RU2783696C1 - Thermoelectric circuit breaker - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: invention relates to the field of electrical engineering, namely to thermoelectric switches designed for switching circuits of energy-intensive electrical components in various operating conditions and modes. To achieve the effect, the movable link of the thermoelectric disconnector is made in the form of a metal rod resting with one end against a low-melting thermoelement with a resistive heater, while the rod and thermoelement are fixed in the center along the length of the housing, which consists of two parts.

EFFECT: increasing the speed of the disconnector while optimizing the design.

1 cl, 2 dwg

Description

The invention relates to the field of electrical engineering, namely, to thermoelectric switches designed for switching circuits of energy-intensive electrical components (power electronic components and devices, power supplies, single-phase electric motors, etc.) in various operating conditions and modes, for example, when the temperature is exceeded environment above the operating temperature limit of the component or when the component is controlled by an external electrical signal.

A thermoelectric switch (thermoswitch) is a switching device made using a fusible alloy that melts (softens) when heated to a certain temperature, switching the circuit directly or with the help of auxiliary elements, and is not restored (does not return to its original state) after operation. Therefore, they are often referred to as disposable thermal switches.

Thermal switches are simple in design (unlike thermal relays) and have a wide variety of types and designs depending on the type of controlled component, conditions and modes of their operation.

"Thermal switch" is a general term, but is most commonly used for switching devices designed to switch circuits and containing changeover or make and break contacts. Thermal switches intended only for closing circuits are often referred to as thermoelectric contactors, and thermal switches for opening the circuit are called thermoelectric circuit breakers or thermal fuses.

Thermoelectric switching devices of different types (according to the type of switching) contain common structural elements for all types (case, terminals, low-melting alloy grasping two parts or as a structural element called a thermoelement) and common structural elements for several types and versions (contacts, moving link , carrying a movable contact element, a spring driving a movable link, a contact spring, a heater, etc.). Therefore, the design features of common elements, their placement, manufacturing method, etc. of one type of thermoelectric device also characterize the state of the art of another type of thermoelectric device.

Known switch disposable (with changeover contact) [1], containing a housing, the first, second and third fixed cylindrical contact elements connected to the findings, a movable cylindrical contact element placed for movement inside the fixed contact elements on the rod (movable link) of insulating material, a resistive heater in the form of a cylindrical winding mounted with an insulating sleeve on fixed contact elements, and a spring. In the initial state, the movable contact element is connected to the first and second fixed contact elements by low-melting alloy soldering, forming a NC contact. When voltage is applied to the heater winding, the soldering melts and the movable contact element moves under the influence of the spring, crossing the second and third fixed contact elements. After the winding is turned off, the solder cools down, rigidly fixing the connection of these contact elements, forming a closing contact.

The disadvantage of such a switch is the large size of the housing in the radial direction due to the placement of the movable contact element, the fixed contact element, the insulating sleeve and the heater winding one below the other, while the inner diameter of the fixed contact elements must be no less than the diameter of the drive spring. The disadvantages of the switch should also include:

- switching inertia, which is determined by the increased heating time of the metal parts that make up a significant mass of the switch, to the soldering melt temperature;

- low stability of the operation time due to additional heating of the soldering by the passed load current, the value of which can vary from zero to short-circuit currents.

The increased switch response time and poor switch stability, in turn, reduce the protection reliability of the high-current component.

Known switches with opening and closing contacts [2, 3], containing bridge contacts, the movable bridges of which are mounted on an insulating traverse, a drive and a fixed cylindrical cores connected by soldering from a low-melting alloy, a resistive heater consisting of a winding and an insulating sleeve fixed on a fixed core, and a switching spring placed inside the movable core. When the heater winding is turned on, the soldering that seizes the fixed and movable cores melts, and the movable core with a traverse with contact bridges is set in motion, switching the circuits. Due to the use of bridge contacts isolated from the drive part of the structure, reliable switching is ensured and the aforementioned negative effect of the load current on the operation of the switches is eliminated.

The disadvantages of switches [2, 3] include large overall dimensions and low speed due to the implementation of the drive part, as in the switch [1], in the form of a "layered" design, consisting of a spring, two cores, an insulating sleeve, a heater winding and an external insulation, and large heating inertia (low speed).

A common disadvantage of the known switches [1, 2, 3] is the complexity of the design of the conclusions intended for connecting external conductors, and the method of fastening the housing during operation. The mass and dimensions of the terminals can make up a significant part of the mass and overall dimensions of the switch. At high rated currents of the switch (50 A or more), ensuring the manufacturability of the design of the leads and their fastening in the housing can be the main problem of introducing the switch into production.

The closest technical solution in terms of the main design features (type of contact, composition, type of execution and mutual placement of the main structural elements) to the proposed device (prototype) is a thermal fuse (thermoelectric circuit breaker) [4], which is designed to protect electrical equipment and components for rated currents up to 10 A against damage if they are overheated above the allowable operating temperature. The prototype contains a housing, two terminals, a thermocouple, a NC contact, a movable link, an element bearing a movable contact, a contact and a NC (actuating) spring. The body is made in the form of a cylindrical conductive sleeve, closed at one end with an insulating sleeve. The conclusions are fixed rigidly on the ends of the housing. The movable link carrying the contact element is made in the form of a conductive disk with bent edges, fixing it inside the housing sleeve, with the possibility of movement, and is pressed by a contact spring to the end of the output with a fixed contact element, fixed in the insulating sleeve. In this case, the contact spring rests with the other end on the thermoelement, which is a low-melting alloy, with which part of the internal volume of the sleeve is filled.

A feature of this design is the placement of the main structural elements (terminals, moving link, thermoelement, contact and drive springs) sequentially one after another along the longitudinal axis of the structure, i.e. in one plane, which allows to reduce the overall size in diameter as much as possible.

The work of the prototype is as follows. When heated from an elevated ambient temperature, the thermoelement melts and the contact spring goes inside it, and the movable link carrying the movable contact element begins to move under the influence of the drive spring, opening the circuit of the protected component. After cooling the fusible alloy, the contact spring remains in the expanded state and the open state of the contact is maintained.

The disadvantage of the prototype is the low switching capacity, determined by the ability to pass small currents (10-15 A) for a long time and switch only active loads, which are due to design features and operation:

- in the closed state, the load current passes through five contact transitions, a contact spring, usually made of steel with high electrical resistance, and a low-melting alloy, so a lot of power is released inside the circuit breaker itself, which can lead to overheating of structural elements without a significant increase in dimensions;

- in the process of operation (operation), the movable contact element moves during the melting of the thermoelement for several tens of seconds, and near the limit values of the softening temperature, the contact spring may be slowly immersed inside the thermoelement, so the electric arc that occurs with an inductive load between slowly diverging contact elements can lead to their welding, leading to failure of the circuit breaker.

Thus, the technical solutions of the prototype do not allow the implementation of a technological design of the circuit breaker for high rated currents (50 A or more), capable of switching inductive loads.

The objective of the invention is to create a small-sized thermoelectric circuit breaker of simple design with increased switching capacity, designed for one-time opening of high-current circuits with inductive loads.

The technical result is increased performance while optimizing the design.

The technical result of the claimed invention is achieved by the fact that in a thermoelectric circuit breaker containing a housing, two terminals, a thermoelement, a breaking contact, the movable contact element of which is installed on the movable link, the contact and disconnecting springs, the movable link is made in the form of a metal rod with placed on it, in series along the length, by a bridge-type movable contact element, contact and opening springs, and with one end resting on a thermoelement, which, in turn, is made in the form, for example, of a low-melting alloy cylinder with a resistive heater installed on it, consisting of a winding with an external connection and an insulating frame, while the rod and the heater are fixed in the center along the length of a flat case made of insulating material, consisting of two halves, and the terminals, made flat, are on the sides of the case.

The technical result is increased performance while simultaneously optimizing the structure in terms of being flat, with an optimized height (overall size relative to the mounting plane), and are as follows:

- the main structural elements - a contact bridge, a rod, contact and disconnecting springs and a thermoelement with a heater, are placed sequentially along the longitudinal axis of the housing and the height of the disconnector is determined by the diameter of the springs, which is practically minimized in size, and the thickness of the housing walls; the case, consisting of two halves, and the terminals are made flat, while the terminals serve simultaneously for fastening the disconnector during operation;

- the design contains a minimum number of parts that are simple and easy to assemble (without special technologies);

- the fusible alloy of the thermoelement is melted by a resistive heater installed directly on it in seconds, and the rod resting on it with a contact bridge, by the total force of the compressed contact and disconnecting springs, the value of which at high currents is about ten newtons, almost instantly passes into another state, opening the electrical circuit with inductive load without arc tightening. The contact, made in the form of a bridge, excludes the passage of the load current through the structural elements and their heating, the cross section of the conductive parts does not affect the dimensions of the circuit breaker and allows the passage of high currents (50 A or more). The large stroke of the rod and the contact bridge makes it possible to increase the contact gap and increase the switching capacity of the disconnector.

The specified set of features allows you to create a simple small-sized thermoelectric circuit breaker with increased switching capacity.

In FIG. 1 shows a general view of the inventive thermoelectric circuit breaker (without one half of the housing); in fig. 2 - section A-A.

The thermoelectric circuit breaker contains a housing 1, consisting of halves 1a and 16, flat terminals 2 and 3 with holes for connecting to external conductors (to buses, to terminal blocks of power components, etc.), fixed on the sides of the housing between its halves 1a and 16, thermoelement 4, made, for example, in the form of a cylinder made of low-melting alloy, bridge 5, which forms with protrusions of terminals 2 and 3 a bridge-type NC contact, contact spring 6, disconnecting spring 7, metal rod 8 supported under the action of springs 6 and 7 on the end of the thermoelement 4, a resistive heater, representing the winding 9, which is isolated from the thermoelement 4 by a bushing 10 made of a heat-resistant material. The compressed state of the springs 6 and 7 is provided with the help of lock washers 11.

The work of the circuit breaker is as follows. In the initial state (in normal long-term operation), the contact is closed under the action of the contact spring 6, which is compressed due to the stop of the rod 8 against the end of the thermoelement 4. When voltage is applied to the winding 9 of the resistive heater, the thermoelement 4 melts and the rod 8 carrying the movable bridge 5 comes into motion under the action of the forces of springs 6 and 7, pushing the molten alloy from inside the heater and at the same time opening the contact. The dip and gap values of the contacts are determined by the distance S between the locking washer 11 and the baffle in the housing, which also serves as a guide rod 8. After the breaker is activated, the contact remains in the open state, providing a break in the circuit of the controlled (protected) electrical equipment.

In accordance with the proposed technical solutions, dummies of a thermoelectric disconnector for a rated current of 50 A and overload currents of up to 180 A with a height of H = 8 mm and a weight of about 15 g were made. The mockups successfully passed tests for compliance with the technical requirements for them.

Sources of information:

1. Patent 84156 RU, IPC H01H 37/76. Single action switch / Miryutov A.V., Fomin K.N., Kashin P.I.; patent holder OJSC "Scientific and Production Center "Polyus" - publ. 06/27/2009 Bull. No. 18.

2. Patent 80708 RU, H01H 37/76. Single action switch / Miryutov A.V., Fomin K.N., Abakumova G.V., Susenkova K.N., Kashin P.I.; patent holder OJSC "Scientific and Production Center "Polyus" - publ. 20.02.2009 Bull. No. 5.

3. Patent 2403644 RU, H01H 37/76. Single action switch / Miryutov A.V., Galkin V.V., Shevchenko Yu.M., Fomin K.N. Isaev A.A.; patent holder JSC "Research and Production Center "Polyus". - publ. 11/10/2010 Bull. No. 31.

4. Catalog KLS Electronic, Fuse and fuse holder/ www.cnkls.com

Claims (1)

A thermoelectric circuit breaker, comprising a body, two leads, a thermoelement, a breaking contact, the movable contact element of which is mounted on the movable link, contact and disconnecting springs, characterized in that the movable link is made in the form of a metal rod with a movable contact element of the bridge type placed in series along the length, contact and disconnecting springs, resting with one end on a fusible thermoelement located in a heat-resistant sleeve with a winding with external connection, forming a resistive heater, while the rod and thermoelement in the sleeve are fixed in the center along the length of the body, which consists of two parts.

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