DE102007010604A1 - Switching contact for electromechanical switchgear, has fuse-resistant intermediate element arranged between contact piece and contact holder, where conductivity of intermediate element is smaller than conductivity of contact piece - Google Patents

Abstract

The switching contact (1) has an electrically conductive contact piece (3) arranged on an electrically conductive contact holder (2). A fuse-resistant intermediate element (7) is arranged between the contact piece and the contact holder, where electrical conductivity of the intermediate element is smaller than electrical conductivity of the contact piece. The intermediate element is made of graphite or graphite material. The conductivity of the intermediate element lies around a range over the conductivity of the contact piece. Independent claims are also included for the following: (1) a method for determining a life span end of a switching contact (2) an arrangement for determining a life span end of a switching contact.

Description

The The invention relates to a switching contact for an electromechanical Switching device or the like, with an electrically conductive Contact carrier and one on the contact carrier arranged electrically conductive contact piece. Moreover, the invention relates to the use of a such switching contact in an arrangement for determining the end of life of switching contacts, a method for determining the end of life of Switching contacts and an arrangement for carrying out the Process.

For devices after EN 60947-4-1 (Sagittarius) is the end of the electrical life usually after exhaustion of the contact material (usually silver alloys) and after exhaustion of the through-pressure and associated with the decrease of the contact force reached close to zero. It comes to the contact of the contact carrier, which consist mostly of copper (Cu) or Cu alloys. As a result of the material properties, the contact carriers are likely to fuse under the influence of the switch-on arc. The device can then no longer be switched off.

For devices after EN 60947-2 (Circuit breaker) with z. As double interruptions, the supply is usually chosen lower than the strengths of the contact pads. This ensures that sufficient contact material is still present at the end of the electrical life and is not switched to the carrier material. The risk of welding is lower compared to shooters. However, a decrease in the contact force is also close to zero here with the exhaustion of the through-pressure. There is a risk of contact swapping as a result of unsafe contact. The associated arc can lead to overheating (power conversion increased by a factor of 1000) and welding of the contacts as a result of bridging by molten contact material.

It is therefore an object of the invention, in contact-switching switching devices, z. B. as shown in the embodiments as a contactor or circuit breaker, the near-life end reliable to detect, so that the switching device in a safe Out of state can be transferred before a Malfunction occurs.

to Solution of this problem is a switching contact according to claim 1 proposed. Thereafter, it is provided between the contact piece and the contact carrier at least one weld-resistant intermediate element to arrange, whose electrical conductivity is lower, as the electrical conductivity of the contact piece.

About that In addition, this object is achieved by a method according to claim 7 or 8 or an arrangement according to claim 9 solved.

While in "normal" switching operations, where always the contact materials (silver alloys) interconnect, and so that the contact resistance is low, takes place after a removal (erosion) of the contact material according to the invention from at a certain time switching to the intermediate element. The contact resistance changes in comparison to "normal" switching operations clearly there is a gradual warming of the contact environment, which can be detected by means of temperature sensors.

With It is therefore possible for the present invention, to consume (almost) the comparatively expensive contact material, without taking the risk that the carrier material will be welded. On the other hand, the near end of life of a switching contact reliably detected and the necessary steps to Avoidance of malfunction.

advantageous Embodiments of the invention are in the subclaims are given below and in connection with the description a preferred embodiment of the invention in more detail explained. Hereby show:

1 the schematic structure of a switching contact according to the prior art,

2 the schematic structure of a switching contact according to a first embodiment of the invention,

3 a schematic representation of a switching contact according to a second embodiment of the invention and

4 a schematic representation of an arrangement for determining the end of life of switching contacts.

A conventional switching contact 1 as he is in 1 is illustrated, regardless of the type of device is constructed such that on an electrically conductive contact carrier 2 an electrically conductive contact piece 3 is arranged. The contact piece 3 is with his bottom 4 on top 5 of the contact carrier 2 soldered. The contact carrier produced, for example, from copper (Cu) 2 is doing with the contact piece 3 , which is made for example of a silver-nickel alloy (AgNi), via a solder or welding layer 6 (for example made of silver) connected.

According to the invention it is now planned, un ter the contact piece 3 to arrange at least one weld-resistant intermediate element whose electrical conductivity is lower than the electrical conductivity of the contact piece 3 ,

In the in 2 illustrated embodiment of the invention is for this purpose a high-resistance intermediate layer 7 provided, which is essentially the entire bottom 4 of the contact piece 3 covered and made of metal graphite (metal-C). In other words, there is a current flow from the contact piece 3 to the contact carrier 2 only through this intermediate layer 7 possible.

Is on the contact piece 3 switched, the total resistance of the arrangement by the Engewiderstand R of the contact piece 3 dominated. The Engewiderstand is through R = ρ / 2r0 where ρ is the resistivity and r _{0 is} the contact surface radius.

The resistance of the intermediate layer 71 is only in the form R = ρ · L / A where L is the thickness and A is the cross-sectional area of the intermediate layer 7 designated.

The ratio 1 / 2r ₀ to L / A is in the order of magnitude> 100: 1 for realistic contact arrangements. This ensures that the high-resistance intermediate layer 7 the proper operation of the switching contact 1 does not bother.

If, however, by frequent switching the contact piece 3 almost used up, so is on the interlayer 7 connected. The total resistance of the assembly is then determined by the resistance of the intermediate layer 7 certainly. Is the specific resistance of the intermediate layer 7 to z. For example, the factor 10 above that of the contact piece 3 , as an approximation (assuming comparable hardness) follows by a factor 10 higher total resistance. This results in contrast to the ignition of an arc as a result of unsafe contact with applied flow in the proposed solution only increased by an order of magnitude increase in performance. The associated rather moderate transient temperature increase can be detected much easier and safer than the rapid rise in temperature in the contact zone caused by an arc. For different hardnesses of the materials used for contact piece 3 and intermediate layer 7 is to be taken into account that this would result in the result differently sized contact surfaces, whereby the Engewiderstand and the temperature behavior would be influenced.

In 3 a further embodiment of the invention is shown. Instead of an intermediate layer 7 are several in or on the bottom 4 of the contact piece 3 spaced apart spacers 8th provided such that these erosion of the contact piece 3 be exposed for the purpose of a targeted contact pollution. The intermediate pieces 8th , which are preferably made of graphite, are formed pin-shaped in the embodiment shown here and lie in the connecting plane between contact piece 3 and solder / weld layer 6 , Instead of a cylindrical shape, the intermediate pieces 8th but also have a different geometric shape, for example, they may be spherical or shaped like beams. Important for the shape of the spacers 8th it is that these are exposed by the Schaltabbrand.

The individual intermediate pieces 8th are preferably such over the contact piece 3 at least in good time before welding to contact with at least one of the intermediate pieces 8th comes. This is best done with a uniform distribution over the entire contact piece underside 4 reached. When the contact material is used up, the intermediate pieces automatically become 8th exposed.

Instead of graphite or graphite materials, other materials for the spacers 8th or the intermediate layer 7 are used, for example tungsten or metal oxides.

The switching contact according to the invention 1 is preferably used in switch contact arrangements which provide a determination of the end of life of the switch contacts. The working principle of such arrangements, for example, on the Be mood of the resistance of the switching contact 1 based. For this purpose, it is preferable to monitor the resistance via two closed switch contacts 1 with the help of a parallel to the switch contacts 1 arranged measuring circuit. The detected resistance is then compared with a predetermined limit resistance value. If this is exceeded, a lifetime end signal is output according to the invention. As an alternative or in addition to the detection of electrical quantities, it is provided according to the present invention, a temperature detection element, for example a temperature sensor in the form of a thermocouple in the vicinity of the switching contact 1 to monitor the temperature in the contact area.

Will the resistance difference between contact piece 3 and intermediate layer 7 not chosen too large, so there is a low temperature gradient along the contact carrier 2 , Advantageously, thereby the temperature sensing element can be placed further away from the contact point. The influence of overload and short-circuit shutdowns is reduced. The exceeding of a critical limit temperature in the contact region takes place later, so that a higher temperature rise is observed at a greater distance from the contact point. The distinction between normal switching load and the approach to the end of life is well differentiable.

A switching device 9 with an arrangement 10 for determining the end of life of switching contacts 1 is schematic in 4 displayed. Used in monitoring the temperature by temperature sensing elements 11 in the contact area of the switching contact 1 found that the current temperature in the arrangement 10 stored preset limit temperature value, then according to the invention, a end-of-life signal is output. This signal can be used, for example, to activate an optical display 12 be used. However, it is particularly advantageous if the end of life signal is used to the switching device 9 in which the relevant switching contact 1 located by means of an ON / OFF switch 14 automatically to a safe off state. So can malfunctions of the switching device 9 especially safe to avoid.

The temperature sensing element 11 is preferably not directly at the contact point 13 of the switching contact 1 arranged. It is particularly advantageous if the temperature sensing element 11 embedded in a plastic sheath or the like and from the contact carrier 2 is shielded so that it can not come into direct contact with a possibly occurring switching arc. This will avoid the temperature sensing element 11 is destroyed by the switching arc. The distance between the contact point 13 and the temperature sensing element 11 is usually a few millimeters.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited non-patent literature

• - EN 60947-4-1 [0002]
• - EN 60947-2 [0003]

Claims (10)

Switching contact ( 1 ) for an electromechanical switching device ( 9 ) or the like, with an electrically conductive contact carrier ( 2 ) and one on the contact carrier ( 2 ) arranged electrically conductive contact piece ( 3 ), characterized in that between the contact piece ( 3 ) and the contact carrier ( 2 ) at least one weld-resistant intermediate element ( 7 . 8th ) is arranged, whose electrical conductivity is lower than the electrical conductivity of the contact piece ( 3 ). Switching contact ( 1 ) according to claim 1, characterized in that the electrical conductivity of the intermediate element ( 7 . 8th ) by an order of magnitude above that of the contact piece ( 3 ) lies. Switching contact ( 1 ) according to claim 1 or 2, characterized in that the intermediate element ( 7 . 8th ) consists of graphite or a graphite material. Switching contact ( 1 ) according to one of claims 1 to 3, characterized by several in or on the underside ( 4 ) of the contact piece ( 3 ) spaced apart spacers ( 8th ) such that these erosion of the switching piece ( 3 ) are exposed for the purpose of targeted contact contamination. Switching contact ( 1 ) according to one of claims 1 to 4, characterized in that the intermediate element has a substantially the entire underside ( 4 ) of the contact piece ( 3 ) covering intermediate layer ( 7 ). Use of a switching contact ( 1 ) according to one of claims 1 to 5 in an arrangement ( 10 ) for determining the end of life of switching contacts. Method for determining the end of life of a switching contact according to one of Claims 1 to 5, comprising the steps of: monitoring the temperature in the contact region of the switching contact ( 1 ), - comparing the detected temperature with a predetermined limit temperature value and - outputting a end-of-life signal when the limit temperature value is exceeded. Method for determining the end of life of a switching contact according to one of Claims 1 to 5, comprising the steps of: - monitoring the resistance of the switching contact ( 1 ), - comparing the detected resistance with a predetermined limit resistance value and - outputting a end-of-life signal when the limit resistance value is exceeded. Arrangement ( 10 ) for determining the end of life of a switching contact ( 1 ) according to one of claims 1 to 5, with an element ( 11 ) for detecting the temperature in the contact region of the switching contact ( 1 ). Arrangement ( 10 ) according to claim 9, characterized in that the temperature sensing element ( 11 ) not directly at the contact point ( 13 ) of the switching contact ( 1 ) is arranged.