EP0172442A2 - Expulsion chamber for an electric switching device, particularly for application in low-voltage energy technics - Google Patents

Abstract

The contact points of the switchgear are situated in an argon-filled expulsion chamber and, apart from any minor additions of one or more metals used as sintering aid or wetting aid, are composed of 35 to 75% by volume of tungsten or molybdenum and 0 to 12% by volume of one or more elements from the group comprising tellurium, antimony and bismuth, the remainder being copper.

Description

• - Der Kontaktwiderstand soll gering sein, und zwar auf Dauer,
• - die Kontaktstücke sollen eine gute Abbrandfestigkeit unter dem Einfluß von Schaltlichtbögen zeigen,
• - die Kontaktstücke sollen beim Schließen unter Last eine möglichst geringe Neigung zum Verschweißen zeigen,
• - und nach dem Öffnen des Schalters soll ein Wiederzünden des Schaltlichtbogens nicht auftreten.

The starting point of the invention is a switching chamber for an electrical switching device with the features specified in the preamble of claim 1. To date, silver is the essential component of most contact materials used in low-voltage switchgear, most often in connection with metal oxides (cadmium oxide, tin oxide, indium oxide, zinc oxide and others, individually or in combination), which are dispersed in silver and their proportion 10 to Does not exceed 15% by weight. Silver is practically the only metal that can be used in low-voltage switchgear as the basis for materials for electrical contacts that are supposed to switch in air, because it does not form stable oxides in air and has a high electrical conductivity. However, silver is a metal whose price is relatively high and is also influenced by speculation. Efforts are therefore underway to replace the silver-based contact materials with base metal-based contact materials in low-voltage switchgear. Because of the good electrical conductivity of copper, contact materials containing copper are suitable for this purpose. However, they can only be used in low-voltage switchgear if they meet a number of requirements:

• - The contact resistance should be low, in the long run,
• - The contact pieces should have good resistance to erosion under the influence of switching arcs,
• the contact pieces should have the lowest possible tendency to weld when closed under load,
• - And after opening the switch, the switching arc should not be re-ignited.

Because of the easy oxidizability of the copper, a long-term low contact resistance can only be achieved if the copper-containing switch contacts are not operated in air but under an oxygen-free protective gas. In principle, any gas which does not react in an undesirable manner with the contact material (as would be possible with nitrogen with the formation of nitride) and which does not release any harmful decomposition products under the action of the switching arc can be used as protective gas. Since switching devices whose contact pieces are enclosed in a switching chamber filled with protective gas, but have to compete with the air-switching, structurally simpler switching devices with silver-based contact pieces, it is crucial to replace the silver-based contact pieces with those based on non-precious metals to find the necessary switching chamber with protective gas filling as simple and inexpensive a solution as possible.

Based on these considerations, argon is the only protective gas that can be used, because argon is cheap and consequent Due to its large atomic radius, it is easy to enclose, ie, with modest effort, it is possible to implement an argon-filled switching chamber from which the argon will not diffuse for years. Unfortunately, however, argon has a very low dielectric strength (see Manfred von Ardenne: Tables on Applied Physics, Volume 3, page 418; VEB Deutscher Verlag der Wissenschaften Berlin 1973). The low dielectric strength of the argon gives rise to concerns that the arc cannot be reliably re-ignited after a switch has been opened, and this concern has arisen in studies carried out by the inventors, inter alia, on contact pieces made of 88% by weight copper and 12% cadmium oxide, from 75% by weight copper and 25% by weight chromium.

From Japanese published patent application 58-22 346 a contact material for encapsulated contact systems in low-voltage switching devices is known, which contains 5 to 25% by weight, preferably 10% by weight, molybdenum and the balance copper. Nothing is known about the type of protective gas used. According to the information in this published specification, a contact resistance was measured with contact pieces made of 10% molybdenum and 90% copper, which was comparable to the contact resistance of contact pieces made of silver with 12% by weight cadmium oxide. However, this material does not behave satisfactorily with regard to the resistance to erosion and the tendency to weld as well especially with regard to the reignition of the arc after opening the switch. The latter is not surprising, since the instant hardening tension, which has a decisive influence on the reignition behavior, is very low and therefore unsuitable for high-boiling metals such as tungsten and molybdenum and for materials containing these high-boiling metals, e.g. for tungsten with 30% by weight silver, to prevent the arc from re-igniting, whereas the instant hardening voltage for materials such as silver-nickel and silver-cadmium oxide is high and therefore favorable (see A. Keil, WA Merl, E. Vinaricky: Electrical contacts and their materials, Springer-Verlag 1984, Page 101).

The invention has for its object to find a contact material which is particularly suitable in switchgear, in particular in those for low-voltage energy technology, for use under argon as a protective gas. This object is achieved through the use of a contact material which, apart from any minor addition of one or more metals serving as a sintering aid or wetting aid, consists of 35 to 75% by volume of tungsten or molybdenum and 0 to 12% by volume of one or more elements consists of the group tellurium, antimony and bismuth as well as the rest of copper. The particular suitability of such contact materials is given the known poor dielectric Properties of the argon and the low instantaneous hardening stress of the tungsten and the molybdenum are extremely surprising, and all the more so since the contact material used according to the invention contains a very high proportion of heavy metals (in the case of tungsten, the 35 to 75% by volume corresponds to a content of around 55 to 85% by weight. -%). The additional metals tellurium, antimony and bismuth - of which antimony is particularly suitable - represent at most a small proportion of the contact material; they are preferably used in a proportion of 1 to 6% by volume (corresponding to approximately 0.5 to 2.5% by weight) in the contact material, low contents being particularly preferred.

Contact pieces can be produced from the contact material according to the invention by first producing a porous molded body from tungsten powder or from molybdenum powder by sintering, which is then infiltrated with copper, which contains the additional metals tellurium, antimony and / or bismuth, optionally as alloy metals, and preferably by excess soaking. The tungsten powder or the molybdenum powder can contain small amounts of an additional metal in a manner known per se which promotes the sintering process; Suitable sintering aids are, for example, nickel or cobalt, which may be added to the tungsten in a proportion of around 0.5% by weight. Furthermore, the contact material can contain small amounts (less than 1% by weight) of one or more Contain metals, which serve as a wetting aid and favor the infiltration of the copper or the copper alloy; In addition to zircon, cobalt and nickel are also suitable as wetting aids, which can optionally be added to the copper to be infiltrated.

However, one could also mix the tungsten or molybdenum powder with copper powder as well as with antimony, tellurium and / or bismuth powder, possibly also with an additional metal provided as a sintering aid or wetting aid, and produce a shaped body from the powder mixture by sintering in the liquid phase. In this case, an excess amount of the impregnating material (copper and the intended additional metal from the group of antimony, bismuth and tellurium) is preferably placed on the powder mixture given in a mold in order to impregnate the tungsten or molybdenum structure formed during sintering as completely as possible guarantee and at the same time to get a well solderable and weldable surface layer on one side.

Contact pieces made of the material according to the invention not only have a low contact resistance and thus only a low contact heating, but also a long service life, sufficiently low erosion and sufficiently low tendency to weld, and in particular excellent suitability for arc quenching, especially under argon as a protective gas.

An embodiment of the invention is given below: 99.5 parts by weight of tungsten powder with an average grain size between 1 and 10 µm (FSSS) and 0.5 part by weight of fine-grained nickel powder are mixed together, placed in a mold, compacted therein and then at a temperature of around 1100 ° C for a period of 30 min. sintered under cracked gas. In this way, a molded body is formed from a porous tungsten framework, which is then impregnated with an alloy of copper with 3% by weight of antimony. Soaking takes place at a temperature of approx. 1150 ° C in a vacuum.

After the impregnation process, the contact piece blank has a residual porosity of less than 2% and has the following composition by weight

Contact pieces assembled in this way initially show a contact resistance of 200 - 300 µΩ under argon (50% or 99% values of the total frequency, test current Ip = 50A, test voltage U _p = 37V, contact force F _K = 7N, no arc), which in the course of 10,000 switching cycles (I _p = 300A, Up = 220V, power factor cos ϕ = 0.35,

Arc duration r _arc = 10 ms) to values between 300 - 400 µΩ rise.

The corresponding values for contact pieces made of silver with 12% cadmium oxide when switching in air are 300 - 400 µΩ or 500 - 700 µΩ.

The burnup for the contact pieces made of silver with 12% cadmium oxide in air is 20 mg / 1000 switching cycles, for the contact pieces made of the material according to the invention in the above composition in combination with argon as protective gas, 15 mg / 1000 switching cycles. The reconsolidation voltage, which was determined under argon for frequencies in the range of 20 - 100 kHz of the transient voltage with an overshoot factor of 1.1 (test current Ip = 300A, test voltage Up = 220V, power factor cos _f = 0.35, arc duration τ _arc = 10 ms, average separation speed of the contact pieces v _o = 1ms ^-1 , contact distance in the end position d = 5 mm), reached values that are otherwise achieved with contact pieces made of silver with 12% cadmium oxide when switching in air.

Claims (2)

1. switching chamber for an electrical switching device, in particular for use in low-voltage energy technology, in which contact pieces made of a contact material containing copper and a high-melting metal and a protective gas are enclosed,
characterized in that the contact material - apart from any minor additions of one or more metals serving as sintering or wetting aid - from 35 to 75% by volume of tungsten or molybdenum and 0 to 12% by volume of one or more elements from the group tellurium, antimony and bismuth, to the rest consists of copper and that the protective gas is argon. 2. switching chamber according to claim 1,
characterized in that the elements from the
Tellurium, antimony and bismuth with a proportion of 1 to 6% by volume are contained in the contact material.