RU2769958C1 - Four-wire switch - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: invention relates to the field of electrical units, namely, to inverter switches. The switch comprises a body and a button, four connecting terminals, a control element configured to rotate in two opposite directions around a first axis (a1) of rotation by means of the button, a rotor configured to rotate in two opposite directions by means of the control element around a second axis (a2) of rotation perpendicular to the first axis (a1) rotation, two oscillating switching elements configured to be rotated simultaneously by the rotor to form and break jumpers between pairs of connecting terminals.

EFFECT: provided inverter switch characterised by a reduced working stroke of the start button and reduced dimensions.

15 cl, 13 dwg

Description

FIELD OF TECHNOLOGY

[0001] The present invention relates to the technical field of electrical installations and, in particular, relates to a four-wire switch, which is also called an inverter switch.

BACKGROUND OF THE INVENTION

[0002] As is known, in modern electrical systems, such as, for example, wiring systems in buildings and structures, the use of modular electrical devices, such as modular switches or modular sockets, each of which is designed to perform a predetermined function, is widespread. By correctly combining modular devices with each other, you can get relatively more complex nodes in which a group of different functions is available.

[0003] Among the possible different types of modular switches are so-called four-wire switches, also called inverter switches. This type of modular switch is typically used in indoor lighting wiring circuits, for example, to control the same device or lighting unit from spatially different positions, i.e. from different lighting control points.

[0004] A prior art inverter switch 1 is shown in FIG. 1 showing a side view of the inverter breaker 1, and FIG. 2, which shows an exploded axonometric view of the inverter circuit breaker 1.

[0005] The inverter switch 1 includes a support structure 2 made of an electrically insulating material or a box-shaped housing 2 that defines an internal space for accommodating and attaching electromechanical components that are part of the inverter switch 1. Additionally, the inverter switch 1 includes a sliding button 3, which is closed by a corresponding overlay element 4, mechanically coupled, for example, by means of latches, with a sliding button 3, in such a way that it slides along with it along the sliding axis Z-Z.

[0006] In addition, the inverter switch 1 includes a dust cap 7, made, for example, in accordance with the ideas of patent application WO 2010006867 A1, called "Push-button switch with anti-jamming device". The protective dust cap 7 closes the button 16, which is slidably engaged with the guide frame 18 and can slide along it together with the button 3.

[0007] Inverter switch 1 includes a first pair of connection terminals 11, 12 and a second pair of connection terminals 13, 14. Inverter switch 1 includes two rocker switching elements 6 that move simultaneously such that inverter switch 1 selectively accepts one or the other of the following configurations:

- the first operating configuration, in which the first connection terminal 11 of the first pair of terminals 11, 12 is electrically connected only to the first connection terminal 13 of the second pair of terminals 13, 14 and in which the second connection terminal 12 of the first pair of terminals is electrically connected only to the second connection terminal 14 of the second pairs of terminals 13, 14; or

- the second operating configuration, in which the first connection terminal 11 of the first pair of terminals 11, 12 is electrically connected only to the second connection terminal 14 of the second pair of terminals 13, 14 and in which the second connection terminal 12 of the first pair of terminals is electrically connected only to the first connection terminal 13 of the second pairs of terminals 13, 14.

[0008] In the inverter switch shown in FIG. 1 and 2, there is only one rocker control element 5, which simultaneously rotates both rocker switching elements 6 by means of two spring-loaded links 8. By applying hand pressure to the button 3, the rocker control element 5 can be rotated. The pressure-transmitting rotary element 15 is functionally placed between the button 3 and the rocker control element 6 .

[0009] The pressure-transmitting rotary member 15, the rocker control member 5, and the pair of rocker switching members 6 are rotatable about three respective axes that are parallel to each other and perpendicular to the sliding axis Z-Z.

[0010] The design of the inverter switch 1 described above can be obtained from the design disclosed in international patent application WO 2010006867 A1 by adding a spring-loaded link and an appropriate rocker switching element and a proper arrangement of fixed and movable electrical contact elements.

[0011] The inverter switch 1 of the type described above has hitherto been widely used in electrical systems of residential or commercial buildings to control lighting devices or assemblies.

[0012] Although the inverter switch 1 of the type described above is widely used, however, it has some disadvantages.

[0013] The first disadvantage is that the inverter switch 1 has a relatively large extension in the axial direction.

[0014] The second disadvantage is related to the overall inertia of the mechanism and the noise that the user perceives when the inverter switch is operated manually.

[0015] The third drawback is related to the relatively long travel required to move the button 3 to move the inverter switch 1 from the first operating configuration to the second operating configuration and vice versa.

[0016] Therefore, there is a need for an inverter switch that can completely or partially overcome the shortcomings of the prior art inverter switch described above.

[0017] It is an object of the present invention to provide an inverter switch that satisfies the need described above.

[0018] Such a problem is solved using an inverter switch, such as generally described in claim 1 of the claims. Preferred and advantageous embodiments of the aforementioned inverter switch are defined in the appended dependent claims.

[0019] The present invention will be better understood from the following detailed description of specific embodiments, given for illustrative purposes and not limiting, with reference to the accompanying drawings, disclosed in the following section.

BRIEF DESCRIPTION OF THE DRAWINGS

[0020] FIG. 1 is a side view of a prior art inverter breaker.

[0021] In FIG. 2 is an exploded 3D view of the inverter circuit breaker shown in FIG. one.

[0022] FIG. 3 is a side view of a non-limiting embodiment of an inverter switch including a body, a button, a cover plate, and an operating element.

[0023] FIG. 4 is a three-dimensional view of the inverter circuit breaker shown in FIG. 3, in which the overlay and operating element have been removed.

[0024] FIG. 5 is an exploded 3D view of the inverter circuit breaker shown in FIG. 4.

[0025] FIG. 6 is a three-dimensional view of the inverter circuit breaker shown in FIG. 4, where the button has been removed.

[0026] FIG. 7 is a three-dimensional view of the inverter circuit breaker shown in FIG. 4, in which the button and part of the housing have been removed and in which the rotor is visible.

[0027] In FIG. 8 is a three-dimensional view of the inverter circuit breaker shown in FIG. 3, on which the body has been removed.

[0028] In FIG. 9 is a three-dimensional view of a part of the inverter circuit breaker shown in FIG. 8, where the button has been removed.

[0029] FIG. 10 is a three-dimensional view of a portion of the inverter circuit breaker shown in FIG. nine.

[0030] FIG. 11 is a plan view of an additional part of the inverter circuit breaker shown in FIG. nine.

[0031] In FIG. 12 is a three-dimensional view of an additional part of the inverter circuit breaker shown in FIG. 9, in which the rotor with some parts is shown transparent.

[0032] FIG. 13 is a three-dimensional view of an additional part of the inverter circuit breaker shown in FIG. nine.

DETAILED DESCRIPTION

[0033] With reference to the accompanying FIGS. 3-13, a specific, non-limiting embodiment of an inverter switch 100 or a four-wire switch 100 will now be described. For example, such an inverter switch 100 is a modular electrical device. For the purposes of this description, a modular electrical device means an electrical device intended to be installed in a wall-mounting frame, adjacent to other electrical devices of the same type or, more generally, adjacent to other modular electrical devices, such as, for example, sockets or other controls. electrical devices for energy management and distribution.

[0034] The inverter switch 100 can be operated manually by a user, and can be used without any restriction to control a lighting device or a node, for example.

[0035] The inverter switch 100 includes a housing 20, 21, preferably made of an electrically insulating material such as plastic, and a button 30 mechanically coupled to the housing 20 so that it can be moved relative to the latter.

[0036] Preferably, the button 30 is engaged, directly or indirectly, with the body 20, 21 so that it can slide relative to it along a Z-Z sliding axis between an initial rear position and a final forward position. For the purposes of this description, "forward end position" means the position at the end of the stroke when the button 30 approaches the body 20, 21, while "rear end position" means the position at the end of the stroke when the button 30 moves away from the body 20, 21. Thus, it is clear that the terms "front" and "rear" refer to the position of the button 30 in relation to the body 20, 21.

[0037] According to an alternative embodiment, the button 30 may be a rocker button instead of a button sliding relative to the body 20, 21. In the following description, for simplicity, reference will be made to the body, in which the button 30 is a button sliding in engagement with the body 20, 21, but without any restriction on the ability to make the button 30 a rocking type rather than a sliding one.

[0038] According to a preferred embodiment, the inverter switch 100 includes at least a resilient return member 33 operable to press the button 30 in the rear end position. According to a preferred embodiment, this rear end position is the only stable position of the button 30. In the non-limiting example shown in the illustrations, the inverter switch 100 includes, in particular, two coil springs 33, each of which pushes the button 30 to the rear end position.

[0039] The button 30 is preferably made of an electrically insulating material such as plastic.

[0040] According to a preferred embodiment, the button 30 includes a hollow button body 31 having an open side, and further comprises a button cap 32 attached to the hollow button body 31 so as to cover said open side. The button cap 32 is attached to the button hollow body 31 by means of locking connectors, preferably snap connectors.

[0041] The housing 20, 21 of the inverter switch 1 preferably includes a first part 20 and a second part 21 that are mechanically interlocked with each other, for example by means of latches.

[0042] The first part 20 of the housing 20, 21 preferably includes a hollow side wall 20a and a bottom wall 20b connected to the hollow side wall 20a. The first part 20 of the body 20, 21 has an open side 20c opposite the bottom wall 20b. The hollow side wall 20a and bottom wall 20b define an interior space within which button 30 slides.

[0043] The second part 21 of the body 20, 21 preferably includes a hollow side wall 21a and a bottom wall 21b connected to the hollow side wall 21a. The second part 21 of the body 20, 21 has an open side 21c opposite the bottom wall 21b. The open side 21c is closed by the first side of the housing 20 when the two parts of the housing 20, 21 are joined together. The hollow side wall 21a and the bottom wall 21d define an interior space capable of accommodating four electrical connection terminals 81, 82, 83, 84 in addition to some electromechanical components of the inverter breaker 100, which will be described later.

[0044] The electrical connection terminals 81, 82, 83, 84 are, for example, screw terminals. In one alternative embodiment, the connection terminals may be quick disconnect terminals, such as those described in patent application WO2010006867 A1 or the like.

[0045] According to a particularly preferred embodiment, the inverter switch 100 includes latch elements 29, 39 configured to engage the button 30 with the housing 21, 21, preferably the first part 20 of the housing 20, 21.

[0046] For example, such latch elements 29, 39 comprise additional latch elements located on the button 30 and on the housing 20, 21. , 21 at the assembly stage of the “body-button” assembly, and after the latches are bent, a fixed pairing is made between the button 30 and the body 20, 21, according to which the button 30 engages with the body 20, 21 with the possibility of sliding .

[0047] According to a preferred embodiment, the above-mentioned additional elements 29, 39 with a latch include a plurality of teeth 39 protruding from the button 30 towards the body 20, and a plurality of protrusions 29 delimited in the body 20, 21, in particular on the inside of the hollow wall 20c of the first part 20.

[0048] The inverter switch 1 preferably includes a system of spaced rails configured to guide the button 30 sliding relative to the housing 20, 21 along the Z-Z sliding axis. According to a particularly preferred embodiment, the spaced rail system is made in accordance with the teachings of patent application WO2017141089 A1 titled "Push Button Switch with Anti-Jamming Guide System". Such a system of spatially spaced guides includes first guide elements functionally located between the side walls of the button 30 and the hollow side wall 20a of the housing 20, 21, and the second guide elements deployed relative to the first guide elements and located at a smaller distance from the bottom wall 20b compared to the first guide elements. Preferably, the second guide elements comprise a guide socket 20d and a guide pin 30d sliding in the guide socket 20d. The guide pin 30d protrudes from the button 30 towards the body 20, 21 and preferably passes through the guide socket 20d defined in the lower part 20b of the first part 20 of the body 20, 21.

[0049] The inverter switch 100 further comprises a rocker control 50 rotatable about a first rotation axis a1 in two opposite directions by means of a button 30. The rocker control 50 is preferably hinged to the housing 20, 21 and preferably to the first housing part 20p 20, 21, more preferably towards the bottom wall 20b. For example, the bottom wall 20b includes a through opening 23 into which a rocking control element 50 is inserted.

[0050] According to an embodiment, the rocker control 50 comprises two oppositely spaced connectors that allow the rocker control 50 to pivotally mate with the housing 20, preferably with the first housing portion 20. In the specific example shown in the illustrations, the aforementioned opposite connecting elements comprise two opposite rods 59 protruding from the central body 55 in opposite directions. For example, such opposite rods 59 are inserted into respective through openings or recesses defined in two opposite walls of the first part 20 of the body 20, 21, for example, in two walls defining the through opening 23.

[0051] The inverter switch 100 further comprises:

a rotor 60 rotatable in two opposite directions by the rocker control 50 about a second rotation axis a2 which is perpendicular to the first rotation axis a1 of the rocker control 50;

- two swinging switching elements 72,73, made with the possibility of simultaneous rotation of the rotor 60 for the formation and interruption of bridges, ie electrical connections, between pairs of connecting terminals 81-84.

[0052] According to a preferred embodiment, the two rocker switching elements 72, 73 are configured to be simultaneously rotated by the rotor 60 to form and break bridges between the connection terminals 81, 82, 83, 84 such that the inverter switch 100 selectively accepts one or the other of the following configurations:

- the first working configuration, in which one first connection terminal 81 is electrically connected only to the second connection terminal 82, and the third connection terminal 83 is electrically connected only to the fourth connection terminal 84; or

- a second operating configuration, in which the first connection terminal 81 is electrically connected only to the third connection terminal 83, and the second connection terminal 82 is electrically connected only to the fourth connection terminal 84.

[0053] According to a particularly preferred embodiment, if the button 30 is a sliding button, in the rear end position, this button 30 does not interfere with the fit to the rocker control element 50, since said button 30 is configured to interact with the rocker control element 50 from a certain point when it sliding from the rear end position to the front end position.

[0054] According to a preferred embodiment, the button 30 includes a pressure transfer element 35 configured to abut the rocker control 50 from a certain point when the button 30 is moved from the rear end position to the front end position. The pressure transmitting member 35 allows hand pressure applied to the button 30 to be transmitted to the rocker control member 50 to make it rotate about the first rotation axis a1. The rocker control element 50 preferably has two stable angular positions.

[0055] The pressure transmitting element 35 is preferably rotatable about a third axis of rotation a3 in two opposite directions starting from an angular rest position (or center position). According to a preferred embodiment, the pressure transmitting member 35 is hinged to the button 30 and in particular to the button hollow body 32 .

[0056] The button 30 preferably includes at least a resilient member 36 configured to return the pressure transmission member 35 to its original angular position after it has rotated about the third rotation axis a3.

[0057] In order for the user to manually operate the button 30 with very limited resistance, the aforementioned resilient member is or includes a wire spring 36 and preferably a straight wire spring. The aforementioned wire spring 36 is, for example, a steel wire spring.

[0058] According to a particularly preferred embodiment, the pressure transfer element 35 and the resilient element 36 are made in accordance with the general or specific principles of patent application No. WO 2017141091 entitled "Push-button operated switch with rocker control".

[0059] The pressure transmitting element 35 preferably includes a central portion 37 and two contact protrusions 38 that are separated from the central portion 37.

[0060] The aforementioned pressure transmitting member 35 is configured such that, from a certain point during the sliding of the button 30 from the rear position to the forward position, it contacts the rocker control member 50, for example, through the contact projections 38. After such contact, the pressure transmitting member 35 starts rotation relative to the angular position of rest, and during further movement of the button 30, it determines the rotation of the rocker 50 about the first axis of rotation a1, starting from its first operating position to the second operating position. At this stage, if the pressure on the button 30 is released, it will return to its rear position due to the pressure from the coil springs 30, and the pressure transmission member 36 can return to its resting position due to the elastic return force generated by the wire spring 36, while the rocker control 70 preferably remains in the second operating position if this position is stable. In this case, when the button 30 is subsequently pressed, by means of a sequence of movements similar to that described above, the rocker control element 50 can return to the first operating position and remain there, despite the fact that the button 30 has been released, until the button 30 is pressed again.

[0061] The oscillating control element 50 preferably comprises a first contact portion having two shaped surfaces 58 that engage and receive pushing force from the pressure transmitting element 36, and in particular from the two protrusions 38, respectively. The aforementioned shaped surfaces 58 are preferably two stepped surfaces.

[0062] The rocker control 50 further comprises at least a rotation transmission member configured and adapted to rotate the rotor 60 about the second rotation axis a2 when the rocker control 50 rotates about the first rotation axis a1. For example, the rotation transmitting element includes two teeth 57 that protrude from the central portion 55 of the rocker control 50, between which a recess 56 is defined. In such an embodiment, the rotor 60 includes a protrusion 66 inserted into the recess 56.

[0063] The rotor 60 is preferably rotatably attached to the housing 20, 21, more preferably inserted inside the second housing 21.

[0064] According to an embodiment, the rotor 60 includes two opposing hinge members 64, 65, configured to engage with the first housing portion 20 and the second housing portion 21, respectively. In the specific example shown in the illustrations, the two opposing hinge members 64, 65 comprise, respectively, a rod 64 inserted inside a socket defined in the bottom wall 20b of the first body part 20 and a recess 55 inside which a rod protruding from the bottom wall 21b is inserted. the second part 21 of the body in the direction of the rotor 60.

[0065] The rotor 60 comprises two rotation transmitting elements 62, 63, each of which is engaged with a respective oscillating switching element 72, 73 and configured to rotate the oscillating switching elements 72, 73 when the rotor 60 rotates about the second rotation axis a2. According to a preferred embodiment, each of the oscillating switching elements 72, 73 rotates about a respective axis of rotation a4, a5 which is parallel to the second axis of rotation a2.

[0066] Each of the two oscillating switching elements 72, 73 preferably comprises a flat main element made of an electrically conductive material such as copper. The swinging switching elements 72, 73 are made of sheet metal, for example.

[0067] According to a particularly preferred embodiment, each of the rocker switching elements 72, 73 includes a pair of moving contacts located opposite each other. As shown in FIG. 11, in an exemplary embodiment, the oscillating switching element 72 comprises two opposite moving contacts m1, m2, and the oscillating switching element 73 comprises two opposite moving contacts m3, m4.

[0068] Thus, the oscillating switching elements 72, 73 are movable supports of the contact holder, in particular pivoting supports of the contact holder.

[0069] The inverter switch 100 preferably includes two electrically conductive support hinges 92, 93, each bearing a respective oscillating switching element 72, 73. The support hinges 92, 93 are made of, for example, cut and bent metal sheet.

[0070] In accordance with a particularly preferred embodiment, the rotor 60 exerts a pushing force, preferably through the rotation transmission elements 62, 63, on the rocking switching elements 72, 73 in order to press them against the respective support hinges 92, 93 and to ensure the continuity of electrical contact between support hinges 92, 93 and swinging switching elements 72, 73.

[0071] According to a preferred embodiment, at least one rotation transmission element 62, 63 comprises or consists of a sliding slider, and the rotor 60 comprises at least an elastic element 69 configured to push said sliding slider towards a corresponding commutating element 72, 73. Preferably, both elements 62, 63 of the transmission of rotation contain a corresponding sliding slider. More preferably, an elastic element, such as a coil spring 69, is functionally placed between the two sliding sliders.

[0072] Preferably, the rotor 60 comprises a hollow body, made of, for example, an electrically insulating material, through which passes a channel, inside which the elastic element 69 is located and inside which at least one slider 62, 63 slides, preferably two sliders, while , at least one sliding slider 62, 63 has a portion protruding outward from the channel to cooperate with the respective rocker switching element 72, 73.

[0073] In a currently less preferred embodiment, it can be ensured that only one of the rotation transmission elements 62, 63 slides and receives the pushing force from the resilient element 69.

[0074] Preferably, each support hinge 92, 93 includes a support and engagement portion 92a, 93a shaped to form a groove, such as having a V-shaped cross section. More preferably, each support hinge 92, 93 further comprises a connection section 92b, 93b which is part of the corresponding connection terminal 82, 83 of the inverter switch 100.

[0075] In accordance with a preferred embodiment, each of the oscillating switching elements 72, 73 is an L-shaped plate having a larger base resting on a respective support hinge 92, 93 and, in particular, on a respective support and contact area 92a, 93a and a narrower base arm to which the respective moving contacts m1, m2 and m3, m4 are attached.

[0076] Movable contacts m1-m4 are, for example, two pairs of opposite contact pads made of electrically conductive material, such as a silver alloy, fixed, such as welded, on opposite sides of the swinging switching elements 72, 73.

[0077] The inverter switch 100 further includes four fixed contacts f1, f2, f3, f4. Four fixed contacts f1-f4 are located at the corners of a quadrilateral, such as a rectangle.

[0078] According to a preferred embodiment, the inverter switch 100 includes two electrically conductive support members 91, 94 for fixed contacts f1-f4, such as copper. Each of the support elements 91, 94 is attached to or embedded in a respective connection terminal 81, 84.

[0079] According to a particularly advantageous embodiment, each support member 91, 94 supports a respective pair of fixed contacts f1-f4. In the example shown in the illustrations, the support member 91 supports the fixed contacts f1, f3 and the support member 94 supports the fixed contacts f2, f4. The fixed contacts f1-f4 are, for example, welded to the respective support elements 91, 94 and are, for example, pads made of an electrically conductive material, such as a silver alloy.

[0080] In one particularly preferred embodiment, the support elements 91, 94 are shaped like a T or a Y. In other words, each of the support elements 91, 94 includes a stem and two branches separating from the stem. Each of the two branches carries a corresponding fixed contact.

[0081] The proposed inverter switch 100 fully achieves its goals, because it overcomes the shortcomings inherent in known switches. In fact, due to the presence of the rotor 60 pivoting about an axis a2 perpendicular to the rotation axis a1 of the rocker control 50, a significant reduction in axial extension has been achieved.

[0082] In addition, a significant reduction in the stroke required for button 30 has been achieved.

[0083] Despite the principle of the invention, embodiments and implementation details will vary widely with respect to what is described and illustrated for illustrative and non-limiting purposes, without deviating from the scope of the invention as limited in the appended claims.

Claims (22)

1. Inverter switch (100), containing: - a body (20, 21) and a button (30) movable relative to the body (20, 21); - four connecting terminals (81-84); - swinging control element (50), made with the possibility of rotation in two opposite directions around the first axis (a1) of rotation using the button (30); - a rotor (60) rotatable in two opposite directions by means of a rocking control element (50) around a second axis (a2) of rotation perpendicular to the first axis (a1) of rotation; - two swinging switching elements (72, 73), made with the possibility of simultaneous rotation of the rotor (60) to form and interrupt jumpers between pairs of connecting terminals. 2. Inverter switch (100) according to claim 1, in which two rocker switching elements (72, 73) are made with the possibility of simultaneous rotation of the rotor (60) to form and interrupt jumpers between the connecting terminals in such a way that the inverter switch (100) selectively accepts one or the other of the following configurations: - the first working configuration, in which the first connection terminal (81) is electrically connected only to the second connection terminal (82), and the third connection terminal (83) is electrically connected only to the fourth connection terminal (84); or - the second operating configuration, in which the first connection terminal (81) is electrically connected only to the third connection terminal (83), and the second connection terminal (82) is electrically connected only to the fourth connection terminal (84). 3. Inverter switch (100) according to any one of the preceding claims, in which the rocking switching elements (72, 73), respectively, are rotatable about two axes (a3, a4) of rotation parallel to the second axis (a2) of rotation of the rotor (60 ). 4. An inverter switch (100) according to any one of the preceding claims, comprising four fixed contacts (f1-f4) located at the corners of a quadrilateral. 5. Inverter switch (100) according to any one of the preceding claims, comprising two electrically conductive bearing hinges (92, 93), each bearing a respective rocking switching element (72, 73). 6. Inverter switch (100) according to any one of the preceding claims, wherein the rotor (60) exerts a pushing force on the rocking switching elements (72, 73). 7. Inverter switch (100) according to claim 4, containing two electrically conductive support elements (91, 94) fixed contacts (f1-f4), while each support element (91, 94) carries a corresponding pair of fixed contacts (f1 -f4) . 8. Inverter switch (100) according to claim 7, in which the supporting elements (91, 94) are in the form of a letter T or letter Y. 9. Inverter switch (100) according to any one of the preceding claims, wherein the rotor (60) comprises two elements (62, 63) for transmitting rotation, each of which is engaged with a respective oscillating switching element (72, 73) and is made with the possibility of rotation of the swinging switching elements (72, 73) when the rotor (60) rotates around the second 15 axis (a2) of rotation. 10. Inverter switch (100) according to claim 9, in which at least one of the elements (62, 63) for transmitting rotation contains a sliding slider and in which the rotor (60) contains at least an elastic element (69 ) configured to push said sliding slider towards the corresponding rocking switching element (71, 72). 11. The inverter switch (100) according to claim 10, in which both elements (62, 63) of the transmission of rotation contain a corresponding sliding slider. 12. Inverter switch (100) according to claim 11, wherein said resilient element (69) is functionally placed between two sliding sliders. 13. An inverter switch (100) according to any one of the preceding claims, wherein the rotor (60) comprises a hollow body. 14. Inverter switch (100) according to paragraphs. 12 and 13, in which said elastic element (69) is located inside said hollow body. 15. Inverter switch (100) according to any one of the preceding claims, in which the housing (20, 21) comprises a first section (20) and a second section (21) interconnected, and in which the rotor (60) is placed in the second section ( 21) and is functionally placed between the second section (21) and the first section (20).

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