WO2019228657A1

WO2019228657A1 - Switch for an electrical device

Info

Publication number: WO2019228657A1
Application number: PCT/EP2018/071987
Authority: WO
Inventors: Franc Stuklek
Original assignee: Elrad International D.O.O.
Priority date: 2018-06-01
Filing date: 2018-08-14
Publication date: 2019-12-05
Also published as: DE102018113100A1; CN112292743A

Abstract

The invention relates to a switch for an electrical device, in particular for a power tool, having a controller (400) for setting the rotational speed of the electrical device, wherein a printed circuit board (10) is arranged in a contact area (218) of a switch housing, wherein the controller (400) bears against conductor tracks of the printed circuit board (10) by way of servo contacts (30) in the contact area (218), and wherein the controller (400) is able to be actuated by means of a slider (300). To form such a switch with a high seal tightness against infiltrating dust, the invention makes provision for the controller (400) to be mounted so as to be able to rotate and for the sliding movement of the slider (303) to be converted to a rotational movement of the controller (400) by means of a gear, and for the slider (303) to be held and guided outside of the contact area (218).

Description

Switch for an electrical appliance

Switch for an electrical appliance, in particular for a power tool, with a controller for adjusting the speed of the electrical appliance, wherein in a contact space of a switch housing a circuit board is arranged, wherein the controller cooperates with electrical components of the circuit board, preferably with control contacts in the contact space on tracks of the circuit board is applied, and wherein the controller is actuated by means of a slider.

Such a switch is known from DE 10 2015 113 949 A1. Such switches are used for example as a multiple switch in electrical appliances, especially in drills, cordless screwdrivers and other electric hand tools or even in household appliances. The controller is adjustable via a linear, displaceable against a restoring force control. Sliders are known, which are arranged directly with a power circuit of the electrical appliance or in a operated with low voltage and low current control circuit. In the low voltage and low current operated sliders provide a proportional to the position of the slider running output signal, which is supplied to a power electronics. This amplifies the output signal and supplies it to a drive unit of the electrical appliance. For example, the speed of the power tool can be adjusted via the slider. In addition to the known slider includes known from the prior art multiple switch another switching element for Switching the direction of rotation of the drive unit or for switching on / off the electrical device. In this case, these switching elements often engage in the power circuit of the electrical appliance. Alternatively, it can be provided that the switching elements are arranged in the control circuit and their switching signals are forwarded to the power electronics accordingly. The well-known slider forms a potentiometer, so it is designed as a variable resistance with sliding contacts. The sliding contacts are connected by means of a mechanical translation with the control.

Furthermore, it is known to perform slide regulators as capacitive displacement sensors, as described in document DE 10 2011 002 009 A1. The document discloses a capacitive encoder with a housing attachable to a circuit board. The housing has a receptacle in which a slider is movably mounted. The slider is permanently arranged in a reference region between a first measuring electrode and an opposite ground electrode. As a result of the sliding movement, the slider is introduced more or less far into a measuring range between a second measuring electrode and a second ground electrode, wherein the ground electrodes of the reference and of the measuring range can be embodied as a one-piece electrode. The change in the capacitance between the electrodes arranged in the measuring region and the capacitance between the electrodes arranged in the reference region during a movement of the slide is evaluated. The measuring electrodes can be arranged on the circuit board, while the ground electrode is integrated in the lid of the housing.

Both the described capacitive displacement sensor and the ohmic displacement sensor operate in a control circuit at low currents and voltages. In both, even slight contamination of the contacts and the electrodes lead to disturbances and thus to a malfunction of the controlled electrical appliance. Advantageously, the required further switching elements are integrated into the control circuit. Switches are realized according to known arrangements via two arranged on the circuit board, open contact surfaces, which can be bridged by a conductive bridge. This inexpensive construction has However, the disadvantage that dust and dirt that enters the area of the contact surfaces, the contact resistance between the contact surfaces and the bridge can change so much that the function of the switch is disturbed. A disturbance occurs especially at the low voltages and currents used in the control circuit already at relatively low levels of contamination.

The operating element is pressed against a restoring force in a switch housing during actuation of the slide control and pushed back on discharge to a stop from the switch housing. By in the switch housing and extended control element space is displaced in the switch housing and released again. This creates a pumping effect in which the air pressure in the switch housing changes. As a result, air is displaced from the housing and then sucked in again. Due to the sucked air, dirt and dust are drawn into the switch housing even through the smallest openings and cracks. The amount of dust thus introduced into the switch housing or dirt is many times greater than the amount which penetrates into the switch housing without actuation of the operating element and thus without aspirated air. The dirt and dust settle in particular on the open contacts of the control circuit and cause interference.

It is an object of the invention to provide a working in low voltage range and at low currents switch, in particular multiple switch, which provides a wegproportionales control signal and which is less prone to pollution-related failures in a simple and kleinbauendem structure.

This object is achieved in that the controller is rotatably mounted and the sliding movement of the slider is converted by means of a gear in a rotational movement of the controller, and that the slider is held and guided outside the contact space. The fact that the slide is held and guided outside of the contact space, it is prevented that caused by the adjusting movement of the slide, a change in the air volume in the contact space. Also, the rotatable arrangement of the controller in the contact space leads to no change in volume. As a result, pumping effects are prevented over the dust would be sucked into the contact space. In this way, a high-dustproof switch can be realized, which is characterized by a high level of operational reliability in the smallest space.

According to a preferred embodiment of the invention, it may be provided that a housing part of the switch housing in a bearing receptacle rotatably receives a converter, and that the converter has a driver, by means of which it is rotatably connected to the controller directly or indirectly. In this way, the implementation of the linear movement of the slider in the rotational movement of the converter can be realized in the smallest space.

In this case, it is also conceivable, in particular, for the converter to have one or more fastening elements in the region of the contact space via which the regulator is coupled, and for the fastening element (s) preferably to have a latching projection by means of which the regulator is locked to a latching receptacle. With this measure, in particular, an automated production can be easily realized.

A mechanical coupling in the gearbox between the slide and the converter can be realized simply by the converter having one or more actuators on its side facing away from the contact space, and the actuator or actuators interacting with actuator receivers to implement the linear movement of the slider in a rotational movement of the converter (100) to effect. The actuating elements or the actuating element receptacles can in this case also be formed in particular by a toothed gear, with a toothed wheel or a partial toothed wheel meshing with a toothed rack. To reduce the parts and assembly costs, it may be provided according to a variant of the invention that the converter has a stop which rests in the issued rest position of the slider on a counter surface of the slider to limit the adjusting movement of the slider.

The rotary mounting of the converter can be realized in a simple manner in that the converter has a base part, that the base part has a circumferential side wall, by means of which the converter is rotatably inserted into a bearing receptacle of the housing part.

If it is provided that the housing part outside the contact space has a sliding surface for the slider, and that connect directly or indirectly to the sliding surface one or more guides, wherein in the guide of the slide is guided linearly with a guide piece, then the slide degree be performed exactly in the housing part and the manufacturing tolerances between the slide and the converter can be minimized in favor of a reliable function.

If it is provided according to a variant of the invention that the housing part has a bottom wall which is arranged at a distance to a wall element of the housing part, and that between the bottom wall and the wall element, the sliding guide is formed for the slide, then the slide is stably held and guided and in particular Also insensitive to transverse loads acting transversely to the direction of adjustment.

In this case, the mounting and fixing of the slider on the housing part in a simple manner by the fact that the housing part in the bottom wall has an opening that is inserted through the opening of the converter in a bearing receptacle in the wall element, and that in the inserted position of the converter at least one Actuator engages in a fastener receiving. A further design simplification results from the fact that the housing part has an integrally formed spring holder, in which a restoring spring (50) is accommodated, which biases a switching element (300) connected to the slide (303).

An inventive switch may be characterized in that the controller has a contact holder having at least one receptacle for fixing the actuating contact. Flierdurch a safe and easy-to-install assignment of the actuating contact, which may be formed in particular as a sliding contact, reached the controller.

A preferred variant of the invention is such that the regulator has a sliding surface in the region of a rear side facing away from the printed circuit board, which bears on a wall surface of the housing part to form a sliding guide.

If it is provided that the controller has a non-symmetrical in cross-section driver receptacle, and that the converter engages with a driver, which also has an asymmetrical cross-section, in the driver receptacle, then a rotationally fixed assignment of the controller is effected to the converter in a simple manner

A multiple switch can be characterized in that in the contact space a rotatable positioning element is held, which in the region of one of the front has recordings, that are held in the receptacles contact elements of a right-left switch, and that the contact elements are preferably in contact with mating contacts of the circuit board. The rotatable positioning also causes no change in volume in the contact space, so that the high density is guaranteed.

The invention will be explained in more detail below with reference to an embodiment shown in the drawings. Show it:

Figure 1 in perspective exploded view of a switch according to the invention Figures 2 and 3 a housing part of the switch in perspective views,

FIGS. 4 and 5 show a converter of the switch in perspective views;

FIG. 6 is a perspective view of an assembly consisting of a switching element and the converter according to FIGS. 4 and 5;

FIGS. 7 and 8 show a regulator in two perspective views,

9 shows a positioning contact in perspective view,

FIG. 10 shows a preassembled assembly in a perspective view,

11 shows a housing upper part in a perspective view from the outside,

FIG. 12 shows the upper housing part according to FIG. 11 in a perspective view from the inside and with a preassembled spring and a preassembled actuating part,

13 and 14 a positioning element in two different perspective views,

Figure 15 shows a second preassembled module of the switch in a perspective view from the inside and

Figure 16 shows the switch in the assembled state.

As shown in FIGS. 1 to 3, the switch has a housing part 200. The housing part 200 is formed as a plastic injection-molded part. It has a bottom wall 201, rise from the opposite side walls 210, a front wall 211 and the front wall 211 opposite rear wall. In the bottom wall 201, an opening 202 is introduced. The aperture 202 has recesses 203, 204, which are adapted to the contour of a converter 100, which will be explained later. Parallel to the bottom wall 201, the housing part 201 has a wall element 205. The wall element 205 has two bearing receptacles 206, 207, which are incorporated in the form of an opening in the wall element 205. As shown in particular in FIGS. 1 and 2, a sliding guide with a sliding surface 208 is formed between the bottom wall 201 and the wall element 205. On opposite sides, close to the sliding surface 208 guides 209. The guides 209 are designed in the form of recesses and incorporated into the wall element 205. In the region of the front wall 211, a spring holder 214 is integrally formed on the housing part 200. The spring holder 214 has a hollow-cylindrical inner contour for receiving a return spring 50 shown in FIG.

As can be seen from FIG. 2, latching elements 215 formed on the side walls 210 of the housing part 200 are present. Per side wall 210, two locking elements 215 are used, which are spaced from each other. As shown in FIG. 3, printed circuit board holders 216 are integrally formed on the housing part 200. These serve to receive a printed circuit board 10 shown in Figure 1. The rear wall of the housing part 200 has a recessed gasket 217. As Figure 3 reveals, the front wall 211, the side walls 210 and 212 and the rear wall enclose a contact space 218th

In Figures 4 and 5, a converter 100 is shown this converter 100 has a base part 101 with a front and a back. The base part 101 has a cylindrical geometry with a circumferential cylindrical side wall 102. On the back of the base member 101 actuators 106, 107 and 109 are arranged. The actuating elements 106, 107 and 109 are designed as stable cams and can, as FIG. 5 shows, be part of a uniform molding on the base part 101. This molding has a stop 110. On the front side of the base part 101, a driver 103 is formed. The driver 103 has flats on opposite sides, as shown in FIG. 4. Furthermore, two fastening elements 104 are integrally formed on the base part 101, which have latching projections 105 at their free ends. FIG. 6 shows a switching element 300. This has a main body 301 with an actuating surface 302. The actuating surface 302 can be operated by hand. On the main body 301, a slider 303 is formed. The slider 303 has a recess 304. In this recess 304, the converter 100 can be used, as will be explained later. The recess 304 has actuating element receptacles 305, 306. A side surface of the recess 304 forms a mating surface 307. As can be seen from FIG. 1, the slider 303 has guide pieces 308 on opposite sides. Furthermore, a spring receptacle 309 is formed in the main body 301. As can be seen from FIG. 6, the converter 100 can insert into the recess 304 with its molding which carries the actuating elements 106, 107 and 109. In the position shown in FIG. 6, the first actuating element 106 engages in the actuating element receptacle 306. The stop 110 of the converter 100 abuts against the counter surface 307. The third actuating element 109 bears against the actuating element receptacle 306 against a body region of the recess 304.

The switching element 300 can be connected to the housing part 200 with the aid of the converter 100 and the spring 50. For this purpose, the spring 50 is first inserted into the spring receptacle 309 of the switching element 300, as FIG. 1 illustrates. Subsequently, the actuator 300 is inserted with its slide 303 in the sliding guide formed between the bottom wall 201 and the wall member 205. In this case, the guide pieces 308 are inserted into the guides 209 of the housing part 200. The insertion movement of the slider 303 takes place from the side which has the front wall 211 of the housing part 200. When inserting the spring 50 is inserted into the spring holder 214. Thus, the insertion movement of the switching element 300 against the bias of the spring 50. The slider 303 is inserted so far into the housing part 200 until the recess 304 of the switching element 300 is in alignment with the opening 202 of the housing part 200. Now, the converter 100 can be pushed by the housing outside through the opening 202 through the bottom wall 201. This is achieved by virtue of the fact that the opening 202 substantially simulates the cross-sectional shape of the converter 100. When the converter 100 is inserted into the housing part 200, the converter 100 is included its circumferential side wall 102 opposite the cylindrical bearing receptacle 206 and the base part 101 strikes with its front side on the jump in sales between the two bearing receivers 206 and 207. The driver 103 passes through the bearing receptacle 206. If now the switching element is relieved when used converter 100, the converter 100 rotates in the formed by the bearing receivers 206, 207 and the cylindrical side wall 212 pivot bearing and the converter 100 takes over the switching element 300 the a position shown in Figure 6. For secure fixation of the converter 100, a controller 400 is used. The controller 400 is shown in FIGS. 7 and 8. As these drawings illustrate, the regulator 400 is formed as a rotational body. It has a contact holder 401 from which a cylindrical projection 402 rises centrally. In the contact holder 401 receptacles 403 are incorporated. Furthermore, positioning parts 404 in the form of bores are present in the contact holder. The regulator 400 is surrounded by a cylindrical peripheral wall 405. In the area of its rear side 406, a driver receptacle 407 is introduced into the controller 400. The driver receptacle 407 is designed with two lateral flattenings that are opposite to each other. Furthermore, a passage 408 is provided in the controller, the detent recesses 409 forms. The rear side 406 of the regulator 400 forms a sliding surface 410.

In order to fix the converter 100 used in the housing part 200, the regulator 400 with its rear side 406 is inserted in advance into the contact space 218 of the housing part 200. In this insertion process, the fastening elements 104 pass in the region of their locking lugs 105 into the bushing 408. At the end of the insertion movement the latching projections 105 snap behind the opposite latching receptacles 409 of the regulator 400 Assignment of the controller 400 to the converter 100 is effected by the fact that the opposite flats of the driver 103 abut the flats in the cam receiver 107. The sliding surface 410 of the regulator 400 bears against the inside of the wall element 205 of the housing part 200. Finally, actuating contacts 30 can be attached to the contact holder 401 of the controller. The actuating contacts 30 are shown in FIG. They have a contact element 31, which merges via a connecting section 32 into a support part 33. In the region of the support part 33, a bent projection 34 protrudes from the underside. The actuating contact 30 is made of a spring plate. The actuating contact 30 can be used with its connecting portion 32 in the receptacle 403. The projection 34 engages in the positioning part 404 of the regulator 401. In this way, a precise assignment of the control contacts 30 is achieved to the controller 400. In Figure 9, a spring-loaded basic position of the actuating contact 30 is shown in dashed lines. When fully assembled, the actuating contact 30 assumes the position shown in solid line in FIG. 9. Flierdurch a contact spring force is generated. In Figure 10, the assembly consisting of housing part 200, converter, 100, controller 400, switching element 300 and control contacts 30 is shown.

In the preassembled housing part can now be used, the circuit board 10. The circuit board 10 has on its the actuating contacts 30 side associated tracks, the contacts together with the trained as Schleiftkontakte actuating contacts 30 form an ohmic potentiometer. On its side facing away from the contacts, the circuit board 11 further contact elements, which will be explained later. To the circuit board 10, a connection cable 13 is soldered. The connecting cable 13 is guided through a seal 12. The printed circuit board 10 has recesses 11 on opposite sides. With these recesses 11, the circuit board 10 can be pushed onto the circuit board holder 216 of the housing part 200. The seal 12 is inserted into the seal receptacle 217 (see FIG. 3) of the housing rear wall. With the circuit board 10, the control contacts 30 can bring in the clamping position shown in Figure 9 (solid line representation). In this case, the contact elements 31 are then subjected to force on the underside of the printed circuit board 10 on the associated printed conductors.

FIGS. 11 and 12 show an upper housing part 600. The upper housing part 600 has a bottom 601. To the bottom 601 are two opposite side walls 602, a front wall 603 and a rear wall 604 formed. The bottom 601, the side walls 602, the front wall 603 and the rear wall 604 define a contact space that completes the contact space 218 of the housing part 200. In the region of the front wall 603, a spring holder 605 for the spring 50 is integrally formed on the housing upper part 600. The spring holder 605 has a partially hollow cylindrical support surface 606, which abuts the outer contour of the spring 50 to complete the spring holder 214 of the housing part 200. As FIG. 11 illustrates, a depression 607 is formed in the bottom 601, which terminates with a surface 608. In the surface 608 an opening 609 is incorporated. The recess 607 forms a hollow cylindrical receptacle. On the side walls 602 counter-locking elements 610 are formed. In the area of the rear wall 604, a trough-shaped gasket receptacle 611 is incorporated. As can be seen in FIG. 12, a web 612 is arranged in the interior of the housing upper part. The web 612 is spaced from the rear wall 604. Between the web 612 and the rear wall 604 so forms a spring receptacle for a spring 20. The spring 20 has two spring portions 22 which adjoin a connecting portion 21. At the end of the spring portions 22 Flalteelemente 23 are bent. The spring element 20 is made of spring steel. The spring 20 can be inserted into the upper housing part 600 such that the connecting section 21 is securely received in the area formed between the web 612 and the rear wall 604.

In Figure 11, an actuating part 60 is shown, which can be connected to the upper housing part 600. The actuating part 60 has a bearing piece 61 in the form of a circular plate. This plate forms on its, the upper housing part 600 side facing a guide surface 62 (see Figure 12). On the bearing piece 61, a driver 63 is integrally formed. The driver 63 has flats on opposite sides. Furthermore, the bearing piece 61 carries two locking elements 64 with latching lugs 65. On its front side, the actuating part 60 has a projection 66 with which the actuating part 60 can be operated. The actuating member 60 can be used with its bearing piece 61 in the recess 607, wherein the guide surface 62 rests on the surface 608 to form a sliding guide. The cylindrical outer wall of the bearing piece 61 forms together with the cylindrical inner wall of the recess 607 a pivot bearing. The actuating element 60 engages with its driver 63 and the latching elements 64 the opening 609 in the housing upper part 600. This situation is shown in FIG.

In FIGS. 13 and 14, a positioning element 500 is illustrated. As these illustrations show, the positioning element 500 has a front side 501. In this front 502 shots and positioning parts 503 are incorporated. Furthermore, a protruding cylindrical projection 504 is formed in the region of the front side 501. On its rear side, the positioning element 500 has a cylindrical bearing projection 507. This bearing lug 507 is penetrated by a bushing 506, 506 snap-in receptacles 505 are present in the implementation. As illustrated in FIG. 14, the positioning element 500 has positioning receptacles 509 in the region of its peripheral surface. The holding elements 23 of the spring 20 can engage in different setting positions on opposite sides thereof. In particular, three mutually rotated adjusting positions can be realized.

The positioning element 500 can be connected to the structural unit shown in FIG. For this purpose, first the spring 20, as described above inserted into the upper housing part. Subsequently, the positioning element 500 can be inserted into the housing upper part, wherein the bearing lug 507 engages in the opening 609. In this case, flattenings in the region of the bushing 506 reach opposite to the flattenings of the carrier 63 of the actuating part 60, so that a rotationally fixed assignment of the positioning element 500 to the actuating part 60 is achieved. When inserting the positioning element 500, the locking elements 64 slide into the passage 506 until the locking elements 64 snap behind the locking receptacles 505. As a result, the assembly step is completed. In the mounted position, the sliding surface 508 is located on the inside of the bottom 601 to form a sliding guide. As FIG. 15 shows, two contact elements 40 can be connected to the positioning element 500. The contact elements 40 are substantially identical in construction to the contact elements 30, so that reference may be made to the above statements. The Contact elements 40 again have a contact element 41, which is connected via a connecting portion 42 with a support member 43. From the support member 43 protrudes a projection 34. The contact elements 40 can be connected in the same way with the positioning element 500, as the contact elements 30 with the controller 400. To avoid repetition, reference is therefore made to the above statements.

For the final assembly, the two preassembled modules according to FIGS. 10 and 15 can now be connected to one another. Flierzu the housing upper part 600 is placed on the housing part 200. In this joining movement, the spring-loaded contact elements 30 and 40 are compressed, so that the contact elements 31, as described above, to the backside tracks of the circuit board 10 and the contact elements 40 with their contact elements 41 at apply spring-loaded contacts on the front side of the printed circuit board. In the assembled state, the connecting cable 13 is sealed via the seal 12 inserted into the switch housing. The seal 12 is received in the seal receptacle 611 of the upper housing part and the seal receptacle 217 of the housing part 200. The fully assembled switch is shown in FIG.

When the switching element 300 is actuated, the slider 303 is adjusted linearly in the housing part 200. Due to the gear formed between the slider 300 and the regulator 400 with the actuator 106,107,109 and the actuator receptacles 305, 306, the linear movement of the slider 303 outside the contact space 208th converted into a rotary motion of the regulator 400. When the controller 400 rotates, so are the controller 400, the control contacts 30 are rotated on the circuit board 10, whereby the ohmic resistance can be adjusted.

With the actuating part 60, three switching stages can be realized. In an intermediate switching stage, the two contact elements 40 are not electrically connected to each other. As a result, an off position is realized. Starting from this middle switching stage, the actuating member 60 can be rotated in both directions become. Upon rotation of the actuating part 60, the rotatably connected positioning element 500 is rotated in the contact space 218. The rotation is effected by means of the spring 20, which is in the individual switching stages with their holding elements 23 in the positioning receptacles 509. With the rotation of the positioning member 500 and the contact elements 40 are rotated. In the switching stages represented, the contact elements 40 are electrically conductively connected to one another via the printed circuit board 10, as a result of which an anticlockwise or clockwise position can be achieved.

Claims

claims

1. switch for an electrical appliance, in particular for a power tool, with a controller (400) for adjusting the speed of the electrical appliance,

wherein in a contact space (218) of a switch housing, a printed circuit board (10) is arranged,

wherein the controller (400) cooperates with electrical components of the printed circuit board (10), preferably with control contacts (30) in contact space (218) to printed conductors of the printed circuit board (10), and wherein the controller (400) by means of a slide (300) operable is

characterized,

the regulator (400) is rotatably mounted and the sliding movement of the slide (303) is converted by means of a transmission into a rotary movement of the regulator (400),

and that the slider (303) is held and guided outside the contact space (218).

2. Switch according to claim 1, characterized in that a housing part (200) of the switching housing in a bearing receptacle (206, 207) rotatably receives a converter (100), and that the converter (100) has a driver (103), by means of it is rotatably connected to the controller (400) directly or indirectly.

3. Switch according to claim 2,

characterized in that the converter (100) in the region of the contact space (218) has one or more fastening elements (104), via which the controller (400) is coupled, and that the one or more fastening elements (104) preferably a latching projection (105) has / - s by means of which the controller (400) is locked to a latching receptacle (409).

4. Switch according to one of claims 1 or 2, characterized in that the converter (100) on its, the contact space (218) facing away from a or a plurality of actuating elements (106, 107, 109), and that the actuating element (106, 107, 109) or the actuating elements (106, 107, 109) with actuating element receptacles (305, 306, 307) cooperate to implement a To cause linear movement of the slider (303) in a rotational movement of the converter (100).

5. Switch according to one of claims 1 to 4, characterized in that the converter (100) has a stop (110) which rests in the issued rest position of the slide (303) on a counter surface (307) of the slide (303), to limit the actuating movement of the slide (303).

6. Switch according to one of claims 1 to 5, characterized in that the converter (100) has a base part (101), that the base part (101) has a circumferential side wall (102), by means of which the converter (100) in a Bearing receiver (206) of the housing part (200) is rotatably inserted.

7. Switch according to one of claims 1 to 6, characterized in that the housing part (200) outside the contact space (218) has a sliding surface (208) for the slide (303), and that indirectly or directly to the sliding surface (208 ) connect one or more guides (209), wherein in the guide (209) of the slide (303) with a guide piece (308) is linearly guided.

8. Switch according to one of claims 1 to 7, characterized in that the housing part (200) has a bottom wall (201) which is spaced from a wall element (205) of the housing part (200) is arranged, and that between the bottom wall (201 ) and the wall element (205), the sliding guide for the slide (303) is formed.

9. Switch according to claim 8, characterized in that the housing part (200) in the region of the bottom wall (201) has an opening (202) that through the opening (202) of the converter (100) in a bearing receptacle (206) in the wall element (205) is usable, and that in the inserted position of the converter (100) engages at least one actuating element (106, 107, or 109) in a fastening element receptacle (305, 306).

10. Switch according to one of claims 1 to 9, characterized in that the housing part (200) has an integrally formed spring holder (214) in which a return spring (50) is accommodated, which is connected to the slide (303) switching element (300). biases.

11.Schalter according to one of claims 1 to 10, characterized

in that the controller (400) has a contact holder (401) which has at least one receptacle (403) for fixing the actuating contact (30).

12. Switch according to one of claims 1 to 11, characterized in that the controller (400) in the region of the printed circuit board (10) facing away from the rear side (406) has a sliding surface (410) which is adapted to form a sliding guide on a wall surface of Housing part (200) is applied.

13. Switch according to one of claims 1 to 12, characterized in that the controller (400) has a non-symmetrical in cross section driver receptacle (407), and that the converter (100) with a driver (103), which also has an asymmetrical cross-section , engages in the driver receptacle (407).

14. Switch according to one of claims 1 to 13, characterized in that in the contact space, a rotatable positioning element (500) is held, which in the region of one of the front side (501) receptacles (502) that in the receptacles (502) contact elements ( 40) of a right-left switch, and that the contact elements (40) are preferably in contact with mating contacts of the printed circuit board (10).