NL8401005A - CONSTRUCTION OF CONTACTS OF A VACUUM CIRCUIT BREAKER. - Google Patents

Description

'jr & W 4746-9 Ned.dB / LdB *

Short designation: Icon stimulation of contacts of a vacuum circuit breaker.

The invention generally relates to vacuum circuit breakers and in particular to the construction of contacts for such a vacuum circuit breaker.

Vacuum circuit breakers generally have an evacuated, house or evacuated chamber surrounding a pair of circuit-closing or breaking contacts, which are mounted inside the house so that they can be moved in and out of contact with each other. When the circuit breaker is used to interrupt the current, the contacts are moved apart, creating an arc between the releasing contacts. The arc generated between the opposing contact surfaces heats the contact surfaces to a fairly high temperature. Should this relatively high temperature still exist if the circuit is closed again by reconnecting the contacts of the circuit breaker, a weld may develop between the two contact surfaces. Such contact welding is disadvantageous in that it hinders the proper and easy detachment of the contacts when it is desired to interrupt or open the electrical circuit again, which includes the vacuum circuit breaker.

Many improvements in the design of vacuum circuit breakers have already been described, intended to reduce or avoid the adverse contact welding. It is, of course, desirable to form the contact pads 25 of the contacts of a material which minimizes the possibility of a weld. It has also been established that the ability to form a weld can be reduced by rapidly moving the arc across the surfaces of the contacts.

The rapid arc movement causes a lower contact temperature, thereby reducing thermo-electron emission by decreasing the amount of electrode material being evaporated and by increasing dispersion of the electrode material to be evaporated, thereby faster recovery of the dielectric in the gap between the contacts occurs. Slots in the contact and / or in the contact support member, together with the magnetic forces generated by the current to be interrupted, cause the arc to rotate and radially outwardly over the contact surfaces. Many modes of forming these slots are described in U.S. patents. In vacuum circuit breakers, 40 which use disc-shaped rather than annular contacts, 8401005-2 -, helical grooves are formed in the contact face, as shown in U.S. Patents 3,327,081 and 3,462,572. In cup-shaped contacts, the grooves are formed to extend from the contact face of the contact, helically through the contact support wall 5 to the support base of the contact construction. Grooved cup contacts of this type are described in U.S. Pat. in the support structure. This type is shown in U.S. Patent 4,267,416.

The preferred material for the contact construction in a vacuum circuit breaker is generally copper or a copper alloy. This material is preferred because it has both high electrical and high thermal conductivity. Copper or a copper alloy further have good dielectric strength derived from its high tensile strength. However, since it is necessary to subject the contact structure to a soldering cycle during mounting, where temperatures of the order of 1800 ° C may occur, the 20 parts of copper or a copper alloy lose their hardness, so that they become quite soft. When soft, the contact structures are deformed quite easily when subjected to the closing force applied to the contacts. Although the deformation of the contact structures by repeated closing strengthens these structures, the resulting deformation of the contact structures is very undesirable. Thus, it has been found to be highly desirable, in particular in the case of cup-shaped contacts, to provide means for strengthening the contact structure, especially when its walls are weakened by slitting it therein. causing the arc to rotate about the contact surfaces.

According to the present invention, a contact structure for a vacuum circuit breaker is provided, in which cup-shaped contacts, provided with arc-rotating slots, are first reinforced by the provision of a reinforcing member. The contact structure has a main part, formed of a high electrical conductivity material, for example, copper or a copper alloy, and an annular contact part, which is also preferably formed of copper or a copper alloy.

The main part consists of three parts, a support part, a middle part and a closed wall part protruding from the middle part in the opposite direction to the support part. The part with 8401005 * - r - 3 - closed wall forms with the middle part a cup-shaped construction on the lip of which the annular contact is mounted. The annular contact is attached to the edge of the cup-shaped part by a soldering operation. Although the annular contact is continuous, i.e. without grooves, the arc arc rotation is caused by helical grooves formed in the closed wall portion. In order to prevent deformation of the contact structure and in particular of the closed-wall part thereof, a reinforcing member is provided which extends between the middle part of the contact structure and the annular contact. In one embodiment, this reinforcing member, which is formed of a material of high strength and greater electrical resistance than the copper, is supported at one end by the center portion of the contact assembly and contacts the annular contact at the other end contact.

When the closed-wall part is formed as a circular cylinder, the reinforcing part is also formed as a circular cylinder, fitting within the closed-wall part. The contact ring covers the free ends of both the closed wall portion and the reinforcement member. In another embodiment of the invention, the closed wall portion may be formed with a circular-cylindrical outer wall and a frusto-conical inner surface. In this embodiment, the reinforcing member is a hollow truncated cone, the outer surface of which abuts the internal truncated conical surface of the closed-wall portion.

The invention will be explained in more detail below with reference to the drawing, in which some exemplary embodiments of the vacuum spreader according to the invention are shown.

Fig. 1 is a side view of a pair of contact structures for a vacuum circuit breaker according to a first embodiment.

FIG. 2 is a sectional view through the contact structures of FIG. 1..

Fig. 3 is a section through the contact structures of another embodiment.

Although this invention can be practiced in many different embodiments, two preferred embodiments are shown in the drawing.

Fig. 1 shows a pair of contact structures 10 and 12 according to a first embodiment. This embodiment is also shown in section in Fig. 2. Each of the contact structures has a first part 14 consisting of a support part 16, a middle part 18 and 40 a closed wall part 20. In the preferred embodiment, the first 8401005 "2 - 4" part 10 is formed from a piece of copper or a copper alloy.

The support part 16 is shown as a cylindrical part, the ends of which have been broken away to indicate that they can be of any length. The support member 16 provides a means by which electrical and mechanical connections can be made to the contacts, for the purpose of conducting electrical current to the contact, and connecting the contacts to the housing of the vacuum circuit breaker and to the contact operating mechanism .

The center section 18 is shown here as a solid cylinder 10 with a larger diameter than the support section 16. The closed wall section 20 is shown as a hollow circular cylindrical section, the outer diameter of which corresponds to that of the adjacent center section 18. A cylindrical opening 22 is formed through the inner face 24 of the closed wall portion 20 and a circular base 26 through the center portion 18.

. According to the invention, a reinforcing member 28 in the form of a hollow circular cylinder is disposed within the cylindrical opening 22. The reinforcing member or circle cylinder 28 is formed of a non-magnetic. material that retains its strength when subjected to the high temperatures encountered during a soldering cycle, which is part of the assembly procedure for a vacuum interrupter with the contacts of this invention. The preferred material that meets these requirements is stainless steel A.I.S.I.

304. Other non-magnetic metals suitable for use for the reinforcing member are tungsten, titanium, zircon and molybdenum, ie metals of groups IVB, VB and VIB of the periodic table and beryllium oxide, Al 2 O 3 with high specific gravity and boron nitride.

As shown in Figs. 1 and 2, the outer surface of the reinforcing member 28 abuts the inner surface 24 of the closed wall member 20. An annular contact 30 is attached to the exposed 30 ends of the closed wall 20 and the reinforcing member 28. The inner diameter 32 of the annular contact 30 corresponds to the inner diameter of the reinforcing member 28, while the outer diameter 34 of the annular contact corresponds to the outer diameter of the closed wall 20. Thus, the annular contact 30 completely covers the ends of the the reinforcing member 28 and the closed wall 20, so that any arc which arises between the annular contacts 30 is prevented from ending at the reinforcing member 28 or the closed wall 20.

In an elongated contact thus mounted, the reinforcement member 40 carries the cylinder 28 the annular contact 30 at the center portion 40, so that deformation of the closed wall portion 20 is prevented when the opposing annular contacts 30 collide when closing the circuit. In a preferred method of mounting the elongated vacuum breaker contact assembly 5 of the invention, the annular contact 30 is attached to the main contact portion 10 by a soldering operation. The reinforcing member 28 is attached in the same operation.

Although the reinforcing cylinder 28 is shown as a solid part in FIGS. 1 and 2, this need not be so. For example, the part may also be formed as a pair of rings, one abutting against the annular contact 30 and the other against the center portion 18, with a plurality of columns or bars keeping the rings spaced apart.

The need for the reinforcement member 28 is particularly great when slots 36, as shown in Fig. 1, ie extending entirely through the radial thickness of the closed wall 20 and from the free end of the wall to the support member 16 and at an angle with respect to the longitudinal axis of the contact 10 or 12 ^ are arranged in the closed wall 20 for the purpose of increasing the rotation of the arc around the plane of the annular contact 30. The provision of the slots 36 considerably weakens the closed wall part 20 so that without the reinforcement cylinder 28, pressing the contact rings 30 against each other when closing the contact would probably deform the closed wall part 20.

When the reinforcement cylinder 28 is a solid part and when slots 36 are provided in the closed wall 20, openings or slots can also be provided in the reinforcement cylinder 28, aligned with the slots 36, for connecting the volume to the outside air. is formed within a pair of the cup-shaped contacts when they are closed.

A second embodiment is shown in FIG. 3. The elements of FIG. 3 corresponding to those of FIGS. 1 and 2, without significant changes, are indicated by the same numerals as the corresponding elements in FIGS. 1 and 2. The embodiment .35 of FIG. 3 differs from that of FIGS. 1 and 2 in that the reinforcing member 40 is formed as a hollow truncated cone rather than a hollow straight circle cylinder. The inner surface 42 of the closed wall part 20 is also formed as a frusto-conical surface, so that during mounting it will abut against the outer surface of the reinforcing part 40. As in the previous embodiment, an end lies 8 4 0 10 0 5 \ 6 of the reinforcing member 40 abuts the center portion 18 at the base 26, while the other end abuts the top surface of the annular contact 30 to support it from the center portion 18.

Although in the preferred embodiments the main contact parts 10 and 12 are formed of copper or a copper alloy, the annular contact 30 is also formed of a copper alloy and the reinforcing part of stainless steel (A.33.S.I. 304), other materials may also be used. For example, the reinforcing member could be formed of a material that retains its strength after a high temperature soldering cycle and is not magnetic, so that other materials can also be used, as mentioned above.

From the above, it can be seen that many modifications can be made without departing from the scope of the invention. For example, the reinforcing member can have other shapes. The outer diameter of the closed wall part 20 can be smaller than that of the middle part 18, so that a molding is formed on the middle part 18, which can carry a reinforcing part surrounding the outer circumference of the closed wall part 20. Furthermore, an annular slot can be formed in the closed wall 20, so that the base of the slot is formed by the center portion 18, after which a reinforcement member, placed in the slot, abuts and supports the bottom surface of the annular contact 30. Obviously, no restrictions are intended with respect to the embodiments shown. It is, of course, intended with the appended claims to cover all modifications which fall within the scope of the invention. 1 8401005

Claims (8)

Elongated contact construction suitable for use in a vacuum circuit breaker, characterized by a middle part (18) formed of a material with high electrical conductivity, a support part (16). also formed of a high electrical conductivity material projecting from the center portion in a first direction substantially along the longitudinal axis of the elongated contact structure, a closed wall portion (20J, also formed of a high electrical conductivity material protruding from one part in a second direction, opposite to the first direction, substantially along the longitudinal axis of the elongated contact construction, the main part of which protrudes from the central part so as to form a cup-shaped construction, an annular contact part (30) supported by the free end of the main part, which annular contact part has a radial thickness in the direction perpendicular to the longitudinal axis, which is greater than that of the free end of the closed wall part, which annular contact part has a contact surface, facing in the second direction and a support face, facing the first direction, which support face first and t has two parts, the first part of which abuts against the free end of the closed wall part to form an electrical connection therewith, and a reinforcing part (28) is provided, formed of a material with a higher electrical resistance than the wall part and extending between the middle part and the second part of the support surface of the annular contact, for supporting the annular contact of the middle part, thereby preventing deformation of the wall part when a closing force is exerted on the annular contact by contacting this contact surface with another contact. Construction according to claim 1, characterized in that the material with higher electrical resistance is a non-magnetic material. Construction according to claim 1 or 2, characterized in that the material with higher electrical conductivity is copper or a copper alloy, and the material with high electrical resistance is stainless steel. Construction according to any one of the preceding claims, characterized in that a number of slots C36) are formed in the closed wall part (20), which extend entirely through the radial thickness of this closed wall part 8401035-8-4P, * r and extend from the free end of the wall part to the support part and slope relative to the longitudinal axis of the elongate contact construction. Construction according to any one of the preceding claims, characterized in that at least one opening is provided in the reinforcing member, connected to at least one of the slots, whereby the volume formed within the cup-shaped structures, when a pair of of the. contact surfaces are brought together, connected to the outside air. Construction according to any one of the preceding claims, characterized in that the closed wall part (20) is formed as a circular cylinder and the annular contact (30) as a circular disc, while the reinforcing part (28) is a circular cylinder. Construction according to any one of the preceding claims, characterized in that the outer diameter of the closed wall part (20) is substantially equal to the outer diameter (34) of the annular contact (30), while the inner diameter (24) of the closed wall portion is substantially equal to the outer diameter of the reinforcement member (28), the inner diameter of the reinforcement member being substantially equal to the inner diameter (32) of the annular contact. Construction according to any one of claims 1 to 5, characterized in that the closed wall part (20) is formed with a circular cylindrical outer surface and a frusto-conical inner surface (42), with a larger diameter at the free end than adjacent at the center portion, the reinforcing member (40) being formed as a hollow truncated cone, the outer surface of which abuts the truncated conical inner surface (42) of the closed wall portion. 30 35 40 8 40 1 00 5