GB2353409A - Improvements in electrical contacts - Google Patents

Abstract

An electrical switch arrangement comprises first and second contact arms 10, 30. Each contact arm comprises a terminal portion 12, 32 and a contact portion 14, 34 connected by respective intermediate portions 16, 36. Each contact portion 14, 34 carries two contact members 20, 22, 40, 42 and are disposed such that the contact members 20, 22 of the fixed contact arm 10 align with the contact members 40, 42 of the moving contact arm 30. The contact portion 34 of the moving contact arm 30 comprises a bifurcated element 38, each part of the bifurcated element 38 carrying one of the contact members 40, 42. The separation force between each contact member is effectively a quarter that of a single contact arrangement resulting in a halving of the total separation force and the contact resistance and heat generated are effectively halved.

Description

2353409 IMPROVEMENTS IN OR RELATING TO ELECTRICAL SWITCBES The present

invention relates to improvements in or relating to electrical switches, and is more particularly, although not exclusively, concerned with electrical switches or switch modules used in electricity meters.

In switch modules which are used in electricity meters, there is an undesirably high contact resistance that contributes to excessively high temperatures inside the meter casing during long-term high current flow.

This is a particular problem in three-phase switch modules.

Additionally, the contacts of the switch have a tendency to weld together during high over-current tests, such as a 3kA rms half sine wave test - a standard test for the industry.

It is therefore an object of the present invention to provide a contact arrangement which overcomes the problems described above.

It is another object of the present invention to provide a switch module which overcomes the problems described above.

In accordance with one aspect of the present invention, there is provided a method of operating a switch arrangement comprising first and second contact elements connected to respective first and second conductors, one contact element comprising a bifurcated element carrying two contact members at its bifurcated end, the method comprising arranging one contact element such that electric current flowing through its associated conductor relative to an adjacent conductor enhances the contact force with the other contact element.

In accordance with another aspect of the present invention, there is provided a contact arrangement comprising:- a first terminal; a second terminal; a first conductor connected to the first terminal; a second conductor connected to the second terminal; and a switch arrangement located between the first and second terminals, the switch arrangement comprising first and second contact elements connected to respective ones of the first and second conductors; characterised in that one contact element is arranged such that electric current flowing through its associated conductor relative to an adjacent conductor enhances the contact force with the other contact element; and in that the one contact element comprises a bifurcated element carrying two contact members at its bifurcated end.

Preferably, the associated conductor comprises a generally U-shaped member having substantially parallel arms, one arm carrying said one contact element and the other arm remote from the contact element comprising the adjacent conductor.

It is preferred that the first terminal is connected to the first contact element with the first terminal lying in a first plane and the contact members carried by the first contact element lying in a second plane, the second plane being substantially orthogonal to the first plane. Additionally, the second terminal may be connected to the second contact element with the second terminal lying in a first plane and the contact members carried by the second contact element lying in a second plane, the second plane being substantially orthogonal to the first plane.

The first terminal may comprise an input terminal and the second terminal comprises an output terminal. Alternatively, the second terminal may comprise the input terminal and the first terminal the output terminal.

In accordance with a further aspect of the present invention, there is provided a switch module comprising a contact arrangement as described above.

There is also provided a three-phase switch module which comprises 5 three contact arrangements as described above.

In accordance with still a further aspect of the present invention, there is provided an electricity meter comprising a switch module as described above.

For a better understanding of the present invention, reference will now be made, by way of example only, to the accompanying drawings in which:Figure I illustrates a first contact arrangement for a switch in accordance with the present invention; Figure 2 illustrates a second contact arrangement for a switch in accordance with the present invention; Figure 3 illustrates another view of the second contact arrangement of Figure 2; and Figure 4 illustrates the relationship between first and second contact arrangements of Figures I to 3 in the switch arrangement in accordance with the present invention.

The present invention will be described with reference to a contact arrangement for a three-phase switch module of an electricity meter. However, for simplicity, one contact arrangement will be described and illustrated, but it will be appreciated that three substantially identical contact arrangements are utilised in a three-phase switch module. Moreover, the present invention is not limited to a three-phase application and can be implemented in other applications.

It has been found that contact welding occurs where a separation of contacts by a mutually repulsive force generated at the contact interface by necking' of the current paths as they pass through a restricted contact area.

This repulsive force is proportional to the product of the currents and can be expressed as F = 0.51112N, where 1, and,2are the currents in kA. However, where the currents are substantially equal, this becomes F = 0.51' N.

For an rms current of 3kA, with a peak current of 4.242kA, the peak repulsive force produced is approximately 9N. This is a significant force in relation to normal levels of initial contact pressure.

Turning now to Figure I of the drawings, a first contact arm 10 is shown. The arm 10 has a terminal portion 12, a contact portion 14 and an intermediate portion 16 connecting the terminal portion 12 to the contact portion 14. In this particular embodiment, the first contact arm 10 is fixed within a housing (not shown) and the terminal portion 12 lies in a first plane and the contact portion 14 lies in a second plane which is substantially orthogonal to the first plane. The intermediate portion 16 comprises a first portion 16a which lies in the first plane enabling connection with the terminal portion 12 and a second portion 16b which lies in the second plane enabling connection with the contact portion 14. The intermediate portion also comprises a third portion 16c which connects the first portion 16a to the second portion 16b, the third portion 16c providing the transition between the first plane and the second plane.

Portion 16b also includes a measurement portion 18 via which the voltage appearing on the contact arm 10 can be measured, the measurement portion 18 making contact with a spring element connected to a printed circuit board (not shown) in a switch module.

It will readily be appreciated that, although the intermediate portion 16 is shown as comprising three portions 16a, 16b, 16c, it may be of any convenient shape according to the particular switch module arrangement.

The terminal portion 12 provides connection with an electricity supply (not shown) either as an input terminal or an output terminal. Contact portion 14 comprises two contact members 20, 22 which are spaced apart by a predetermined distance as shown.

Figures 2 and 3 illustrate a second contact arm 30 which cooperates with the first contact arm 10 to provide a switching mechanism. The second contact arm 30 comprises a terminal portion 32, a moving contact portion 34 and an intermediate portion 36, the contact portion 34 being more clearly seen in Figure 3. As before, terminal portion 32 provides connection with an electricity supply (not shown) either as an input terminal or an output terminal.

The terminal portion 32 lies in the first plane and the contact portion 34 lies in the second plane with the intermediate portion 36 comprising a first portion 36a, a second portion 36b and a third portion 36c. The first portion 36a lies in the first plane enabling connection with the terminal portion 32, the second portion 36b lies in the second plane enabling connection with the contact portion 34, and the third portion 36c connects the first portion 36a to the second portion 36b providing the transition between the first plane and the second plane. Second portion 36b comprises a first part 36b,, a second part 302parallel to but spaced from the first part 36b, and a third part 36b3 connecting the first part 36b, to the second part 36b2. Whilst it will be appreciated that the same current flows throughout the second portion 36b, it will be noted that the current in the first part 36b, is in the opposite direction to that flowing in the second part 302 and hence in the contact portion 34.

As before, it will readily be appreciated that, although the intermediate portion 36 is shown as comprising three portions 36a, 36b, 36c, it may be of any convenient shape according to the particular switch module arrangement.

Contact portion 34 comprises a bifurcated element 38 having a first end 38a which is connected to part 36b2of portion 36b of the intermediate portion 36, and a second end 38b having two portions 38b, and 38b2, Portions 3 8b, and 3 8b2carry respective contact members 40, 42 as is shown more clearly in Figure 3. As element 38 is bifurcated, it provides two current paths at its second end 38b and therefore halves the amount of current carTied by each contact member 40, 42.

Turning to Figure 4, an assembly 50 is shown which comprises first contact arm 10 and second contact arm 30 in an operative position. Contact members 20, 22 carried by contact portion 14 of first contact arm 10 are aligned with contact members 40, 42 carried by bifurcated element 3 8 of second contact arm 30 in the second plane and with terminal portions 12, 32 lying adjacent one another in the first plane. It will be understood that one terminal portion 12 may fonn the input terminal for the switch module whilst the other terminal portion 32 forms the output terminal. Alternatively, the terminal portion 32 may comprise the input terminal with the terminal portion 12 forming the output terminal. The choice of which terminal portion 12, 32 forms the input and output terminals depends on the particular arrangement of the switch module and the application in which it is to be employed.

It will be appreciated that, in the assembled three-phase switch module, there will be three assemblies 50, one for each phase. Each assembly 50 lies parallel and spaced apart from adjacent assembly(ies) 50. It will also be appreciated that means (not shown) will be provided to effect movement of the bifurcated element 38 attached to each second contact arm 3 0 relative to a respective one of first contact arms 10 to make and break connection between respective pairs 20, 40 and 22, 42 of the contact members 20,22,40,42.

In one embodiment, a bifurcated leaf spring (not shown) provides basic contact pressure on the bifurcated element 38 due to each arm of the leaf spring pressing on the back of respective parts 38b, and 38b2 thereof By having a double parallel contact arrangement as described above, it will be appreciated that the separation force of 9N discussed above will be reduced for each contact pairing as the current is shared between the two contact pairings. This means that as the current is halved for each contact pairing, the separation force is then effectively a quarter of the separation force for a single contact pairing as discussed above as the current is the same in parts 36b, and 36b2. This arrangement will also produce half the resistance of a single contact and half the heat for a given current level when compared to a single contact arrangement.

The electromagnetic forces generated between conductors comprising a switch as described above and the connections to the switch may be useful in maintaining contact pressure. The direction of the force in relation to the contact pressure depends on the configuration of the contacts and conductor loops. In the embodiment described above, the conductor arrangement increases contact pressure under current flow. The force generated between two conductors carrying the same current is proportional to the square of the current and therefore this force can be beneficial in withstanding high current tests.

Another advantage of using parallel contacts is that, when breaking current flow, one contact pair becomes sacrificial with respect to the other.

This occurs because one contact will always open last and will therefore bear the effects of the resulting arc, while the contact which opens first is largely protected from the effects of the arc.

Although the second contact arm 30 has been described as carrying the bifurcated element 38 to substantially reduce the separation forces and contact resistance, it will be appreciated that, in an alternative embodiment, the bifurcated element 38 may be carried by the first contact arm. Moreover, it may be possible, for a particular switch arrangement, that both the first and second contact arms have bifurcated elements which carry the contact members.

Although the switch arrangement according to the present invention has been described with reference to a three-phase electricity supply, it will readily be appreciated that the same switch assembly can also be applied to single-phase electricity supplies.

Claims (12)

CLAIMS:

1. A method of operating a switch arrangement comprising first and second contact elements connected to respective first and second conductors wherein one contact element comprises a bifurcated element carrying two contact members at its bifurcated end, the method comprising arranging one contact element such that electrical current flowing through its associated conductor relative to an adjacent conductor enhances the contact force with the other contact element.

2. A method according to claim 1, wherein the associated conductor comprises a generally U-shaped member having substantially parallel arms, one arm carrying the contact element and the other arm remote from the contact element comprising the adjacent conductor.

3. A contact arrangement comprising:- a first terminal; a second terminal; a first conductor connected to the first terminal; a second conductor connected to the second terminal; and a switch arrangement located between the first and second terniinals, the switch arrangement comprising first and second contact elements connected to respective ones of the first and second conductors; characterised in that one contact element is arranged such that electrical current flowing through its associated conductor in relation to an adjacent conductor enhances the contact force with the other contact element; and in that the one contact element comprises a bifurcated element carrying two contact members at its bifurcated end.

4. A contact arrangement according to claim 3, wherein the associated conductor comprises a generally U-shaped member having substantially parallel arms, one arm carrying said one contact element and the other arm remote from the contact element comprising the adjacent conductor.

5. A contact arrangement according to claim 3 or 4, wherein the first terminal is connected to the first contact element with the first terminal lying in a first plane and the contact members carried by the first contact element lying in a second plane, the second plane being substantially orthogonal to the first plane.

6. A contact arrangement according to any one of the claims 3 to 5, wherein the second terminal is connected to the second contact element with the second terminal lying in a first plane and the contact members carried by the second contact element lying in a second plane, the second plane being substantially orthogonal to the first plane.

7. A contact arrangement according to any one of claims 3 to 6, wherein the first terminal comprises an input terminal and the second terminal comprises an output terminal.

8. A contact arrangement according to any one of claims 3 to 7, wherein the second terminal comprises an input terminal and the first terminal compnses an output terminal.

9. A switch module comprising a contact arrange ment according to any one of claims 3 to 8.

10. A three-phase switch module comprising three contact arrangements according to any one of claims 3 to 8.

11. An electricity meter comprising a switch module according to claim 9 or 10.

12. A contact arrangement substantially as hereinbefore described with reference to the accompanying drawings.