BR112018015572B1 - BUTTON OPERATED SWITCH WITH ANTI-JAM GUIDE SYSTEM - Google Patents

Abstract

A button operated switch (10) including: a housing (20) made of electrically insulating material, having a bottom wall (21), side walls (20a, 20b, 20c, 20d) being joined to the bottom wall (21) and a open side (21?) opposite the lower wall (21); a button (30) that can be operated so as to command an electrical commutation of the switch (10) having a body provided with side walls (30a, 30b, 30c, 30d) crossing said open side (21?), the button ( 30) being adapted to slide relative to the box (20) along a sliding axis (Z-Z), between a forward position and a backward position; a system of spatially distributed guides adapted to guide the slide of the button in relation to the case along said sliding axis. The spatially distributed guide system includes: first guide elements (22, 32) operatively interposed between the side walls of the button (30) and the side walls of the box (20); second guide elements (24, 34) spaced in relation to the first guide elements (22, 32) and positioned, in relation to the first guide elements, at a smaller distance from the lower wall (21).

Description

Field of Invention

[001] The present description refers to the technical field of electrical installations and, more specifically, deals with a button-operated switch with an anti-seizing guide system.

State of art

[0002] European patent EP1584096 describes a button-operated switch comprising a support structure, or casing, made of insulating material having the shape of a box and defining a recessed compartment for housing and supporting the electromechanical components forming part of the switch. . The structure has an open side. The switch also includes a button slidably coupled to the structure by means of guide elements so as to close the open side. The mechanical coupling between the button and the frame allows relative and guided sliding of the button relative to the frame along a sliding axis. Such a slide is necessary to control an electrical switch on the switch using the button. Pressing the button determines the advance of the button in relation to the structure. Releasing the button causes the button to move away from the structure. The button therefore moves between a forward position and a backward position, representing both button end positions. In a button-operated switch it is very important to prevent the loss of the sliding coupling between the button and the structure as this can cause temporary or permanent relative blocking of the switch. In practice, this blockage is due to the button sticking against the walls of the structure.

[0003] European patent EP1866944, European patent EP2297759 and European patent EP2553700 describe possible solutions to the jamming problem.

[0004] The above-mentioned solutions of the prior art, although significant and widespread, lead to a notable increase in the axial overload of the button-operated switch and an increasing number of switch components.

[0005] In relation to prior art solutions, the need is felt to implement a button-operated switch that is more compact, simpler to assemble and possibly having a reduced number of components and that is not affected, or that is affected as little as possible, due to the problem of jamming.

[0006] The object of the present description is to make available a button-operated switch which satisfies the need described above in relation to prior art switches.

[0007] Such an object is achieved through a button-operated switch as generally defined in Claim 1. Preferred and advantageous configurations of the button-operated switch mentioned above are defined in the appended claims.

[0008] The invention will be better understood from the detailed description of particular configurations below by way of example only, but not limited to, with reference to the accompanying drawings briefly described in the following paragraph.

Brief description of the figures

[0009] Figure 1 presents a perspective view of a button-operated switch configuration including a box, a button slidably restricted to the box, and a switch coupled to the button.

[0010] Figure 2 shows a side view of the button-operated switch of Figure 1.

[0011] Figure 3 presents an additional perspective view of the switch of Figure 1 from which the key has been removed.

[0012] Figure 4 shows a top view of the switch box of Figure 1 from which all components contained within the box have been removed.

[0013] Figure 5 shows a top view of the switch button of Figure 1.

[0014] Figure 6 shows a perspective view of the bottom of the switch button of Figure 1.

[0015] Figure 7 presents a perspective view of the partial section of the switch of Figure 1, from which the key and some of the components contained within the box have been removed.

[0016] Figure 8 presents a perspective view of the switch box of Figure 1, where some of the components contained within the box are visible.

[0017] Figure 9 presents a perspective view of the partial section of an enlarged part of the switch of Figure 1.

[0018] Figure 10 shows an additional perspective view of a partial section of an enlarged part of the switch of Figure 1.

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

[0020] Figure 12 presents a perspective view of a partial section of the switch box of Figure 1, where a support fulcrum inserted into the box is visible.

[0021] Figure 13 shows a side view of a partial section of the box and the support fulcrum of Figure 12.

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

[0023] Figure 15 shows a pressure transmission member of the switch button of Figure 1.

[0024] Figure 16 shows an additional top perspective view of the switch button of Figure 1.

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

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

[0027] Figure 19 presents a perspective view of the assembly of Figure 17 where a swing control member is also shown.

[0028] Figure 20 presents an additional perspective view of the assembly of Figure 19.

[0029] Figure 21 presents a perspective view of the balance control member of Figure 19.

Detailed Description

[0030] With reference to the attached figures, a particular non-limiting configuration of a button-operated switch 10 will now be described. By button-operated switch is meant a switch manually operated by a button in order to determine a, or by least one, electrical switching. Preferably, as in the illustrated example, the button-operated switch 10 is of the modular type, which is designed to be mounted on a support frame for wall installation alongside other modular circuit breakers of the same type or on other modular electrical appliances in the general, such as sockets. The switch 10 can be operated manually and can be used, for example, to control electrical power and/or lighting in a residential or commercial building.

[0031] In the present description, the term switch is understood to mean both a device for opening and closing a single electrical contact and a device for opening an electrical contact with the simultaneous closing of another electrical contact and vice versa (diverter). .

[0032] The button-operated switch 10 comprises a support structure 20 made of an electrical insulating material, such as plastic, having preferably, but not restrictively, approximately a parallelepiped shape. The support structure 20, hereinafter referred to as the box, includes a bottom wall 21 and four side walls 20a, 20b, 20c, 20d connected to the bottom wall 21. The box 20 includes an open side 21' opposite the bottom wall 21. The side walls 20a, 20b, 20c, 20d and the bottom wall 21 define a recessed compartment adapted to hold the electromechanical components of the switch 10 and at least two electrical connection terminals Cl, C2, C3. In the example shown in the Figures, the recessed compartment of the box 20 accommodates, without any limitation, three electrical connection terminals Cl, C2, C3.

[0033] Preferably, the bottom wall 21 is integrated with the box 20, however in an alternative configuration the bottom wall 21 can be a separate piece from the side walls 20a, 20b, 20c, 20d of the box 20 and fitted into them.

[0034] The button-operated switch 10 comprises a button 30, being manually operated so as to command an electrical commutation of the switch 10, having a body provided with side walls 30a, 30b, 30c, 30d crossing the open side 21' of the housing 20. The button 30 is adapted to slide relative to the housing 20 along a Z-Z sliding axis and along a space delimited between a forward position and a rearward position. For the purposes of the present description, by "forward position" is meant an end-of-travel position in the approaching movement of the button 30 relative to the box 20, while by "backward position" is meant an end-of-travel position in the movement away from the button 30 in relation to the box 20. Therefore, it is clear that the terms "forward" and "backward" refer to the position of the button 30 in relation to the box 20.

[0035] The button-operated switch 10 comprises a system of spatially distributed guides adapted to guide the slide of the button 30 relative to the housing 20 along the Z-Z sliding axis.

[0036] The spatially distributed guide system includes first guide elements 22, 32 operatively interposed between the side walls 20a, 20b, 20c, 20d of the box 20 and the side walls 30a, 30b, 30c, 30d of the button body 30.

[0037] The spatially distributed guide system also includes second guide elements 23, 24, 33, 34 spaced relative to the first guide elements 22, 32 and positioned relative to the first guide elements 22, 32 at a shorter distance from the lower wall 21 of the box 20. More precisely, mutually cooperating friction surfaces of the first guide elements 22,32, have a distance from the lower wall 21 of the box 20 greater than the distance in relation to the lower wall 21 of the box 20 of the cooperating friction surfaces between the second guide elements 23,24,33,34.

[0038] According to an advantageous configuration the first guide elements 22, 32 include a first plurality of appendages 22 projecting from the side walls 20a, 20b, 20c, 20d of the box 20 towards the side walls 30a, 30b, 30c, 30d of the button 30 and a second plurality of appendages 32 projecting from the side walls of the button 30 towards the side walls 20a, 20b, 20c, 20d of the case 20 and each being adapted to make contact with a respective appendage 22 of the first plurality of appendages 22 of mode to slide over it when button 30 slides in relation to box 20.

[0039] In the non-limiting exemplary configuration shown in the Figures, there are provided four appendages 22 projecting from the side walls 20a, 20b, 20c, 20d of the box 20 and four corresponding appendages 32 projecting from the side walls 30a, 30b, 30c, 30d button 30.

[0040] According to an advantageous configuration, the first plurality of appendages 22 and the second plurality of appendages 32 allow the side walls 30a, 30b, 30c, 30d of the button 30 to be spaced from the side walls 20a, 20b, 20c, 20d of the box 20 when the button 30 slides relative to the box 20. Thus, in effect, the button-operated switch 10 is less vulnerable with respect to the intrusion of dust or sand between the side walls 20a, 20b, 20c, 20d of the box 20 and the side walls 30a, 30b, 30c, 30d of the button 30 which would normally cause a jamming inside the switch, instead, due to a wide overlap between the side walls of the button 30 and those of the housing 20, there are wider friction surfaces .

[0041] According to a preferred configuration, the protruding appendages 22, 32 mentioned above are linear appendages, which in the example presented extend linearly along axes that are parallel to each other and parallel to the Z-Z sliding axis.

[0042] According to a preferred configuration, the side walls of the button 30 are parallel in pairs and define edges 32', each being defined by a pair of adjoining side walls 30a, 30b, 30c, 30d of the button 30. Each appendage 32 of the second plurality of appendages is disposed on a corresponding edge 32'. Preferably, the edges 32' are chamfered.

[0043] According to an advantageous configuration, the second guide elements 23, 24, 33, 34 are staggered with respect to the first guide elements 22, 32. In other words, the second guide elements 23, 24, 33, 34 are more close to some of the first guide elements 22, 32 and further away 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 socket 23 and a guide pin 33 having a terminal portion 34 slideable in the guide socket 23. In the exemplary configuration there is no -limiting shown in the Figures, the guide pin 33 extends from the button body 30 towards the bottom wall 21 of the housing 20 while the guide socket 23 is fixed to the bottom wall 21 of the housing 20. Preferably, the guide pin 33 is integrated into the button 30 and projects from the button body 30 towards the lower wall 21 of the housing 20. Preferably, the button body 30 and the guide pin 33 form a single piece.

[0045] According to an advantageous configuration, said terminal portion 34 of the guide pin 33 has a cross-shaped section. By cross-shaped section is meant a section in a plane perpendicular to the Z-Z sliding axis. In the specific configuration presented in the Figures, said cross-shaped section includes a circular central part from which four arms originate, forming a Greek cross.

[0046] According to an advantageous configuration, the guide pin 33 does not interfere with the side walls 20a, 20b, 20c, 20d of the box 20 during the sliding movements of the button 30 relative to the box 20. In other words, the pin guide 33 is distanced from the side walls 20a, 20b, 20c, 20d of the box 20 in order to avoid friction between the surface of the side walls of the box 20 and the guide pin 33.

[0047] Referring to Figures 4 and 7, according to one configuration the guide fitting 23 includes four parallel side walls 24 in pairs. Preferably, the side walls 24 of the guide socket 23 are separated from each other and joined to the bottom wall 21 of the box 20. In an alternative configuration the guide socket 33 may be a continuous ring, having a quadrangular or circular section. In the specific example presented, the side walls 24 are integrated with the bottom wall 21 of the box 20, projecting from it towards the button 30.

[0048] Referring to Figure 8, in accordance with one embodiment, the button-operated switch 10 includes at least one elastic element 40 adapted to exert a pushing force on the button 30 so as to bring back or maintain the button 30 in the backward position in the absence of external forces. In the specific configuration shown in Figure 8, the switch 10 includes two elastic elements 40 having the form of two springs 40. In particular, in the example shown, the switch 10 also includes a diaphragm 41 held within the casing 20 and the elastic elements 40 are inserted operatively between the diaphragm 41 and the button body 30, each having for example a terminal portion inserted into a corresponding socket 39 provided in the button body 30 (Figure 6). Fittings having the same function may also be present on the diaphragm 41.

[0049] Referring to Figures 8-10, in order to stop the button 30 in the rearward position, the button-operated switch 10 includes a first stopping system including contact surfaces 251, 351 of the side walls of the box 20 and the side walls of the button 30 respectively, which remain pressed against each other when the button 30 is in the rearward position. In a particularly advantageous configuration, the first stop system includes alignment elements 250, 350 interacting with each other from a given point during the sliding movement of the button 30 from the forward position toward the backward position before to reach the backward position. Such alignment elements 250, 350 allow progressive alignment of the button 30 with respect to a reference plane R_P (Figure 11) which is perpendicular to the Z-Z sliding axis.

[0050] According to an advantageous configuration, said alignment elements 250, 350 include at least one variable section guide 250, and a corresponding variable section slider 350 adapted to be inserted into the variable section guide 250, starting from from a given point during the movement of the button 30 before reaching the backward position and ending when it reaches the position. Preferably the variable section guide 250 is a tapered guide, having a decreasing section towards the R_P reference plane. In this case, for example, the variable section slider 350 has a wedge shape.

[0051] According to an advantageous configuration, in order to further increase the accuracy of the alignment of the button 30 with respect to the R_P reference plane and to ensure better coupling between the button 30 and the box 20 and the contact surfaces 251, 351 are surfaces which, in the backward position of button 30, remain in a plane I_P inclined with respect to the reference plane R_P.

[0052] According to a particularly advantageous configuration, the switch 10 includes complementary plug-in elements 25, 35 provided on the side walls of the box 20 and on the side walls of the button body 30. Said complementary plug-in elements 25 have a shape that facilitates the forced insertion of the button body 30 through the open side 21' of the box 20 in the assembly step of the button-box assembly and which, after passing through the fitting position, creates an engagement coupling between the button 30 and the box 20 , based on which the button 30 is slidably restricted to the box 20.

[0053] In the specific example depicted in the Figures, without limitation, the engagement elements 25, 35 include four engagement teeth 25 on the side walls of the housing 20 and four complementary engagement teeth 35 arranged on the side walls of the button body 30. Preferably The engagement teeth 25, 35 are arranged at the corners of a rectangle or square positioned in a plane that is perpendicular to the Z-Z sliding axis.

[0054] According to a particularly advantageous configuration, said fitting elements 25, 35 carry said alignment elements 250, 350 and preferably also carry said contact surfaces 251, 351.

[0055] According to a preferred embodiment, in order to stop the button 30 in the forward position, the button-operated switch 10 includes a second stopping system including contact elements 26, 36 respectively provided on the side walls of the housing 20 and on the side walls of the button body 30. In the specific example presented, said contact elements 26, 36 include two small blocks 36 projected from opposing walls 30b, 30d of the button body 30 and contact surfaces 26 provided in two opposing side walls 20b, 20d of box 20.

[0056] According to one embodiment, the button-operated switch 10 includes a support fulcrum 50 positioned within the housing 20. As is known, in a switch a support fulcrum 50 acts as a support means for a movable member of electrically conductive switching, in particular rotatable, bearing at least one movable electrical contact element. Said electrically conductive movable switching member will be referred to in the present description as a contact rotary support. The support fulcrum 50 is, for example, made of a bent and perforated sheet of metal.

[0057] According to an advantageous configuration, in order to ensure stable attachment of the support fulcrum 50 to the box 20, the box 20 includes a TJ fitting area of the support fulcrum 50 and the button-operated switch 10 includes a system plug-in coupling system adapted to secure the support fulcrum 50 to the box 20 in the plug-in area 27. Preferably, the plug-in area 27 is disposed within the box 20 on the lower wall 21 and the plug-in coupling system comprises at least one elastic engagement tooth 28 adapted to engage the support fulcrum 50 with the lower wall 21 of the box 20. Preferably said elastic engagement tooth 28 is integrated with the lower wall 21 of the box 20 and forms a single piece with it. In the example shown in the Figures, the snap coupling system includes a plurality of elastic engagement teeth 28, in particular three elastic coupling teeth 28.

[0058] According to an advantageous configuration that allows the simplification of the manufacture of the box 20, below the elastic engagement tooth 28, the lower wall 21 of the box 20 has a passage opening 28'. Thus, the need to mold opposing recessed surfaces into the bottom wall 21 of the box 20 is usefully avoided.

[0059] According to a preferred configuration, the elastic engagement tooth 28 has a free end portion and a end portion restricted to the lower wall 21 of the box 20 and the free end portion engages with a peripheral portion of the support fulcrum 50.

[0060] According to an advantageous configuration, at least two engagement teeth 28 are provided which are arranged on opposite sides with respect to the support fulcrum 50.

[0061] According to one embodiment, the TJ fitting area of the support fulcrum 50 is a recessed fitting implemented in the bottom wall 21 of the housing 20. Preferably, the fulcrum 50 includes a support and contact portion 51 that has a groove, such as having a V-shaped section, positioned within the recessed fitting area 27. Preferably, the support fulcrum 50 also includes a connecting portion 52, being part of a connecting terminal 50 of the switch 10 The connecting terminal Cl includes a screw 54 and a fixing plate 55, and the screw 54 crosses the connecting portion 53 of the support fulcrum 50 to engage with the fixing plate 55. According to an advantageous configuration, between the support and contact portion 51 and the connecting portion 53, the support fulcrum 50 includes an intermediate portion 52 forming an inclined plane of connection between the support and contact portion 51 and the connecting portion 53.

[0062] According to a particularly advantageous configuration, the switch 10 also includes an anchoring system 59, 29 from the support fulcrum 50 to the box 20, in particular to the lower wall 21 of the box 20. For example, the anchoring system 59 , 29 includes a fin 59 integrated with the support fulcrum 50 and an anchoring area 29 (visible in Figure 4) arranged within the lower wall 21 of the box 20 carrying the fin 59. This allows stabilization of the position of the support fulcrum 50 in in relation to external stresses affecting, for example, the support fulcrum 50 during wiring operations of the switch 10, for example caused by the binding of the connection terminal CL

[0063] In addition to the specific example presented in the drawings, more general or more specific configurations have been described so far, where switch 10 is a generic button-operated switch.

[0064] Hereinafter some configurations will be described, in which switch 10 is a button-operated switch with a rocker mechanism. A configuration of a button-operated switch with a rocker mechanism is, for example, described in European patent EP1866944. In addition to the peculiar configuration described in the above patent, it should be noted that by button-operated switch with rocking mechanism is generally meant a switch operated by means of a sliding button including a rocking element that controls switching, hereinafter called , for ease of explanation, of balance control member.

[0065] With reference to Figures 3, 5, 6, according to an advantageous configuration, the button 30 includes a pressure transmitting member 60 rotationally restricted to the body of the button 30. The pressure transmitting member 60 is adapted to rotate in two opposite directions from a rest position (or central position) and the button 30 includes at least one elastic element 61 adapted to bring the pressure transmitting member 60 back to the angular rest position after a rotation. With reference to Figures 6 and 15 it should be noted that the pressure transmitting member 60 is adapted to rotate about the axis of rotation AI-AI (which will be called the third axis of rotation).

[0066] According to an advantageous configuration, which allows a user to manually operate the button 10 while experiencing very limited resistance, said elastic element is, or includes, a wire spring 61 and preferably a straight wire spring. Said spring 61 is, for example, a wire spring made of spring steel. It has been observed that a wire spring 61 with a reduced section, for example, with an included diameter between 0.25 mm and 0.75 mm and, for example, equal to 0.5 mm, is capable of bringing the transmission member of pressure 60 back to the angular rest position and is capable of withstanding the stress generated when button 30 is manually operated.

[0067] Preferably, said wire spring 61 has two opposing end portions 62 connected to the button 30 and a central portion 63 adapted to exert an elastic force on the pressure transmitting member 60. Preferably, with reference to Figure 15, the transmitting member pressure 60 includes a central portion 600 and two appendages 601 and 602 originating from the central portion 600. Preferably, the central portion 600 includes a channel 630, such as a recess or hole, crossed by the central portion 63 of the wire spring 61 .

[0068] Referring to Figure 16, according to an advantageous configuration, the button body 30 includes a passage opening 360, crossed by the pressure transmitting member 60, thus the wire spring 61 is disposed on one side of the opening passage 360 near at least a part of the central portion 600 of the pressure transmitting member 60, while the remaining part of the pressure transmitting member 60 is disposed on the other side of said opening passage 360.

[0069] Referring to Figure 15, according to a further advantageous configuration, the pressure transmitting member 60 includes two opposing pivot pins 610 originating from the central portion 600 of said member. For example, the two pivot pins 610 are cylindrical pins. Such pivot pins 610 are oriented along the axis of rotation AI-AI of the pressure transmitting member 60. According to an advantageous configuration, in order to simplify the assembly of the button 30, it includes two semicircular recesses (visible in Figure 6 ), or generally having the shape of the arc of a circle, aligned along the axis of rotation of the pressure transmitting member 60, each of which is adapted to partially receive a respective pivot pin 610. In the present case, the spring wire 61, in addition to serving as an elastic return causing the transmitting member 60 to return to its resting position, it also serves as an element fixing the member 60 to the button 30.

[0070] According to an advantageous configuration, with reference to figure 16, the button 30 includes a fixing socket 361 of the wire spring 61 made in the thickness of the lower wall 31 of the button 30 and which in this configuration is positioned on top of the opening passageway 360 of the button 30. Preferably, such locking socket 361 includes two grooves 362 aligned with each other along the direction of the prevailing longitudinal extension of the wire spring 61 and are intersected by the terminal portions 62 of the wire spring 61. Preferably, the terminal portions 62 of the wire spring 61 project beyond such grooves 362 from opposite sides relative to the central portion 63 of the wire spring 61. Conveniently, the fastening socket 361 of the wire spring 61 includes stop elements 365 adapted to limit or prevent an undesired translation of the wire spring 31 with respect to the button 30. Such translation may in fact cause an undesired decoupling of the wire spring 61 from the button 30 and, therefore, in this configuration may also cause decoupling of the transmitting member. pressure 60.

[0071] Referring to Figure 7, said pressure transmitting member 60 is such that it connects, from a certain point during the sliding of the button 30 from the backward position to the forward position, a swing control member switch 70, for example, a bistable member, included in the button-operated switch 10 in case said switch 10 is a button switch provided with a rocker operating mechanism. After such contact, the pressure transmitting member 60 begins to rotate with respect to the rest position, and during further advancement of the button 30 is such that it determines a rotation of the swing control member 70 starting from a first operative position. until reaching a second operative position. At this point, if the pressure of the button 30 is released, it will be able to return to the rear position and the pressure transmitting member 60 can return to the rest position as a result of the wire spring 61, while the swing control member 70 will be able to remain in the second operating position, if this is a stable position, or, in the opposite case, return to the first operating position (for example, as a result of a return force applied by an elastic element). If the swing control member 70 returns to the first operating position, an additional press of the button 30 will determine a sequence of movements as described above. Otherwise, the swing control member 70 remains in the second operating position, upon further pressing of the button 30 through a sequence of movements similar to that described above, it will be able to return to the first operating position and remain in this position. when button 30 is released and until a subsequent press of button 30.

[0072] Referring to Figures 17-21, the button-operated switch 10 includes at least one fixed electrical contact element 92, 92' (hereinafter also called a fixed contact element) and at least one movable contact element movable 82, 82' (hereinafter also called movable contact member) and the swing control member 70, moving as a result of the pressure transmitted by the pressure transmitting member 60, determines a rotation of the rotary contact support 81 around an axis of rotation A3-A3 (hereinafter also called the first axis of rotation) which, in turn, rotates the movable contact element 82 between a first and a second operating position, being angularly spaced one from the other. other. In the non-limiting configuration shown in Figures 17-21, switch 10 includes two opposing movable contact elements 82,82' and two fixed contact elements 92,92', being spaced apart and facing toward each other. In this case the switch 10 is therefore a bidirectional diverter, whereby in one of said operating positions the movable contact element 82 makes contact with a fixed contact element 92 and the movable contact element 82' is separated from the other element. fixed contact element 92' while in the other operating position the movable contact element 82 is separated from the fixed contact element 92 and the movable contact element 82' makes contact with the other fixed contact element 92'. However, it should be noted that the teachings of the present description can be easily applied by one skilled in the art even in the case of a button-operated switch 10 having a single fixed contact element and a single movable contact element. Consequently it is possible to generalize by stating that the movable contact element 82, 82' rotates around an axis of rotation A3-A3 between two angularly spaced operating positions so as to interrupt or bypass an electrical circuit. Hereinafter, reference will be made, without limitation, to the case where the switch 10 includes two movable contact elements 82, 82' and two fixed contact elements 92, 92'. In such a case the switch 10 includes two fixed contact supports 91,91' to which the fixed contact elements 92,92' are respectively fixed, for example by soldering. The fixed contact supports 91,91' are made of an electrically conductive material, e.g., copper, and each includes a connector portion 93,93'. Each connector portion 93, 93' is, for example, part of a corresponding electrical connector terminal C2, C3 of the switch 10. Each connector terminal C2, C3 includes a screw 94, 94' and a fixing plate 95, 95' and each screw 94, 94' crosses the respective connecting portion 93, 93' to engage with an associated fixing plate 95, 95'.

[0073] The movable contact elements 82, 82' are, for example, two opposing electrically conductive pads and, for example, made of sintered silver, fixed, for example, welded, on two opposite sides of a terminal portion of a movable contact element. contact 81, also made of an electrically conductive material, for example copper. It is evident, therefore, that in this configuration the movable contact elements 82, 82' are electrically connected to each other. The opposite end portion of the movable contact support 81 lies on the support fulcrum 50 and in particular on the support and contact portion 51 of the support fulcrum 50. The movable contact support 81 rotates around a first axis of rotation A3 -A3, in the example defined by the support fulcrum 50, in order to rotate the movable contact element 82,82' between the first and second operating positions and vice versa. For example, the movable contact support 81 is an L-shaped plate having a larger base 810 resting on the support fulcrum 50 and a narrower arm 811 of the base 810 projecting therefrom and of which the terminal portion opposite the base 810 the movable contact elements 82,82' are fixed.

[0074] The swing control member 70 includes a body 75, preferably made of an electrically insulating material, e.g. plastic, rotatable with respect to the housing 20 so as to rotate around an axis of rotation A2-A2 (here called the second axis of rotation), parallel to a first axis of rotation ABAS, so as to rotate the rotary contact support 81. Preferably, the second axis of rotation A2-A2 is parallel to both the third axis of rotation AI-AI as for the first axis of rotation A3-A3. Preferably, the body 75 of the swing control member 70 is rotatably hinged to the housing 20.

[0075] According to an advantageous configuration, in order to further reduce axial locking of the button-operated switch 10, the body 75 of the swing control member 70 has a shape that allows the contact rotary support 81 in its rotation around the first axis of rotation A3-A3 may intersect the second axis of rotation K2.-K1, that is, the axis of rotation of the body 75 of the swing control member 70.

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

[0077] According to one embodiment, the body 75 of the swing control member 70 includes a bridge portion 71 surrounding an operative space 710 in which the rotary contact support 81, or a terminal portion thereof, such as a terminal portion of arm 811 is free to rotate. For example, the bridge portion 71 includes at least one bent bridge arm 711, 712, 713, preferably two bent bridge arms 711, 713 originating from two different points of the body 75 and joining at the same point. In the specific configuration shown, the bridge portion 71 includes three bent bridge arms 711, 712, 713 originating from three different points of the body 75 and joined at the same point to form a cage structure that defines the operative area 710 within the which rotary contact support 81, or a terminal portion thereof, such as the terminal portion of the arm 811, is free to rotate. According to one possible configuration, the bridge portion 71 may include a continuous bridge wall provided with a recess or a pocket in which the rotatable contact support 81, or an end portion thereof, is free to rotate.

[0078] According to an advantageous configuration, as in the example shown in the Figures, the bridge portion 71 also extends beyond a space occupied by the fixed contact support 91, 91', the fixed contact element 92, 92' and the movable element contact area 82, 82'. In this way, the bridge portion 71 exceeds a spatial region of the switch 10 where the junction and separation between the movable contact element 82, 82' and the fixed contact element 92, 92' occur.

[0079] According to one embodiment, the switching control member 70 includes two opposing coupling elements that allow rotational coupling of the control member 70 with two opposing side walls of the housing 20. In the specific example shown in the Figures, said coupling elements include two opposing cylindrical pins 76 projected from the body 75 along the axis of rotation A2-A2 in opposite directions. According to an advantageous configuration, one of said pins 76 projects from the contact portion 72 and another of said pins projects from the bridge portion 71. For example, said pins 76 are inserted into through holes or recesses. 276 corresponding devices arranged on two opposite side walls of the box 20.

[0080] In one embodiment, the body 75 of the swing control member 70 includes a portion 73 containing a hollow socket adapted to receive an elastic element, for example, a spring 77, operatively inserted between the swing control member. swing 70 and the movable contact support 81. For example, the movable contact support 81, and in particular its base 810, includes a protruding appendage 87 inserted into the spring 77.

[0081] According to additional configurations, in the body of the swing control member 70 additional accessory elements may be provided, such as a wall 79 with a recess (not visible in the drawings as it faces towards the lower wall 21 of the box 20 ) adapted to receive the tip of an elastic element (such as a spring) adapted to make the swing control member 70 a monostable member

[0082] As clearly shown by the above description, the proposed button operated switch 10 allows full achievement of the intended scope in terms of overcoming the disadvantages of the prior art. Indeed, experimental evidence demonstrates that, thanks to the provision of a system of spatially distributed guides including first guide elements 22, 32 operatively interposed between the side walls of the button 30 and the side walls of the housing 20 and second guide elements 23, 24, 33, 24 distanced from the first guide elements 22, 32 and arranged, in relation to the first guide elements 22, 32 at a smaller distance from the lower wall 21, it is possible to significantly reduce the friction surfaces between the button 30 and the housing 20, limit the vulnerability of the switch 10 to sand or dust intrusion and keeping the axial locking of the switch under control.

[0083] Subject to the principle of the invention, the configurations and implementation of details may be very varied in relation to what has been said and presented for example purposes, but not limited to, without departing from the field of the invention as defined in the claims in attachment.

Claims (16)

1. Button-operated switch (10), including: - a box (20) made of an electrically insulating material, having a bottom wall (21), side walls (20a, 20b, 20c, 20d) joined to the bottom wall (21 ) and an open side (21') opposite the lower wall (21); - a button (30) that can be operated to control an electrical commutation of the switch (10) and having a body provided with side walls (30a, 30b, 30c, 30d) crossing said open side (21'), the button ( 10) being adapted to slide relative to the box (20) along a sliding axis (Z-Z), between a forward position and a backward position; - a system of spatially distributed guides adapted to guide the slide of the button (30) relative to the housing (20) along said sliding axis (Z-Z), wherein the system of spatially distributed guides includes: - first guide elements ( 22, 32) operatively interposed between the side walls of the button (30) and the side walls of the box (20); second guide elements (23, 24, 33, 34) distanced in relation to the first guide elements (22, 32) characterized by the fact that said second guide elements (23, 24, 33, 34) are positioned in relation to the first guide elements (22, 32), at a smaller distance from the lower wall (21). 2. Button-operated switch (10) according to claim 1, characterized in that the first guide elements (22, 32) comprise a first plurality of appendages (22) projecting from the side walls of the box (20) toward the side walls of the button (30) and a second plurality of appendages (32) projecting from the side walls of the button (30) toward the side walls of the case (20) and each being adapted to make contact with a respective appendage of the first plurality so as to slide over it when the button (30) slides relative to the box (20). 3. Button-operated switch (10) according to claim 2, characterized in that said first plurality of appendages and said second plurality of appendages allow the side walls of the button (30) to be distanced from the walls sides (20) when the button (30) slides in relation to the box (20). 4. Button-operated switch (10) according to claim 3, characterized in that said appendages are linear appendages. 5. Button-operated switch (10) according to any one of claims 2 to 4, characterized in that the side walls of the button body (30) are parallel in pairs and define edges (32'), each one being defined by a pair of adjacent side walls, and wherein each appendage (32) of the second plurality of appendages is disposed on a respective edge (32'). 6. Button-operated switch (10) according to claim 5, characterized in that said edges (32') are chamfered. 7. Button-operated switch (10) according to any one of the preceding claims, characterized in that the second guide elements (23, 24, 33, 34) are decentralized with respect to the first guide elements (22, 32 ). 8. Button-operated switch (10) according to any one of the preceding claims, characterized in that the second guide elements (23, 24, 33, 34) comprise a guide socket (23) and a guide pin ( 33) having a terminal portion (34) slideable in the guide fitting (23). 9. Button-operated switch (10) according to claim 8, characterized in that the guide pin (33) extends from the button body (30) towards the lower wall (21) and where the guide fitting (23) is fixed to the lower wall (21). 10. Button-operated switch (10) according to claim 8 or 9, characterized in that said terminal portion (34) of the guide pin (33) has a cross-shaped section. 11. Button-operated switch (10) according to any one of claims 8 to 10, characterized in that the guide pin (33) does not interfere with the side walls of the housing (20) during sliding movements of the button (30) in relation to the box (20). 12. Button-operated switch (10) according to any one of claims 8 to 11, characterized in that the guide pin (33) is integrated into the button body (30). 13. A button-operated switch (10) according to any one of claims 8 to 12, characterized in that the guide fitting (23) includes four side walls (24) being parallel in pairs. 14. Button-operated switch (10) according to claim 13, characterized in that the side walls of the guide fitting (23) are separated from each other. 15. Button-operated switch (10) according to any one of the preceding claims, characterized in that said switch is a button-operated switch including a rocker control member (70). 16. Button-operated switch (10) according to claim 15, characterized in that it includes a pressure transmitting element (50) rotationally restricted to the button (30) and wherein the control member (70) is restricted rotatably to two opposite side walls of the box (20).