CZ9900898A3 - Device for overvoltage protection of electric network terminal equipment - Google Patents

Abstract

The present invention relates to a device for overvoltage protection of electric network terminal equipment, which device comprises a variable-resistance resistor (2) the first and second terminals (21, 22) of which are interconnected with connecting lines (51, 52) serving for connection to a phase contact (L) or neutral contact (N) of a terminal equipment, whereby one of the terminals (21, 22) is connected to a stationary contact (31) of heat-disconnecting electric disconnect switch. Said stationary contact (31) is connected through the mediation of a low-melting soldered joint with a disconnecting contact (32) being subjected to the action of move away force (F) acting on the disconnecting contact (32) in the direction from said stationary contact (31). The disconnecting contact (32) of the heat-disconnecting electric disconnect switch is interconnected by means of a stranded wire conductor (34) with the second connecting line (52) and simultaneously it is coupled with a move away means (35) mounted in the device structure and producing the move-away force (F).

Description

Equipment for overvoltage protection of electrical equipment terminal equipment

Technical field

BACKGROUND OF THE INVENTION The invention relates to a device for overvoltage protection of a terminal element of a power network comprising a varistor, the first and second terminals of which are connected to connection lines for connection to the phase or neutral contact of the device.

BACKGROUND OF THE INVENTION

In the area of overvoltage protections of category D (according to DIN VDE 675 Teil 6 / A1), there is currently a development that focuses on the structural arrangement of overvoltage protections of category D directly into socket boxes. From the safety point of view, the overvoltage protections must be designed in such a way as to eliminate the possibility of fire and damage due to changes that may occur with the varistor, which is the main element of the overvoltage protection.

Due to excessive load, varistors can change, resulting in a change in its properties. As a result of excessive load, the varistor will release more or more current or even breakdown and the varistor will become conductive. The design of the overvoltage protection must under these conditions ensure that the varistor is disconnected from the power supply. This disconnection is carried out in different ways, the methods of disconnection used having different properties depending on their design.

A device for disconnecting the varistor by means of a low-melting solder connection is known. The protrusion of the varistor electrode is connected by a low-melting solder connection to a spring-loaded conductor which forms the connection of the respective pole of the varistor to the circuit.

When the voltage of the varistor decreases, electric current flows through the varistor. At low current, the low-melting solder heats up as a result of the varistor heating

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4 4 will melt, thereby releasing the resilient conductor from contact with the varistor electrode protrusion and moving away a desired distance from the varistor electrode protrusion.

A different situation occurs when a large current flow reaches tens of amperes. In this case, the resistance of the varistor is low, and before the low-melting solder joint is heated to the desired temperature, the flexible conductor is heated so as to anneal and the melted conductor does not move away from the varistor electrode after melting the low-melted solder joint. At higher currents, the spring-loaded conductor can also melt, which is relatively small in relation to the desired travel path and is damaged before the circuit is interrupted by a pre-fuse, which may be a fuse or circuit breaker.

Another known device for disconnecting the varistor is based on the mechanical contact of the conductive elements, one side of the mechanical contact being fixed in position by a low-melting non-conductive fixative that supports the contact pressure spring.

Temperature transfer from the varistor is provided to the low-melting non-conductive fixative. The maintenance of the mechanical contact is counteracted by a spring which upon melting of the low-melting non-conductive fixative mass causes the pressure spring to be immersed in the molten fixative mass, thereby canceling its force effect and moving away from the contact surfaces. Removing the contacts will break the circuit.

The disadvantage of this device is that the contact joint is a critical point in terms of the effects of the current pulses. The pulse current can result in welding of the contact surfaces of the mechanical contact, whereby the thermal cut-off device loses its function. This can cause a dangerous temperature rise and destruction of the overvoltage protection system due to the varistor degradation.

SUMMARY OF THE INVENTION

The aforementioned disadvantages of the prior art are overcome by the overvoltage protection device, which consists in that the second outlet of the varistor is connected to the fixed contact of the thermally disconnectable electrical switch-disconnector,

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The fixed contact is connected by a low-melting solder connection to a detachable contact which is connected to a second connection line by means of a wire conductor, the detachable contact being coupled to a detachment means exerting a detachment force acting on the detachable contact away from the fixed contact.

The device ensures reliable operation in the whole spectrum of possible current loads.

To simplify the design and achieve variability in use, the varistor is mounted on a base plate that can be easily incorporated into an end device such as a socket.

To ensure good heat transfer from the varistor to the low-melting solder joint and to ensure sufficient thermal inertia, the solid contact is formed by a body surrounding part of the side surfaces and part of the circumference of the varistor.

In this case, it is advantageous if the fixed contact is in contact with at least one surface of the varistor, which further improves the heat transfer from the varistor to the fixed contact, in particular the higher flow currents.

By placing a firm contact on the base plate, the variability of use and the possibility of easy installation into the terminal device are achieved.

In order to achieve reliability of operation and simple construction of the device, the releasing means is formed by a tension spring, one end of which is mounted on the detachable contact and the other end is mounted in an electrical non-conductive place.

In a particular embodiment, it is preferred that the end of the tension spring is mounted on the base plate.

In order to ensure reliable operation of the device, it is advantageous if the detachable contact is connected mechanically to the stranded conductor without the use of solder.

In a particular embodiment, the detachable contact is provided with a loop in which a stranded conductor is molded, thus ensuring a secure connection of both components at all current load variants.

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In all of the above embodiments, the reliable operation of the device is ensured by the elements of the current path through which the varistor is connected to the phase and neutral contacts of the power terminal equipment, i.e. the wires, conductors and contacts have a conductive cross section equal to or greater than the varistor terminals.

Overview of the drawings

1 shows a view of the device, FIG. 2 shows a plan view of the device according to FIG. 1 in partial cross-section, and FIG. 3 shows a wiring diagram.

DETAILED DESCRIPTION OF THE INVENTION

The overvoltage protection device is arranged in the terminal 1 of the electrical network, for example in an electrical socket. As shown in Fig. 3, a varistor 2 is connected between the phase contact L and the neutral contact N of the terminal 1, with a heat-disconnecting switch 3 inserted in one branch of the varistor 2. The lightning arrester is connected between the neutral contact N and the PE ground terminal. 4.

1 and 2, the overvoltage protection device is arranged on a base plate 10, which can be applied, for example, to the rear wall of a terminal device 1 (not shown), with which it can be placed in the known device together with the terminal device 1; insulating boxes (not shown).

A base 511 of the first connection line 51 and an end 521 of the second connection line 52 are disposed on the base plate 10, wherein the free ends of the first connection line 51 and the second connection line 52 are intended to be connected to phase contact L or neutral contact N of the terminal 1. 511 of the first connecting line 51 is fixed the first terminal 21 of the varistor 2, the second terminal 22 of which is connected to the fixed contact 31 of the thermally disconnect switch 3, which further comprises a detachable contact 32, which is ϊ ^:

It is connected to the fixed contact 31 by means of a low-melting solder joint 33 whose melting point is less than the melting point of other parts of the apparatus, for example 130 ° C to 140 ° C. The disconnectable contact 32 of the thermal disconnect switch 3 is provided with a loop 321 in which one end of the cable 34 is fastened mechanically without soldering, i.e. by pressing, the other end of which is fixed at the end 521 of the second connection line 52. of the disconnect switch 3, a catch 322 is provided in which one end of the detachment means 35 is received which exerts a detachment force F acting on the detachable contact 32 away from the fixed contact 31. In the illustrated embodiment, the detachment means 35 is formed by a tension spring 351. is mounted on the retainer 322 of the detachable contact 32 and the other end is mounted on a base plate 10 that is of an electrically nonconductive material. The other end of the spring 351 may also be mounted in another suitable electrically non-conductive location, for example on the body of the terminal device 1.

In the embodiment (not shown), the spacing means 35 is formed by a leaf spring or a coil spring.

The fixed contact 31 of the thermal disconnect switch 3 is formed by a body surrounding a portion of the side surfaces of the varistor 2 and a portion of the circumference of the varistor 2. The fixed contact 31 contacts at least one of these surfaces of the varistor 2. and from there to a low-melting solder joint 33.

The current path of the varistor 2, formed by the connecting line 5, the cable conductor 34 and the thermally disconnect switch 3, has a conductive cross section greater than or equal to the conductive cross section of the outlet 21, 22 of the varistor 2.

When the voltage of varistor 2 decreases, electrical current flows through varistor 2. At low current flow, in the order of tens of milliamperes, the varistor 2 heats up. From the varistor 2, heat transfer via the second outlet 22 of the varistor 2 heats the fixed contact 31 of the thermally disconnectable electrical switch 3. and the force of the tension spring 351 separates the disconnectable contact 32 from the fixed contact 31, thereby disengaging the varistor 2 from the source

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32, current. Due to the detachable contact 43 (connected to the end 521 of the second connecting line 52 by means of a cable guide 34, the tension spring

351 at all times move the disconnect contact 3ff away from the fixed assembly 31.

At a higher current flow, in the order of tens of amperes, the varistor 2 heats up very quickly and heat transfer from the surface of the varistor 2 to the solid contact surfaces surrounding and possibly touching the varistor 2 helps to heat the solid contact. a low-melting solder joint 33 and detaching the detachable contact 32 from the fixed contact 31 by the tension spring 351.

Due to the good current conduction and sufficient thermal inertia, the size of the solid-state contact S and sufficient dimensioning of the conductive cross-section of the current-conducting path elements of the varistor 2 makes it possible to use only a circuit breaker for short-circuit currents.

In addition to the shown and described embodiment, the overvoltage protection device can be structurally adapted to various specific embodiments of the electrical network terminal 1, the essential feature of all solutions being to maintain a small thickness of the equipment. While maintaining a sufficient dimensioning of the conductive cross-section of the varistor 2 current path elements, the shapes of the fixed contact 31, the disconnectable contact 32, the shape, size and location of the connecting lines 5 and the location of the other end of the tension spring 351 can be changed.

The device works reliably in the whole range of possible current loads and does not require a separate short-circuit fuse pre-fuse, but it only needs a pre-fuse.

In the illustrated embodiment, the correct functioning of the device is signaled by a known glow lamp connected to the circuit in a known manner.

Claims (9)

PATENT CLAIMS An apparatus for overvoltage protection of a power supply terminal device, comprising a varistor, the first and second terminals of which are connected to connection lines for connection to a phase or neutral contact of the terminal, one of the terminals being thermally disconnectable to the connection line, characterized in that the second terminal (22) of the varistor (2) is connected to the fixed contact (31) of the thermally disconnectable electrical switch-disconnector (3), the fixed contact (31) being connected to the disconnectable contact (32) by a low melting solder connection (33). which is connected by means of a cable (34) to the second connecting line (52), the detachable contact (32) being coupled to the detachment means (35) exerting the detachment force (F) acting on the detachable contact (32) away from the fixed contact (31). Device according to claim 1, characterized in that the varistor (2) is mounted on the base plate (10). Device according to one of claims 1 to 2, characterized in that the fixed contact (31) is formed by a body surrounding part of the side surfaces and part of the circumference of the varistor (2). Device according to one of claims 1 to 3, characterized in that the fixed contact (31) is in contact with at least one surface of the varistor (2). Device according to claim 3 or 4, characterized in that the fixed contact (31) is mounted on the base plate (10). Device according to one of claims 1 to 5, characterized in that the delay means (35) is formed by a tension spring (351), one end of which is mounted on the detachable contact (32) and the other end is mounted in an electrically non-conductive location. Device according to claim 6, characterized in that the other end of the tension spring (351) is mounted on the base plate (10). ·· * «PS3205EN -88. Device according to one of Claims 1 to 7, characterized in that the detachable contact (32) is mechanically connected to the cable conductor (34) without the use of a solder. Device according to claim 8, characterized in that the disconnectable contact (32) is provided with a loop (321) in which the stranded conductor (34) is pressed. Device according to one of Claims 1 to 9, characterized in that the terminals (21, 22) of the varistor (2) have a conductive cross-section less than or equal to the conductive cross-section of the conduit elements to which the varistor (2) is connected to the phase contact (L). ) and the neutral contact (N) of the terminal (1) of the electrical network.