RU2707584C1 - Device for overvoltage limitation with self-diagnostics function of protective element state - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: invention relates to the field of electric engineering, namely to the overvoltage limitation device with the self-diagnostics function of the protective element state, and can be used for improvement of the electric equipment operation reliability, in order to increase the fire safety. Overvoltage limitation device includes protective element located inside insulating housing with cover, which is a highly non-linear resistor, emergency shutdown actuation indicator, movable emergency shutdown contact connected by means of solder with a contact plate having an outlet into the cavity between the insulating housing and the cover, in contact with the second contact plate for connection to the circuit, installed on one side in the surface of the insulating housing and coming out from the other side outside from the insulating housing, and connected to the emergency shutdown actuation indicator such that when the protective element is damaged, the connection is opened between the movable emergency shutdown contact and the second contact plate for connecting to the circuit, wherein the connection between the movable emergency shutdown contact and the contact plate having an outlet into the cavity between the insulating housing and the cover is soldered and, by the springing properties of the emergency shutdown contact, is moved away while simultaneously moving the emergency shutdown actuation indicator flag, which enables to visually determine emergency shutdown of the protective element.

EFFECT: higher reliability of emergency shutdown of protective element with possible visual control of emergency shutdown is technical result of invention.

1 cl, 3 dwg

Description

The proposed technical solution relates to the field of electrical engineering and can be used to improve the reliability of electrical equipment used in electrical networks with an operating voltage of up to 1000 V AC and up to 1500 V DC.

The prior art (patent RU No. 2289864) known device for limiting overvoltage.

Such a device comprises first and second electrical leads located on opposite inner surfaces of the sides of the electrical insulating casing, each of which is made in the form of an electrical conductive contact plate and an electrical conductive connecting plate fixed to one of its ends on the surface of one of the sides of the electrical conductive contact plate and outgoing other ends thereof through the side surface of the insulating housing to the outside.

The ends of the conductive plates of the first and second electrical leads are arranged in parallel planes, symmetrically with respect to the central axis of the electrical insulating casing, bent opposite each other with their ends and perpendicular to the end surfaces of the nonlinear resistor and placed with their bent ends in the same plane, or each of which is made in the form of an electrically conductive contact a plate, an electrically conductive connecting plate fixed to one of its ends on the surface of one of the side walls it has an electrically conductive contact plate and an electrically conductive cylindrical pin fixed at one of its ends to the other end of the electrically conductive connecting plate and exiting with its other ends to the outside through the side surface of the insulating body.

The ends of the conductive connecting plates of the first and second electrical leads are arranged in parallel planes, symmetrically with respect to the central axis of the electrical insulating casing, bent opposite each other with their ends perpendicular to the end surfaces of the nonlinear resistor, placed with their bent ends inside the electrical insulating casing in the same plane and fixed with their respective bent ends on the corresponding ends of the conclusions of the conductive cylindrical pins located ennyh other with their ends facing outwards through the lateral surface of the electrically insulating body in a single plane and parallel to each other.

The technical result achieved by this technical solution consists in eliminating the contact resistances of the intermediate elements designed to connect the ends of the first and second electrical leads to a network supplying various types of electrical apparatus, in reducing the weight and weight parameters and in expanding the arsenal of technical means of protection.

Also from the prior art (patent RU No. 2096850), a technical solution is known containing:

- electrical insulating hollow cylindrical body with a bottom and with a cover mounted on the upper end of the electrical insulating hollow cylindrical body;

- the first electrical outlet, made in the form of a metal flange mounted with its corresponding surface on the bottom of the insulating hollow cylindrical body, and an electrically conductive rod protrusion (bolt), connected at one end to the bottom surface of the metal flange of the first electrical outlet and outgoing from the other with its other end hollow cylindrical body through a hole made in the bottom of the insulating hollow cylindrical body sa;

- at least one non-linear resistor mounted by one of its end surfaces on the upper surface of the metal flange of the first electrical terminal;

- a second electrical terminal, made in the form of a metal flange mounted between the inner lower surface of the lid and the upper end surface of at least one non-linear resistor and an electrically conductive rod protrusion (bolt) connected at one end to the upper surface of the metal flange of the second electrical terminal and exiting its other end outward from the insulating hollow cylindrical body through an opening made in the cover of the insulating hollow c hindric case;

- a sealant located inside the insulating hollow cylindrical body.

Common features of the claimed technical solution and the above analogues are:

- electrical insulating casing;

- a first electrical terminal mounted with its corresponding surface on the lower inner surface of the electrical insulating casing and exiting with its end outward from the electrical insulating casing;

- a non-linear resistor mounted by one of its end surfaces on the surface of the first electrical terminal;

- a second electrical terminal, mounted with its corresponding surface on the upper end surface of the nonlinear resistor and with its end facing out from the electrical insulating casing.

However, none of the analogs given allows us to determine the operability of the protective element of the surge protection device without conducting complex instrumental control, usually carried out with the dismantling of the device.

In case of degradation of the protective element, surge arresters can be a source of fire hazard. In this regard, during the operation of devices, it is necessary to periodically conduct instrumental checks of the state of surge protection devices in laboratory conditions.

The technical result, which cannot be achieved by any of the above analogues, is that the claimed surge protection device with a self-diagnosis function allows visual monitoring of the state of the protective element, with the possibility of disconnecting the protection device from the protected electrical network in case of permanent degradation of the characteristics of the protective element.

The reason for the impossibility of achieving a technical result with the above-mentioned devices known from the prior art is that none of the above analogues provides an indication of the operability of the protective element, as well as disconnecting the protected element from the electrical network when its technical characteristics are irreversibly degraded.

The analysis of the known technical solutions showed that none of them contains both the entire set of essential features and the distinguishing features of the proposed device for limiting overvoltages, which allowed us to conclude that it is new and inventive.

Attention is drawn to the fact that the leakage current causing the heating of the protective element can have a value of less than 1A, while the heating temperature of the protective element can reach a value significantly exceeding the value of 100 ° C. It is not possible to ensure the shutdown of such currents by existing standard devices (circuit breakers and fuses).

Given the characteristics and analysis of known similar technical solutions, we can conclude that the task of creating surge protection devices in a sealed enclosure, with the function of self-diagnosis of the state of the protective element, is relevant today.

The technical result achieved by the claimed technical solution is a visual control of the state of the protective element, with the possibility of disconnecting the protection device from the protected electrical network in case of irreversible degradation of the characteristics of the protective element.

The achievement of the technical result is ensured by the presence in the claimed technical solution of the indicator of emergency shutdown and emergency shutdown devices.

The presence of an emergency shutdown indicator allows you to visually determine the operability of the device and to avoid periodic costly instrumental checks of the operability of surge arresters.

Also, the presence of an emergency shutdown device allows you to avoid heating the protective element to a temperature that causes a risk of ignition of the equipment and installation elements at the installation site of the overvoltage limiting device.

In general terms, the claimed technical solution is a device for limiting overvoltages with the function of self-diagnosis of the state of the protective element, including an insulating casing (1) with a cover (9).

A protective element (2) is located inside the insulating casing, which is a highly non-linear resistor located inside the plastic sealed casing, connected on one side to a contact plate having an exit into the cavity between the insulating casing and the cover, and on the other hand to the first contact plate for connecting to the circuit mounted on one side in the surface of the insulating casing and exiting on the other side out of the insulating casing (3).

Also inside the case there is an emergency shutdown indicator (7), a movable emergency shutdown contact (6), connected by solder to a contact plate having an exit into the cavity between the insulating body and the cover (4), in contact with the second contact plate for connection to the circuit installed on one side in the surface of the insulating casing and exiting on the other side out of the insulating casing (5).

The mobile emergency shutdown contact is connected with the emergency shutdown indicator so that if the protective element is damaged, the connection between the movable emergency shutdown contact and the second contact plate for connection to the circuit is opened, the connection between the mobile emergency shutdown contact and the contact plate having an exit into the cavity between insulated body and cover, soldered, due to springing properties, the emergency shutdown contact moves away, while moving a flag of the indicator of the emergency shutdown, which allows you to visually determine the emergency shutdown of the protective element.

The claimed technical solution is illustrated in figure 1 (front view) and figure 2 (side view). The figure 3 illustrates a front view of the device with the contact of the emergency shutdown device in open form.

The positions indicated in figures 1-3:

1. The case is insulating;

2. Security element;

3. The first contact plate to connect to the circuit;

4. A contact plate having an exit into the cavity between the insulating body and the cover;

5. The second contact plate for connection to the circuit;

6. Mobile contact of the emergency shutdown device;

7. Indicator of emergency shutdown;

8. The soldering point of the movable contact;

9. The cover.

The surge protection device with the function of self-diagnosis of the state of the protective element consists of the following elements:

Insulating housing (1) is made of structural plastic. The protective element (2) is a highly linear resistor of a cylindrical shape (in the form of a disk), with conductive plates located on two opposite sides, placed in an insulating casing made of fire-resistant structural plastic.

To reduce the transient resistance between the surface of the protective element and the conductive contact plates, the protective element is filled with plastic together with the first contact plate for connection to the circuit (3) and the contact plate having an exit into the cavity between the insulating body and the cover (4), under high pressure .

This ensures a tight fit and tightness of the protective element, which is very sensitive to moisture.

The contact plate for connection to the protected circuit (3) adjacent to the housing of the protective element is a contact for connection to the protected circuit.

The contact plate (4) has a conclusion through the insulating casing into the cavity of the casing, which is closed by a lid (9) made of plastic.

Inside the cavity of the insulating casing there is a movable contact of the emergency shutdown device (6).

The movable contact of the emergency shutdown device (6) is connected to the second contact plate for connection to the circuit (5).

The connection between the contact of the emergency shutdown device (6) and the contact plate (4) is made so that when the protective element fails, the opening between the contact of the emergency shutdown device (6) and the second contact plate for connection to the circuit (5) occurs.

The principle of operation of the self-diagnosis system of the protective element is as follows.

If the protective element is damaged, an increased conductivity current flows through it, while the connection of the movable contact of the emergency shutdown device (6) and the contact plate (4) is heated and melted.

The movable contact of the emergency shutdown device (6) is disconnected from the output of the contact plate (4) and breaks the connection of the protective element with the second contact plate for connection to the circuit (5), which is connected to the protected circuit.

Thus, the conductivity current flowing through the protective element is interrupted. This reduces the fire hazard of the equipment. Contact (6) may be made of a spring material having good electrical conductivity. As one of the options, a spring can be applied, creating an additional force for opening the contacts (4) and (6). The contact group (6; 4) is hermetically closed by an insulating cover (9), which provides protection against moisture and mechanical damage. The characteristics of the contact group (6; 4) and the connection node of these contacts with solder (8) are also calculated for the flow of pulsed current with the amplitude-time characteristics for which the protective element is designed.

To visually determine the operability of the surge protection device, an emergency shutdown indicator (7) is used. The principle of operation of the indicator is as follows: a movable contact (6) connected at one end to the indicator flag (7), during an emergency shutdown, is moved away from the output of the contact plate (4) at the same time by its own spring properties (or alternatively by the action of an additional spring) moving the indicator flag, the indicator flag at the same time overlaps the transparent indicator window located in the upper part of the device housing, which allows you to visually determine the emergency shutdown of the protective element es of the rather complex instrumental control. Thus, the overvoltage limiting device with the function of self-diagnosis of the state allows not only to monitor the state of the protective element, but also provides a visual display of information in case of failure.

Claims (1)

A device for limiting overvoltages with the function of self-diagnosis of the state of the protective element, including a protective element located inside the insulating casing with a cover, which is a highly non-linear resistor located inside the plastic sealed casing, connected on one side to a contact plate with an exit to the cavity between the insulating casing and the cover, and on the other hand, with a first contact plate for connection to a circuit mounted on one side in the surface of the insulating body ca and exiting from the insulating casing on the other hand, an emergency shutdown operation indicator, a movable emergency shutdown contact connected by solder to a contact plate having an exit into the cavity between the insulating casing and the cover in contact with the second contact plate for connection to a circuit installed on the one hand in the surface of the insulating casing and outgoing from the other side out of the insulating casing, and associated with the emergency trip indicator Because if the protective element is damaged, the connection between the movable emergency shutdown contact and the second contact plate for connection to the circuit is opened, the connection between the movable emergency shutdown contact and the contact plate having an exit to the cavity between the insulating casing and the cover is soldered off, due to spring properties the emergency shutdown contact moves away while moving the flag of the emergency shutdown indicator, which allows you to visually identify the emergency shutdown protection element.

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