RU2557008C2 - Switching apparatus for electric circuit section mainly for explosion hazardous zones - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: switching apparatus for an electric circuit section mainly for explosion hazardous zones with a power supply source consists of two switching elements capable of movement towards each other and complete with contact plates at opposite ends of the elements in the direction of their movement and output conductors. In one conductor in series of the current passage there is a variable resistor, a current meter and one contact plate of the above contact. At that the second conductor is connected to the second contact plate of the contact and the variable resistor is complete with a regulator and indicator indicating limit values. The variable resistor may be made as a rheostat or a gate-controlled thyristor and before switching it is brought to the maximum value of resistance up to 10¹⁵ Ohm.

EFFECT: increased operational safety in explosion hazardous zones due to prevented spark producing in the switching process.

5 cl, 1 dwg

Description

The invention relates to electrical engineering, in particular to devices for switching sections of an electric circuit with a power source included in it, primarily intended for use in hazardous areas.

The breaking or shorting of a portion of an electric circuit with a direct or alternating current power source included in it is predominantly accompanied by the appearance of a spark or electric arc between the moving contact plates or converging towards each other, or diverging from the connection state.

The occurrence of an arc leads to a sharp increase in temperature, heating of the contact plates, melting and welding together, which prevents the contact from further performing its main functions: opening or closing the electrical circuit for preventive purposes or in an emergency. In this case, by contact plates we mean both the surface of the contacting monolithic parts of the contact and specially made elements from more durable or arc-resistant materials. For example: silvering of contact surfaces or making contact plates from conductive ceramics.

One of the ways to combat the arcing electric arc is the use of arcing chambers in circuit breakers that reduce the dangerous effects of arcing, as, for example, in patent for invention RU No. 2087973, H01H 1/20, 3/12, 13/14, 13/52, "Opening unit for switch".

Another method is the use of special gases in the arcing chambers, which have improved qualities compared to air, for example, the use of SF6 gas (sulfur hexafluoride), which has a higher electric strength, has a cooling and suppressing ability, as, for example, in RU Patent No. 2168787, H01H 31/00, "Gas-filled disconnector of a complete high voltage switchgear with gas insulation."

In the patent for the invention RU No. 2374716, H01H 1/58, “Connecting device with a cooler”, a method is proposed for reducing the negative effects of the arc by lowering the thermal energy released in the contact during switching.

In the patent for invention RU No. 2455720, H01H 1/22, “Contact node of a high-speed circuit breaker”, a device is proposed in which the main movable contact in the switching process is involved in rotational-translational movement, which provides a denser grinding in to the stationary contact, has silver contact soldering and removable arcing horn, this ensures a sequential opening of the main and arcing contacts with the protection of silver soldering from electric arc erosion.

In the patent for invention RU No. 2402091, H01H 1/48, “Contact system of a circuit breaker”, a L-shaped groove is provided in the movable contact element, so that in the case of welding of the movable and stationary contact elements under the influence of a pulling spring, the fracture of the movable element in the region -shaped groove and release contact.

In the patent for invention RU No. 2417474, H01H 1/48, “Contact node of a high-speed circuit breaker”, the contact node contains a first main contact element fixed on the first axis, drive mechanisms with contact pressing springs, and an intermediate element mounted on a link is located between the main elements linear operation associated with the actuator and the trip spring. All contact plates of elements are made of silver with solders made of refractory conductive material.

When a shutdown signal is applied at the time of a short circuit or operational shutdown, the intermediate contact element, mounted on the thrust of linear operation, moves vertically upward under the action of the drive and the efforts of the shutoff spring toward the disconnected position. In this case, a sequential transition from silver contact plates to refractory cermet material occurs. Thus, a tripping arc is formed on refractory brazings, and the working surface of the silver contact is protected from burning. The arc is extinguished in the interrupter circuit breaker.

The main disadvantage of all these inventions is that they are not aimed at preventing the arc itself, but at eliminating the consequences of its occurrence.

Known solutions to prevent the formation of an arc, consisting in the fact that one contact is divided into several contacts that are installed in several parallel branches.

So, in the invention according to patent RU No. 2154321, H01H 33/00, "Method for disconnecting an electric circuit" describes a method of disconnecting an electric circuit with a switching device, the current-carrying circuit of which consists of two parallel branches with different breaking capacity, each of which contains at least one arcing device.

In the invention according to patent RU No. 2308780, H01H 31/24, "Multi-ampere disconnector", a switching device is described in which the input current is distributed through several parallel current leads ending in contact elements, in which, in fact, the circuit is switched.

The disadvantages of the inventions in patents RU No. 2154321 and RU No. 2308780 include the fact that theoretically equal branches of current leads burn during operation and become electrically different, which leads to a redistribution of the currents flowing through them and the appearance of an arc.

Note the general property of the considered inventions: they are all designed for flowing along the current working circuits, which mainly have large values in power plants.

There is a field of technology in which not only arcing, but also sparking is unacceptable. These are productions in the atmosphere of which a gaseous explosive mixture is present for a long or short time, which, when a spark with a certain energy occurs, can explode and lead to destructive and even tragic consequences.

In order to prevent a possible explosion of an explosive mixture in the atmosphere of production, several types of explosion protection have been developed, such as "flameproof enclosures d", "pressurized enclosures p", "intrinsically safe electrical circuit i" and others. Moreover, for electrical circuits with switching devices, the most acceptable type of explosion protection is "intrinsically safe electrical circuit i".

By definition (GOST R IEC 60079-11-2010 "Explosive atmospheres. Part II. Intrinsically safe electrical circuit" i ") intrinsically safe" i "is a type of explosion protection based on the limitation of electrical energy in electrical equipment and connecting wiring that are exposed to potentially explosive media below a level that causes ignition from sparking or heating.

Thus, the possibility of sparking of individual elements of intrinsically safe circuits is fundamentally permissible provided that the released electric energy does not ignite the explosive mixture formed in the atmosphere of a specific industrial production. Such contacts are called normally sparking. However, it follows that circuits with such normally sparking contacts must undergo mandatory certification tests for intrinsic safety.

Intrinsic safety tests are carried out using a spark-generating mechanism. According to GOST R IEC 60079-11-2010 for circuits of the "ic" level, the connection of the spark-generating mechanism should be considered (among others) instead of normally sparking contacts, for example, connectors, button switches, potentiometers, (p. 45 of the cited standard). And this requires considerable laboriousness and is a drawback of constructing such explosion protection schemes.

Electric devices are also known that make it possible to use the intensity of lighting systems: a dimmer or dimmer (a stepped rheostat, in other words, a variable resistance), as well as a contact electronic light intensity regulator, which can function alone, with peripheral devices or with a push button (T. Gallozie, D. Fedullo. "Encyclopedia of electrician. A practical guide." M., "Omega", 2009).

In each of the listed devices there is a position switch (on / off) own or third-party (button). Moreover, it is characteristic for each of them that the position switch is installed first in the direction of a higher potential (phase of the power source).

The disadvantage of such devices is that on one of the contact plates of the switch there is a potential phase of the power source and a charge is formed.

When the second contact plate is moved (approaching when turned on or removed when turned on), another sign of charge forms on it. At a certain distance and speed of movement of the contact plate, a spark may form, fueled by current from the power source.

As a prototype, select a dimmer.

The essence of the invention lies in the creation of a device for switching a section of an electric circuit mainly for hazardous areas, preventing the formation of sparks during the switching process.

The technical result is achieved by the fact that a device is proposed for switching a section of an electric circuit mainly for hazardous areas, consisting of two switching elements capable of moving towards each other, equipped with contact plates at the opposite ends in the direction of their movement and lead conductors, while in one conductor in series in the direction of the physical flow of current, variable resistance is included, a current measuring device and one contact plate, a second wire arrestor is connected to the second contact plate, and is provided with a variable resistance controller, and an indicator indicating the boundary values. Moreover, before the implementation of switching, the variable resistance has a maximum value.

The calculation of the electrical circuit is subject to inclusion in it in series with the contact of variable resistance in a state with a minimum value. Thus, the presence of resistance in the circuit will not affect the performance of its main function.

Before opening the circuit, the variable resistance is gradually transferred to the state with the maximum value. In this case, the current reaches such a value (for example, 10 μA) that the opening of the contacts does not lead to the formation of a spark due to the small amount of energy released when such a circuit breaks. A sharp increase in the current value during the separation of the contact plates cannot occur, since in the conductor, in the direction of the physical flow of current, there is a very large resistance and the appearance of a spark between the contact plates is impossible. After the circuit is opened, the variable resistance remains in the same state, therefore, before the circuit is closed, it also has the maximum resistance value, which means that when we close it we get the same minimum current (10 μA) adjusted for the transient effect. As with opening the circuit, a sharp increase in current is impossible due to the presence of high resistance in the conductor in the direction of the physical flow of current. And, therefore, when the circuit is closed, sparking also does not occur. So, the achievement of the technical result will be observed. The power source can be either a voltage source or a current source. This solution is mainly used for DC circuits.

In switching devices requiring the participation of a person (for example, a button), the measuring device allows you to visually evaluate the result of bringing the regulator to one of the limit values, and an indicator (for example, a light bulb) allows reaching the limit value. The controller may be integrated in the design of the button. For example, before pressing the button, you need to turn the upper cylindrical part of the button clockwise (otherwise it will not press), and the variable resistance will be converted to the required boundary value.

In switching devices that do not require human involvement, the controller plays the role of an automatic circuit, but the presence of a measuring device and boundary value indicators allows maintenance personnel to monitor the process.

It is known that in DC circuits with relatively small operating voltages and currents, arcing can be achieved by including spark-extinguishing chains (circuits) parallel to the breaking contacts, usually consisting of capacitance, inductance, and active resistance connected in series. (N.K. Myshkin, V.V. Konchits, M. Braunovich. “Electrical Contacts.” Dolgoprudny, Intellect Publishing House, 2008). Such a spark suppression circuit requires additional contacts to break the chains themselves and leads to switching difficulties: when the contacts break, the chain must turn on before breaking the contacts and disconnect after that, and when connecting, turn on before connecting the contacts, and then disconnect.

Since the openable and closable electrical circuits can be energized in tens of kilovolts, it is advisable that the variable resistance reaches 10 ¹⁵ Ohms to prevent sparking.

If it is necessary that there is no reactance in the circuit being closed and / or the circuit being opened, it is advisable to carry out the resistance in the form of a rheostat.

To simplify the construction of automatic circuits for closing and / or opening circuits, it is advisable to perform variable resistance in the form of a lockable thyristor.

To ensure the symmetry of the alternating current circuits, it is advisable to carry out the alternating resistance in the form of two structurally independent elements included in the conductors from different sides of the contact.

The invention is illustrated by an example in the form of an electrical circuit shown in the drawing. The circuit switched by the proposed device with the power source included in it is depicted as a two-terminal device.

The two-terminal 1 shown in the drawing has two terminals (potential φ ₁ and potential φ ₂ with the direction of current flow from φ ₁ to φ ₂ ) to which a serial circuit of variable resistance 2, measuring device 3 and contact 4 is connected in the required order (contact closed , Work mode).

The manufacturing technology of a device for switching a portion of an electrical circuit primarily for hazardous areas according to this invention is as follows.

As a rule, resistance variables are installed on the same board with switching devices (buttons, relays). For this, standard printed circuit methods are used. Rheostats, lockable thyristors, buttons, relays, indicator lights, potentiometers, ammeters are selected from commercially available products.

After installation, the printed circuit board is installed in a commercially available box, if necessary, filled with a compound. Subsequently, the box is installed on the equipment mounting plate.

To confirm the technical result, a direct current circuit diagram was assembled, shown in the drawing, in which the variable resistance 2 is made in the form of a rheostat with a maximum resistance of 10 ¹⁰ Ohms, with an on / off button with pin 4. In series with the variable resistance 2, an ammeter 3 is included in the branch . At the output of a two-terminal 1 between points φ ₁ and φ _2, the potential difference is 100 V. The current flowing in the branch with the contact closed is approximately 10 A. The minimum resistance of the rheostat is approximately 10 Ω .

The experiment was carried out as follows. The current value was monitored in the current state with the contact closed. After making sure that it is approximately 10 A, the rheostat was brought to the maximum position for one minute and the maximum current value was fixed.

Then, by pressing the button, the contact was opened. After one minute, by pressing the button, the contact was closed and the maximum current value was again fixed. When the contact was closed and opened, the possibility of spark formation was visually observed. This cycle was repeated fifty times.

During the test, sparking was not observed a single time. The maximum current value when opening and closing the contact ranged from 5 × 10 ^-7 A to 3 × 10 ^-8 A. The spread of current values in the current state was within ± 1.7% of the nominal value.

Test results confirm the achievement of the technical result.

Claims (5)

1. Device for switching a section of an electric circuit mainly for hazardous areas, consisting of two switching elements capable of moving towards each other, equipped with contact plates at the opposite ends of the elements in the direction of movement and output conductors, characterized in that in one conductor in series in the direction of the physical current flow includes variable resistance, a current measuring device and one contact plate, the second conductor is connected to the second contact hydrochloric plate and provided with a variable resistance controller, and an indicator indicating the boundary values, wherein prior to performing the switching variable resistance has a maximum value. 2. The device according to p. 1, characterized in that the maximum value of the variable resistance reaches 10 ¹⁵ Ohms. 3. The device according to p. 1, characterized in that the variable resistance is made in the form of a rheostat. 4. The device according to p. 1, characterized in that the variable resistance is made in the form of a lockable thyristor. 5. The device according to claim 1, characterized in that the variable resistance is made in the form of two structurally independent elements included in the conductors from different sides of the contact.