuit, an actuator connected to the network through a rectifier, characterized in that an actuator is inserted in it, connected in series with the load, the actuator is made in the form of a series connected thyristor and control windings of the executive body, and the thyristor control electrode is connected through the relay contact of the measuring circuit to the midpoint a resistive voltage divider connected to the thyristor power electrodes to which an RC circuit is connected in parallel, the connection point of the RC circuit capacitor, one of the thyristor power electrodes and a resistive divider is connected to one of the terminals of the said rectifier, the second output of which is connected to the free terminal of the winding control of the executive body, and the measuring circuit is made in the form of a bridge circuit, one of the inputs of which is connected through two limiting resistors to two phases of the network, the other through varis Or - to the body ( "earth"), and the relay coil measurement circuit shunted by a capacitor connected to the output of said bridge circuit.

A device for monitoring the insulation resistance and protection of electrical machines and apparatuses, comprising a network generator with a measuring circuit, a rectifier connected in phases to the network, characterized in that the measuring circuit is made in the form of series-connected relay coils of the measuring circuit shunted by a capacitor, a limiting resistor and a varistor, moreover the second terminal of the mentioned winding is connected to the output of the rectifier, and the second terminal of the varistor is connected to the housing (“ground”), and is turned on to the two phases of the network between the generator and the load ep of series-connected relay contacts measuring circuit limiting resistor and indicator.

The device for monitoring and protecting the insulation resistance of electrical machines and apparatuses, containing a network generator with a measuring circuit connected to the network, is characterized in that the measuring circuit is made in the form of a bridge circuit, one of the inputs of which is connected through two limiting resistors to two phases of the network, and the other through a varistor - to the case ("ground"), the measuring circuit relay winding shunted by a capacitor is connected to the output of the bridge circuit, and a circuit from series-connected contacts le measuring circuit, limiting resistor and indicator.

The device according to the above options is characterized in that a switching device is introduced which comprises a resistor connected in series with the first excitation winding of the generator, in parallel with which an opening contact of the actuating element is connected, the other opening contact of said element being connected in series to the circuit of the second excitation winding of the generator.

Figure 1 - figure 10 shows a structural diagram of the proposed device and its variants, as well as nodes of the circuit diagrams of devices.

The device (Fig. 1) contains a network generator 1 (can be located both inside and outside the device), an actuator 2, connected to the generator 1 by an input, and an output 3 with a load, in addition, the output of the said executive body 2 connected to the input of the rectifier 4, supplying both the measuring circuit 5 and the actuator 6, and the output of the measuring circuit 5 is connected to one of the inputs of the actuator 6, the output of which is connected to the control input of the actuator 2.

Figure 2 presents the nodes of the structural diagram of figure 1.

The main winding of the generator of network 1 (in a three-phase version) contains three windings connected by a “star”, the executive body 2, for the purpose of unification, contains two two-contact switches 8 and 9 connected in three phases of the network, and in one phase 2 are connected in series contact (it is possible to use one three-pin or three one-pin switches), the rectifier 4 is, for example, a bridge rectification circuit (Grets circuit) on diodes 10-13, the output of the bridge circuit is connected to the input of the measuring circuit, with holding a current relay 14, shunted by a capacitor 15, one input of circuit 5 is connected to one of the outputs of the rectifier 4, the other through an adjustable limiting resistor 16 to the other output of the rectifier, a rectifier diode 17 is connected in series to the connection point of the elements 14, 15, 16, the second limiting a resistor 18 and a varistor 19, and the free (second) terminal of said varistor is connected to the housing (“ground”). The insulation resistance is conventionally shown by the node 20.

The actuating element 6 contains a thyristor 21 connected in series and control windings 8 'and 9' by the actuator 2, the thyristor 21 control electrode is connected to the midpoint of the resistive divider 24, 25 through the contact 14 'of the measuring circuit 14, the lower arm of which is shunted by the capacitor 26.

Figure 3 shows a structural diagram in which to power the measuring circuit 5 uses a separate rectifier 27 connected to the output of node 2.

Figure 4 shows the nodes of the structural diagram of figure 3, which uses a three-pin actuator 28 and its control winding 28 ’connected to the connection point of the elements 24 and 25 on one side and one of the outputs of the rectifier on the other.

Figure 5 presents a structural diagram in which the node 5 is made in the form of a node 29, i.e. the measuring circuit is made in the form of a bridge rectification circuit (Fig.6), one of whose inputs through two limiting resistors 30, 31 is connected to two phases of the network, the rectification bridge circuit contains diodes 32-35, the other input of the bridge circuit through a varistor is connected to the housing (“Ground”), and the coil of the measuring circuit relay 14, shunted by the capacitor 15, is connected to the output of the mentioned bridge circuit. This takes into account not only the active component of the insulation resistance 20, but also its capacitive component 20 ’.

Fig. 7 shows a block diagram in which a node 36 is used, connected to two phases of the network between the generator 1 and the load 4, containing (Fig. 8) a circuit from a series-connected contact of the relay 14 'of the measuring circuit 5, a limiting resistor 37 and an indicator 38 .

Figure 9 shows an embodiment using a node 36 and a node 29 connected to two phases of the network (for a three-phase version).

Figure 10 shows the first excitation winding 39 of the generator of the network 1, in series with which a resistor 40 is connected, in parallel with which the opening contact 41 of the actuating element is connected, the elements 40 and 41 being the switching device 42, the main winding of the generator 1 is presented in the form of windings 43 for a three-phase version and a half-wave three-phase rectifier (Larionov circuit) 44, the input of which is connected to the aforementioned three-phase winding 43, and the output to the second field winding 46, in series with which another opening contact 45 of said actuating element.

The device depicted in figure 1, operates as follows. In normal operation, i.e. in the presence of insulation resistance within the established standards, the actuator 2 is turned on and the load 3 is powered by a generator 1. Rectifier 4 supplies nodes 5 and 6.

In emergency conditions, with a symmetric or asymmetric change in insulation resistance below the established norms, the reaction is perceived by element 5, acts on element 6, which, acting on the actuator 2, disconnects the load 3 from the generator 1, i.e. mains voltage.

In the device of FIG. 2, in normal operation, the elements 8 and 9 of node 2 are closed and the load is powered by generator 1. In this mode, the current flowing through the winding of the current relay 14 is insufficient to turn on this relay, the thyristor 21 is in the off state, the contacts of the windings controls 8 'and 9' are open and the two-contact switches 8 and 9 are in the on state. The current flowing through the circuit from the elements 14, 17, 18, 19, due to the presence of the varistor 19 is extremely small, and the resistance of this circuit, as a rule, exceeds 1 MOhm established by domestic and international standards. Equivalent insulation resistance can be represented in the form of resistors 20 connected in a "star".

In emergency mode, i.e. when the insulation resistance decreases below the established norms, the current flowing through the measuring circuit from the elements 14, 17, 18, 19, turns on the relay 14, closes the contact 14 ', turns on the thyristor 21, receives windings 8' and 9 'and the elements 8 and 9 disconnect the load from the network.

The principle of operation of the device, the structural diagram of which is shown in FIG. 3, differs only in that an additional 27 is introduced, i.e. a separate rectifier 27 is used (for example, three-phase). In this case, unlike the device of FIG. 2, the alarm conditions are equivalent regardless of the phase in which the insulation resistance has decreased. In the device of FIG. 2 with a combined rectifier 4, the emergency current depends on the phase in which the insulation resistance decreased. This disadvantage can be eliminated by calculation, adjusting the level of response of the resistor 18.

Figure 4 presents a number of nodes in accordance with the structural diagram of figure 3. The executive body (for a three-phase system) is made on a three-pin switch 28 with a control winding 28 '. The principle of operation in normal and emergency modes is similar to that described previously.

In the device shown in FIG. 5, the assembly 29, the measuring circuit of which is shown in FIG. 6, differs from the previous ones in that it can be used in cases where not only the active component 20, but also the reactive component plays a significant role in the insulation resistance , in particular, the capacitive component 36.

In normal mode, the principle of operation of the device does not differ from that described previously. In emergency mode, currents pass through a measuring circuit containing elements 30, 31, 14, a bridge rectifier on diodes 32-35 and varistor 19, which is constant at the output of the bridge rectifier and alternating from two phases of alternating current through resistors 30 and 31 and varistor 19, which makes it possible to take into account the reactive component of the insulation resistance.

In those cases when operational load disconnection is not required and only an indication of faults is sufficient (block diagram - Fig. 7, nodes 36, 5, 29 - Figs. 8 and 9), in normal operation, element 14 'is open and indicator 38 is not lights up, in emergency mode, the element 14 'closes and the indicator 38 turns on (lights up), indicating a decrease in insulation resistance below the established norm.

The device depicted in figure 10, operates as follows.

In the normal operating mode, the elements 41 and 44 are closed and the field windings 39 and 46 perform their main functions, in emergency conditions they close, providing a decrease in the load voltage to almost zero.

The authors tested various options for the proposed device. In particular, for the device of FIG. 2, a varistor with a threshold of 80 V, with a series resistance of 33 kOhm, element 14, a current relay of a RES 64 A with a tripping current Icp = 1.2-1.3 mA and with a winding resistance, was used as element 19 10 kOhm. The operation of the node 5 occurred with an insulation resistance of 38 to 75 kOhm depending on the mains voltage of 200-250 V.

Thus, the proposed device (options) provides protection and control of the insulation resistance of electrical machines and devices in a wide range of loads.

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. Bull. No. 20.

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

3. RF patent No. 2189603, cl. G 01 R 27/00, H 02 H 3/10, 3/16, publ. 2002, Bull No. 26.

Claims (10)

1. A device for monitoring the insulation resistance and protection of electrical machines and apparatuses, comprising a network generator with a measuring circuit, an actuator connected to the network through a rectifier, characterized in that an actuator is inserted into it, connected to the generator by an input, output with a load, except Moreover, the output of the said executive body is connected to the input of the rectifier supplying both the measuring circuit and the actuating element, and the output of the measuring circuit is connected to one of the inputs of the executive electric an element whose output is connected to the control input of the executive body, while the executive element is made in the form of series-connected thyristor and the control coil of the executive body, and the control electrode of the thyristor is connected through the relay contact of the measuring circuit to the midpoint of the resistive voltage divider connected to the thyristor power electrodes, to which the RC circuit is connected in parallel, the connection point of the capacitor of the RC circuit, one of the power electrodes of the thyristor and a resistive divider it is connected to one of the outputs of the said rectifier, the second output of which is connected to the free terminal of the control winding by the executive body, and the measuring circuit is made in the form of a relay coil of the measuring circuit shunted by a capacitor, one of the terminals of the mentioned winding is connected to one of the outputs of the rectifier, the second through a limiting resistor - to another output of the rectifier, and the second output of the winding is simultaneously connected to a circuit containing a diode connected in series, a second limiting resistor and var side, the second terminal of said varistor is connected to the housing. 2. The device according to claim 1, characterized in that a switching device is introduced comprising a resistor connected in series with the first excitation winding of the generator, in parallel with which an opening contact of the actuating element is connected, the other opening contact of said element being connected in series with the second excitation winding generator. 3. A device for monitoring the insulation resistance and protection of electrical machines and apparatuses, comprising a network generator with a measuring circuit, an actuator connected through a rectifier, characterized in that an additional rectifier and an actuator are connected to it, an input connected to a network generator, an output with a load, in addition, the output of the said executive body is connected to the inputs of the rectifier supplying the actuating element and an additional rectifier supplying the measuring circuit, and the output is a meter the ohmic circuit is connected to one of the inputs of the actuator, the output of which is connected to the control input of the actuator, while the actuator is made in the form of series-connected thyristor and control coil of the actuator, and the thyristor control electrode is connected through the relay contact of the measuring circuit to the midpoint of the resistive divider voltage connected to the power electrodes of the thyristor, to which the RC circuit is connected in parallel, the connection point of the capacitor of the RC circuit, one of silt electrodes of the thyristor and resistive divider is connected to one of the terminals of the said rectifier, the second output of which is connected to the free terminal of the control winding by the actuator, and the measuring circuit is made in the form of a relay coil of the measuring circuit shunted by a capacitor, one of the terminals of the winding is connected to the output of the additional rectifier , the second terminal of the winding is connected to a circuit containing a series-connected limiting resistor and a varistor, the second terminal of said varistor connected to the housing. 4. The device according to claim 3, characterized in that a switching device is introduced comprising a resistor connected in series with the first excitation winding of the generator, in parallel with which an opening contact of the actuating element is connected, the other opening contact of said element being connected in series with the second excitation winding generator. 5. A device for monitoring the insulation resistance and protection of electrical machines and apparatuses, comprising a network generator with a measuring circuit, an actuator connected to the network through a rectifier, characterized in that an actuator is inserted into it, connected to the generator by an input, output with a load, except Moreover, the output of the said executive body is connected to the input of the rectifier supplying the actuating element, and the output of the measuring circuit is connected to one of the inputs of the actuating element, the output of which is connected is connected to the control input of the executive body, while the executive element is made in the form of series-connected thyristor and the control coil of the executive body, and the thyristor control electrode is connected through the relay contact of the measuring circuit to the midpoint of the resistive voltage divider connected to the thyristor power electrodes, which are connected in parallel RC circuit, the connection point of the capacitor of the RC circuit, one of the power electrodes of the thyristor and a resistive divider is connected to one of the terminals a rectified rectifier, the second output of which is connected to the free terminal of the control winding by the executive body, and the measuring circuit is made in the form of a bridge rectification circuit, one of the inputs of which is connected through two limiting resistors to two phases of the network, the other through a varistor to the housing, and the measuring relay coil a circuit shunted by a capacitor is connected to the output of said bridge circuit. 6. The device according to claim 5, characterized in that a switching device is introduced comprising a resistor connected in series with the first excitation winding of the generator, in parallel with which an opening contact of the actuating element is connected, the other opening contact of said element being connected in series to the circuit of the second excitation winding generator. 7. A device for monitoring the insulation resistance and protection of electrical machines and apparatuses, comprising a network generator with a measuring circuit, a rectifier connected in phases to the network, characterized in that the measuring circuit is made in the form of a series-connected relay coil of a measuring circuit shunted by a capacitor, a limiting resistor and a varistor, the second terminal of the winding being connected to the output of the rectifier, the second terminal of the varistor connected to the housing, and a circuit from The sequence relay contact connected in the measuring circuit, and indicator limiting resistor. 8. The device according to claim 7, characterized in that a switching device is introduced comprising a resistor connected in series with the first excitation winding of the generator, in parallel with which an opening contact of the actuating element is connected, the other opening contact of said element being connected in series with the second excitation winding generator. 9. A device for monitoring and protecting the insulation resistance of electrical machines and apparatuses, comprising a network generator with a measuring circuit connected to the network, characterized in that the measuring circuit is made in the form of a bridge circuit, one of the inputs of which is connected through two limiting resistors to two phases of the network, the other, through a varistor, to the housing, the measuring circuit relay winding shunted by a capacitor is connected to the output of the bridge circuit, and a circuit from series-connected relay contacts is connected to the mentioned phases of the network ritelnoy chain-limiting resistor and LED. 10. The device according to claim 9, characterized in that a switching device is introduced comprising a resistor connected in series with the first excitation winding of the generator, in parallel with which an opening contact of the actuating element is connected, the other opening contact of said element being connected in series with the second excitation winding generator.

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