The present invention relates to a key module according to the main claims. The key module may be used in a computer keyboard, for example.
Most available key modules (which may also referred to as key module) are relatively high and hard to integrate into the flat keyboards or notebooks. In usual modules, also a “clicking” is variant is realized on the basis of the two-part tappet, in order to output an indication of an actuated key to a user of the key module. In flat key modules, the clicking sound is realized by means of an additional mechanism due to the lack of available space. Consequently, electric switching process is decoupled from the process of producing the clicking sound and thus does not take place synchronously with the production of the clicking sound. Also, LED illumination is designed from one side in most known key modules so that uniform illumination of a surface facing the user of the key module is not possible with one LED (in particular keys with two or three symbols). Furthermore, most key modules are designed to be relatively untight for cost reasons so that damage to the keyboards quickly occurs when water or watery liquids are spilt, for example. The weak spots in the key module with respect to damage caused by liquids especially are the electric switching mechanism and guidance of the tappet. Moreover, on the part of the user, there is often a need for different key modules, for example with a linear force path upon actuation, with a pressure point for actuation, with a clicking sound upon actuation and with various force-displacement characteristics. However, such variety necessitates an enormous variety of variants of key modules, which mostly are to be produced in different modes of production and thus at high cost, to be kept available by the key manufacturers. Also, the guidance of the tappet in low modules upon actuation of such a key module is shortened, which increases the likelihood of canting of the key. In a so-called “silent” design of a key module, an expensive two-component tappet is used, which significantly increases the overall module cost. Also, reduced constructional height makes electronic devices (especially when using SMD-based components) hard or impossible to mount the upper side of a circuit board, in particular in connection with frame assembly. Moreover, assembly on the bottom side of the key modules also is problematic because certain components should be directly attached to the modules. Significant difficulties result therefrom in a subsequent module soldering process (especially when using a solder wave), because all components need to be covered. In addition, there is the risk of destruction of the electronic devices due to electrostatic discharge (of up to 8 KV).
Against this background, the present invention provides an improved key module according to the main claims. Preferred embodiments are obvious from the dependent claims and the subsequent description.
The approach presented here provides a key module comprising:
An actuation element may be seen as a tappet, for example. The cam nose may be seen as a protrusion of the actuation element, for example, which engages behind another element such as the contact nose, deflects it and/or takes it along in the case of movement in the direction of the movement axis. A movement axis may be an axis along which the actuation element is moved or movable with respect to the housing element. A contact element may be seen as an element at least partially consisting of electrically conductive material and fixed at a predetermined position in the housing element, for example. The housing element may, for example, be seen as a bottom element for accommodating the contactor unit, the contact element and the actuation element, wherein the housing element may further also comprise, as a further portion, a cover element to encapsulate the components mentioned. A contactor unit may be seen as element comprising a contact nose movable in various directions, wherein the contact nose may be seen as a region of the contactor unit in which electric contact to a corresponding counterpart may be closed. The contact element may, for example, serve as a counterpart to the contactor unit, in order to close an electric contact in the form of a switch. A constructive element may be seen as a guiding surface, a strut, a contour of the cam nose (particularly on its outer surface) or surface on the cam nose, for example, formed to deflect the contact nose in a direction along and/or transverse to the actuation axis, when the contact nose is guided, for example taken along by the cam nose and deflected on the constructive element when the actuation element is moving along the actuation axis.
For example, the housing element may comprise a cover element as a subsection through which the actuation element is guided and/or supported. Also, the housing element may be formed to accommodate the contact element, the contactor unit and at least part of the actuation element. The actuation element and/or the cam nose may comprise a constructive element or a guiding surface oriented obliquely with respect to the direction of the movement axis and formed to deflect the contact nose from a rest position adjacent to the contact piece in the direction along and/or transverse to the movement axis, when the contact nose is taken along or deflected by the cam nose when the actuation element is being depressed.
The approach presented here is based on the finding that, by using the cam nose on the actuation element in a movement of the actuation element along the movement axis, i.e. when depressing the actuation element, the contact nose, as the region of the contactor unit designed so as to be the most movable one, is taken along or around and guided along the constructive element until the contact nose is laterally deflected by sliding on the constructive element so far that it slides laterally past the cam nose and hereby is released (for example abruptly) so as to snap back into its original position, i.e. the rest position. Hereby, on the one hand a clicking noise can be generated, which is very close in time to electrically contacting the contact nose with the contact element, so that the clicking sound may also be perceived as very promptly as confirmation of the electric contact between two electric contacts by a user of the key module. The approach presented here offers the advantage that constructive effort of equipping the key module with a unit for producing the clicking sound can be avoided by deflecting and snapping back of the contact nose of the contactor unit as a part of an electric contact switch. In this way, a key module which is inexpensive and simple to manufacture, yet still has the advantages mostly highly valued by users can be provided.
According to a special embodiment of the approach presented here, the constructive element may be formed to guide the contact nose around the cam nose when the actuation element is being depressed. Such guiding around may mean that the contact nose has the greatest distance to the movement axis at the time of this guiding around, for example. In this manner, the contact nose may be released very easily and at a defined distance, in order to both produce the clicking sound after snapping back and ensure the electric connection in a reversibly repeatable way after depressing the actuation element by a certain distance.
What is also advantageous is an embodiment of the approach presented here wherein the housing element comprises a distance limitation element to limit a distance of movement of the contact nose in the direction of the movement axis. Such an embodiment of the approach presented here offers the advantage that by providing the distance limitation element a distance of movement of the contact nose may be limited so that excessive strain on the contact nose, which would result in a clicking noise perceived as too loud by a user of the key module, can be avoided.
What is also advantageous is an embodiment of the approach presented here wherein cam nose and/or the constructive element comprises a guiding surface oblique with respect to the orientation of the movement axis, in particular wherein the guiding surface is arranged so as to proceed in the direction of a movement of the cam nose from an original position. Alternatively or additionally, the contactor unit may also be formed to hit the contact nose on the at least one portion of the housing element after a deflection on the constructive element. Such an embodiment offers the advantage of both forming a defined surface for deflecting the contact nose with as little force and friction as possible and providing a strike surface on the housing element or cover element, which may be both reinforced correspondingly and structured correspondingly for producing a certain sound and connected to further regions of the housing element and/or cover element.
What is also advantageous is an embodiment of the approach presented here in which the contactor unit at least partially comprises a U-shaped portion, in particular wherein the contact nose is arranged on one end of the U-shaped portion of the contactor unit, and/or wherein a U-shape of the contactor unit is formed in a plane oriented substantially perpendicularly with respect to the movement axis. Such an embodiment of the approach proposed here offers the advantage of a contactor unit being very easy to realize technically, yet having the contact nose with corresponding desired mobility various directions of. For example, the contactor unit may be formed as a correspondingly shaped bent metal strip.
What is also conceivable is an embodiment of the approach presented here in which the contactor unit has (mechanical) stiffness greater with respect to movement of the contact nose in the direction of the movement axis then in the direction transverse to the movement axis. Such an embodiment of the approach proposed here offers the advantage that the contact nose moves significantly more quickly in the direction of the movement axis than transverse to the movement axis when moving back after being guided around over the cam nose. In this way, it is ensured that the clicking sound is caused substantially by movement in the direction of the movement axis, which is designed clearly reproducibly and offers sufficient snapping path for the contact nose so as to generate the clicking sound in a clearly perceptible manner for the user.
What is particularly reliable and long-life is an embodiment of the approach proposed here in which the contactor unit comprises, in the region of the contact nose, a strike portion formed to strike the contact nose on the at least one portion of the housing element or the cover element. In particular, the strike portion may comprise a surface aligned substantially in parallel with the at least one portion of the housing element or the cover element or part of the cover element, and/or wherein the strike portion is formed by an angled part of the contactor unit or the contact nose, and/or wherein the strike portion has a length of a surface oriented toward the at least one portion of the housing element or the cover element greater than a thickness.
So as to ensure quick and repeated actuation of the key module, the return movement of the actuation element along the movement axis should take place as unhindered as possible or only with little hindrance. What is particularly advantageously is an embodiment of the approach proposed here in which the cam nose of the actuation element comprises at least one reset surface portion, which comprises a surface oriented obliquely with respect to the direction of the movement axis, in particular wherein the reset surface portion is formed to guide the contact nose around the cam nose upon a reset of the actuation element. In this way, it can be ensured that the contact nose or the contact tip can be guided around the cam nose easily and without increased effort when the actuation element moves back to the rest position. In addition, there is the possibility of producing a clicking sound also in the reset of the actuation element, in this case for example when the contact nose is lifted from the contact element and is guided back onto the contact element after being guided around the cam nose.
According to another embodiment of the approach proposed here, the contactor unit may have, in the region of the contact nose, a surface portion the surface of which is oriented obliquely with respect to the direction of the movement axis, in particular the surface of which at most is oriented at an acute angle with respect to the constructive element, in particular the surface of which is aligned in parallel with the constructive element. This surface portion may be formed and arranged to slide along on the constructive element. Such an embodiment of the approach presented here offers the advantage of particularly low-friction sliding of the surface portion on the constructive element. In this way, it is achieved that the key module can be actuated with as little force as possible and reliably.
What is particularly advantageous is an embodiment of the approach proposed here in which the at least one portion of the housing element or the cover element has a cover slope with a surface oblique with respect to the direction of the movement axis in the region of an opening through which the actuation element is guided, and/or wherein the actuation element has a tappet slope with a surface oblique with respect to the direction of the movement axis in a passage area surrounded by the at least one portion of the housing element or the cover element. In particular, the cover slope may be arranged circumferentially around the opening in the at least one portion of the housing element or in the cover element. Alternatively or additionally, the tappet slope may also be arranged circumferentially around the actuation element in the passage area. Such an embodiment offers the advantage of a particularly tight lock between at least one portion of the housing element or the cover element and the actuation element, in particular for avoiding entry of the liquids into the key module.
What is particularly well protected against entry of liquids is a key module according to an embodiment of the approach presented here in which a sealing element arranged between the at least one portion of the housing element or the cover element and the housing or bottom element is provided, in particular wherein the sealing element is arranged or press-fit in a groove of the at least one portion of the housing element or the cover element and/or a groove of the housing or bottom element. In such an embodiment, in particular, capillary action can be utilized to prevent the liquid from entering the key module.
In an embodiment of the approach proposed here which offers particularly great protection against liquids entering the key module, the sealing element may close the region of the actuation element, of the contactor unit and of the contact element in a fluid-tight manner, in particular wherein the sealing element is formed in the shape of a labyrinth seal or as a labyrinth seal. Hereby, a hermetic seal of the components most important for the function of the key module can be achieved with little cost of materials.
According to another embodiment of the approach proposed here, the at least one portion of the housing element or the cover element may comprise at least one light guiding element, in particular wherein the light guiding element is formed at least partially annularly around a region in which the actuation element is guided through the at least one portion of the housing element or the cover element. Such an embodiment offers the advantage of a particularly good possibility of eliminating a keycap to be put on the key module, so that the user can recognize the meaning of the symbols on the keycap quickly, unequivocally and reliably.
So as to ensure maximum protection against canting of the actuation element when being depressed, according to a further embodiment, the actuation element may comprise a cylindrical keycap support portion in a passage region, in which it protrudes through the at least one portion of the housing element or the cover element, and at least one rib on a guiding portion on an outer surface adjacent to the keycap support portion, and wherein the housing or bottom element comprises, for accommodating the guiding portion of the actuation element, at least one accommodating bowl with at least one recess for accommodating the rib of the actuation element.
The actuation element can be guided in a particularly safe manner when being depressed if the actuation element comprises an at least partially hollow cylindrical portion in the region of the guiding portion, in particular wherein the at least one rib is formed on an outer surface of the hollow cylindrical portion, and/or wherein a guiding piston of the housing element engages the hollow cylindrical portion of the guiding portion of the actuation element.
A key module according to a further embodiment can be made particularly low-noise by providing a shock absorber element arranged between the actuation element and the housing element, in particular wherein the shock absorber element is formed to be cylindrical or annular. Such an embodiment of the approach proposed here offers the advantage of using standardized conventional components, such as rubber stoppers, whereby an inexpensive variant of the low-noise key module can be produced.
The invention shall be explained in greater detail by way of example on the basis of the attached drawings, in which:
In the subsequent description of preferred embodiments of the present invention, the same or similar reference numerals shall be used for similarly acting elements illustrated in the various figures, wherein repeated description of these elements shall be omitted.
The key module 100 may be realized inexpensively in three variants in terms of function. Substantially, what changes is especially the actuation nose on the tappet 105, which is also referred to as cam nose 135 here, and in part a contour wall as constructive element 140 in the housing element 130, subsequently also referred to as guiding wall.
The tappet to 105 further comprises a cylindrical keycap supporting portion 160 (onto which a symbol-bearing keycap not illustrated in
In the assembled state of the key module 100, the guiding portion 165 is accommodated in an accommodating bowl 175 of the housing element 130, wherein the accommodating bowl comprises recesses not illustrated in
By using the tappet 105 with the keycap supporting portion 160, which projects through an advantageously circular opening of the cover element 110, the tappet 105 can be guided with as little canting as possible when the tappet 105 is being depressed. This low-canting guidance of the tappet 105 when being depressed can be enhanced further if the wing (or wings) 170 of the guiding portion 165 of the tappet 105 engage the recess(es) of the accommodating ball 175, and thus can ensure both guidance of the tappet 105 the direction of the movement during depressing and guidance with respect to rotation. Hereby, very low-canting actuation of the tappet 105 of the key module 100 can be ensured.
Moreover, it can be seen in
Particular focus lies on the click variant described with reference to the subsequent figures is an embodiment of a key module 100. In contrast to most solutions known worldwide, in which a clicking sound is produced with an additional part or additional mechanism supplementary to the electric switching mechanism, the clicking sound is induced directly by one of the electric switch contacts, for example by an impact of part of the contactor unit 115, especially the contact nose 140, on the cover element 110 or tappet 105 after passing the cam nose 135, according to the approach presented here. Thus, only the components of the electric switch contacts are necessary as part or component for providing the click and switch function.
According to the embodiments of the approach presented here, the contactor unit 115 is designed so that at least part of the contactor unit 115 can be deflected (actuated) three-dimensionally, like the contact nose 140. The contactor unit 115 is installed in the switch module or key module 100 in a preloaded state so that, for example, gold crosspoint contacts of the contactor unit 115 (forming the contact tip 145, for example) and of the fixed contact or the contact element 120 are pressed onto each other. With a defined preload, a defined contact force is set in the switched (i.e. electrically connected) state, which remains virtually unchanged over the entire life. This preload or actuation movement takes place in the horizontal plane, i.e. in a direction transverse or perpendicular to the movement axis CC. In particular, this is valid for the linear and pressure point variants of the key module 100 mentioned here.
In the clicker variant according to the embodiment presented here, in which also a clicking sound is produced in addition to the electrical switching, the contactor unit 115 or the contact nose 140 as part of the contactor unit 115 is deflected also in the actuation direction or in the direction of the movement axis 200, which means vertically corresponding to the illustration in
When the cam nose 135 is being depressed further, the contact nose 140 is deflected transversely to the direction of the movement axis 200 by the cam nose 135, i.e. to the right in the horizontal direction in the illustration of
Furthermore, there may be provided a surface portion 500 of the contact nose 140 which is oriented obliquely with respect to the direction of the movement axis 200. Specifically, the surface of the surface portion 500 may be oriented at most at an acute angle to the movement axis 200, wherein particularly small sliding resistance can be achieved when the contact nose 140 slides along on a reset surface portion described in greater detail in the following, if the surface of the surface portion 500 is aligned in parallel with this reset surface portion.
After the strike of the contactor unit or the contact nose 140 the cover element 110 or the strike wall 610, the contactor unit 110 or the contact nose 140 the horizontal plane, i.e. towards the tappet 105 or the contact element 120, the electric contact is closed with predefined force.
What can also be seen in
After releasing the tappet 115, due to the reset force of the compression spring 125, the return of the tappet 105 to an original position takes place. In this process, the contactor unit 115 of the contact nose 140 is deflected in the right direction from
The sound and the intensity of the clicking sound may be adjusted arbitrarily by the deflection path, material properties of the contactor unit 115, distance to the strike surface 610, stiffness and weight of the contactor unit or the contact nose 140.
Due to the small constructional height of the embodiment of the key module 100 presented here, it is useful to enhance the anti-canting protection of the actuation guidance for the actuation or the depression of the tappet 105 in the key module 100. In order to achieve this with limited length of a guiding device for guiding the movement of the tappet along the movement axis 200, the lower guidance, i.e. a guiding device in the region of the housing element 130, should be designed to be as narrow as possible (for example about 1 mm) and the upper guidance, i.e. a guiding device in the region of the cover element 110 or the tappet 105, to be as wide as possible (to a certain degree). This poses a technical challenge because a guiding pin (usual design) with a diameter of 1 mm does not exhibit sufficient strength (for example in the case of providing a design of plastics material) and, if necessary, would have to be manufactured in a very costly manner from special materials. For this reason, the tappet 105 according to the embodiment presented here with designed such that the upper guidance in the region of the tappet 105 takes on a cylindrical shape with great diameter (which is easy to manufacture).
A relatively good seal with positive locking of the key module 100, at least in the non-actuated state, is ensured by the interface between the cover element 110 with the cover slope 225 and the tappet 105 with the tappet slope 220, which form a conical ring stop. Additionally, in contrast to most known key modules, the upper guidance is formed as a cylindrical holed sleeve, which means a cylindrical guiding portion 160 of the tappet 105, which may be guided in the opening 215. This embodiment prevents the entry of foreign particles and liquids in greater amounts also over the entire actuation path, as already disclosed with reference to
Because it happens every once in a while over the life of a keyboard that aqueous liquids are spilt, a certain resistance of the key modules 100 against the entry of liquids should be ensured at least in the rest position. The switching mechanism, which is the electric contact is such is presently the contactor unit 115 and the contact element 120, and the components for guiding the tappet 105, in particular the compression spring 125 and the wings 110 and the recesses 900, which would lead to loss of operability of the key module 100 in the case of conglutination, are particularly sensitive to water or sugary liquids, such as coke. For example, the robustness of the key module 100 is improved significantly by introducing a labyrinth seal as sealing element 150 between the cover element 110 and the housing element 130 acting as a base. The labyrinth seal as sealing element 150 protects the entire switching mechanism, which is the contactor unit 115 and the contact element 120, and the components for the guidance of the tappet 150, as already described with reference to
In certain customer applications, it is desired that the keyboards comprise reduced noise development. Presently, in MX Silent modules of the applicant, for example, costly two-component technology is used. Soft damper elements are sprayed in at certain locations here, in order to reduce noise development in the case of an impact of components to these parts. The manufacture of such a key module 100 thus is very expensive, limited in the selection of materials and requires special tools and processes.
In the approach presented here, a key module 100 is presented in which this issue is provided for by additionally installing a rubber profile as shock absorber element 230 (for example in a round, square, etc. . . . shape) as a damper element in the centering stud as guiding piston 235, for example.
Reduced construction of the height of the key modules 100 renders the assembly of frequently required electronic devices (for example SMD-based) on the top side of the circuit board as a carrier of the key modules 100 difficult or impossible, in particular in connection with frame assembly. Assembly of the required devices on the bottom side of such a circuit board also is problematic, because certain devices should be attached directly to the key modules 100. This results in considerable difficulties in the subsequent key module soldering process (especially when using a solder wave), because all components need to be covered. Moreover, there is the risk of destruction of the electronic devices due to electrostatic discharge (of up to 8 KV). According to embodiments of the approach presented here, placing SMD devices (for example LEDs, diodes; resistors) below the key module 100 on the top side of the circuit board can be provided as a solution of the problem.
If an embodiment comprises an “and/or” connection between a first feature and a second feature, this may be read to mean that the embodiment comprises both the first feature and the second feature according to one embodiment and either only the first feature or only the second feature according to a further embodiment.
Number | Date | Country | Kind |
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102018111707.8 | May 2018 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2019/062283 | 5/14/2019 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2019/219643 | 11/21/2019 | WO | A |
Number | Name | Date | Kind |
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10211006 | Liao | Feb 2019 | B2 |
10236141 | Tsai | Mar 2019 | B1 |
10275041 | Chen | Apr 2019 | B2 |
20170221653 | Liao et al. | Aug 2017 | A1 |
20180240622 | Yuan et al. | Sep 2018 | A1 |
20180330898 | Chen | Nov 2018 | A1 |
Number | Date | Country |
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0353900 | Feb 1990 | EP |
Entry |
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International Search Report for PCT/EP2019/062283 dated Jul. 31, 2019. |
Number | Date | Country | |
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20210175027 A1 | Jun 2021 | US |