ITTO20130179A1 - SINGLE-DRIVE CONTROL SWITCH - Google Patents

Description

TITLE: SINGLE ACTUATOR CONTROL SWITCH

-------------------------------------------------- -------- The present invention relates to a control switch comprising an actuation mechanism for pushbuttons preferably comprising electronic contacts and silicone domes.

From patent application EP2468590 are known switches comprising mechanisms for actuating contacts comprising silicone domes in which an actuation tip is included, associated with a key, able to slide on an inclined plane in which during the stroke on the inclined plane, the tip acts on an actuator element which, by rotating around a fixed fulcrum point, included for example in the structure on which the same inclined plane is obtained, is able to act on a silicone dome. The action of the actuator element on the dome causes the structure to collapse and consequently close an electrical contact.

Although this solution is simple, difficulties arise in ensuring that all components of this switch have an adequate level of safety in the activation and deactivation of the command.

The main difficulties are due to the limited excursion that these rocker keys have, both for aesthetic reasons and for ergonomic reasons, which often do not guarantee the correct switching of the contacts.

In addition, the new structural specifications require the interaxial distance of the contacts to be increasingly reduced, for example the distance between the silicone domes. This implies that, given the reduced distance between the silicone domes and the fixed fulcrum point, it is necessary to generate a very large angle to obtain the stroke sufficient for electrical commutation. Said high angle is not suitable for a correct actuation of the dome, which should be as vertical as possible

The present invention aims to solve the aforementioned problems by making a control switch comprising an actuation mechanism with the characteristics of the attached claim 1.

The accessory characteristics of the present invention are present in the attached dependent claims.

The characteristics and advantages of this switch will be clearer and more evident from the following description of an embodiment with reference to the attached figures, which specifically illustrate:

Figure 1 illustrates an axonometric view of a switch, with associated operating mechanism, according to the present invention;

• figure 2 illustrates the exploded view of the button in figure 1;

• Figure 3 shows in a plan view of the switch and in particular of the housing structure, of the switch according to the present invention;

• figures 4A, 4B and 4C illustrate a first embodiment of the switch of figure 1 in three configurations assumed by the operating mechanism in three consecutive instants; Figure 4A the switch in the rest operating configuration, Figure 4B the switch in the transition from the rest operating configuration to the pull operating configuration; Figure 4C the switch in the operating configuration of pull;

• figures 5A, 5B, 5C and 5D illustrate a second embodiment of the switch of figure 1 in four configurations assumed by the operating mechanism in four consecutive instants; Figure 5A the switch in a first transaction to reach the operating pull configuration; Figure 5B the switch in a first transaction to reach the operating pull configuration; figure 5C the switch in the pull configuration, figure 5D the switch in a further stroke of the button after switching;

Figure 6 shows the displacement force graph obtained by the drive mechanism illustrated in figures 5A-5D;

• figures 7A-7D show sectional details of the different embodiments, in particular figure 7A shows a bottom section of the switch, with respect to a lower plane than the section plane used in figure 3; figure 7B a vertical section of the switch of figure 7A; figure 7C shows a detail of the tip, of the flared structure and of the contact portions in a first embodiment; figure 7D shows a detail of the tip, of the flared structure and of the contact portions in a second embodiment.

With reference to the aforementioned figures, the control switch comprises a key 2, for example rocking, through which the user acts on the switch, a housing structure 3, in the upper portion of which said key 2 is fixed so as to be able to rotate around to a first fulcrum "O"; a tip 4, fixed at one end to the key 2, moving integrally with it, in such a way as to slide along a first axis "X" of this key 2, opposed by an elastic means 41. Said elastic means 41 is for example a spring helical with pre-established elastic constant "w". Going into the manufacturing details, the tip 4 comprises a sliding portion 43, located at its free end.

This housing structure 3 is preferably a box-like structure in which the upper bases are open in such a way as to allow the insertion of the button 2 in the upper portion and the fixing of a printed circuit 5 in the lower portion as clearly visible in the attached figures.

At the lower end, once assembled in the drive mechanism, according to the present invention, a closing element 37 is fixed.

The printed circuit 5, located in the lower portion of said housing structure 3, comprises at least two buttons 51. A plurality of connection contacts 55 are fixed to said printed circuit 5 and electrically connected to the electrical circuits included in the printed circuit 5. Said connection contacts 55 protrude at least partially from the closing element to allow the switch to be connected to a further electrical circuit, for example included in a vehicle or boat.

This housing structure 3 comprises, in its internal portion 3 ', a flared structure 31 comprising two inclined contact planes 311, opposed for example specularly with respect to a second axis "Z", preferably vertical, creating a first acute angle "α" . On said inclined contact planes 311 said tip 4 can slide in its stroke.

Said flared structure 31 is structurally fixed to the housing structure 3, for example fixed to the internal walls of the internal portion 3 'of the housing structure 3. Said flared structure 31 can be made integrally with the housing structure 3, for example in a single body .

This switch comprises at least one actuator 6, positioned in proximity to said a flared structure 31, comprising two contact portions 65, each placed in correspondence with an inclined contact plane 311, on which the tip 4 acts during the stroke on said contact planes. inclined contact 311, and two actuation portions 63, each located in correspondence with a button 51 and adapted to act on the respective button 51.

As a function of the direct action of the tip 4, each actuator 6 is able to rotate around one of two rotation points (T, T ') which are movable, distinct and specular with respect to said second vertical axis "Z", as a function of direction of rotation of the button 2.

Following the direct action of the tip 4, each actuator 6 is able to rotate around one of two rotation points (T, T '), according to the direction of rotation of the button 2, in particular with respect to the direction of rotation. button 2.

Each of the two points of rotation (T, T ') is preferably respectively in correspondence with an actuation portion 63 of the actuator 6 itself. A pivot point (T, T '), depending on the action on the key 2, is in correspondence with the actuation portion 63 opposite to the actuation portion 63 which must act on the button 51. By varying the direction of rotation of the key 2, varies the pivot point (T, T ') around which the actuator rotates, varying its position between the two actuation portions 63.

In the preferred embodiment, the actuator 6 is monolithic, in particular made in a single piece.

Preferably, said contact portions 65 are interposed between the two actuation portions 63. Said actuation portions 63 are positioned at the ends of the actuator 6 with respect to the longitudinal axis "K" of the same actuator, as for example visible in Figure 3.

In the preferred embodiment, each pushbutton 51 comprises at least one silicone dome 511, and at least one electrical contact 512 able to close an electrical circuit following the compression of the dome 511, for example following the collapse of the dome itself. Preferably, the actuation portion 63 of the actuator 6 is placed above said silicone dome 511. In the detail of a first embodiment of the actuator 6, each contact portion 65 is an inclined plane, preferably with a variable slope, both with the same profile. Said contact portions 65 are opposite specular with respect to said second axis "Z" realizing a second flared structure with a second acute angle "φ", as clearly visible in figure 7C.

This configuration of the contact portion 65 performs the function of a cam through which a button 51 is activated following the interception of the same portion 65 by the tip 4.

Said second acute angle “φ” is lower than said first acute angle “α” realized by the inclined contact plane 311, as clearly visible in figure 7C.

Said actuation mechanism is assembled in such a way that said actuator 6 rotates around the rotation points (T, T '), respectively rotating around a first rotation point (T) when the key 2 is rotated in one direction, for example counterclockwise or push, and rotates around a second pivot point (T ') when key 2 is rotated in the opposite direction, such as clockwise or pull.

Even more in detail, as shown in the figures, said pivot points (T, T ') are in correspondence with the actuation portions 63, and in particular at the actuation portion corresponding to the button 51 opposite to the button 51 which must be operated following the rotation of key 2.

This switch essentially assumes three operating configurations:

• rest in which the first axis "X" of key 2 is substantially parallel to the second vertical axis "Z", and both buttons 51 are both deactivated, for example open;

• of push, in which key 2 is inclined, preferably forward, for example counterclockwise, in such a way as to move the tip 4 and activate a first button, for example the button located to the left of the "Z" axis as visible in the attached figures;

• pull, in which key 2 is tilted in the opposite direction to the push configuration, preferably backwards, in such a way as to move the tip 4 and activate a second button, for example the button located to the right of the "Z" axis as visible in the attached figures.

The transition from the rest configuration to one of the other configurations of the switch requires the intervention of the user, who imposes a force on key 2, making it move around the first fulcrum "O". The key 2, rotating around the fulcrum “O”, drags the tip 4 integral with it in the movement.

Once the user has applied force on key 2, it automatically returns to the rest configuration. This phenomenon is allowed by the action of the elastic means 41 and the flared structure 31.

The sliding portion 43, during the movement performed by the tip 4, crawls on an inclined contact plane 311, since the same tip 4 is opposed by the elastic means 41.

During the stroke of the tip 4, the sliding portion 43 intercepts the actuator 6, at a predetermined angle of rotation of the button 2, causing it to rotate around the corresponding fulcrum "T" or "T '".

In the embodiments illustrated, the pivot point is in correspondence with the actuation portions 65 located above the silicone dome 511, and in particular in contact.

The intercepted actuator 6, in turn, exerts a force on the silicone dome 511, corresponding to the intercepted contact portion 65. The force imparted by the push rod 4 to the actuator 6, by means of said actuation portion 63, is transmitted to the corresponding dome 511. In particular, the actuated contact portion 65 imparts a compression force to the dome 511 of the corresponding button 51, causing electrical switching . In this situation, the actuator 6 will rotate around the pivot point (T, or T ') corresponding to the actuation portion 63 opposite to the actuation portion 63 acting in compression on the dome. In particular, the actuator 6 rotates around a rotation point (T or T ') placed in correspondence with the actuation portion 63, not affected by the action of the tip 4 on the contact portion 65.

By releasing the switch button 2, according to the present invention, the drive mechanism automatically returns to the rest operating configuration.

When the switch is in the operating configuration of rest, the actuator 6 ends its action on the corresponding button 51, thus avoiding involuntary switching.

The silicone dome 511 has elastic properties which allow the dome itself to return to its initial shape, after it is crushed and / or deformed.

Said silicone dome 511 is preferably made of a silicone mat, placed for example above the printed circuit 5. Preferably all the silicone domes included in the switch according to the present invention, are included in the aforementioned silicone mat.

In various embodiments not illustrated, said silicone dome can comprise said electrical contact 512, integrated thereto. In the embodiment illustrated in the images, the electrical contacts 512 are comprised in a suitably shaped metal sheet.

Each actuation portion 63 is adapted to be positioned in correspondence with the respective silicone dome 511, and in particular on its top, preferably in contact. Said contact portion 65 is also the pivot point around which the actuator 6 rotates when operated by the tip 4 to actuate the opposite contact.

In the assembly of the switch according to the present invention, said actuator 6 is placed in such a way as to rest on the silicone domes 511 in the rest operating configuration of the switch. Said silicone domes are placed at a known and dictated interaxial distance "d" from the project specifications.

In the embodiment illustrated in the accompanying figures, the housing structure 3 is structurally associated with this flared structure 31 which in turn comprises at least two inclined contact planes 311, with equal inclination, mutually opposed so as to create a flared structure symmetrical and specular.

The difference between said first acute angle "α" and second acute angle "φ" define a difference in inclination between the first flared structure 31 of the housing structure 3 and the second flared structure made by the contact portions 65, as clearly visible in the figures attached. The resulting difference in inclination allows the tip 4 to act on the actuator 6, which, by rotating around the appropriate rotation point "T" or "T '", will press on the silicone dome 511 of the associated button 51, by means of the suitable actuation portion 63.

This key 2 comprises a guide 21, suitable for housing a portion of said tip 4, allowing the tip 4 itself to be able to slide along the first axis "X" of the key 2 during the transitions between the various operating configurations, opposed by at least one means elastic 41 for example a helical spring.

The run of the tip 4 inside the guide 21 is delimited, in one direction by the structure of the elastic means 41 itself, and in the opposite direction, by limit switches made in the guide 21, not illustrated in detail.

For the purposes of this description, the behavior of the switch components according to the present invention will be described in detail below, illustrated for example in figures 4A-4C.

In the rest operating configuration, the first axis "X" of the button 2 is substantially parallel to the axis "Z" of the switch since the sliding portion 43 of the tip 4 is positioned in the lowest point of the flared structure 31 and kept in this position, avoiding involuntary vibrations or movements, by the action of the elastic means 41 on the tip 4 itself, as visible in Figure 4A. In this operating configuration, said actuator is placed in such a way that its longitudinal axis "K" is orthogonal to the "Z" axis

In the preferred embodiment, the sliding portion 43 is kept in this position also by the contact portions 65 of the actuator 6, which create a flared structure in which the inclined planes have greater slope, given by the lower acute angle "φ".

When the key 2 is used to switch to the pull configuration, it rotates around the fulcrum "O" by dragging the tip 4 in movement, which is opposed by the elastic means 41, starting to slide on the inclined contact plane 311, as illustrated in Figure 4B.

The tip 4, during its stroke, intercepts the corresponding contact portion 65 of the actuator 6, which in the illustrated case is an inclined plane, causing it to rotate around the corresponding point of rotation "T", hence the actuation portion 63 of the the same actuator 6, when lowered, acts on the corresponding button 51, compressing the silicone dome 511, causing electrical switching.

Going into the detail of the illustrations in the pull configuration, the tip slides on the contact plane inclined to the left with respect to the second axis "Z", acting on the corresponding contact portion 65. The action of the tip on the contact portion 65 rotates the actuator 6 around the pivot point "T" located in correspondence with the actuation portion 63 located to the right of the second axis "Z". This rotation causes the opposite actuation portion 63, ie the one on the left, to lower, by acting on the corresponding button 51 and in particular by compressing the silicone dome 511. During the compression of the left silicone dome, the right silicone dome does not collapse since the compression force acting on this cathedral it is not enough for its collapse. These characteristics are clearly visible in figure 4C. In the push or pull operating configuration of the switch according to the present invention, it is inclined, not perpendicular, with respect to the vertical "Z" axis.

Once the action on the key 2 by the operator has ended, due to the effect of the elastic means 41 the tip crawls in the reverse direction returning to the operating rest condition, releasing the contact portion 65 from its action and the actuator 6 eliminating the action of the portion 63 on the corresponding dome 511.

The actuator 6 is in turn brought back into position by the dome 511, which thanks to its elastic characteristics allows it to rise again by returning the activator 6 to its position.

By acting on key 2, to switch to push configuration, the sequence is repeated in a mirror-like manner, involving the contact portion 65 on the right and rotating around the second rotation point "T '", located in correspondence with the actuation portion on the left, with respect to to the second "Z" axis.

In the event that the user continues to maintain in a configuration, push or pull, the switch the tip 4 through the sliding portion 43 continues to act on the corresponding contact portion 65 of the actuator 6, without generating spurious switching of the button 51 .

In the embodiment illustrated in Figures 5A-5D, said contact portions 65 have a configuration such as to obtain a predetermined course of the force / displacement function perceived by the user, and in particular, to obtain a force / displacement function in which there is a point balance "e", in which without further displacement of the key 2 there is a substantially instantaneous reduction of the force which results in the switching of the button 51 and in particular the collapse of the silicone dome 511 which acts on the contact 512, switching.

This function is described in the graph shown in figure 6.

In the first section "a" of the graph corresponds to the phase preceding the configuration shown in figure 5A in which the tip 4 slides along the inclined contact planes 311 until it reaches point "b" where it begins to intercept the contact portion 65. Upon reaching a point "b", the mechanism arrives in an operating configuration, for example illustrated in figure 5B in which the tip 4, instead of continuing in its run along the inclined plane 311, compresses the elastic means 41, equipped with a predetermined elastic constant “W”, sliding on the same portion of contact 65. When the key 2 is rotated, the elastic means 41 will continue to compress, corresponding to the line “c” of the graph, up to the point “e” of the graph.

Along the section "c" of the graph, the conformation of the contact structure 65 on which the tip 4 slides, causes the elastic means 41 to compress, accumulating energy. Upon reaching the point "e", without further displacements of the button 2, there is a substantially instantaneous reduction of the force which results in the switching of the button 51, and in particular in the collapse of the dome 511. This configuration is visible in Figure 5C. Figures 5B and 5C substantially correspond to the same displacement of the key 2 but to two consecutive instants of time, before and after the reduction of force visible in the graph of Figure 6.

The point "f" corresponds to the point in which the tip starts to slide again along the contact portion 65, completing the section of the graph "g". Point "h" corresponds to the limit switch in the rotation of button 2.

To obtain this result in the feeling and in the desired displacement graph, the conformation of the respective contact portions 65 was carried out and in particular by realizing:

• a first portion in which the contact portion has a trend such as not to be influential for the actuation of the button 51, up to a predetermined angle of rotation of the button 2.

• a second portion with a horizontally asymptotic curved profile, substantially in the shape of a humpback.

Furthermore, the elastic means 41 has an elastic constant "w" with a predetermined value capable of compressing itself, during the sections "c" and "g" of the graph of figure 6, avoiding triggering the rotation of the actuator 6 in an involuntary way at angles of unwanted rotation.

Furthermore, the portion with curved profile of the contact portion 65 causes there to be a multiplicative effect of the arm, thus allowing the passage substantially instantaneously between the points "e" and "f" of the graph of figure 6.

The substantially instantaneous term means that the decrease in the force represented in the graph and in transition between the configurations of Figure 5B and 5C occurs in an instant of reduced time, equal to a few milliseconds.

Each movement of the button 2 corresponds to the movement of a single actuation portion 63 of the actuator 6 and of the button 51 associated with it.

In the present solution, the criticalities of activating the pushbuttons are almost completely eliminated.

As mentioned above, the return movement of button 2 is implemented thanks to the elastic means 41, while returning the actuator 6 to the initial condition by ending the action of the latter on button 51, allowing the dome 511 to rise again.

In general, as can be seen in Figures 7A and 7B, in order to avoid longitudinal displacements of the actuator 6, for example along said longitudinal axis "K" during the movement of the button 2, at least one retaining element 67 is included, suitable to be inserted in a suitable housing 33 obtained for example in the internal portion 3 'of the housing structure 3. The positioning and location of this retaining element 67 is clear and evident from figures 7A and 7B, and in particular said retaining element 67 it is for example a projection included in the actuator 6, located in correspondence with the actuation portion 65.

Said retaining element 67 will act against the walls of the respective housing 33 when the contact portion 65, next to it, will perform the function of rotation point (T or T ') of the actuator, in order to avoid longitudinal displacement. of the same actuator 6, for example a movement in the direction towards the contact element 65 which is intercepted by the tip 4.

This solution allows to ensure the correct switching of the switch contacts despite the design specifications reduce the rotation angle of button 2 and the distance between buttons 51 is always shorter. This solution also does not need to increase the details or components necessary for the construction of the drive mechanism to allow the device to work, simplifying assembly.

NUMERICAL REFERENCES:

Button 2 Guide 21 Housing structure 3 Flared structure 31 Internal portion 3 'Inclined contact surfaces 311 Housings 33 Closing element 37 Plunger 4 Elastic means 41 Sliding portion 43 Printed circuit 5 Push button 51 Silicone dome 511 Electrical contact 512 Connection contacts 55 Actuator 6 Drive portion 63 Contact portion 65 Retaining element 67 First fulcrum "O" First axis "X" Second axis "Z" Longitudinal axis "K" First pivot point "T" Second pivot point "T '" First angle acute "α" Second acute angle "φ" Distance "d"

Claims (7)

CLAIMS: 1. Control switch comprising: • a button (2), • a housing structure (3), in the upper portion of which said button (2) is fixed in such a way as to be able to rotate around a first fulcrum (O); • a tip (4), fixed at one end to the key (2), moving integrally with it, in such a way as to slide along a first axis (X) of this key (2), opposed by an elastic means (41); • a printed circuit (5), comprising at least two buttons (51), located in the lower portion of said housing structure (3); this housing structure (3) comprises, in its internal portion (3 '), a flared structure (31) comprising two inclined contact planes (311), opposite each other specularly with respect to a second vertical axis (Z) realizing a first acute angle (α), on which said tip (4) can slide in its stroke; said flared structure (31) is structurally fixed to the housing structure (3); this switch comprises at least one actuator (6), positioned in proximity to said a flared structure (31); characterized by the fact that each actuator 6 comprises two contact portions (65), each placed in correspondence with an inclined contact plane (311), on which the tip (4) acts during the stroke on said inclined contact planes (311) , and two actuation portions (63), each located in correspondence with a button (51) and adapted to act on the respective button (51); and by the fact that as a function of the direct action of the tip (4), each actuator 6 is able to rotate around one of two pivot points (T, T ') which are movable, distinct and specular with respect to said second vertical axis ( Z), depending on the direction of rotation of the button (2). 2. Switch according to claim 1, in which two points of rotation (T, T ') each respectively corresponding to an actuation portion (63) of the actuator (6) itself. 3. Switch according to claim 1, in which the actuator (6) is monolithic. 4. Switch according to claim 2, wherein said switch each button (51) comprises at least one silicone dome (511), and at least one electrical contact (512) adapted to close an electrical circuit following the compression of the dome (511); the actuation portion (63) of the actuator (6) is placed above said silicone dome (511). 5. Switch according to claim 1, in which each contact portion (65) of the actuator (6) is an inclined plane; said contact portions (65) are opposite and specular with respect to said second axis (Z) realizing a second flared structure with a second acute angle (φ). 6. Switch according to one of the preceding claims, in which said contact portions (65) are interposed between the two actuation portions (63) and said actuation portions (63) are positioned at the ends of the actuator (6) with respect to the axis longitudinal (K) of the actuator (6). 7. Switch according to claim 1, in which at least one retaining element (67) is included, able to be inserted in a suitable housing (33) obtained for example in the internal portion (3 ') of the housing structure (3) in order to avoid longitudinal displacements of the actuator (6), along said longitudinal axis (K). 1. Control switch comprising: a key (2); • a housing structure (3), onto which upper portion said key is fitted so as to be able to rotate around a first fulcrum (0); • a rod (4), fitted on one end of the key (2) and moves therewith in an integral manner, so as to slide along a first axis (X) of said key (2), countered by an elastic means (41 ); A printed circuit (5), which comprises at least two push-buttons (51) arranged in the lower portion of said housing structure (3); said housing structure (3) comprises, in its inner portion {3 <1>), a flared structure (31) comprising two inclined contact planes (311), which are opposite to one another in a mirror-like manner with respect to a second vertical axis (Z), thus creating a first acute angle (a), on which said rod (4) can slide during its stroke; said flared structure (31) is structurally fixed to the housing structure (3); said switch comprises at least one actuator (6), which is arranged close to said flared structure (31); characterized in that each actuator (6) comprises two contact portions (65), each of which is arranged in correspondence to an inclined contact plane (311), on which the rod (4) acts during the stroke on said inclined contact planes (311 ), and two actuation portions (63), each of which is arranged in correspondence to a push-button (51) and is adapted to act upon the respective push-button (51); and in that as a function of the direct action of the rod (4), each actuator (6) is able to rotate around one of the two mobile rotation points (T, T <1>), which are distinct and mirror-like with respect to said second vertical axis (Z), as a function of the rotation direction of the key (2). 2. Switch according to claim 1, wherein the two rotation points (T, T ') are each respectively arranged in correspondence to an actuation portion (63) of the actuator (6) itself. 3. Switch according to claim 1, wherein the actuator (6) is monolithic. 4. Switch according to claim 2, wherein each push-button (51) comprises at least one silicone dome (511) and at least one electric contact (512), for closing an electric circuit after the compression of the dome (511); the actuation portion (63) of the actuator (6) is arranged on said silicone dome (511). 5. Switch according to claim 1, wherein each contact portion (65) of the actuator (6) is an inclined plane; said contact portions (65) are opposite to one another in a mirror- like manner with respect said second axis (Z), thus creating a second flared structure with a second acute angle (<p) ,. 6. Switch according to any of the previous claims, wherein said contact portions (65) are interposed between the two actuation portions (63), and said actuation portions (63) are arranged at the ends of the actuator (6) with respect to the longitudinal axis (K) of the actuator (6). 7. Switch according to claim 1, wherein at least one holding element (67) is provided, adapted to be inserted into a suited housing (33) obtained, for example, in the inner portion (3 ') of the housing structure (3 ), so as to prevent the actuator (6) from longitudinally moving along said longitudinal axis (K).