DE102015219348B3 - BUTTON FOR A CONTACT DEVICE - Google Patents

Abstract

The present invention relates to a probe (1) for a contact device (100) for checking the presence of a component. The push-button comprises: - an actuating element (2) movable in its longitudinal axis (3) between a starting position (4) and a first stop position (5), - at least one actuating element (2) perpendicular to the longitudinal axis (3) of the actuating element (2 ) deflectable contact element (9, 10), wherein the contact element (9, 10) at least one contact portion (11, 12) which in the deflection of the contact element (9, 10) by the actuating element (2) is deflectable such that the Contact section (11, 12) in a contact position (7) contacted an electrical element (24) for generating an electrical signal when the actuating element (2) has reached the first stop position (5). The contact element (9, 10) comprises a stem part (18) and a bottom part (19) for forming a spring, wherein the stem part (18) is angled substantially at right angles to the bottom part (19) and the longitudinal axis (20) of the stem part (19). 18) parallel to the longitudinal axis (3) of the actuating element (2). The stem part (18) has a stem (21) and at least two deflectable side parts (22), wherein the side parts (22) are each arranged laterally on the trunk (21), and wherein each side part (22) has a contact portion (11, 12 ) having.

Description

Technical area

The present invention relates to a probe for a contact device, in particular for a contact device for checking the presence of a component.

State of the art

From the prior art buttons are known as so-called controls, which are operated by pressing and which then return to the starting position. A button is therefore a switching device that produces an electrical contact with another component only as long as you press on a so-called switching rib. If you let go of the switching rib, it returns together with the actuated by their switching contact by spring pressure back to their original position.

A well-known type of button is the so-called membrane switch. By pressing with a finger or with a plastic button, conductor tracks made of foil are electrically connected.

Another type of known buttons, which are used for example in computer keyboards, remote controls or mobile phones, so-called silicone chess mats, also called Leitgummitaster. This type of probe consists of a conductive contact rib, which presses on a comb-like interlocking structure of conductive surfaces, for example on a printed circuit board.

However, this embodiment of a probe has the disadvantage that the contact with a printed circuit board is usually done via electrical contacts that usually protrude from such a button.

Another disadvantage of the known in the prior art buttons is that often a contact security is not sufficiently guaranteed. It is also disadvantageous for many buttons that they are housed in a closed housing, and therefore a repair of the probe is difficult or even impossible.

Another disadvantage of the known from the prior art buttons is that when the push button is pressed from a switching point at which the contact is triggered, no margin is left to ensure the contact reliability of the probe. However, this is particularly important in the case of probes, which are used in test systems in which the presence of a component is tested, which is plugged into a probe. A corresponding signal is always triggered when the component contacts the button. In today's conventional buttons, it is often not possible to determine the distance from the switching point, ie the point at which the contact triggers, to the mechanical end stop of the button. However, this is disadvantageous if in a test system components are contacted with a probe, and these components have manufacturing tolerances that must be compensated accordingly. The manufacturing tolerances of components thus prevent a high contact reliability of the probe.

From the DE 28 48 567 A1 a pushbutton according to the preamble of claim 1 is known.

The DE 33 30 624 A1 discloses a key switch consisting of three parts, namely a contact spring plate, a carrier plate made of insulating material and a one-piece prior to assembly contact element, which is separated during the assembly process, so that two independent contact elements arise. At the contact elements mounting plates are formed, which, when the contact elements are placed on the one surface of the support plate, pass through provided in the support plate recesses.

Description of the invention

The object of the present invention is to develop such a button for a contact device for checking the presence of a component that a large contact reliability over a long distance of the probe is guaranteed and at the same time there is the ability to easily build the button and repair.

This object is achieved by the features of the independent claim.

An inventive button for a contact device for checking the presence of a component comprises a movable in its longitudinal axis between a starting position and a first stop position actuating element. Furthermore, the push-button comprises at least one contact element which can be deflected by the actuating element perpendicular to the longitudinal axis of the actuating element. The contact element has at least one contact section which can be deflected during the deflection of the contact element by the actuating element in such a way that the contact section in a contact position contacts an electrical element for generating an electrical signal when the actuating element has reached the first stop position.

The contact element has a stem part and a bottom part for forming a spring, wherein the stem part is angled substantially at right angles to the bottom part and the longitudinal axis of the stem part runs parallel to the longitudinal axis of the actuating element. In this way it is ensured that the movement of the actuating element is converted in the vertical direction into a horizontal movement.

The trunk part has a trunk and at least two deflectable side parts, wherein the side parts are each arranged laterally on the trunk, and wherein each side part has a contact portion. The contact portion of each side member may have, as mentioned above, a first surface element which is connected to a second surface element. This first surface element then comprises at least one obliquely formed surface in order to be contacted by the actuating element of the probe can. Thus, when the actuator deflects the two side members toward a contact position, then a circuit is closed and the current can flow from the one side member via the second side member back into the printed circuit board or into the electrical element. The two side parts, which are deflected in parallel, guarantee a higher contact reliability due to the redundancy. An advantage of the present invention is that the stylus ensures high contact safety, i. that the path from the switching point, ie the point at which the contact triggers, is adjustable up to the mechanical end stop and within this distance the contact up to and including the end stop of the probe remains safe. This so-called overpressure, so that the switching point in relation to the end stop is reached very early, is desired in order to better compensate for component tolerances.

Another advantage of the present invention is that the probe is easy to assemble due to its individual components and there is the possibility of repair.

Another advantage of the probe according to the invention is that the button lateral forces that can arise, for example, by an oblique actuation of the button can record. In this way, the possibility of twisting the button is prevented during its operation.

Another advantage of the probe according to the invention is that the probe allows a direct contacting of a circuit board to generate a signal that signals the presence of a component which is plugged onto the button.

Another advantage of the probe according to the invention is that the components of the probe can be put on a very tight space and the operation of the probe and its high contact reliability is still ensured.

Preferred embodiments of the invention

In a preferred embodiment of the present invention, the contact portion of the contact element comprises a first surface element, which is connected to a second surface element, wherein the first surface element is contacted by the actuating element and the second surface element is adapted to contact the electrical element. The first surface element of the contact portion is thus deflected by the actuating element. The second surface element, which is connected to the first surface element, is also deflected upon deflection of the first surface element in such a way that it can contact the electrical element. The electrical element may be a contact point on a printed circuit board. By reaching the contact position in which the second surface element contacts the electrical element, a circuit is closed on the electrical element, so that a signal can be generated which signals the presence of a component which is placed on the button.

Another advantage is that the probe according to the invention a large contact reliability with a large margin tolerance - about 1 to 4 mm - allows to compensate for manufacturing tolerances of components that are placed on a button. Another advantage of the probe according to the invention is that a simple installation of the probe is possible because the probe mechanics and the electrical element can be mounted separately from each other.

In a preferred embodiment of the present invention, the first surface element has at least one obliquely formed surface. By this obliquely formed surface and its arrangement in the first surface element can be set, at which time the actuating element of the button reaches the first stop position in which the contact element is deflected such that the contact portion of the contact element is brought into a contact position to the electrical element to contact to generate an electrical signal.

In a preferred embodiment of the present invention, the contact element is designed as a spring. This has the advantage that the contact element again independently in his Return home position when the actuator of the button returns from its stop position to its original position. This is always the case, for example, when a component is removed from the probe after the presence test for that particular component is completed.

In a preferred embodiment of the present invention, the traversable distance between the starting position and the first stop position is approximately 1 mm. This has the advantage that component tolerances can be better compensated if the switching point comes very early in relation to the end stop and a possible way of overpressing is very long.

In a preferred embodiment of the present invention, the actuating element is movable towards a second stop position, which is defined as the end stop of the actuating element, wherein between the first stop position and the second stop position, the contact position of the contact portion of the contact element is maintained. Upon movement of the actuating element from a first stop position to an end stop, the contact position of the contact element remains secure. In this way, a large tolerance range is ensured by ensuring contact safety, regardless of whether the components to be tested, which are placed on the probe, have component tolerances. The design of the touch movement in this sense thus provides room for the probe movement and makes it possible to compensate for component tolerances.

In a preferred embodiment of the present invention, the traversable distance of the actuator between the first stop position and the end stop is approximately 3 to 4 mm. This has the advantage that component tolerances can be better compensated if the switching point comes very early in relation to the end stop and a possible way of overpressing, here 3 to 4 mm is very long. In a preferred embodiment of the present invention, the actuating element comprises a spring element counteracting the movement of the actuating element. The spring element can be designed as a return spring, which makes it possible that the actuating element can return by spring force to its original starting position independently. This is the case, for example, when the component plugged onto the pushbutton is removed again after the presence check has been carried out.

In a preferred embodiment of the present invention, the spring element is arranged between the actuating element and the bottom part of the contact element.

In a preferred embodiment of the present invention, the actuating element has at least one guide element. The guide element allows the absorption of lateral forces in an oblique push button movement and thus prevents rotation of the button during the button movement. Twisting forces are thus absorbed and at the same time they are prevented from influencing the function of the probe. By the guide element a better motion control of the probe along a housing portion of a probe housing is possible, with which the button can be connected.

In a preferred embodiment, the actuating element comprises at least two guide elements. The guide elements absorb lateral forces, so-called torsional forces, which would otherwise result from an oblique actuation of the probe. In this way it is prevented that these undesired twisting forces influence the feeler function.

In a preferred embodiment of the present invention, the actuating element comprises a head part and a foot part. In a preferred embodiment of the present invention, the foot part comprises at least one guide element.

In a preferred embodiment of the present invention, a bead-like elevation is formed on a surface of the foot part. The bead-like elevation allows the collection of dust particles, which would otherwise penetrate into the interior of the probe.

In a preferred embodiment of the present invention, the electrical element is formed as a printed circuit board. The contact element is connected via arranged on the circuit board contacts with the circuit board itself. The contact element is electrically connected in the contact position with the printed circuit board.

In a preferred embodiment of the present invention, the contact element is formed as a stamped sheet. The use of a stamped sheet allows a cost reduction in the manufacture of the probe.

Short description of the figures

The invention will be described with reference to an embodiment which is explained in more detail with reference to drawings. Hereby show:

1 a schematic illustration of the probe according to the invention with an actuating element in a starting position and a contact element and an electrical element;

2 an embodiment of the inventive button according to 1 but without the actuator;

3 a further perspective view of the probe according to the invention 1 ; and

4 a sectional view of the probe according to the invention 1 ,

1 shows a button 1 for a contact device 100 for the presence check of a component, whereby the button 1 an actuator 2 that includes in its longitudinal axis 3 between a starting position 4 and a first stop position 5 is movable (not shown). The button 1 furthermore comprises feeler elements 9 . 10 , respectively by the actuator 2 perpendicular to the longitudinal axis of the actuating element 2 are deflectable. The two contact elements 9 . 10 each have at least one contact section 11 . 12 on. The contact section 11 . 12 is at the deflection of the respective contact element 9 . 10 deflected by the actuating element such that the contact portion 11 . 12 in a contact position 7 (not shown) an electrical element 24 contacted to generate an electrical signal when the actuator 2 the first stop position 5 (not shown) has reached.

1 further shows that each contact section 11 . 12 a contact element 9 . 10 a first surface element 13 having that with a second surface element 14 connected is. The first surface element 13 is doing of the actuator 2 contacted. The second surface element 14 is formed, the electrical element 24 to contact if the contact section 11 . 12 is deflected accordingly and the contact position 7 reached.

The first surface element 13 of the contact section 11 . 12 includes an obliquely formed surface 16 . 17 ,

The contact element 9 . 10 is designed as a spring, ie the contact element 9 . 10 is deflectable and automatically returns to its original position when the corresponding deflection force is no longer present.

The actuator 2 is to a second stop position 6 towards movable (not shown), as the end stop of the actuating element 2 is defined, wherein between the first stop position 5 and the second stop position 6 the contact position 7 of the contact section 11 . 12 of the contact element 9 . 10 is maintained. The traversable distance between the starting position 4 and the first stop position 5 in which the contact element 9 . 10 the contact position 7 reached is about 1mm. The zurücklegbare distance of the actuating element 2 between the first stop position 5 and the end stop 6 is preferably about 3 to 4 mm. This will ensure that the contact position 7 of the contact element 9 . 10 certainly remains and there is a margin for the button movement. This also ensures that the switching point, ie the point to which the contact position 7 is achieved, in relation to the end stop 6 reached very early and thus a possible way of the so-called over-pushing is very long. Because this is a high contact reliability of the actuator 2 achieved, which makes it possible to compensate for component tolerances. An additional advantage of the probe according to the invention is also that the direction of movement of the actuating element 2 parallel to the next to the actuator 2 arranged electrical element 24 runs, which may be formed as a printed circuit board. The longitudinal axis 3 of the actuating element 2 So in this case it is parallel to the electrical element 24 arranged.

Preferably, the zurücklegbare distance of the actuating element 2 between the first stop position 5 and the end stop about 3 to 4 mm.

From the 1 it can be seen that the button is a spring element 23 that includes the actuator 2 counteracts. The spring element 23 is preferably designed as a return spring, so that the actuating element 2 can return independently by spring force to its original starting position. This is always the case when the plugged onto the button component (not shown) is removed.

The spring element 23 is between the actuator 2 and a bottom part 19 of the contact element 9 . 10 arranged.

At the button of 1 includes the actuator 2 two guide elements 25 , Through the guide elements 25 the inclusion of lateral torsional forces is prevented when an oblique push button operation takes place. In this way, a twisting of the button 1 while pressing the button prevents.

In the embodiment of the button according to 1 includes the actuator 2 a headboard 27 and a foot part 28 , The foot part 28 includes at least one guide element 25 , The guide element 25 may be formed as one or more parts existing tread.

1 further shows that the foot part 28 a surface 29 has, on the a bead-like elevation 30 is trained. This allows the collection of dust particles that would otherwise penetrate into the interior of the probe.

The electrical element 24 is formed as a printed circuit board, such as the 1 . 2 . 3 and 4 demonstrate. On the circuit board 24 may be so-called "pads", so be formed individual contacts or contact surfaces. The movement of the actuator 2 or the longitudinal axis 3 of the actuating element runs parallel to the illustrated printed circuit board 24 , The contact surfaces are of the second surface element 14 of the respective contact section 11 . 12 of the contact element 9 . 10 in a contact position 7 contacted when the contact element 9 . 10 through the actuator 2 is deflected. By the arrangement of the button 1 in relation to the circuit board 24 the Kraftkinkplungsweg takes place on the printed circuit board 24 in that the vertical stylus movement of the actuating element 2 in a horizontal movement of the contact element 9 . 10 is diverted. This type of contacting a larger tolerance compensation is possible, ie the contact of the button with the circuit board remains from the first stop position to the end stop of the actuator 2 be sure, even if components of the same type are used, but which have small differences in their dimensions due to the manufacturing. In addition, the probe claimed due to its arrangement and its design only minimal space.

The contact element 9 . 10 is in the contact position 7 (not shown) of the contact section 11 . 12 with the electrical element 24 electrically connected to trigger a signal indicating the presence of a component.

The contact element 9 . 10 is preferably formed as a stamped sheet. This can save costs in the manufacture of the probe.

2 shows the button according to the invention 1 , but without actuator 2 , which is hidden for clarity. Well visible in the 2 the contact element 9 . 10 , which is constructed as follows: The contact element 9 . 10 , which is designed as a spring, comprises a stem part 18 and a bottom part 19 , where the stem part 18 at the bottom part 19 is substantially angled at right angles and the longitudinal axis 20 of the parent part 18 runs parallel to the longitudinal axis 3 of the actuating element 2 (not shown). The stem part 18 includes a trunk 21 and two deflectable side panels 22 , The side parts 22 are each on the side of the trunk 21 arranged. Each side part 22 has a contact element 9 . 10 on, which in turn each a contact section 11 . 12 having.

Like from the 2 Further, each contact section has 11 . 12 a first surface element 13 on that with a second surface element 14 connected is. 2 also shows that the first surface element 13 of each contact section 11 . 12 an obliquely formed surface 16 . 17 having. This obliquely formed surface can from the actuator 2 of the button 1 be contacted.

Depending on how the obliquely formed surface of the first surface element 13 is formed, ie at what angle the inclined surface 16 . 17 opposite the longitudinal axis 3 the movable actuator 2 (not shown) is formed, the deflection of the contact element can be 9 . 10 adjust accordingly or the distance of a contact section 11 . 12 to the electrical element 24 to adjust.

It should be noted that the zurücklegbare distance between the starting position 4 of the actuating element 2 and the first stop position 5 of the actuating element 2 preferably about 1 mm.

In the 2 includes the bottom part 19 two tab elements 32 , each as a folded surface elements of the bottom part 19 protrude. The tab elements 32 prevent the contact element 9 . 10 twisted. The tab elements 32 are bent up with a defined radius, so that it is possible, the contact element 9 . 10 during assembly of the button easier in a push-button housing (not shown) to insert.

3 shows a perspective view of the probe according to the invention 1 with an actuating element 2 , It is easy to see that the foot part 28 of the actuating element 2 two guide elements 25 includes. Furthermore, the foot part includes 28 on a surface 29 a bead-like elevation 30 ,

It should be noted that the bottom part 19 of the contact element 9 . 10 in the 1 and 2 does not float in the air, but on an intermediate plate 35 is mounted, the sake of clarity, while not in the 1 . 2 and 3 is shown, however, in the 4 ,

The 4 shows a sectional view of the probe according to the invention 1 , In this illustration, it can be clearly seen that the bottom part 19 on an intermediate plate 35 rests. The intermediate plate 35 is part of a push-button housing 40 , In the case 40 are a battery 36 and an electrical element 24 accommodated. The foot part 28 of the actuating element 2 of the button 1 is from the case 40 enclosed, only a section of the headboard 27 of the actuating element 2 of the button 1 protrudes from the case 40 visible out. The housing 40 also includes a housing portion on which guide elements 25 at the foot part 28 of the actuating element 2 are arranged to be guided along to the function of the button 1 not to interfere with an oblique pressing the button. This housing section may for example be part of a housing cover 41 be like in the 4 shown in the part of the button 1 in its operation, so the headboard 27 of the actuating element 2 , retracts. The electrical element 24 is designed as a printed circuit board. The circuit board 24 runs in the embodiments of the probe according to the 1 to 4 while parallel to the longitudinal axis 3 of the button 1 , Due to the contact element 9 . 10 and its deflection by the actuator 2 of the button 1 So it is possible the electrical element 24 (= PCB) parallel to the longitudinal axis of the actuator 2 to arrange, thereby leaves space within the housing 40 save on. Another advantage of this arrangement is that the individual components of the probe 1 separately or independently of the mounting of the circuit board 24 and the battery 36 in the push button housing 40 can be mounted. This also makes it easier to replace individual probe components in the event of a probe defect.

The button according to the invention 1 For example, in a test system (not in the 1 to 4 shown) are used to ensure the presence of components on a wiring harness, such as clips, grommets, shafts, and as will be explained in more detail below. The button 1 or part of it, is in the case 40 arranged. To check the presence of components on the button 1 plugged. By appropriate operation of the button 1 , ie by a deflection of the contact element 9 . 10 through the actuator 2 of the button 1 a signal is used by a connected hardware in the test system when the contact element 9 . 10 his contact position 7 achieved, ie that the contact element 9 . 10 is deflected by the actuating element such that the second surface element 14 of the contact section 11 . 12 of the contact element 9 . 10 a contact position 7 reached and thus the electrical element 24 contacted. If the component is removed again from the button, the button automatically returns to its original position 4 back.

Furthermore, it should be noted at this point that when reaching the contact position 7 through the contact section 11 . 12 of the contact element 9 . 10 a circuit is closed, as follows: First, flows out of the circuit board 24 a stream in a side part 22 a contact element 9 (like in the 2 shown). About the trunk 18 the current then flows on to the second side part 22 of the contact element 10 from where the electricity is then back in the circuit board 24 flows. In this way, a circuit is closed, and a signal is generated indicating the presence of a component on the button 1 signaled.

LIST OF REFERENCE NUMBERS

1

button

2

actuator

3

Longitudinal axis of the actuating element

4

Starting position of the actuating element

5

first stop position of the actuating element

6

 second stop position of the actuator / end stop

7

Contact position of the contact section

9, 10

contact element

11, 12

Contact section of the contact element

13

first surface element of the contact element

14

second surface element

16, 17

obliquely formed surface

18

stem portion

19

the bottom part

20

Longitudinal axis of the stem part

21

Trunk of the parent part

22

Side part of the stem part

23

spring element

24

electrical element

25

guide element

27

Head part of the actuating element

28

Foot part of the actuating element

29

Surface of the foot part

30

bead-like elevation of the foot part

32

tab member

35

intermediate plate

36

battery

40

casing

41

housing cover

100

contact device

Claims (11)

Button ( 1 ) for a contact device ( 100 ) for the presence test of a component, comprising: - one in its longitudinal axis ( 3 ) between a starting position ( 4 ) and a first stop position ( 5 ) movable actuator ( 2 ), - at least one by the actuating element ( 2 ) perpendicular to the longitudinal axis ( 3 ) of the actuating element ( 2 ) deflectable contact element ( 9 . 10 ), wherein the contact element ( 9 . 10 ) at least one contact section ( 11 . 12 ), which in the deflection of the contact element ( 9 . 10 ) by the actuating element ( 2 ) is deflectable such that the contact section ( 11 . 12 ) in a contact position ( 7 ) an electrical element ( 24 ) to generate an electrical signal when the actuator ( 2 ) the first stop position ( 5 ), characterized in that the contact element ( 9 . 10 ) to form a spring a stem part ( 18 ) and a bottom part ( 19 ), the parent part ( 18 ) at the bottom part ( 19 ) is angled substantially at right angles and the longitudinal axis ( 20 ) of the parent part ( 18 ) parallel to the longitudinal axis ( 3 ) of the actuating element ( 2 ) and that the parent part ( 18 ) a trunk ( 21 ) and at least two deflectable side parts ( 22 ), wherein the side parts ( 22 ) each side of the trunk ( 21 ) are arranged, and wherein each side part ( 22 ) a contact section ( 11 . 12 ) having. Button ( 1 ) according to claim 1, wherein the contact section ( 11 . 12 ) of the contact element ( 9 . 10 ) a first surface element ( 13 ) having a second surface element ( 14 ), wherein the first surface element ( 13 ) of the actuating element ( 2 ) and the second surface element ( 14 ) is formed, the electrical element ( 24 ) to contact. Button ( 1 ) according to claim 2, wherein the first surface element ( 13 ) at least one inclined surface ( 16 . 17 ) having. Button ( 1 ) according to one of the preceding claims, wherein the contact element ( 9 . 10 ) is designed as a spring. Button ( 1 ) according to one of the preceding claims, wherein the traversable distance between the starting position ( 4 ) and the first stop position ( 5 ) is about 1mm. Button ( 1 ) according to one of the preceding claims, wherein the actuating element ( 2 ) to a second stop position ( 6 ) is movable towards the end stop of the actuating element ( 2 ) is defined, wherein between the first stop position ( 5 ) and the second stop position ( 6 ) the contact position ( 7 ) of the contact section ( 11 . 12 ) of the contact element ( 9 . 10 ) is maintained. Button ( 1 ) according to claim 6, wherein the traversable travel distance of the actuating element ( 2 ) between the first stop position ( 5 ) and the end stop ( 6 ) approximately 3 up to 4 mm. Button ( 1 ) according to one of the preceding claims, comprising a movement of the actuating element ( 2 ) counteracting spring element ( 23 ). Button ( 1 ) according to claim 8, wherein the spring element ( 23 ) between the actuator ( 2 ) and the bottom part ( 19 ) of the contact element ( 9 . 10 ) is arranged. Button ( 1 ) according to one of the preceding claims, wherein the electrical element ( 24 ) is formed as a printed circuit board. Button ( 1 ) according to one of the preceding claims, wherein the contact element ( 9 . 10 ) is formed as a stamped sheet metal.

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