UA58075C2 - Device for automatically switching on standby power supply - Google Patents

Abstract

The proposed device for automatically switching on standby power supply contains two electromechanical switches for connecting the load to the main or backup power-supply source. Each switch contains fixed and movable power contacts, an electromagnetic actuator, a control unit, and a self-contained power-supply unit. The electromagnetic actuator contains a magnetic core with an air gap, a winding, and an armature that is coupled with the movable contacts. In the air gap of the magnetic core, an insert made of magnetically hard material is installed that is designed for adjusting the magnetic flux in the magnetic core. The control unit contains elements for monitoring the power supply parameters and generating control signals for the actuator. The actuator is controlled by short-time current pulses in the winding. The unit for the electromechanical interlock of the switches contains a lever that is coupled with the armature of each switch so as to exclude a possibility of concurrently switching on both the switches.

Description

Description of the invention

The invention relates to the field of electrical engineering, specifically to emergency or backup 2 power supply schemes and can be used in power supply systems of responsible consumers of electricity with a voltage of up to 10008, for example for powering computer systems, special electric motors and converters, including for powering gas turbines for separation of isotopes of heavy metals, etc. consumers with strict requirements for the quality of power supply and especially strict requirements for the duration of interruptions in the power supply, that is, in the end - for the speed of the device for automatic inclusion of the reserve (hereinafter 70 in the text - АВР).

In electrical engineering, many responsible electrical receivers do not allow even relatively minor interruptions in the power supply. So, for example: - computer networks and systems do not allow interruptions in the supply of electricity of a certain quality for a period exceeding 100ms, without possible consequences of such an interruption, related to the loss of information; 19 - lighting system with halogen lamps - for a period exceeding 20ms without disruption of lighting as a result of such a break; - gas turbines, which are used for the separation of isotopes of heavy metals or as high-vacuum pumps, also do not allow interruptions in energy supply due to a possible loss of dynamic stability with subsequent destruction; -it. others

The use of modern technologies largely depends on the availability of reliable power supply.

The consequence of this is the use of consumer back-up power systems with the use of AVR devices, in which switching devices with electrical and/or electromechanical blocking are used to prevent emergency counter-switching of various sources of electricity. with

A well-known AVR device on contactors with electromechanical blocking in the form of cams rigidly connected to the moving parts of the magnetic circuit breakers - see, for example, A.A. Fedorova and G.V.

Serbinovsky. Directory of electrical supply for industrial enterprises. M., "Energy", 1973, vol. 1, p. 429)

PI.

The design of the known device is relatively simple, and its cost is relatively small due to the relatively small cost of switching devices and their configuration. -

However, during the operation of such a device, the speed of automatic activation of the reserve (taking into account only the switching time) is a significant value, calculated in tens of seconds, which is determined by the design features of the known device and is its comparatively insufficient indicator. Therefore, the known device can be used only for energy supply of low-responsible energy consumers. 3o In addition, such a device is relatively ineffective in operation due to its lack of reliability due to the inherent features of the design of the known device, due to the possible jamming of the cams, since the windings of its control coils are constantly under voltage during the entire time of operation of the device. "

A known device in which the electromechanical switch is made in the form of at least one pair of C 70 electromagnetic contactors with power contacts for connecting electricity consumers and with at least one magnetizing control coil on a composite magnetic circuit, the moving part of which is rigidly connected to the moving power contacts and is made with the possibility of reciprocating movement, while the component magnetic wire of the switch is at least partially made of a hard-magnet material, with at least one air gap in the magnetic circuit of the magnetic wire and with the possibility of successive minimization of the air gap, closing the magnetic flux in the magnetic wire during magnetization by applying the i-th pulse current into the control winding of the coil and keeping the switch in the on state without consumption

Ge | of electricity through the winding of the control coil to supply the control coil with a current pulse of reverse polarity and remagnetization (demagnetization) of the magnet wire -- see, for example, M.S. Babich Patent of Ukraine No. 27664 dated 15.09.02. Bulletin "Industrial Property", Mo. 4, 2000.) (21. -and 20 In the known device, the above-mentioned shortcomings are partially eliminated - it ensures minimal consumption of electricity, namely consumption only at the moments of supplying control electric impulses to the winding of the control coil of the electromagnetic starter ( contactor), as a result of which its efficiency is comparatively higher. In addition, its cost, which is also mainly determined by the cost of switching devices and their adjustment, is relatively small. 25 However, due to design features, the known device cannot provide automatic switching

GF) reserve - connecting consumers to the reserve power supply system. In addition, the known device is also unable to provide sufficiently high performance and, moreover, it is also relatively inefficient due to the rigid connection of the electromechanical blocking elements, as a result of which it cannot be used to power responsible consumers of electricity. 60 The indicated shortcomings are partially eliminated in the well-known AVR device of the ABSO company (USA) with electromechanical blocking in the form of rocking overturning contacts on a rotary-wheel mechanism, which according to the achievable results and the set of technical features is the closest to the declared technical solution | see, for example, V.P. .Sour. Reliable connection of a backup power source. /In the magazine "Zlectropanorama",

K., 2001, Mo 1, pp. 18 - 20-- prototype) IZ). Because the known technical solution, which was selected as a prototype, contains a housing in which at least one electromechanical switch with power contacts is placed for connecting electricity consumers to one of the power inlets, with at least one magnetizing control coil on a magnetic circuit, the moving part of which is a rigidly connected drive connected with movable power contacts and made with the possibility of reciprocating movement, while the magnetic circuit of the switch is made with a stationary stator, a movable armature and at least one air gap in the magnetic circuit of the magnetic circuit, and each of the switches is equipped with a control circuit, each of which is electrically connected connected to its power input and provided with at least one device for monitoring the quality of the power supply and an energy source for switching the switches. 70 This implementation of the known device ensures its relatively higher efficiency both due to the absence of significant energy consumption, since the current in the winding of the control coil flows only when control pulses are supplied, and due to increased reliability, including due to the presence of a structural electromechanical blocking against reverse switching switching power sources.

However, the above-mentioned shortcomings in the known device are incompletely eliminated: - its cost is quite high due to structural features and the high cost of the used electromechanical switching devices and the complexity of their adjustment and is approximately 4 times higher than the cost of AVR devices on electromagnetic contactors; - its speed, taking into account only the time for switching (of the order of 1 bOhms), is comparatively insufficient; - the costs associated with its operation are relatively large; - and its reliability is relatively insufficient, since in the case of simultaneous absence of high-quality voltage on both power inputs, electrical consumers connected to the backup power input may be forced to work in partial phase mode. In this case, if, for example, after de-energizing the main input and connecting consumers to the backup power input, one of the phases of the supply voltage "drops out" on the latter, which is supplied to the control element (the control coil - in ABSO, the electric motor - in general automatic switches with an electric drive, etc.), then in this case there will be no high-quality energy source for switching the switches and the control circuit will be de-energized with the consequences that follow from this. and)

The basis of this invention is the technical task of improving the design of the known AVR device by eliminating the specified shortcomings, namely by - increase in speed up to 15 - 20ms, as well as increase in efficiency due to: - increase in reliability due to the exclusion of the possibility of consumers working in incomplete phase mode, - - decrease in operating costs due to reduction in energy consumption, o - and also decrease in the cost of the AVR device due to the use of such switching elements of the device as electromagnetic contactors. co

The technical problem set in the invention is solved by the fact that in the known device of emergency switching on of the reserve (AVR) with electromechanical blocking, containing a housing in which at least one electromechanical switch with power contacts for connecting electricity consumers to one of the power inputs is placed, with at least one magnetization control coil on a magnetic wire, the moving part of which - the drive is rigidly connected to the moving power contacts and is made with the possibility of reciprocating movement, while the magnetic wire of the switch is made with a fixed stator, with a movable armature and with at least one air gap in the magnetic magnetic circuit circuit, and each of the switches is equipped with a control circuit, each of which is electrically connected to its power input and ;" equipped with at least one device for controlling the quality of the power supply and an energy source for switching the switches, according to the invention, the device is made with a housing in which at least one pair of electromechanical switches is placed, each of which is equipped with at least one magnetizing control coil on a magnetic circuit made of composite material and equipped with an insert made of magnetically solid material with the possibility of controlling the magnetic flux in the magnetic conductor due to the minimization of the air gap c, closing of the magnetic flux in the magnetic conductor and remagnetization of the magnetic conductor material o with the help of short-term multipolar current pulses in the winding of the magnetizing control coil and with the possibility of holding the magnetic conductor of the switch and connected with its moving part of the power contacts

Ш- in the switched-on state without applying the supply voltage to the winding of the magnetizing control coil of the switch until s demagnetization of the magnetic circuit by supplying a short-term control current pulse to the winding of the indicated control coil. At the same time, the electromechanical blocking of each pair of switches, the movable power contacts of which are electrically connected to the corresponding power inputs, is made in the form of a lever, the fixed point of support of which is hinged to the body of the device, and the free ends of the lever are made with the possibility of kinematic interaction with the movable part of the magnetic circuit of each switch with the provision of mechanical blocking and (Ф, the impossibility of simultaneously turning on both switches, and the control scheme of each of the switches is provided with an additional energy source for switching the switches.

The problem set in the invention is also solved by the fact that in the claimed device the ends of the electromechanical locking lever enter into kinematic interaction without engagement with the base of the moving part of the magnetic circuit of the corresponding switch with the possibility of mechanical movement of the moving part of the magnetic circuit of this switch in the event of a violation of its electrical blocking, following its disconnection with the disconnection of its moving power contacts from the power input and the subsequent inclusion of another switch with the connection of its power contacts to the backup power input. 65 The problem is also solved by the fact that in the claimed device there is an additional source of energy for switching the switch when the high-quality supply voltage of the winding of the control coil of the magnetization of the switch disappears,

made in the form of a source selected from a series consisting of a block of electrical capacitors (BEC), an uninterruptible power supply (UPS), a direct current battery (DCB), a source of mechanical energy (DME), potential and/or kinetic, their combination.

In addition, the problem is solved by the fact that in the claimed device an additional source of energy for switching the switch when the quality voltage that feeds the winding of the control coil of the magnetization of the switch is made in the form of a block of electric capacitors, in which the capacitor, with a charge voltage of one, positive, polarity , connected to the winding of the control coil of the switch through the normally open contacts of the switch with the possibility of magnetizing the magnetic system of the switch when the capacitor discharges to 7/0 of the winding of the control coil, the subsequent operation of the switch, closing the moving power contacts of the switch and keeping them in the on state without consumption by the coil winding of electricity from power input until the voltage on this power input disappears. And a capacitor with a charge voltage of a different, negative, polarity, when the qualitative voltage on the supply input disappears, is connected to the winding of the control coil of the switch through the normally closed contacts of the switch with the possibility of subsequent demagnetization of the magnetic /5 system of the switch when the capacitor is discharged on the winding of the control coil, the next release of the switch , opening the moving power contacts of the same switch and keeping them in the open state until a high-quality voltage is applied to the power input.

The switch can be made in the form of a control relay.

Finally, the problem set in the invention is also solved by the fact that the claimed device is made with the possibility of fast operation, which is a value that does not exceed 20ms.

This implementation of the declared technical solution ensures. - improvement of speed up to 15 - 20ms; - increasing the efficiency of the stated device due to: - increasing its reliability as a result of eliminating the possibility of consumers working in partial phase mode, sch - reducing the costs of its operation due to reducing energy consumption to a minimum, and | o - as well as reducing its cost due to the use in its design of such switching elements of the device as electromagnetic contactors.

This is ensured due to the simultaneous use of: a) non-rigid (hinged) kinematic connection of the moving elements of the structure of electromechanical and locking switches; b) in combination with the property of the magnetic system of the electromagnet of each switch to work as a powerful permanent magnet after supplying a short-term current pulse to the control winding of the magnetizing coil and after that keep the moving power contacts in the closed state for an unlimited time without consuming electricity to keep them. At the same time, the return of the electromagnetic system to the original so

This state is possible only after applying an electric current pulse of reverse polarity to the control winding of the magnetization coil, which resets the magnetic flux in the magnetic circuit; c) an additional energy source in the control scheme of each of the switches.

The fact that the device is made with a case in which at least one pair of electromechanical switches is placed, each of which is equipped with at least one magnetization control coil on a "magnetic wire, made of composite material and equipped with an insert made of magnetically hard material with the possibility of 7-3 s control of the magnetic flux in the magnetic wire according to due to the minimization of the air gap, subsequent closing of the magnetic flux in the magnetic conductor and remagnetization of the magnetic conductor material with the help of short-term of opposite-polarity electric current pulses in the winding of the magnetizing control coil and with the possibility of holding the switch magnet wire and the power contacts connected to its moving part in the switched-on state without applying supply voltage to the magnetization control coil winding of the switch until demagnetization from the magnet wire by supplying a short-term control electric current pulse to the winding of the specified control coils, provides the magnetic system of each switch with the property of the device to work as a powerful permanent magnet after applying a short-term pulse of electric current to the control winding of the magnetizing coil and to keep the moving power contacts in the closed state for an unlimited time without consuming electricity to maintain them. At the same time, the return of the electromagnetic system to the initial state is possible only after the supply of an electric current pulse of reverse polarity to the control winding of the magnetization coil, which resets the magnetic flux in the magnetic circuit.

The fact that the electromechanical blocking of each pair of switches, the movable power contacts of which are electrically connected to the corresponding power inputs, is made in the form of a lever, the fixed point of support of which is hingedly connected to the body of the device, and the free ends of the lever are made with the possibility of kinematic influence on the moving part of the magnetic circuit of the corresponding switch without engaging with it and with the provision of mechanical (Ф) blocking and the impossibility of simultaneously turning on both switches, provides a non-rigid kinematic connection of the structural elements of the electromechanical blocking of the switches.

The fact that the control scheme of each of the switches is equipped with an additional energy source for switching the switches ensures an increase in the efficiency of the claimed device due to an increase in its reliability, since it excludes the possibility of operation of consumers in incomplete phase mode when the voltage of one of the phases disappears or deteriorates.

The fact that the ends of the electromechanical blocking lever enter into kinematic interaction without engagement with the base of the moving part of the magnetic circuit of the corresponding switch with the possibility of mechanical movement 65 of the moving part of the magnetic circuit of this switch in case of violation of its electrical blocking, then its disconnection with the disconnection of its moving power contacts from the power input and the next switching on of another switch with the connection of its power contacts to the backup power input, provides an increase in the efficiency of the device also due to a further increase in its reliability.

That the additional energy source for switching the switch when the quality voltage that feeds the winding of the magnetizing control coil of the switch is made in the form of a source that is selected from a series consisting of a block of electric capacitors (BEC), an uninterruptible power supply (UPS), a battery direct current (DC), mechanical energy source (DME), potential and/or kinetic, their combination also provides an increase in the efficiency of the device by increasing its reliability and expands the possibilities of a constructive solution to the problem. 70 The fact that the additional source of energy for switching the switch when the quality voltage that feeds the winding of the control coil of the magnetization of the switch, is made in the form of a block of electric capacitors, in which the capacitor with the charge voltage of positive polarity is connected to the winding of the control coil of the switch through the normally open contacts of the switch with the possibility of magnetizing the magnetic system of the switch during the discharge of the capacitor on the winding of the magnetizing control coil, the subsequent activation of the /5 switch, the closing of its moving power contacts and keeping them in the on state without consuming electricity by the coil winding from the power input until the quality voltage on this power input disappears, and the capacitor with a charge voltage of a different, negative, polarity, when the quality voltage at the power input disappears, it is connected to the winding of the control coil of the switch through the normally closed contacts of the switch with the possibility of subsequent demagnetization of the magnetic system hiccup when the capacitor discharges 2o on the winding of the control coil, its subsequent release, opening of the moving power contacts of the switch and keeping them in the open state until a high-quality voltage is applied to this power input, while a control relay can be used as a switch, also ensures an increase in the efficiency of the declared device by further increasing its reliability.

The fact that the device is made with the possibility of high-speed operation, which is a value that does not exceed 20 Ohms, provides a solution to the technical problem set in the invention and provides a new property of the device about the emergency inclusion of the reserve - improved speed of operation compared to the prototype.

Thus, in all known AVR devices with electromechanical locking of switches, including the prototype, there is a rigid interaction of the moving parts of the switches with the structural elements of the lock, as a result of which one of the switches must first disconnect, that is, de-energize, and move

From to the initial (initial) position, and only then should another switch be turned on. In connection with the need to ensure this condition, none of the known technical solutions can in principle provide a satisfactory - high-speed operation due to the presence of the specified structural defect, namely due to the rigid interaction of the movable parts of the switches with the structural elements of the lock. As a result, only sequential disconnection of the first and inclusion of the second switch can be ensured. In addition, with a strong interaction can so

35 Jamming or jamming of moving structural elements. All this reduces the reliability of the known AVR devices and worsens their speed.

In contrast to the above, in the claimed AVR device with an electromechanical lock, there is no such rigid interaction of the moving parts of the switches with the structural elements of the lock, and there is a sliding (non-rigid) interaction of the free ends of the locking lever with the specified moving parts of the switches. "

This ensures: in c - improvement of speed due to the reduction of the time for the switches to operate - instead of their sequential operation, their parallel (simultaneous) operation takes place. At the same time, in force;" features of the claimed design, the free end of the locking lever, in addition to performing the main function, namely the locking function, does not interfere, but, on the contrary, helps the accelerated disconnection of the de-energized switch, since its action is coordinated with the action of the springs that disconnect the de-energized switch; c - if, for any reason, the de-energized switch still does not turn off, that is, it does not return to its original position, then the switch that is turned on, through the locking lever, will first help c to turn off this de-energized switch, that is, it will mechanically help to return it to its original position, and only then will it turn itself on. Thus, due to the design features of the declared AVR device, the possibility of simultaneous voltage supply to energy consumers from two different power inputs is excluded, and thus

Sh- the efficiency of the declared AVR device is increased by increasing its reliability; sp - In addition, the reliability of the declared AVR device is also ensured by the fact that, due to the pulsed power supply of the windings of the magnetizing control coils on the magnetic wires of the switches, the time of mechanical impact on the mechanical locking lever practically does not exceed the time of action of the pulse of the mechanical shock absorber, the pulse of electric current in the winding of the control coil and/or pulse discharge time of the capacitor on the winding of the magnetizing control coil. (F, In the following, examples of specific implementation of the claimed invention are briefly explained with the figures of the drawings, which, although they illustrate individual specific variants of the implementation of the invention and at the same time explain its content, but in no way can it be considered that only they are limited to its essence and the general scope is exhausted inventive idea.

Figures in the drawings schematically show:

Fig. 1 is a schematic representation of the claimed AVR device, side view, partial cut-out;

Fig. 2 - the control scheme of the declared AVR device;

Figures 3 and 4 are additional power sources of the control circuit, made (each) in the form of a block of electric 65 capacitors.

The declared device for emergency switching on of the reserve (AVR) with electromechanical blocking in the variants of execution, which are shown in Fig. 1 - 4, contains a pair of electromagnetic switches 1 and 2 in the form of electromagnetic contactors of the KM20 series, located in the general housing 3. Each of the switches is equipped with one control coil, namely, switch 1 - coil 4, placed on the magnetic conductor 5, and switch 2 - respectively, coil 6, placed on the magnetic conductor 7.

Magnetic conductors 5 and 1 are made of components, equipped with inserts 8 and, respectively, 9 of magneto-hard material Alnico-18 and made with the possibility of controlling the magnetic flux in the magnetic conductors of the contactors due to the minimization of air gaps between the stator 5 and the movable armature 10 of the magnetic conductor of the switch 1 and, accordingly, by the stator 7 and the movable armature 11 of the magnetic circuit of the switch 2, closing the magnetic flux in the 7/0 Corresponding magnetic circuit and remagnetizing the material of the corresponding component magnetic circuit with the help of short-term multipolar pulses of electric current in the winding of the control coil 4 of the switch 1 or, accordingly, in the winding of the control coil 6 of the switch 2.

The stator 5 of the switch 1 is mechanically rigidly connected to the fixed power contacts 12, 13 and 14 of the switch 1, which are electrically connected to phases A, B and C of the power input B 4, and its anchor, made in the form of a crossbar 10, mechanically rigidly connected to the movable power contacts, respectively, 16, 17 and 18 of the switch 1, which are electrically connected, respectively, to the inputs 1-3 of the energy consumers 15.

In turn, the stator 7 of the switch 2 is mechanically rigidly connected to the fixed power contacts 19, 20 and 21 of the switch 2, which are electrically connected, respectively, to phases A, B and C of the power input B", and its anchor, also made in in the form of a traverse 11, mechanically rigidly connected to the movable power contacts 22, 23 and 24 of the switch 2, which are electrically connected to the inputs 1 - Z of the energy consumers 15.

At the same time, the magnetic conductors of the switches 1, 2 are made with the possibility of their retention, as well as retention of the power contacts 12, 13, 14 and, respectively, the power contacts 19, 20, 21 connected to them by the movable anchors 10 and 11 in the on or, respectively, in the switched-off state, without applying supply voltage to the winding of the control coil 4, magnetizing the switch 1 or, respectively, the control coil 6, magnetizing the switch 2, until the demagnetization of the magnetic wire 5 of the switch 1 or, respectively, the magnetic wire 7 of the switch 2, by supplying a short-term control pulse of electric current to the winding of the control coil switch and)

Electromechanical blocking of a pair of switches 1 and 2, movable power contacts 16, 17, 18 and, respectively, 22, 23, 24, which are electrically connected to the corresponding power inputs В 3 and Во, made in the form of a rocker arm 25, support point 26 which is hingedly connected to the housing 27 of the locking mechanism, rigidly connected to both switch 1 and switch 2 through the housing of the claimed device.

The free ends of the rocker arm 25 are made with the possibility of kinematic interaction without engagement with the crossbar - switch 1 and the crossbar 11 of switch 2, but with the provision of mechanical blocking and the impossibility of simultaneously turning on both switches, that is, with the provision of the impossibility, in the end, of counter-turning on the power inputs B. and B". co

Each of the switches is equipped with its own control circuit (Fig. 2, C and 4). At the same time, each control scheme is provided with an additional power source for switching the switch, namely source 28 for switching (turning on and/or turning off) switch 1 and, accordingly, power source 29 for switching (turning on and/or turning off) switch 2.

The ends of the lever-rocker 25 of the electromechanical blocking are introduced into kinematic interaction without rigid engagement with the base of the traverse 10 of the switch 1 and the base of the traverse 11 of the switch 2 with the possibility of mechanical movement of the specified moving parts of the magnetic lines in cases of violation of the electrical blocking of the corresponding switch, i.e. in case of circuit failures control, followed by its (corresponding from the switch) disconnection and, therefore, disconnection of its moving power contacts from the power input, and then switching on another switch.

Each of the additional energy sources (fig. 3 and 4) is made in the form of a block of accumulating electric capacitors: for the energy source 28 - in the form of a block of capacitors 3 and 31, and for the energy source 29 - in the form of, respectively, a block of capacitors 32 and 33 At the same time, one terminal of the capacitor 30 is connected to the cathode of the charging diode 37 through the normally closed (further on in the text - n. 3z3.) contacts 34 - 35 of the control relay 36, the anode of which is through the charging resistor 38, terminal 39, 5p Normally open ( further on in the text - n.v.) contacts 40 - 41 of relay 42 of quality control of three-phase voltage - power input B; and terminals 43 - 44 of the switch 45 is connected to phase C of the power input Vi, and the second output sp of the capacitor 30 is connected to the common zero bus, which is electrically connected to the terminal 46 of the additional power source 28. The ZO capacitor is connected to phase C of the power input Vi with the possibility of applying a voltage of positive polarity to it. To smooth out negative ripples, the ZO capacitor is shunted by a diode 47, the anode of which is connected to the common zero bus, and the cathode - to the first terminal of the capacitor 30.

Capacitor 30 through n. in. contacts 34 - 49 of the control relay 36 and terminal 50 are electrically connected to the winding

Ф) 4 of the control coil of switch 1, the second output of which is connected to the common zero bus, with the possibility of applying pulse voltage of positive polarity to the coil.

One output of the capacitor 31 through n. in. contacts 51 - 52 of the control relay 36 is connected to the anode of the charging diode 53, the cathode of which through the charging resistor 38, terminal 39, n.v. contacts 40 - 41 of the relay 42 for quality control of the three-phase voltage of the power input B. and terminals 43 - 44 of the switch 45 are connected to phase C of the power input B;, and the second output of the capacitor 31 is connected to the common zero bus, which is electrically connected to the terminal 46. Capacitor 31 is connected to phase C of the power input B. with the possibility of applying a voltage of negative polarity to it. 65 Capacitor 31 through n. with. contacts 52 - 54 and terminal 50 is electrically connected to the winding 4 of the control coil of the switch 1 with the possibility of applying a pulse voltage of negative polarity to it.

One output of the control relay 36 is connected to the common zero bus, and the second - to the terminal 55 of the additional power source 28 of the switch 1.

Terminals 39 and 55 of the additional power source 28 of switch 1 are input, and its terminals 46 and 50 are output

Terminals

One terminal of the capacitor 32 through n.z. contacts 56 - 57 of the control relay 58 is connected to the cathode of the charging diode 59, the anode of which through the charging resistor 60, the terminal 61 of the additional power source 29 of the switch 2, n.v. contacts 62 - 63 of the relay 64 for quality control of the three-phase voltage of the power input B" and terminals 65 - 66 of the switch 67 are connected to phase C of the power input Vo, and the second output of the capacitor 32 is connected to the common 70 zero bus, which is electrically connected to the terminal 68. Capacitor 32 is connected to phase C of the power input

Vo with the possibility of applying a voltage of positive polarity to the capacitor. To smooth out negative ripples, the capacitor 32 is shunted by a diode 69, the anode of which is connected to the common zero bus, and the cathode - to the first terminal of the capacitor 32.

Capacitor 32 through n.v. contacts 56 - 70 of the control relay 58 and terminal 71 of the additional power source 29 /5 of the switch 2 are electrically connected to the winding 6 of the control coil of the switch 2 with the possibility of supplying it with a pulse voltage of positive polarity.

One terminal of the capacitor 33 through the n.v. contacts 72 - 73 of the control relay 58 is connected to the anode of the charging diode 74, the cathode of which through the charging resistor 60, terminal 61, n.v. contacts 62 - 63 of the relay 64 for monitoring the quality of the three-phase voltage of the power supply input Vo and terminals 65 - 66 of the switch 67 are connected to phase C of the power input 2o input B", and the second output of the capacitor 32 is connected to the common zero bus, which is electrically connected to the terminal 68. The capacitor 33 is connected to phase C of the power input Vo with the possibility of applying a voltage of negative polarity to the capacitor.

Capacitor 33 through n.z. contacts 72 - 75 and terminal 71 is electrically connected to the winding 6 of the control coil of the switch 2 with the possibility of applying a pulse voltage of negative polarity to it. high school

One output of the control relay 58 is connected to the common zero bus, and the second - to the terminal 76 of the additional power source 29 of the switch 2. i)

Terminals 61 and 76 of the additional power source 29 of switch 2 are input terminals, and its terminals 71 and 68 are output terminals.

The relay 42 for monitoring the quality of the three-phase voltage of the power input V. is connected with its three inputs 1 - Z through terminals mm zo of the Switch 45 to phases A, B and C of the power input V/, and output 4 - to the common zero bus.

The winding of the time relay 77 is connected by one end 1 to phase C of the power input B. through terminals 43 - 44 - switch 45, n.v. contacts 40 - 41 of the relay 42 of the quality control of the three-phase voltage of the supply input Vi and n.z. su contacts 78 - 79 relay 80 time or through n.v. block contacts 81 - 82 of switch 1, and its other end - to the common zero bus. co

The winding of the time relay 83 is connected with one end 1 to phase C of the power input Vo through terminals 65 - 66 and the switch 67, n.v. contacts 62 - 63 of the relay 64 of the quality control of the three-phase voltage of the power input Vo and n.z. contacts 84 - 85 of relay 86 of time or through n.o. block contacts 87 - 88 of switch 2, and its other end - to the common zero bus.

The winding of the intermediate relay 89 is connected with one end 1 to phase C of the power input Vi through terminals "343 - 44 of the switch 45, n.v. contacts 40 - 41 of the relay 42 of the quality control of the three-phase voltage of the power input Vu, She) with n.v. contacts 90 - 91 relay 77 time and N.Z. contacts 92 - 93 of the symmetrical control relay 94 of the switch 2, and its other end 2 - to the common zero bus. In the variant of the priority of the power input V. contacts 92 - 93;" of the control relay 94 are shunted by a-B shunt (in Fig. 2, the shunt is shown by a dashed line).

The winding of the intermediate relay 94 is connected with one end 1 to phase C of the power input Vo through terminals - 66 of the switch 67, n.v. contacts 62 - 63 of the relay 64 of the quality control of the three-phase voltage of the power input V 2, with n.v. contacts 95 - 96 relay 83 time and N.Z. contacts 97 - 98 of the symmetrical intermediate relay 89 of switch 1, and its other end 2 - to the common zero bus. In the version of the priority of the power input Vo, contacts 97 - 98 of the intermediate relay 89 are shunted by a shunt c-4 (the shunt is shown by a dashed line in Fig. 2). At the same time, it should be noted that, in general, the shunt can be used only once in the circuit: only for commutation a-5 or 5or only for commutation c-th.

Ш- The winding of the time relay 80 is connected by one end 1 to phase C of the power input B. through terminals 43 - 44 of the switch 45, n.v. contacts 40 - 41 of relay 42 of quality control of the three-phase voltage of the power input V 4, n.v. contacts 90 - 91 relay 77 time and N.Z. contacts 99 - 100 of relay 64 of the quality control of the three-phase voltage of the power input Vo or n.v. contacts 101 - 102 of the intermediate relay 89, and its other end 2 - to the common zero of the bus. In parallel with the winding of the time relay 80, the winding of the control relay 36 is connected through the terminal 55 of the additional power source 28.

Ф) The winding of the time relay 86 is connected with one end 1 to phase C of the power input Vo through terminals 65 - 66 of the switch 67, n.v. contacts 62 - 63 of the relay 64 of the quality control of the three-phase voltage of the power input V 5, n.v. contacts 95 - 96 relay 83 time and N.Z. contacts 103 - 104 of the relay 42 of the quality control of the three-phase voltage of the supply 6o input Vi or n.v. contacts 105 - 106 of the intermediate relay 94, and its other end 2 - to the common zero bus. In parallel with the winding of the time relay 86, the winding of the control relay 58 is connected through the terminal 76 of the additional power source 29.

To return the traverses 10, 11 of the switch 1 and/or, respectively, 2 to the original position and opening the corresponding power contacts associated with them, mechanical energy sources with springs 107 (Fig. 1) are provided. 65 The claimed device for emergency switching on of the power reserve (AVR) with electromechanical blocking (fig. 1 - 4) works in the following way.

After turning on the switches 45 and 67, the claimed device and the control circuit of the claimed device are ready for operation.

When high-quality voltage is applied to the power inputs V. and Vo, relays 42 and, accordingly, 64 control the quality of electricity received from the power inputs, i.e. control not only the voltage and current values for each phase of each power input, but also other necessary parameters selected from the series, which consists of the reactive component of the current, the average values of voltage and current, Со8 f, K-factor (quality factor), active and reactive power, the amount of consumed electricity in kWh, phase shift of 95, the number of switches on a real scale time, switching protocol, their combinations, The indicated relays 42 and 64 control 7/0 power quality through their N.V. contacts 40 - 41 and, respectively, 62 - 63 supply the voltage of phase C of the corresponding power input to power the control circuit of the corresponding switch. In this case, voltage will be applied to the windings of the time relay 77 and, accordingly, 83.

With his n.v. contacts 40 - 41 relay 42 includes the charge circuit of the storage capacitor 30 with the rectified voltage of phase C of the power input B through the terminal 39 of the 1st input of the additional source 28 7/5 power supply, charging resistor 38, rectifier diode 37 and n.z. contacts 34 - 35 of the control relay Zb, as a result of which the capacitor 30 is charged with a voltage of positive polarity.

With its normally open contacts 62 - 63, the relay 64 includes the charge circuit of the storage capacitor 32 with the rectified voltage of the phase C of the power input Vo through the terminal 61 of the 1st input of the additional power source 29, the charging resistor 60, the rectifier diode 59, etc. contacts 56 - 57 of the control relay 58, as a result of which the capacitor 32 is charged with a voltage of positive polarity.

At the same time, the voltage of phase C of the power input Vi. supplied to the winding of the relay 77 time After n.z. contacts 78 - 79 relay 80 time.

After triggering the 77-time relay through its n.v. contacts 90 - 91 and n.z. contacts 92 - 93 of relay 94 supply power to the winding of relay 89, which with its N.Z. contacts 97 - 98 breaks the power circuit of the winding with relay 94, and with its N.V. contacts 101 - 302 through terminal 55 supplies the voltage of phase C of the power input B. to the 2nd input of the additional power source 28 and turns on the winding of the control relay 36. As a result of this n.3z. contacts 34 - about 35152 - 54 of relay 36 are opened, and n.v. contacts 35 - 49 and 51 - 52 of this relay are closed. As a result of this, the storage capacitor ZO is disconnected from phase C of the power input B and is connected to winding 4 of the magnetizing control coil of switch 1 with the supply of a positive discharge current pulse (C winding. At the same time, the storage capacitor 31 is disconnected from winding 4 of the magnetization control coil of switch 1 and connected to the supply voltage source of phase C of supply input B 4. -

As a result of supplying a positive impulse current to the winding of the control coil 4, it creates a pulse of the magnetic DC flux in the magnetic circuit of the switch 1, ensures the minimization of the air gap of the magnetic circuit, the closing of the magnetic circuit, the activation of the switch 1 and its maintenance in the activated state without powering the winding 4 so

Control coil magnetization switch. As a result, switch 1 with its N.V. blocks-contacts u 81 - 82 blocks the power circuit of the winding of the time relay 77, and with its power contacts 12 - 16, 13 - 17 and 14 - 18 it connects energy consumers 15 to the three-phase power input Vch.

The 80-time relay has a switch-on delay, the value of which exceeds the activation time of switch 1. Therefore, in normal operation, its activation and disconnection of the N.C. of contacts 78 - 79 does not affect the state of the relay 77 " of the time, which will be powered by a circuit through the n.v. contact blocks 81 - 82 of switch 1 and, in this way, the claimed device works in stable mode. If, for any reason, switch 1 does not operate even after applying a control influence to it, then in this case its N.V. blocks-contacts 81 - 82 do not close and "" after the activation of the time relay 80 and its disconnection of the N.C. contacts 78 - 79, the winding of the time relay 77 is de-energized, its N.V. contacts 90 - 91 are opened and the windings of the control relay 36, the intermediate relay 89 and the time relay 80 are de-energized. Relay 80 with its n.v. contacts 78 - 79 prepares the circuit for supplying the supply voltage and from re-switching on the switch 1 to the supply input 1 in the case when there is no high-quality voltage at the supply input 2, as a result of which the n.v. contacts 62 - 63 of relay 64. because if at this moment there is high-quality voltage and n.v. contacts 62 - 63 of relay 64 will be closed, then through N.Z. contacts 97 - 98 of relay 89 power is supplied to the winding of the intermediate relay 94, and through it the n.v. contacts 105 - 106 and terminal 76 of input 2 of the additional source 29 of the power switch 2 - on the winding

She of the control relay 58. As a result, the relay 58 is triggered and opens its N.C. contacts 56 - 57 and 72 - 75, and n.v. 4 contacts 57 - 70 and 72 - 73 close. As a result, the storage capacitor 32 is disconnected from phase C of the power input B" and is connected to the winding 6 of the magnetizing control coil of the switch 2 with the supply of a positive discharge current pulse to the winding, and the storage capacitor 33 is disconnected from the winding 6 of the magnetization control coil of the switch 2 and is connected to the source supply voltage of phase C of the supply input B" for charging with a voltage of negative polarity. iF) As a result of the supply of a positive impulse current to the winding 6 of the control coil, a pulse of the magnetic flux Ф occurs in the magnetic circuit of the switch 2, the minimization of the air gap of the magnetic circuit, the closing of the magnetic circuit, the operation of the switch 2 and its maintenance in the activated state without power supply because the windings of the magnetization control coil are ensured switch 2. As a result, this switch with its n.v. blocks-contacts 87 - 88 blocks the power circuit of the winding of the time relay 83, and with its power contacts 19 - 22, 20 - 23 and 21 - 24 it connects energy consumers 15 to the three-phase power input B".

In the case of the priority of one of the power inputs, the control scheme of the declared device due to the installation of the appropriate shunt on terminals a-5 or c-4 provides for the possibility of connecting energy consumers 15 to the b5 backup power input in cases of lack of high-quality voltage on the main (priority) input with subsequent return in the future to the main (priority) input after applying quality voltage to it.

In the event of voltage failure or other deterioration of the quality of electricity on at least one of the phases of the power input, V. releases the relay 42 of the control of the quality of electricity on this water and its N.V. contacts 40 - 41 disconnects the power circuit of the control circuit of the switch 1. At the same time, the relay 42 with its N.Z. contacts 103 - 104 closes the power supply circuit of the winding of the control relay 58, when it is activated, a positive (on) pulse of current is supplied to the winding b of the magnetizing coil of contactor 2. At the same time, the winding of the control relay 36 is de-energized, as a result of which a negative (switching) pulse of current is supplied to the winding 4 magnetizing coils of contactor 1. In this case, under the action of its springs 107 and rocker arm 25 of mechanical blocking, whose directions of action coincide, contactor 1 is disconnected and with its 7/0 ball contacts 12 - 16, 13 - 17 and 14 - 18 disconnects energy consumers 15 from the power input B., after which the contactor 2 is turned on, which with its power contacts 19 - 22, 20 - 23 and 21 - 24 connects energy consumers 15 to the power input B" for a time that does not exceed 15 - 20ms. Thus, in comparison with known technical solutions, the action of the rocker arm 25 of mechanical blocking not only excludes the possibility of simultaneous supply of the voltage of the power inputs B. and Vo to the energy consumers 15, but also, in addition, 7/5 improves the speed of the AVR device.

In the event of a voltage failure or other deterioration of the quality of electricity on at least one of the phases of the power input B. with subsequent switching of energy consumers 15 to the backup power input B", if for any reason it turns out that the voltage at the backup input has deteriorated and does not meet the required quality, in this case, the claimed device provides for disconnection of energy consumers 15 also from the power input

Vo, as a result of which the supply of low-quality (for example, incomplete phase) voltage to energy consumers 15 is stopped, which increases the reliability of the claimed device in comparison with the prototype.

In a similar way, the claimed device works when the voltage disappears or other deterioration of the quality of electricity on at least one of the phases of the power input Vo. In this case, relay 64 releases the power quality control and its N.V. contacts 62 - 63 disconnects the power supply circuit of the control circuit of the switch 2, and closes it with its n.3z. contacts 99 - 100 closes the supply circuit of the winding of the control relay 58, when it is activated, a positive (on) pulse of current is supplied to the winding b of the magnetizing coil of the contactor 2. i)

At the same time, the winding of the control relay 36 is de-energized, as a result of which a negative (disconnecting) pulse of current is supplied to the winding 6 of the magnetizing coil of the contactor 2. At the same time, under the action of its springs 107 and the rocker arm 25 of mechanical blocking, the direction of action of which is agreed, the contactor 2 closes turns off and with its power contacts 19 - 22, 20 - 23 and 21 - 24 disconnects energy consumers 15 from the power input B", after which contactor 1 turns on, which with its power contacts 12 - 16, 13 - 17 and - 14 - 18 connects energy consumers 15 to the feeding input B. for a time that does not exceed 15 - 20 ms. Thus, in comparison with known technical solutions, the action of the rocker arm 25 of mechanical blocking and in this case not only excludes the possibility of simultaneous supply of the voltage of the power inputs B. and Vo to the energy consumers 15, but also improves the speed of the AVR device. yu

In the event of a voltage failure or other deterioration in the quality of electricity on at least one of the phases of the power input Vo with the subsequent switching of energy consumers 15 to the backup power input B. and with this, for any reason, it turns out that the quality of the voltage on the backup input has deteriorated and does not meet the required quality, then in this case, the energy consumers 15 will also be disconnected from the power input B, and the supply of low-quality (for example, incomplete phase) voltage to the energy consumers 15 is stopped, which increases the reliability of the claimed device in comparison with the prototype.

The claimed device additionally provides the possibility of monitoring the state of contactors 1 and 2 after ;" applying a positive control pulse to each of them and allows the contactor to be turned on again if it did not turn on for any reason.

So, for example, in the case of de-energization of the input V., the voltage control relay 42 is turned off and its N.C. with contacts 103 - 104 supplies power to the winding of the control relay 58, which with its n.v. contacts 57 - 70 connects the charged capacitor 32 to the winding 6 of the magnetizing coil of the contactor 2, as a result of which the contactor 2 should turn on and close its N.V. contact blocks 87 - 88, provided that the contactor is in the on state. This ensures that the supply voltage is supplied to the relay 83 after 5 years after the NCs open. contacts 84 - 85 of the time relay 86. In this case, if it turns out that from any

For this reason, contactor 2 did not turn on and its N.V. contacts 87 - 88 are not closed, then after switching on the relay 86, its N.C. contacts 84 - 85 open and de-energize the time relay 83, which with its N.V. contacts 95 - 96 de-energizes the time relay 86 and the control relay 58, as a result of which the re-charging process of the capacitor 32, the re-activation of the contactor 2 and the re-connection of the energy consumers 15 to the power supply begins

INPUT Vo as described above. This increases the efficiency of the claimed device by increasing its reliability.

Ф) In a similar way to the described one, the claimed device works in connection with the re-activation of energy consumers 15 to the power supply input B when the input B is de-energized.

The technical result provided by the invention, in comparison with the prototype, consists of: i - improvement of speed up to 15 - 20ms - and increase in efficiency of the claimed device due to: - increase in its reliability as a result of excluding the possibility of operation of energy consumers in partial phase mode; - reduction of operating costs due to reduction of energy consumption to a minimum - as well as reduction of its cost due to the use in its design of such switching elements 65 of the device as electromagnetic starters and/or contactors.

Sources of information taken into account:

1. A.A.

Fedorova and G.V.

Serbinovsky.

Directory of electrical supply for industrial enterprises.

M., "Energy", 1973, vol. 1, p. 429. 2. M.S.

Babich

Patent of Ukraine No. 27664 dated 15.09.02. Bulletin "Industrial Property", Mo. 4, 2000. 3. V.P. Kyslii.

Reliable connection of a backup power source. /"In the magazine "Zlectropanorama", K., 2001, Mo. 1, pp. 18 - 20-- a prototype.

Claims (6)

The formula of the invention is also 1. Device for automatically switching on the backup power with electromechanical blocking, containing a housing in which at least one electromechanical switch with power contacts is placed for connecting electricity consumers to one of the power inputs with at least one magnetizing control coil on the magnetic circuit, the moving part of which is the drive, rigidly connected connected with movable power /5 contacts and made with the possibility of reciprocating movement, while the magnetic circuit of the switch is made with a stationary stator, a movable armature and at least one air gap in the magnetic circuit of the magnetic circuit, and each of the switches is equipped with a control circuit, each of which electrically connected to its power input and provided with at least one device for monitoring the quality of the power supply and an energy source for switching the switches, which is characterized by the fact that it is made with a housing in which at least one pair of electromechanical switches is located, each of which is equipped with at least one magnetizing control coil on the magnetic conductor, made of composite material and equipped with an insert made of a hard magnetic material with the ability to control the magnetic flux in the magnetic conductor by sequentially minimizing the air gap, closing the magnetic flux in the magnetic conductor, and remagnetizing the magnetic conductor material using short-term multipolar DC current pulses in winding of the magnetizing control coil and with the possibility of holding the magnetic circuit of the switch and the power contacts connected to its moving part in the on state until demagnetization (o) of the magnetic circuit without applying supply voltage to the winding of the magnetizing control coil of the switch by supplying short-term control current pulses to the winding of the specified control coil , electromechanical blocking of each pair of switches, the movable power contacts of which are electrically connected to the corresponding power inputs, made in the form of a lever, the fulcrum of which is a hinge is connected to the body of the device, and the free ends of the lever are made with the possibility of kinematic interaction with the moving part of the magnetic circuit of each switch, ensuring mechanical blocking and the impossibility of simultaneously turning on both switches, and the control circuit of each of the switches is equipped with an additional energy source for switching the switches. (2.0) 2. The device according to claim 1, which differs in that the ends of the electromechanical locking lever engage in kinematic interaction without engagement with the base of the moving part of the magnetic circuit of the corresponding switch with the possibility of mechanical movement of the moving part of the magnetic circuit of this switch in the event of a violation of its electrical blocking, its subsequent disconnection from by disconnecting its moving power contacts from the power input and then turning on another switch with the connection of its power contacts to "70" of the backup power input. w-v with Z. The device according to claim 1, which is characterized by the fact that the additional source of energy for switching the switch when the high-quality supply voltage of the winding of the control coil of the magnetization of the switch disappears is made in the form of a source selected from a series consisting of a block of electric capacitors, an uninterruptible power supply, a battery direct current, sources of mechanical energy, potential and/or kinetic, their combination. 4. The device according to claim 3, which differs in that the additional energy source for switching the switch when the high-quality voltage that feeds the winding of the magnetizing control coil of the switch is made in the form of a block of electric capacitors, in which the capacitor with a charge voltage of one, positive, polarity connected to the winding of the control coil of the switch through the normally open contacts of the switch with the possibility of magnetization of the magnetic system of the switch during the discharge of the capacitor on the winding of the control coil 5r, the subsequent activation of the switch, closing of its moving power contacts and keeping them in the on state until the voltage on the power input disappears, and a capacitor with a charge voltage of a different, negative, polarity, when the quality voltage at the supply input disappears, is connected to the winding of the control coil of the switch through the normally closed contacts of the switch with the possibility of subsequent demagnetization of the magnetic system of the switch when the capacitor is discharged to rev winding of the control coil, the subsequent release of the switch, the opening of its moving power contacts and holding them in the open state without the consumption of electricity by the coil winding until voltage is applied to this power input. (F) 5. The device according to claim 4, which differs in that the switch is made in the form of a control relay. GI 6. The device according to claim 4, which is characterized by the fact that it is made with the possibility of quick operation, which is a value that does not exceed 20 ms. 60 b5