SU817845A1 - Device for protective disconnection of electric equipment - Google Patents

Description

(54) DEVICE FOR SAFETY SHUT-OFF ELECTRICAL INSTALLATION

I

The invention relates to electrical engineering, in particular, to devices for the protective disconnection of electrical installations, preventing electrical personnel from damaging the electrical installation, powered by a low-voltage electrical AC network, in case of damage to the protective grounding circuit or electrical insulation.

A protective and disconnecting device is known, containing a zero-sequence current transformer, in which a two or three-phase winding is twisted into a harness and wound over a secondary wiring, an amplifier, a protection relay and a trip unit 1

When one or two phases are connected to earth, an emf is induced in the secondary coil of the transformer, amplifying with a two-stage amplifier. The protection relay operates and opens the power supply circuit of the coil of the magnetic starter, which disconnects the electrical installation from the power supply system.

However, this device does not provide high reliability for the protection of service personnel against electric shock, since it lacks control over the condition of the grounding conductor and the magnitude of its resistance, as well as the low sensitivity of the control circuit current on the housing.

A device for protection against: electric current rash in systems up to 380 V with an insulated neutral and a phase capacitance of up to 2.5 µF is known, containing a zero-sequence voltage filter, between which zero point and ground voltage relay is connected, three relays The wagons are connected between each of the phases and the ground, the opening contacts of which are connected between each of the phases and the ground through the closing contacts of the relay of the zero-sequence voltage filter (2J.

However, in this device there is no monitoring of the health of the grounding conductor and. the magnitude of its resistance. And this device does not provide sufficient accuracy and sensitivity to control current.

short circuits to the case, since the current flowing through the resistance of a person causes only a slight redistribution of the phase voltages and a small voltage of zero succession, which cannot (not trigger the device and protect the electrical installation) ... protective disconnection of a three-phase electrical installation, containing a contactor, a zero-sequence current transformer, to the secondary winding of which an actuator and a voltage transformer are connected. First the winding of which is turned on on its own) 1V voltage source, and the secondary winding is connected to the three phases via a three-phase single-wave rectifier and to the auxiliary winding of the zero-sequence current transformer via the disconnecting contact of the contactor 3. conductor and the value of its resistance, which allows the electrical installation to be switched on when the grounding conductor is broken and the insulation is faulty. / The closest in technical substance to the present invention is a device for protective disconnection of an electrical installation with a vanned highway connected to the protective highway of the distribution point, containing a contactor, the first closing contact of the first control button, a multi-winding voltage transformer, connected between the control winding circuit one of the phases and the main line, the first of which secondary windings is connected in series with the contact of the first control button, the first and the second relay blocks, the first and second rectifiers, the resistor, the second control button, the secondary voltage of the transformer, the first input of the first relay unit connected to the output of the first rectifier, the second input of which and the first input of the second burr unit in series with the resistor and the second NC contact of the first control button is connected to the output of the second rectifier, and the second input of the relay unit is connected between the output of the second rectifier and the closing contact of the second button the control unit is connected to an additional secondary winding of a voltage transformer, and the opening contact of the first relay unit and the closing contact of the second relay unit are connected in series to the control winding circuit of the contactor, whose block contact is connected in parallel with the first control contact of the first control button, the input of the first the rectifier is connected between the protective circuit of the power supply cable and the main line of the distribution point, and the input of the second rectifier is connected between the control circuit of the pit cable and additional secondary winding of the voltage transformer 4. This device provides a protective disconnection of the electrical installation with an increase in the resistance value of the protective circuit, as well as in the event of a fault in the circuits monitoring the short circuit current to the housing. However, this device does not provide sufficient reliability of the protection of the personnel against electric shock. So, the connection between the protective circuit of the supply cable and the protection highway of the distribution point. the input of the first rectifier and the first relay block connected to its output leads to the fact that when a phase short circuit occurs on the case, the rectifier can fail because the short circuit current reaches its maximum value in a time shorter than the total response time of the first relay block. and time off the contactor. Moreover, if there is a breakdown of a rectifier with a metal closure of its poles (anode and cathode), which often takes place in practice, then the current of the first input of the first relay block does not flow through the coil, as it is shunted by a malfunctioning rectifier, and the contact of the second relay unit remains closed in the coil circuit of the contactor and the protective device does not disconnect the electrical installation of the mains. In addition, when the electrical installation is operatively connected to the power supply network, the second control button is first pressed, which results in the contact of the second relay unit in the contactor coil circuit when the protective and control circuits are in good condition, and then the first control button. This closes the turn-on circuit of the contactor coil and opens the contact of the first button in the circuit between the resistor and the first input of the second relay unit, and the electrical installation is connected to the mains. And if during the period of simultaneous pressing of the first and second control buttons, a breakdown of the insulation occurs and a short circuit (which often occurs during the period when the electrical installation is turned on), accompanied by failure of the first rectifier or breakage of the protective circuit of the supply cable, then the electrical installation is under phase voltage to before releasing the second control button, the device does not control the resistance value of the protective circuit of the electrical installation or its installation, nor does it short-circuit protection to the housing. And the duration

the time of joint pressing of the first and second buttons is arbitrary, and the time of current flowing through a person when touched to live parts is strictly limited.

A significant disadvantage of this device is also the presence in the protective circuit of the supply cable of series-connected rectifiers and relay coils, which results in an increase in the resistance of the protective circuit. And if the accepted limits on the minimum conductance of the neutral wire are met (at least B0 ° / o phase), the resistance of the protective circuit is several times higher than the resistance of the phase wire, and therefore the contact voltage increases significantly and the risk of injury to the person increases.

In addition to the above, the use of this device for the protection of pre-mobile electrical installations and electrical installations on which control buttons are located (since, under the safety conditions, a self-assembly bo can not be located on an electrical installation) requires the power supply of such electrical installations to at least eleven cable cores (three power, one protective cable). and one control, four cores for connecting the first control button and two cores for connecting the second button.

The purpose of the invention is to increase reliability.

The goal is achieved by the fact that the protective circuit of the power cable is connected directly to the electrical installation case and the grounding line, the input of the first rectifier and the resistor are connected in series and connected between the grounding line and the control circuit of the power supply cable, which through the control button is connected to the electrical installation body, the input the second rectifier is connected in series with a part of the resistor between the control circuit of the supply cable and the secondary winding of the transformer, and to its output dklyucheny serially connected input of the second relay unit, connected zaschuntirovanny posledovatelnr and zener diode and a second input of the first relay unit and the first and second inputs of the second relay unit are aligned with each other;

The essence of the proposed device for protective disconnection of an electrical installation is explained by its principally eleutric scheme.

The proposed device contains a contactor 1, the power contacts 2 of which are connected to the mains 3 with the grounding line 4 and to the electrical installation 5. The electrical installation housing 5 of the living 6 (protective circuit) cable 7 is connected to the grounding

line 4, and through button 8, made, for example, with fixation, szhila 9 (control circuit) cable 7, lived 9 is connected to a resistor 10. The input of the second rectifier 11 is connected in series with a part of the resistor 10 between the control circuit of the power cable 7 and the secondary winding 12 transformers 13.

The primary winding 14, the transformer 13 is connected to one of the phases of the supply network 3 and to the grounding line 4. The second output of the secondary o6MOTKw f2 is also connected to the grounding line.4.

The input of the first rectifier, 15 one, is connected to the grounding line 4, and the other is connected to a resistor 10. The first input of the first relay unit 16, made as a two-winding relay, is connected to the output of the first rectifier 15, and mitel .11 connect-; There are serially connected inputs of the second relay unit 17, shunted by series-connected zener diode 18 and a diode 19, and a second input of the first relay unit 16.

The contactor I coil is connected by one terminal through the opening contact 20 of the first relay unit 16 and the closing contact 21 of the second relay unit 17 connected to one of the phases of the power supply network C and the other terminal to the grounding conductor 4.

The operation of the proposed device is carried out as follows.

Pressing the button 8, which can be performed with fixation along the chain; secondary winding 12 of transformer 13, second isolator I, coil of second relay block 17, second input of first relay block 16, second rectifier 11, part of resistor 10, core 9 (control circuit) cable 7, control button 8, electrical installation housing 5, core 6 (protective circuit) of cable 7, the grounding line 4, the secondary winding 12 of the transformer 13 is flowing current. After the second rectifier 11, the current also flows along the circuit; resistor 10 ,, first rectifier 15, first input of the first relay unit 16, rectifier, 15, secondary winding 12 of transformer 13.

The magnitude of the currents flowing through the protective circuit and the circuit of the first input of the relay block 16 is inversely proportional to the magnitude of the resistance of these circuits.

When the control and safety circuits are intact, the relay unit 17 closes its contact 21 in the circuit of the coil of contactor 1, which closes its power contacts 2 and the supply voltage 3 is applied to the electrical installation 5.

The resistor 10 is set to such a value that there is a clear disconnection of the relay unit 17 after it is turned on and the button 8 is opened.

When the total resistance of the protective and control circuits is lost or if one of them breaks, the current in the coil of the relay unit 17 decreases and opens its contact 21 in the coil circuit of the contactor 1, disconnecting the electrical installation 5 from the power supply to its network 3.

When a short circuit occurs on either the case, its potential becomes higher than the potential of the grounding line: and. rip of the protective circuit (conductor 6) and currents flow through the control circuit, the magnitudes of which O are inversely proportional to the resistance values of THESE circuits. At the same time, the current in the coil of the first input of the relay unit 16 increases, as the current from the secondary winding in this coil is summed up, 12, and so on, caused by the magnitude of the voltage on the electrical installation case 5 during a short circuit phase to it. The relay unit 16 is activated and opens its contact 20 in the circuit of the coil of contactor I, which disconnects the electrical installation 20T of the power supply network 3.

Moreover, if any of the phases to which the primary winding 14 of the transformer 13 is not connected to the Case occurs, the voltage on its primary winding 14 and the secondary winding 12 rises, and consequently, the current flowing at the output of the second rectifier 11 also increases. Since the coil of the relay block 17 is bounded by a zener diode 18 and a diode 19, the voltage drop and current in it remain constant in magnitude, and the current in the second and the first inputs of the relay block

16 grows and causes it to be triggered and the contact 20 of the contactor 1 and the electrical installation 5 of the network 3.

When a phase is connected to the case, to 35 of which the primary winding 14 of the transformer 13 is connected, the potential difference across this winding sharply decreases, and the voltage of the secondary winding 12 also decreases. Besides the relay 16, the relay 17 also turns off their contacts 20 and 21 in the coil circuit of the contactor 1 open. The contactor I disconnects the electrical installation 5 from the mains 3.

To increase the response sensitivity of the relay unit 16 and decrease the off time of the relay unit 17, the coil block 17 is shunted by a series-connected zener diode 18, limiting the voltage and 50 current in it, and a diode 19, excluding the possibility of increasing the current in the coil

17 when emf self-induction occurs in it in the period of current decrease in it.

Resistor 10 limits the amount of current flowing during a short circuit across the diodes of the first rectifier 15, which eliminates the possibility of them going out of order.

and also limits the amount of current in the first input of the relay unit 16 and eliminates the likelihood of switching on or being in the on state of the relay unit 17 when the control or protective circuit is opened.

The application of the proposed device allows to significantly / increase the reliability of protection of an electrical installation when a short circuit occurs or an increase in the resistance of the protective ground of the protective circuit is higher than the permissible value and thus increases the safety of the electrical installation, as the voltage of the contact when closed is reduced due to the reduced resistance of the protective device. chains by direct connection | Electrical installation with a grounding line with its additional connection through a control circuit also with a grounding line; the possibility of failure of the first rectifier diodes during a short circuit is excluded, since its input is connected between the electrical installation case and the grounding line through a resistor; The protection sensitivity is increased when closing and increasing the voltage on the transformer, since the voltage and current in the coil of the second relay unit, which checks the health of the protective circuit, remain constant, and the excess voltage is applied to the coils of the first relay unit, which deactivates the electrical installation from the mains; constant control of resistance, protection circuit and protection against short circuits is carried out regardless of the duration of pressing the control button;

In addition, the inclusion of a control button between the electrical installation case and the control (live) power circuit of the cable allows the control circuit of the cable to be used as a control circuit and thereby to power and control the electrical installation with five wires of the protective device against the eleven lived cable required for the operation of the same installation when using a protective device - a prototype.

The proposed device is used to control the electric drives of lifting and moving the self-loader of bakery containers of the model mounted in the body of the van of the car, and in the lift with the mechanisms of lifting and moving the specialized post. for the replacement of units of MAZ, KRAZ, and KAMAZ vehicles, as well as in the nut driver of the GK-63 model of car wheel nuts.

The use of this device allows the use of asynchronous electric drives as electric drives of these mechanisms.

Claims (1)

Claim A device for protective shutdown of an electrical installation containing the first and second relay blocks, a voltage transformer, the primary winding of which is connected to one of the phases and the grounding line, a control and protective circuit of the power cable, the first rectifier, _z 20 to the output of which is connected the first input ^{ζ of the} first relay block , a second rectifier, a body, a resistor, a control button and a contactor, the coil circuit of which includes a series-breaking contact of the first relay block in the closing contact of the second relay block ka, characterized in that; to increase reliability25 Ιθ _Nost,; the protective circuit of the power cable is connected directly to the housing of the installation. and the grounding line, the input of the first rectifier and the resistor are connected in series and connected between the grounding line and the control circuit of the power cable, which is through