The present invention relates to a support assembly for a micro-switch, in particular for a rotative micro-switch acting as auxiliary contact of a switching device.

It is known the use of a micro- switch acting as auxiliary contact within a switchgear and whose function is to monitor, to indicate and to control closing/opening manoeuvres of a circuit breaker. Such a micro-switch is of the linear type, i.e. operates according to a linear working principle. In other words, an operating- shaft of the micro-switch is linearly moved by a driving-mechanism in determined operating conditions, such as a fault or other particular events. Although such a micro-switch performs in a quite satisfying way, it would be desirable and advantageous, for some configurations of switching device/switchgear installations which will be get diffused in the future, to make use of a rotative micro-switch for the auxiliary-contact-function, where such a rotative micro- switch comprises a rotary shaft operating according to a rotative working principle. However, due to high performance of the circuit breaker, in particular due to sudden and rapid closing/opening electrical manoeuvres, such a rotary shaft receives high driving forces and undergoes severe stress even greater than in the case of a linear micro-switch shaft. Therefore, it would be desirable making possible to take advantage of a rotative micro-switch while at the same time preventing any possible damage of the respective rotary shaft due to high driving forces exerted by a lever-mechanism, in particular by providing a technical solution which is at the same time cheap and simple.

This is achieved by a support assembly as defined in the appended claims and described hereinafter in details, which is able to overcome the abovementioned drawback.

The present disclosure encompasses also an auxiliary rotative micro-switch comprising the support assembly, a switching device, in particular a circuit breaker, comprising said auxiliary rotative micro-switch and a switchgear, equivalently called with the term panel or cabinet or switchboard, including the support assembly. Characteristics and advantages of the present disclosure will result from the description and from claims.

The present disclosure can be better understood and implemented with reference to the attached drawings that illustrate an embodiment thereof by way of a non-limiting example, in which:

Figure 1 is a fragmentary perspective view of a switching device provided with a rotative micro-switch which is connected to a support-assembly according to the invention;

Figure 2 is an exploded view of the support assembly associated to the micro-switch of Figure 1; Figures 3, 4, 5 show, according to different perspective views, a part of bracket-support- means included in the support assembly;

Figures 6 and 7 are different views of a lever for the micro-switch shaft provided with coupling-protrusion-means included in the support assembly;

Figures 8, 9, 10 show, according to different perspective views, a further part of bracket- support- means included in the support assembly;

Figures 11 and 12 show the micro-switch and the support-assembly in an assembled configuration and in a first operative position;

Figures 13 and 14 show the mutually assembled micro-switch and support-assembly in a second operative position.

With reference to the attached Figures, a support assembly 1 is shown which is suitable for a micro-switch 2, in particular a rotative micro-switch 2 of a switching device, such as a circuit breaker 3, housed within a medium voltage switchgear. For the purposes of the present application, the term medium voltage refers to applications in the range from IkV up to some tens of kV, e.g. 36 kV.

The micro- switch 2 has an auxiliary contact function and acts for monitoring, for indicating/signalling an operating status of the circuit breaker 3 (for example an overcurrent or a short circuit condition), and for controlling the latter, i.e. to enable/disable an electrical closing/opening procedure thereof.

The micro-switch 2 comprises a rotary operating shaft 8 which is configured for operating according to a rotary working principle. In other words, the rotary operating shaft 8 is rotatable between two angular positions in order to put the micro-switch 2 in an electrical closed and open position respectively in concomitance of determined operating conditions, such as a fault, a short circuit or other particular events.

The rotary operating shaft 8 is rotatable, around a rotation-axis 9, through a lever 14 which in turn is moved by a driving mechanism 30 (Figure 1).

The support-assembly 1 described in the following is configured for protecting and preserving the rotary operating shaft 8 from possible damages, in particular during operation of the circuit breaker 3 in a mechanical type test.

The support-assembly 1 comprises bracket-support-means 4, described in detail in the following, which are suitable for being connected, in a stationary position, to a frame portion 5 of the switching device, in this exemplary and not limitative case, the circuit breaker 3. The support-assembly 1 further comprises coupling-protrusion-means 6 which, in an assembled operating configuration, are positioned at a free end 7 of the rotary operating-shaft 8 of the micro-switch 2 and which are adapted for movably engaging with the bracket-support-means 4. The bracket-support-means 4 and the coupling-protrusion- means 6 are described in detail in the following. The bracket-support-means 4 are adapted for enabling a pivotal-movement of the coupling-protrusion-means 6, and thus of the rotary shaft 8, around the rotation-axis 9 and for preventing a movement of the coupling- protrusion-means 6, and therefore of the rotary shaft 8, transversely to the rotation-axis 9. The coupling-protrusion-means 6 of the support-assembly 1 are obtained on a connecting- portion 15 of the lever 14. In the exemplary and not limitative version shown in the Figures, the coupling-protrusion-means 6 are an integral part of the connecting-portion 15. In other words, the coupling-protrusion-means 6 are integral with the lever 14, i.e. they are directly obtained by pressing or moulding the lever 14, or are obtained by tooling, e.g. by chip-forming-machining the lever 14. On the connecting portion 15 a fitting opening 18 is obtained for the connection to the end 7 of the rotary shaft 8, having for example a square cross-section. In a further possible version, the lever 14 together with the coupling- protrusion-means 6 are integral with the rotary shaft 8 thus defining a single-piece-element suitable for being assembled to, and inserted in the micro-switch 2.

In a further possible embodiment of the support assembly, the coupling-protrusion-means 6 can be configured as separated elements to be fixed to the connecting portion 15 of a known lever 14, in order to achieve the pivotal coupling with the bracket support means 4. In the exemplary and not limitative version here shown and described, the coupling- protrusion-means 6 comprise a first coupling-portion 12 and a second coupling-portion 13, provided at opposite sides on the connecting-portion 15 of the lever 14, and the bracket- support- means 4 include a first-bracket-element 10 and a second bracket-element 11 adapted for engaging with the first coupling-portion 12 and with the second coupling- portion 13, respectively.

In particular, the first coupling-portion 12 and the second coupling-portion 13 protrude from the connecting-portion 15 in opposite directions, with a cylindrical shape, and are adapted for pivotally coupling with a first seat-opening 16 and with a second seat-opening 17 respectively obtained on the first bracket element portion 10 and on the second bracket element portion 11. The first bracket-element 10 comprises a bent- shaped-plate element including a base-portion 19 intended to be applied to the frame portion 5.

The second bracket-element 11 comprises a fixing-portion 20 adapted for being fixed on the first bracket-element 10, and a stop-protrusion 21 configured for limiting a rotation movement of the lever 14 which, as it can be seen in Figures 11 to 14, is rotatable between two angular positions.

The first coupling-portion 12 and the second coupling-portion 13 have an external diameter 24, which can be the same or alternatively different from one other, but which is less than a width-dimension 22 of the connecting portion 15; the width-dimension 22 is measured transversely to the rotation-axis 9 in the assembled configuration of the support-assembly 1.

The first seat-opening 16 and the second seat-opening 17 are shaped as through-openings having a diameter 23 which is less than the width-dimension 22 of the connecting-portion 15, and which is chosen for adapting to the external diameter 24 of the respective first coupling portion 12 and second coupling portion 13.

Owing to the above described structural configuration, in particular owing to the engagement of the first coupling-protrusion 12 and of the second coupling-protrusion 13 with the first seat-opening 16 and the second seat-opening 17 respectively of the first bracket element 10 and second bracket element 11, any movement of the shaft end 7 transversely to the rotation axis 9 is prevented. This means that any possible flexure and bending stress on the shaft 8, due to vigorous and sudden action by the driving-linking- mechanism 30, is avoided, thus preserving the shaft from damages such as fatigue-break. Furthermore, the first bracket element 10 and the second bracket element 11 prevent, from respective opposite sides, a movement of the connecting portion 22 of the lever 14 parallel to the rotation axis 9. In conclusion, only a pivotal movement of the lever 14, and thus of the rotary shaft 8 around the rotation axis 9 is allowed.

The support-assembly 1 allows the rotary shaft 8 to be pivotally driven in a safety mode. In other words, the movement of the rotary shaft 8 has only an angular component, while normal forces that may damage the shaft are compensated by the support-assembly 1. The high forces exerted on the lever 14 are taken by the bearing support-assembly 1, due to its structural configuration, while the rotary shaft 8 is safely moved with no mechanical problems.

Owing to the support assembly 1, all standard requirements are complied, and mechanical strength tests on rotative micro-switches connected to circuit breaker are successfully passed. The rotative micro-switch 2, owing to the support assembly 1, is thus in conditions to lastingly operate in a correct, precise and reliable way. A correct positioning of the rotary shaft 8, and thus a precise closing/opening operation of the micro-switch 2, is ensured.

It has been described how any switching manoeuvres are reliably performed by using a micro-switch 2 of the rotary type owing to the support-assembly 1 according to the invention, which is a technical solution at the same time cheap and simple.

The support-assembly 1 is susceptible of modifications or variations all within the scope of the inventive concept as defined by the appended claims and the described embodiment; any details may be replaced with technically equivalent elements.

One or more of the elements above described may be differently shaped and/or positioned, can be realized in one or more pieces or differently coupled or positioned, etcetera.

In practice, the materials, so long as they are compatible with the specific use, as well as the individual components, may be any according to the requirements and the state of the art.