AU2016392770A1 - A button operated circuit breaker with rocking control member - Google Patents

Abstract

1. A push button operated circuit breaker (10) with rocking control member including: a case (20) made of electrically insulating material, having a bottom wall (21), lateral walls (20a, 20b, 20c, 20d) being joined to the bottom wall (21) and an open side (21') opposite to the bottom wall (21); a button (30) that can be operated to command an electrical switching of the circuit breaker (10) and having a body provided with lateral walls (30a, 30b, 30c, 30d) crossing said open side (21'), the push button (10) being adapted to slide with respect to the case (20) along a sliding axis (Z- Z), between a forward position and a backward position; a rocking control member (70) adapted to control an electrical switching; a pressure transmitting member (60) being rotatably fastened to the body of the push button (30) and adapted to rotate with respect to a rest angular position around a rotation axis (Al-Al); an elastic element (61) adapted to bring back the pressure transmitting member (60) in the rest angular position after its rotation; characterized in that the above-mentioned elastic element is, or includes, a wire spring (61).

Description

FIELD OF THE INVENTION [0001] The present description refers to the technical field of the electrical installations and, more particularly, it concerns a push button operated circuit breaker with rocking control member.

STATE OF THE ART [0002] Push button operated circuit breakers are known wherein the control of the electrical switching occurs by means of a rocking control member.

[0003]European patent EP1584096 discloses a push button operated circuit breaker including a supporting structure made of insulating material, or case, having the shape of a box and defining a recessed compartment for housing and for supporting the electromechanical components being part of the circuit breaker. The case has an open side. The circuit breaker also includes a push button slidingly coupled to the case by means of guide elements in order to close the open side. The mechanical coupling between the push button and the case allows a relative and guided sliding of the push button with respect to the case along a sliding axis. Such sliding is necessary to command by means of the push button an electrical switching of the

WO 2017/141091

PCT/IB2016/057866 circuit breaker. A pressure of the push button determines an advancement of the push button with respect to the case. A release of the push button determines a backward movement of the push button with respect to the case. The push button therefore moves between a forward position and a backward position, that represent two opposite stopping positions of the push button. The push button is coupled to a rotatable pressure transmitting member and the circuit breaker includes a rocking control member that controls the the switching. The pressure transmitting member is adapted to rotate into two opposite directions starting from an angular resting position and the push button includes at least an elastic element adapted to bring the pressure transmitting member back to the angular resting position after one rotation. The elastic element is for example implemented by means of one or more foil springs, for example made of metal foil, folded and sheared off. By pushing the push button, the rotatable pressure transmitting member contacts the rocking control member in order to make it rotate. This rotation, in its turn, is such that it moves a mobile contact element in order to determine an electrical switching.

[0004] In the prior art push button operated circuit breakers, the aforesaid elastic element makes a stand

WO 2017/141091

PCT/IB2016/057866 during the pressure of the push button starting from a certain point on during the push button stroke, particularly when the pressure transmitting member contacts the rocking control member. Such resistance is due to the fact that the elastic elements opposes to the pressure transmitting member rotation. This resistance determines the user's feeling of lack of sliding fluidity while pushing the push button.

[0005] It is therefore felt the need for implementing a push button operated circuit breaker with a rocking control member being such as to reduce the resistance opposed by the elastic element associated to the push button pressure transmitting member.

[0006] The object of the present description is to make available a push button operated circuit breaker with rocking control member being such as to fulfil the above described need with reference to the prior art circuit breaker.

[0007] Such object is achieved through a push button operated circuit breaker with rocking control member as generally defined in claim 1. Preferred and advantageous embodiments of the aforesaid circuit breaker are defined in the enclosed dependent claims.

[0008] The invention shall be better understood from the hereinafter detailed description of particular

WO 2017/141091

PCT/IB2016/057866 embodiments given merely by way of example limited to, with reference to the enclosed briefly described in the following paragraph.

but not drawings

BRIEF DESCRIPTON OF THE DRAWINGS.

[0009] Figure 1 shows a perspective view of one embodiment of a push button operated circuit breaker with rocking control member including a case, a button slidingly constrained to the case and a key coupled to the push button.

[0010] Figure 2 shows a side view of the push button operated circuit breaker of Figure 1.

[0011] Figure 3 shows a further perspective view of the circuit breaker of Figure 1 from which the key has been removed.

[0012] Figure 4 shows a top view of the circuit breaker case of Figure 1 from which all the components contained inside the case have been removed.

[0013] Figure 5 shows a top view of the push button of the circuit breaker of Figure 1.

[0014] Figure 6 shows a perspective view from below of the push button of the circuit breaker of Figure 1.

[0015] Figure 7 shows a partial cross-section perspective view of the switch of Figure 1, from which the key and some of the components contained inside the case have

WO 2017/141091

PCT/IB2016/057866 been removed.

[0016] Figure 8 shows a perspective view of the case of the circuit breaker of Figure 1, wherein some of the components contained inside the case are visible.

[0017] Figure 9 shows a partial cross-section perspective view of an enlarged part of the circuit breaker of Figure

1.

[0018]Figure 10 shows a further partial cross-section perspective view of an enlarged part of the circuit breaker of Figure 1.

[0019]]Figure 11 shows a side view of the circuit breaker of Figure 1 from which the key has been removed.

[0020] Figure 12 shows a partial cross-section perspective view of the case of the circuit breaker of

Figure 1, wherein a supporting fulcrum inserted in the case is visible.

[0021]Figure 13 shows a partial cross-section side view of the case and of the supporting fulcrum of Figure 12.

[0022] Figure 14 shows a perspective view of the 20 supporting fulcrum of Figures 12 and 13.

[0023] Figure 15 shows a pressure transmitting member of the push button of the circuit breaker of Figure 1.

[0024] Figure 16 shows a further perspective view from

WO 2017/141091

PCT/IB2016/057866 above of the push button of the circuit breaker of Figure

1.

[0025] Figure 17 shows a perspective view of the supporting fulcrum, of the mobile contact holder support and of the fixed contact holder support.

[0026]Figure 18 shows a perspective view of the assembly of Figure 17 wherein it is also shown an elastic element, operatively coupled to the mobile contact holder support.

[0027] Figure 19 shows a perspective view of the assembly 10 of Figure 17 wherein a rocking control member is also shown.

[0028] Figure 20 shows a further perspective view of the assembly of Figure 19.

[0029] Figure 21 shows a perspective view or the rocking 15 control member of Figure 19.

DETAILED DESCRIPTION [0030]With reference to the enclosed figures, it will be now described a particular non-limiting embodiment of a push button operated circuit breaker 10 with rocking control member. By push button operated circuit breaker it is intended a circuit breaker operated manually through a push button in order to determine one, or at least one, electrical switching. Preferably, as in the illustrated example, the push button operated circuit

WO 2017/141091

PCT/IB2016/057866 breaker 10 is of modular type, that is destined to be mounted on a supporting frame for the wall installation beside other modular circuit breakers of the same type or in general other electrical modular appliances, as for example sockets. The circuit breaker 10 can be operated manually and can be used for example for controlling the electric power and/or the lighting in a residential or commercial building.

[0031] In the present description, by the term circuit breaker it is meant both a device for opening and closing a single electrical contact and a device for opening an electrical contact with the contemporary closing of another electrical contact and vice versa (diverter).

[0032] The push button operated switch 10 with rocking control member that, for ease of explanation, will be called in the present description also circuit breaker or push button circuit breaker, includes a supporting structure 20 made of electrically insulating material, e.g. plastic, preferably having, but not restrictively, approximatively the parallelepiped shape. The supporting structure 20, hereinafter called case, includes a bottom wall 21 and four lateral walls 20a, 20b, 20c, 20d joined to the bottom wall 21. The case 20 includes an open side 21' opposite to the bottom wall 21. The lateral walls 20a, 20b, 20c, 20d and the bottom wall 21 define a

WO 2017/141091

PCT/IB2016/057866 recessed compartment adapted for housing the electromechanical components of the circuit breaker 10 and at least two electrical connection terminals Cl, C2, C3. In the example shown in the Figures the recessed compartment of the case 20 houses, without any limitation, three electrical connecting terminals Cl, C2,

C3 .

[0033]Preferably, the bottom wall 21 is integrated in the case 20, however in an alternative embodiment the bottom wall 21 may be a piece separated from the lateral

walls 20a,	20b,	20c, 20d	of	the case 20 and	. coupled	to
them.
[0034]The	push	button	operated circuit	breaker	10
includes a	push	button	30,	being operated	manually	to

command an electrical switching of the circuit breaker 10, having a body provided with lateral walls 30a, 30b, 30c, 30d crossing the open side 21' of the case 20. The push button 10 is adapted to slide with respect to the case 20 along a sliding axis Z-Z and along a delimited space between a forward position and a backward position. For the purposes of the present description, by forward position it is meant an end of stroke position in the approaching movement of the push button 30 to the case 20, while by backward position it is intended an end of stroke position in the distancing movement of the push

WO 2017/141091

PCT/IB2016/057866 button 30 from the case 20. It is therefore clear that the terms forward and backward refer to the position of the push button 30 with respect to the case 20.

[0035] The push button operated circuit breaker 10 includes a guiding system adapted to guide the sliding of the push button 30 with respect to the case 20 along the sliding axis Z-Z.

[0036]Preferably, the guiding system is a system of spatially distributed guides including first guide elements 22, 32 operatively interposed between the lateral walls 20a, 20b, 20c, 20d of the case 20 and the lateral walls 30a, 30b, 30c, 30d of the body of the push button 30.

[0037]Preferably, the system of spatially distributed guides also includes second guide elements 23, 24, 33, 34 spaced apart with respect to the first guide elements 22, 32 and placed with respect to the first guide elements 22, 32 at a lower distance from the bottom wall 21 of the case 20. Most precisely, friction surfaces cooperating between them of the first guide elements 22,32, have a distance from the bottom wall 21 of the case 20 higher than the distance with respect to the bottom wall 21 of the case 20 of friction surfaces cooperating between them of the second guide elements 23,24,33,34.

[0038]According to one advantageous embodiment, the

WO 2017/141091

PCT/IB2016/057866 first guide elements 22, 32 include a first plurality of appendices 22 protruding from the lateral walls 20a, 20b,

20c, 20d of the case 20 towards the lateral walls 30a,

30b, 30c, 30d of the push button 30 and a second plurality of appendices 32 protruding from the lateral walls of the push button 30 towards the lateral walls 20a, 20b, 20c, 20d of the case 20 and each being adapted to contact a respective appendix 22 of the first plurality of appendix 22 in order to slide thereon when the push button 30 slides with respect to the case 20.

[0039] In the non-limiting exemplary embodiment shown in the Figures four appendices 22 protruding from the lateral walls 20a, 20b, 20c, 20d of the case 20 are provided as well as and four corresponding appendices 32 protruding from the lateral walls 30a, 30b, 30c, 30d of the push button 30.

[0040] According to one advantageous embodiment, the first plurality of appendices 22 and the second plurality of appendices 32 allow the lateral walls 30a, 30b, 30c,

30d of the push button 30 to be spaced from the lateral walls 20a, 20b, 20c, 20d of the case 20 when the push button 30 slides with respect to the case 20. Thereby, in fact, the push button operated circuit breaker 10 is less vulnerable to an undesired dust or sand intrusion within the lateral walls 20a, 20b, 20c, 20d of the case 20 and

WO 2017/141091

PCT/IB2016/057866 lateral walls 30a, 30b, 30c, 30d of the push button 30 that would otherwise cause a jamming in a circuit breaker wherein, on the contrary, due to a wide overlapping between the lateral walls of the push button 30 and those of the case 20, there are wider friction surfaces.

[0041] According to one preferred embodiment, the aforesaid protruding appendices 22, 32 are linear appendices, which in the shown example extend linearly along axis that are parallel between them and parallel to the sliding axis Z-Z.

[0042] According to one preferred embodiment, the lateral walls of button 30 are parallel in twos and define edges 32', each of them being arranged by a pair of adjacent lateral walls 30a, 30b, 30c, 30d of button 30. Each appendix 32 of the second plurality of appendices is arranged on a corresponding edge 32'. Preferably, the edges 32' are bevelled.

[0043]According to one advantageous embodiment, the second guide elements 23, 24,33,34 are decentred with respect to the first guide elements 22, 32. In other words, the second guide elements 23, 24, 33, 34 are closer to some of the first guide elements 22, 32 and further from other first guide elements 22, 32.

[0044]Preferably, with reference to Figures 4, 6 and 7 the second guide elements 23, 24, 33, 34 include a guide

WO 2017/141091

PCT/IB2016/057866 seat 23 and a guide pin 33 having an end portion 34 slidable in the guide seat 23. In the non-limiting exemplary embodiment shown in the Figures, the guide pin extends from the body of the push button 30 towards the bottom wall 21 of the case 20 while the guide seat 23 is fixed to the bottom wall 21 of the case 20.

Preferably, the guide pin 33 is integrated in the push button 30 and protrudes from the body of the push button 30 towards the bottom wall 21 of the case 20. Preferably, the body of the push button 30 and the guide pin 33 form a single piece.

[0045] According to one advantageous embodiment, the aforesaid end portion 34 of the guide pin 33 has a crossshaped cross-section. By cross-shaped cross-section, it is intended a section on a plane that is perpendicular to the sliding axis Z-Z. In the particular embodiment shown in the Figures, the aforesaid cross-shaped cross-section includes a circular central part from which four arms originate forming a Greek cross.

[0046] According to one advantageous embodiment, the guide pin 33 does not interfere with the lateral walls 20a, 20b, 20c, 20d of the case 20 during the sliding movements of the push button 30 with respect to the case 20. In other words, the guide pin 33 is spaced apart from the lateral walls 20a, 20b, 20c, 20d of the case 20 so as

WO 2017/141091

PCT/IB2016/057866 to avoid having friction surfaces among the lateral walls of the case 20 and the guide pin 33 itself.

[0047]With reference to Figures 4 and 7, according to one embodiment the guide seat 23 includes four lateral walls 24 parallel in twos. Preferably, the lateral walls 24 of the guide seat 23 are separated from one another and joined to the bottom wall 21 of the case 20. In one alternative embodiment the guide seat 33 may be a continuous collar, having a quadrangular or circular section. In the particular example shown, the lateral walls 24 are integrated in the bottom walls 21 of the case 20, protruding from it towards the push button 30.

[0048] With reference to Figure 8 the push button operated circuit breaker 10 includes at least one elastic element 40 adapted to exert a pushing force on the push button 30 in order to bring back or keep the push button 30 in the backward position in absence of external forces. In the particular embodiment shown in Figure 8 the circuit breaker 10 includes two elastic elements 40 having the form of two coil springs 40. In particular, in the shown example, the circuit breaker 10 also includes a diaphragm 41 housed inside the case 20 and the elastic elements 40 are operatively inserted between the diaphragm 41 and the body of the push button 30, each having for example an end portion inserted in a

WO 2017/141091

PCT/IB2016/057866 correspondent recessed seat 39 provided in the body of the push button 30 (Figure 6) . Also in the diaphragm 41 recessed seats having the same function may be provided.

[0049]With reference to Figures 8-10, according to one embodiment, in order to stop the push button 30 in the backward position, the push button operated circuit breaker 10 includes a first stopping system including contact surfaces 251, 351 of the lateral walls of the case 20 and of the lateral walls of the push button 30 respectively, which are abutting to each other when the push button 30 is in the backward position. In one particularly advantageous embodiment, the first stopping system includes a button alignment system including alignment elements 250, 350 engaging with each other starting from a given point on during the sliding movement of the push button 30 from the forward position towards the backward position before reaching the backward position. Such alignment elements 250, 350 allow to progressively align the push button 30 with respect to a reference plane R_P (Figure 11) that is perpendicular to the sliding axis Z-Z.

[0050] According to one advantageous embodiment, the aforesaid alignment elements 250, 350 include at least a variable cross-section guide 250, and a corresponding variable cross-section slider 350 adapted to be inserted

WO 2017/141091

PCT/IB2016/057866 inside the variable cross-section guide 250, starting from a given point on during the motion of the push button 30 before reaching the backward position and up until reaching it. Preferably the variable cross-section guide 250 is a tapered guide, having a decreasing crosssection in the direction towards the reference plane R_P) . In this case, for example, the variable crosssection slider 350 is wedge-shaped.

[0051] According to one advantageous embodiment, in order to further increase the precision of the alignment of the push button 30 with respect to the reference plane R_P and to guarantee a better coupling between the push button 30 and the case 20, the contact surfaces 251 and

351 are surfaces that, in the backward position of the push button 30, lie on a plane I_P inclined with respect to the reference plane R_P.

[0052] According to one particularly advantageous embodiment, the circuit breaker 10 includes complementary snap-fit coupling elements 25, 35 provided on the lateral walls of the case 20 and on the lateral walls of the body of the push button 30. The above said snap-fit coupling elements 25 are shaped in order to ease a forced insertion of the body of the push button 30 through the open side 21' of the case 20 in the assembling phase of the push button-case assembly and, once they pass a

WO 2017/141091

PCT/IB2016/057866 snapping position, to make interlocking snap fit coupling between the push button 30 and the case 20, based on which the push button 30 is slidingly constrained to the case 20.

[0053] In the particular example represented in the Figures, without limitation, said snap-fit coupling elements 25, 35 include four snap-fit coupling teeth 25 on the lateral walls of the case 20 and four complementary snap-fit coupling teeth 35 arranged on the lateral walls of the body of the push button 30. Preferably the snap-fit coupling teeth 25, 35 are arranged at the corners of a rectangular or square lying on a plane that is perpendicular to the sliding axis Z-Z.

[0054] According embodiment, the to one particularly advantageous coupling above described snap-fit elements 25, 35 carry the above described alignment elements 250, 350 and preferably the above described contact surfaces 251, 351 too.

[0055] According to one preferred embodiment, in order to stop the push button 20 in the forward position, the push button operated circuit breaker 10 includes a second stopping system including contact elements 26, 36 respectively provided on the lateral walls of the case 20 and on the lateral walls of the body of the push button 30. In the particular example shown, the aforesaid

WO 2017/141091

PCT/IB2016/057866 contact elements 26, 36 include two small blocks 36 protruding from opposite walls 30b, 30d of the push button body 30 and stopping seats 26 provided on two opposite lateral walls 20b, 20d of the case 20.

[0056] According to one embodiment, the push button operated switch 10 includes a supporting fulcrum 50 housed inside the case 20. As known, in a circuit breaker a supporting fulcrum 50 serves as a supporting means for a mobile electrically conductive switching member, being in particular rotatable, carrying at least a mobile electrical contact element. The aforesaid mobile electrically conductive switching member will be called in the present description rotatable contact holder support. The supporting fulcrum 50 is for example made of metal foil folded and sheared off.

[0057] According to one advantageous embodiment, in order to guarantee a stable fixing of the supporting fulcrum 50 to the case 20, the case 20 includes a housing seat 27 of the supporting fulcrum 50 and the push button operated circuit breaker 10 includes a snap-fit coupling system adapted to fix the supporting fulcrum 50 to the case 20 in the housing seat 27. Preferably, the housing seat 27 is arranged inside the case 20 on the bottom wall 21 and the snap-fit coupling system includes at least a coupling elastic tooth 28 adapted to hook the supporting fulcrum

WO 2017/141091

PCT/IB2016/057866 to the bottom wall 21 of the case 20. Preferably the aforesaid coupling elastic tooth 28 is integrated in the bottom wall 21 of the case 20 and forms a single piece with the latter. In the example shown in the Figures, the snap-fit coupling system includes a plurality of coupling elastic teeth 28, in particular three coupling elastic teeth 28.

[0058] According to one advantageous embodiment allowing to simplify the manufacturing of the case 20, beneath the coupling elastic tooth 28, the bottom wall 21 of the case 20 has a pass-through opening 28'. Thereby, it is usefully avoided having to mould in the bottom wall 21 of the case 20 undercut opposite surfaces.

[0059] According to one preferred embodiment, the coupling elastic tooth 28 has a free end portion and an opposite end fastened to the bottom wall 21 of the case 20 and the free end portion is such that it engages with a peripheral portion of the supporting fulcrum 50.

[0060] According to one advantageous embodiment, at least two snap-fit coupling teeth 28 are provided, arranged at opposite sides with respect to the supporting fulcrum 50.

[0061] According to one embodiment, the housing seat 27 of the supporting fulcrum 50 is a recessed seat implemented in the bottom wall 21 of the case. Preferably, the fulcrum 50 includes a support and contact

WO 2017/141091

PCT/IB2016/057866 portion 51 that is shaped so as to form a groove, for example having a V-shaped cross section, housed inside the recessed housing seat 27. Preferably, the support fulcrum 50 also includes a connecting portion 52, being part of a connecting terminal 50 of the circuit breaker 10. The connecting terminal Cl includes a screw 54 and a clamping plate 55, and the screw 54 crosses the connecting portion 53 of the supporting fulcrum 50 to engage with the clamping plate 55. According to one advantageous embodiment, between the support and contact portion 51 and the connecting portion 53, the supporting fulcrum 50 includes an intermediate portion 52 forming a connection inclined plane between the support and contact portion 51 and the connecting portion 53.

[0062] According to one particularly advantageous embodiment, the circuit breaker 10 also includes an anchoring system 59, 29 of the supporting fulcrum 50 to the case 20, in particular to the bottom wall 21 of the case 20. For example the anchoring system 59, 29 includes a folded little wing 59 integrated in the supporting fulcrum 50 and an anchoring seat 29 (visible in Figure 4) arranged inside the bottom wall 21 of the case 20 housing the folded little wing 59. This allows to stabilise the supporting fulcrum 50 position also with respect to the external stresses that affect for example the supporting

WO 2017/141091

PCT/IB2016/057866 fulcrum 50 during the wiring operations of the circuit breaker 10, for example caused by the clamping of the connecting terminal Cl.

[0063] Apart from the specific example shown in the drawings, more general or more specific embodiments have been so far described wherein the circuit breaker 10 is a generic push button operated circuit breaker.

[0064]Hereinafter some embodiments will be described wherein the circuit breaker 10 is a push button operated circuit breaker with a rocking mechanism. An embodiment of a push button operated circuit breaker with rocking mechanism is for example disclosed in the European patent EP1866944. Apart from the peculiar embodiment disclosed in such patent, it must be noted that by button operated circuit breaker with rocking mechanism it is to be intended in general a circuit breaker operated by a sliding button including a rocking element that controls the switching, hereinafter called, for ease of explanation, rocking control member.

[0065]With reference to Figures 3, 5, 6, according to one advantageous embodiment the push button 30 includes a pressure transmitting member 60 rotatably fastened to the body of the push button 30. The pressure transmitting member 60 is adapted to rotate into two opposed directions starting from a resting position (or central

WO 2017/141091

PCT/IB2016/057866

position) and the push button	30	includes at	least an
elastic element 61 adapted	to	bring the	pressure
transmitting member 60 back	to	the angular	resting

position after one rotation. Referring to Figures 6 and 15, it must be noted that the pressure transmitting member 60 is adapted to rotate around the rotation axis

Al-Al (that will be called third rotation axis).

[0066] In order to allow a user to manually operate the push button 10 perceiving a very limited resistance, the aforesaid elastic element is, or includes, a wire spring 61 and preferably a rectilinear wire spring. The aforesaid wire spring 61 is, for example, a wire spring made of spring steel. It has been observed that a wire spring 61 with reduced section too, for example with a diameter included between 0,25 mm and 0,75 mm and for example equal to 0,5 mm, is able to bring the pressure transmitting member 60 back to the angular resting position and is able to resist to the stresses generated when the push button 30 is manually operated.

[0067]Preferably, the aforesaid wire spring 61 has two opposite end portions 62 constrained to the push button 30 and a central portion 63 adapted to exert an elastic strength on the pressure transmitting member 60. Preferably, referring to Figure 15, the pressure transmitting member 60 includes a central portion 600 and

WO 2017/141091

PCT/IB2016/057866 two appendices 601 and 602 originating from the central portion 600. Preferably, the central portion 600 includes a channel 630, as for example a recess or hole, crossed by the central portion 63 of the wire spring 61.

[0068]Referring to Figure 16, according to one advantageous embodiment, the body of the push button 30 includes a pass-through opening 360, crossed by the pressure transmitting member 60, thereby the wire spring 61 is arranged on one side of the pass-through opening 360 together with at least one part of the central portion 600 of the pressure transmitting member 60, while the remaining part of the pressure transmitting member 60 is arranged on the other side of said pass-through opening 360.

[0069]With reference to Figure 15, according to one further advantageous embodiment, the pressure transmitting member 60 includes two opposite hinge pins 610 that originate from the central portion 600 of the aforesaid member. For example, the two hinge pins 610 are cylindrical pins. Such hinge pins 610 are oriented along the rotation axis Al-Al of the pressure transmitting member 60. According to one advantageous embodiment, in order to simplify the assembly of the push button 30, the latter includes two semicircular recesses (visible in

Figure 6), or generally having the shape of an arc of the

WO 2017/141091

PCT/IB2016/057866 circle, aligned along the rotation axis of the pressure transmitting member 60 each of which is adapted to partially receive a respective pin 610. In such case, the wire spring 61, apart from serving as elastic return to make the pressure transmitting member 60 return into its resting position, also serves favourably as fixing element of the member 60 to the push button 30.

[0070]According to one advantageous embodiment, referring to Figure 16, the push button 30 includes a fixing seat 361 of the wire spring 61 made in the thickness of the bottom wall 31 of the push button 30 and that in the embodiment is placed on top of the pass through opening 360 of the push button 30. Preferably, such fixing seat 361 includes two grooves 362 aligned to each other along the direction of prevalent longitudinal extension of the wire spring 61 and are crossed by the end portions 62 of the wire spring 61. Preferably, the end portions 62 of the wire spring 61 protrude beyond such grooves 362 from opposite sides with respect to the central portion 63 of the wire spring 61. Conveniently, the fixing seat 361 of the wire spring 61 includes stopping elements 365 adapted to limit or prevent an undesired translation of the wire spring 31 with respect to the push button 30. Such translation may in fact determine and undesired detachment of the wire spring 61

WO 2017/141091

PCT/IB2016/057866 from the push button 30 and, thus, in the embodiment also of the pressure transmitting member 60.

[0071]]With reference to Figure 7, the aforesaid pressure transmitting member 60 contacts, from a certain point on during the sliding of the push button 30 from the backward position to the forward position, a commutation rocking control member 70, e.g. a bistable member, included in the push button operated circuit breaker 10. By rocking control member it is meant a rocking control member adapted to control the switching. After such contact, the pressure transmitting member 60 starts rotating with respect to the resting position, and during a further advancement of the push button 30 it determines a rotation of the rocking control member 70 starting from a first operative position until it reaches a second operative position. At this point, if the pressure of the push button 30 is released, it will be able to return back to the backward position and the pressure transmitting member 60 can return back to the resting position as a result of the elastic return force of wire spring 61, whilst the control rocking member 70 will be able to remain in the second operative position, if it is a stable position, or, in the opposite case, return back to the first operative position (e.g. as a result of a return force applied by an elastic element).

WO 2017/141091

PCT/IB2016/057866

In case the control rocking member 7 0 returns in the first operative position, a further pressure of the push button 30 will determine a sequence of movements as the above described one. In case, on the contrary, the rocking control member 70 remains in the second operative position, at the moment of a further pressure of the push button 30 through a sequence of movements similar to the above described one, it will be able to return in the first operative position and remain there despite the push button 30 is released and until a later pressure of the push button 30.

[0072]With reference to Figures 17-21, the push button operated circuit breaker (10) includes at least a fixed electrical contact element 92, 92' (hereinafter also called fixed contact element) and at least a mobile element of mobile contact 82, 82' (hereinafter also called mobile contact element) and the rocking control member 70, by moving as a result of the pressure transmitted by the pressure transmitting member 60, determines a rotation of the rotatable contact holder support 81 around a rotation axis A3-A3 (hereinafter also called a first rotation axis) that in its turn, rotates the mobile electrical contact element 82 between a first and a second operative position, being angularly spaced from one another. In the non-limitative embodiment shown

WO 2017/141091

PCT/IB2016/057866 in Figures 17-21, the switch 10 includes two opposite mobile electrical elements 82, 82' and two fixed electrical contact elements 92, 92', being spaced apart and each other fronted. In this case the circuit breaker is thus a two-way diverter, whereby in one of the aforesaid operative positions the mobile contact element is in contact with a fixed contact element 92 and the mobile contact element 82' is separated from the other fixed contact element 92' while in the other operative position the mobile contact element 82 is separated from

the fixed	contact	element	92	and	the	mobile	contact
element 82'	is in	contact	with	the	other fixed	contact
element 92	'. However, it	is	to	be	noted that the
teachings	of the	present	description	can be	easily

applied from an expert in the field even to the case of a push button operated circuit breaker 10 having a single fixed electrical contact element and a single mobile electrical contact element. Thus, it is possible to generalise by stating that the mobile electrical contact element is 82, 82' rotates around a rotation axis A3-A3 among two operative positions angularly spaced in order to interrupt or deviate an electrical circuit. From now on, reference will be made, without limitation, to the case wherein the circuit breaker 10 includes two mobile electrical contact elements 82, 82' and two fixed electrical contact elements 92, 92'. In such a case the

WO 2017/141091

PCT/IB2016/057866 circuit breaker 10 includes two fixed contact holder supports 91, 91' to which the fixed contact elements 92, 92' are respectively fixed, e.g. welded. The fixed contact holder supports 91, 91' are made of electrically conductive material, e.g. copper, and each one includes a connecting portion 93, 93'. Each connecting portion 93,93' is for example part of a corresponding electrical connecting terminal C2, C3 of the circuit breaker 10. Each connecting clamp C2, C3 includes a screw 94, 94' and a clamping plate 95, 95' and each screw 94, 94' crosses the respective connecting portion 93, 93' for engaging with an associated clamping plate 95, 95'.

[0073] The mobile electrical contact elements 82, 82' are for example two opposite electrically conductive pads, e.g. made of sintered silver, fixed, e.g. welded, at the opposite sides of an end portion of a mobile contact holder support 81, also made of electrically conductive material, e.g. copper. It is thus clear that in this embodiment the mobile electrical contact elements 82, 82' are electrically connected between them. The opposite end portion of the mobile contact support 81 lies on the supporting fulcrum 50 and in particular on the portion and support and contact 51 of the supporting fulcrum 50. The mobile contact holder support 81 rotates around a first rotation axis A3-A3, in the example defined by the

WO 2017/141091

PCT/IB2016/057866 supporting fulcrum 50, in order to rotate the mobile electrical contact element 82, 82' between the first and the second operative portion and vice versa. For example, the mobile contact holder support 81 is an L-shaped plate having a larger base 810 lying on the supporting fulcrum and a more narrow arm 811 than the base 810 that protrudes from the base 810 and on whose end portion opposite to the base 810 the mobile electrical contact elements 82,82' are fixed.

[0074]The rocking control member 70 includes a body 75, preferably made of electrically insulating material, e.g. plastic, rotatable with respect to the case 20 so as to rotate around a rotation axis A2-A2 (herein also called second rotation axis), parallel to a first rotation axis A3-A3, in order to rotate the rotatable contact holder support 81. Preferably, the second rotation axis A2-A2 is parallel both to the third rotation axis Al-Al and to the first rotation axis A3-A3. Preferably, the body 75 of the rocking control member 70 is rotatably hinged to the case .

[0075] According to an advantageous embodiment, in order to further reduce the axial encumbrance of the push button operated circuit breaker 10, the body 75 of the rocking control member 7 0 is shaped in such a way that the rotatable contact holder support 81 in the rotation

WO 2017/141091

PCT/IB2016/057866 around the first rotation axis A3-A3 can cross the second rotation axis A2-A, that is the rotation axis of the body 75 of the rocking control member 70.

[0076]Preferably, the body 75 of the rocking control member 70 includes a contact portion 72 having two shaped surfaces 701, 702 intended to be alternatively contacted and pushed by the pressure transmitting member 60, and in particular by the two appendices 601,602. Preferably, the two shaped surfaces 701, 702 are two stepped surfaces.

[0077] According to one embodiment, the body 75 of the rocking control member 70 includes a bridge portion 71 bypassing an operative space 710 in which the rotatable contact holder support 81, or an end portion thereof, as for example an end portion of the arm 811 is free to rotate. For example, the bridge portion 71 includes at least a bended bridge arm 711, 712, 713, preferably two coplanar bended bridge arms 711, 713 originating from two different points of the body 75 and joining in the same point. In the particular embodiment shown, the bridge portion 71 includes three bended bridge arms 711, 712, 713 originating from three different points of the body 75 and joining in the same point to form a cage structure that defines the operative area 710 within which the rotatable contact holder support 81, or an end portion thereof, as for example an end portion of the arm 811, is

WO 2017/141091

PCT/IB2016/057866 free to rotate. According to one possible embodiment, the bridge portion 71 may include a continuous bridge wall provided with a recess or a pocket within which the rotatable contact holder support 81, or an end portion thereof, is free to rotate.

[0078] According to one advantageous embodiment, as in the example shown in the Figures, the bridge portion 71 bypasses also a space occupied by the fixed contact holder support 91, 91', by the fixed electrical contact

element	92,	92 ’	and	by	the	mobile	electrical contact
element	82,	82 ’ .	In	such	a	way, the	bridge portion 71
bypasses	a	space	region	of	the circuit breaker 10 in

which the joining and separation between the mobile electrical contact element 82, 82' and the fixed electrical contact element 92, 92' occurs.

[0079]According to one embodiment, the rocking control member 70 includes two opposite coupling elements that allow the rotatably coupling of the control member 70 with two opposite lateral walls of the case 20. In the particular example shown in the figures, the aforesaid coupling elements include two opposite cylindrical shaped pins 76 protruding from the body 75 along the rotation axis A2-A2 towards opposite directions. According to one advantageous embodiment, one of the aforesaid pins 7 6 protrudes from the contact portion 72 and the other one

WO 2017/141091

PCT/IB2016/057866 of said pins protrudes from the bridge portion 71. For example, such pins 76 are inserted in corresponding pass through holes or recesses 276 arranged in two opposite lateral walls of the case 20.

[0080] According to one embodiment, the body 75 of the rocking control member 70 includes a portion 73 containing an internally hollow seat adapted to receive an elastic element, e.g. a coil spring 77, operatively inserted between the rocking control member 70 and the mobile contact holder support 81. For example, the mobile contact holder support 81, and in particular its base 810, includes in fact a protruding appendix 87 inserted inside the coil spring 77.

[0081] According to further embodiments, in the body of the rocking control member 70 further accessory elements can be provided, such as a wall 79 with a recess (not visible in the drawings because it points to the bottom wall 21 of the case 20) adapted to receive an end of an elastic element (as for example a coil spring) adapted to make the rocking control member 70 a monostable member.

[0082] As clearly shown from the above description, the proposed button operated circuit breaker with rocking control member 10 allows to fully achieve the planned scopes in terms of overcoming the drawbacks of the circuit breakers of the prior art. As a matter of fact,

WO 2017/141091

PCT/IB2016/057866 experimental evidence has demonstrated that, thanks to the provision of an elastic element which is or includes a wire spring 61, if compared to the push button circuit breakers of the prior art, it is possible to significantly reduce the resistance perceived when pushing the push button 30 starting from the moment when the pressure transmitting member 60 contacts the rocking control member 70. This contributes to produce a sensation of greater fluidity when pushing the push button.

[0083]Subject to the principle of the invention, the embodiments and the implementation details shall be widely varied with respect to what has been said and shown for exemplary purposes but not limited to, without detaching from the field of the invention as defined in the enclosed claims.

WO 2017/141091

PCT/IB2016/057866

Claims (9)

1. A push button operated circuit breaker (10) with rocking control member including:

- a case (20) made of electrically insulating material, having a bottom wall (21), lateral walls (20a, 20b, 20c, 20d) being joined to the bottom wall (21) and an open side (21' ) opposite to the bottom wall (21);

a push button (30) that can be operated to command an electrical switching of the switch (10) ) and having a body provided with lateral walls (30a, 30b, 30c, 30d) crossing said open side (21') , the push button ( dO) being adapted to slide with

respect to the case (20) along a sliding axis (ZZ), between a forward position and a backward position;

a rocking control member ( 70) adapted to control an electrical switching; a pressure transmitting member ( 60) being

rotatably constrained to the body of the push button (30) and adapted to rotate with respect to a rest angular position around a rotation axis (AlAl) ;

an elastic element (61) adapted to bring back the

WO 2017/141091

PCT/IB2016/057866 pressure transmitting member (60) in the rest angular position after its rotation;

characterized in that the above-mentioned elastic element is, or includes, a wire spring (61).

5 2. The push button operated circuit breaker (10) according to claim 1, wherein the wire spring (61) is a rectilinear wire spring.

3. The push button operated circuit breaker (10) according to claim 1 or 2, wherein the wire spring (61)

10 has a diameter between 0.25 mm and 0.75 mm.

4. The push button operated circuit breaker (10) according to any one of the previous claims, wherein the wire spring (61) has two opposite end portions (62) constrained to the body of the push button (30) and a

15 central portion (63) adapted to exert an elastic force on the pressure transmitting member (60).

5. The push button operated circuit breaker (10) according to claim 4, wherein the pressure transmitting member (60) includes a central portion (600) and two

20 appendices (601, 602) originating from the central portion (600), wherein the central portion (600) of the pressure transmitting member (60) includes a channel (630) crossed by the central portion (63) of the wire spring (61).

WO 2017/141091

PCT/IB2016/057866

6. The push button operated circuit breaker (10) according to claim 5, wherein the body of the push button (30) includes a bottom wall (31) having a passthrough opening (360), crossed by the pressure transmitting member (60), thereby the wire spring (61) is arranged on one side of the pass-through opening (360) together with at least one part of the central portion (600) of the pressure transmitting member (60), while the remaining part of the pressure transmitting member (60) is arranged on the other side of said passthrough opening (360).

7. The push button operated circuit breaker (10) according to any one of the previous claims, wherein:

- the pressure transmitting member (60) includes two opposite hinge pins (610) directed along the rotation axis (Al-Al) of the pressure transmitting member (60);

- the body of the push button (30) includes two semicircular or circular arc shaped recesses (310), being aligned along the rotation axis (Al-Al) each of them being adapted to partially receive a respective pin (610) .

8. The push button operated circuit breaker (10) according to claim 4, wherein the push button (30) includes a fastening seat (361) of the wire spring (61),

WO 2017/141091

PCT/IB2016/057866 which is made in the thickness of the bottom wall (31) of the push button (30) including two grooves (362) being aligned to each other along the direction of prevalent longitudinal extension of the wire spring (61)

5 and being crossed by the end portions (62) of the wire spring ( 61), wherein the end portions (62) of the wire spring (61) protrude beyond those grooves (362 ) on

opposite sides with respect to the central portion (63) of the wire spring (61).

10 9. The push button operated circuit breaker (10) according to claim 8, wherein the fastening seat (361) of the wire spring (61) includes stopping elements (365) adapted to limit or prevent the translation of the wire spring (31) with respect to the push button (30).

15 10. The push button operated circuit breaker (10) according to any one of the previous claims, wherein the wire spring (61) is made of spring steel.

WO 2017/141091

PCT/IB2016/057866

1/9

WO 2017/141091

PCT/IB2016/057866

FIG. 4

FIG. 5

2/9

WO 2017/141091

PCT/IB2016/057866

3/9

WO 2017/141091

PCT/IB2016/057866

250 ,5 /. ^s'\

Ni

MN iNW

V t / (/ I ζ ΐϊ^. 1|jl| i/·^{7 k} i //·' /w. IsgF /./

IK> \yw=

1Π0 Z.-.V. 0 4

HIX. txthW/ </ ; 0 .4 / / · z AZ

FIG. 8

WM/ / '^X<F

FIG. 9

FIG. 10

4/9

WO 2017/141091

PCT/IB2016/057866

FIG.11

SW

Hi

276 > - ll VUt Ν-'ίττ < \

1 -4 /Ws. -χχ;-''·' l-ι K ,· iUw /wh ur

I hi IN n

AU.....\ _Ί NAAN I BUte^nb ’-UUhlut i§ ! i r~\i »

XJ

FIG. 12

5/9

WO 2017/141091

PCT/IB2016/057866

FIG. 13

FIG. 14 'A3

FIG. 15

6/9

WO 2017/141091

PCT/IB2016/057866

FIG. 16

FIG. 17

7/9

WO 2017/141091

PCT/IB2016/057866

FIG. 19

8/9

WO 2017/141091

PCT/IB2016/057866

FIG. 20

9/9