EP0012279A1 - Push-button switch, particularly for keyboards of typewriters and similar devices - Google Patents

Abstract

1. A key switch, in particular for the keyboards of typewriters and similar devices, for example, teleprinters and data stations, having a key tappet (1) which on operation of the key can be moved from the rest position into the operating position against the spring force of a helical spring (4) which is fixed between the key housing (6) and a contact surface (2a) on the key tappet (1), wherein the spring (4) forms the moving contact piece which is brought into contact with a stationary counter-contact (3) during contacting, and the key tappet (1) of which can be further moved after contacting, characterised in that the helical spring (4) has two spring sections (4a, 4b) the first (4a) of which is designed in known manner as a compression spring for the return movement of the key tappet (1) from the operating position to the rest position, and the second (4b) of which rests against the side of the contact surface (2a) of the key tappet (1) which faces away from the first spring section (4a), with a given initial tension, and that the counter-contact (3) is arranged in the range of travel of the second spiral spring section (4b) of the spring (4) which is extended above the contact surface (2a) of the key tappet (1).

Description

The invention relates to a key switch, in particular for keyboards in typewriters and similar devices, for example teleprinters and data stations, with a key tappet which, when the key is pressed against the spring force, a helical spring attached between the key housing and a contact surface of the key tappet from the rest position into the working position is movable, the spring forming the movable contact piece, which is brought into contact with a stationary counter-contact when making contact, and whose key tappet can be moved even further by the contact.

There is already a push button switch with a push button mounted in a switch body, which is operably arranged between a rest position and a working position, and with a compression spring, through which the push button from the working position to the rest position is deferred (DE-OS 26 57 783). In this known push button switch, the compression spring is provided with an elongated extension which is brought into interaction with a counter-contact piece when actuated. The known push button switch has the disadvantage that when the contact is made, the elongated extension strikes the mating contact rigidly, which can cause contact bruises. The counter contact must therefore be resilient. The height of the push button switch is limited by the elongated extension, so that no particularly low button can be realized. A larger number of components are required, so that assembly and assembly are difficult.

The object of the invention is to identify and provide a key switch which is ergonomically particularly favorable for the operator, consists of a few individual parts and can be produced with little production outlay.

The solution to the problem is that the helical spring has two sections, of which the first section is designed in a manner known per se as a compression spring for returning the key tappet from the working position to the rest position, that the second spring section on that of the first spring section opposite side of the support surface rests with a certain preload, and that the counter-contact is arranged in the range of movement of the helical second section of the spring, which is extended over the support surface of the key tappet.

The dimensions of the new key switch are particularly small, with the key height being particularly small. The low height of the button is ergonomic This is particularly important for reasons because when the buttons are pressed, the operator's posture is less stressful. This is particularly noticeable when the operator actuates input keyboards that are mounted on operating surfaces of different heights. The new button enables the height to be reduced to more than half of the buttons previously used in practical operation. Despite the low height, the key switch is reliable and inexpensive to manufacture. The key switch consists of a few individual parts that can be assembled in a simple manner. The manufacture and assembly in a manufacturing machine is possible. The mechanical contact is particularly safe and there is a low contact resistance between the closed contact elements. By using the helical return spring, a uniform pressure behavior is achieved when the button is pressed.

An advantageous embodiment of the new push button is that the two sections of the helical spring have different winding diameters. This has the advantage that the spring characteristics for the two spring sections can be chosen differently.

Another advantageous embodiment of the new push button is that the first section has a smaller and the second section of the spring has a larger winding diameter. This has the advantage that a particularly soft response of the contact is achieved by the spring section with the larger diameter, although the required minimum contact pressure is given when contacting. The spring section with the larger diameter is also used to dampen the kickback can be used for the key tappet when returning from the working position to the rest position.

In order to protect the key itself from the effects of the solder bath when the key is soldered by means of a solder bath, in a further advantageous embodiment of the invention a protective collar is arranged around the point to be protected on the key, which is open in the direction of the solder bath and via the Protected area protrudes.

Details of the invention are explained on the basis of advantageous exemplary embodiments shown in the figures.

• Fig. 1 in einer Prinzipdarstellung den grundsätzlichen Aufbau und die Wirkungsweise des neuen Tastenschalters anhand eines vorteilhaften Ausführungsbeispiels
• Fig. 2 und Fig. 3 ein vorteilhaftes Ausführungsbeispiel des neuen Tastenschalters und
• Fig. 4 ein Ausführungsbeispiel des Tastenschalters mit einem Schutzkragen gegen Einwirkungen des Lötbades .bei der Herstellung.

Show it:

• Fig. 1 in a schematic diagram, the basic structure and the mode of operation of the new key switch based on an advantageous embodiment
• Fig. 2 and Fig. 3 shows an advantageous embodiment of the new key switch and
• Fig. 4 shows an embodiment of the key switch with a protective collar against the effects of the solder bath. During manufacture.

The new key principle is explained with reference to FIG. 1. The new key switch consists of a key plunger 1, which is movable in a key housing 6 in a guide 7 when the key is pressed. In the upper area of the key plunger 1, a collar 2 is firmly attached, which limits the movement of the plunger 1 upwards when the key is in the rest position. At the same time, the contact surface 2a the federal government 2 used to support the return spring 4. The helical spring 4 consists of sections 4a and 4b which have different winding diameters. The first spring section 4a with the smaller winding diameter is used as a compression spring, while the second section 4b with the larger winding diameter is used for contacting. The second spring section 4b, which consists of at least one turn, rests with a pretension on the driving lug 5, which is firmly connected to the collar 2 of the key tappet. The preload is selected so that the required contact pressure occurs when the contact is made. The characteristic of the spring can be adjusted with the help of the winding diameter. A soft spring action is achieved due to the larger winding diameter selected compared to section 4a, so that the operator does not have a hard pressure point when making contact. The spring 4 is used as a movable contact element, the end being designed as a contact connection 9. The mating contact 3 with its contact connection 8 is arranged in the housing 6 in a stationary manner as a rigid contact element in the range of motion of the second spring section 4b. The counter contact 3 is advantageously designed as a simple sheet metal plate. The key housing 6 and the key tappet 1 with the firmly attached collar 2 and the support surface 2a and the driving nose 5 can be produced in a simple manner as plastic parts.

The contact surfaces of the mating contact 3 and the winding part 10 of the second spring section 4b, which lie one on top of the other when the key switch is contacted, are coated with a layer which increases the conductivity, for example gold or palladium, for better contact.

In the state shown in Fig. 1, the key switch is in the rest position, i.e. before pressing the button. When the key is pressed, the key plunger 1 is moved in the direction of the arrow A by the operator's finger pressure by means of the attached key button. The key tappet slides long in the guide 7 in the housing 6. The spring section 4a is compressed. With the push button plunger 1, the collar 2 with the firmly attached driving lug 5 moves in the direction of the mating contact 3. The driving lug 5 is moved past the contact surface of the mating contact and the winding part 10 of the spring section 4b comes into contact with the contact surface of the contact 3. At this time, the contact is closed and there is an electrically conductive connection via the contact connection 9, the spring sections 4a and 4b, the counter contact 3 and the contact connection 8. Due to the prestressing of the spring section 4b, the winding part 10 rests on the counter contact when the contact is made with the required contact pressure. This closes the contact of the key switch without bouncing. The key plunger 1 is moved further, so that the driver nose 5 comes to rest below the contact surface of the mating contact 3. As a result, the winding part 10 lies freely on the contact surface of the mating contact. This prevents malfunctions during operation due to uneven pressing, a decrease in finger pressure or trembling when the button is pressed. The key tappet has then reached its end position, the working position, the movement being limited either by the bottom surface of the guide 7 or by the spring section 4a which can no longer be compressed.

When the operator releases the button, the button plunger 1 returns from the working position to the rest position. The compressed spring section 4a, which is delimited on the one hand by the housing 6 and on the other hand by the contact surface 2a on the collar 2, presses the key tappet over the collar 2 in the direction of the arrow R. The contact is reliably interrupted when the driver nose 5 on the contact surface of the mating contact 3 moves past. The spring section 4b then rests on the driving lug 5 with the predetermined pretension. The return movement of the key tappet is limited either by the spring travel of the spring section 4a or by the housing on which the collar 2 abuts. The impact of the key tappet 1 on the housing cover during the return movement is advantageously dampened by the spring section 4b.

1 shows the structure and the mode of operation of the key switch for a normally open contact, FIGS. 2 and 3 show an advantageous exemplary embodiment of a key switch as a changeover contact which can be switched over between a normally closed contact and a normally open contact.

Fig. 2 shows a side view of the key switch in section. Fig. 3 shows the arrangement of FIG. 2 in section in the view from above.

The push button consists of a button 11, which is attached to the push button 1. The key tappet 1 is moved in the key housing 6. The components required for the switching function of the changeover contact are contained in the key housing 6, which is completed by the key cover 14. The key cover 14 is when placed on the housing 6 via the Rastna attached to the housing sen 14a and 14b positively connected by snapping. The housing 6 is snapped into a recess in a carrier plate 13 via the detent springs 19 and 20, which absorbs the assembly and engagement forces. A circuit board 12 is arranged on the underside of the key housing 6, to which the contact connections 8 and 9 are soldered. The chamber formed by the key housing 6 and a key cover 14 protects the contacts and the moving parts associated therewith from external influences such as dust or vapors which arise, for example, during the automatic soldering process of the printed circuit boards.

The key tappet 1 is guided in the guide 7 in the housing and a guide 15 in the key cover 14 when actuated. A collar 2 is fixedly attached to the key tappet 1. The first spring section 4a is supported on the support surface 2a on the underside of the collar 2. The second spring section 4b of the helical spring 4 has a larger diameter than the spring section 4a and extends beyond the contact surface 2a. The other end of the first spring section 4a is supported on the bottom surface of the key housing 6. The driver lugs 5 and 17 are attached to the collar 2. In the button housing 6, the contacts 3 and 16 are arranged in a fixed manner, the contact connections of which are connected to the printed circuit board 12.

In the idle state, the normally closed contact is closed, so that there is an electrically conductive connection to the contact 16 and its contact connection (not shown) on the printed circuit board 12 via the contact connection 9 and dε spring sections 4a and 4b. In this state, the uppermost turn 18 of the second spring section 4b rests on the contact surface of the mating contact 16 with the required contact pressure. This requires that the contact surface of the mating contact 16 below the lower side of the driving lug 17 comes to rest, and the spring tension is selected so that the uppermost turn rests on the contact surface with the contact pressure required for correct contacting. In the idle state of the key switch, the lowermost turn 10 of the second spring section 4b rests on the upper side of the driving lug 5 under prestress. The preload is selected so that it corresponds to the required contact pressure when making contact in the working state.

When the key is actuated in the direction of arrow A, the key tappet 1 is moved downward, thereby compressing the first spring section 4a. When the key tappet moves downward, the second spring section 4b is also moved. The driver nose 17 lifts the uppermost turn 18cbs of the second spring section 4b from the contact surface of the mating contact 16. From this point in time, the uppermost turn 18 rests on the underside of the driving lug 17 with a prestress corresponding to the contact pressure when the contact is made.

When the working position is reached, the lowermost turn 10 of the second spring section 4b comes to rest on the contact surface of the mating contact 3. The contact pressure, -: - with which the lowest turn rests on the contact surface corresponds to the pretension with which the lowest turn 10 has placed on the driving lug 5. In order for this to be achieved, however, it is necessary that the upper side of the driving lug 5 comes to rest below the contact surface of the mating contact 3 in the working position of the push button. In the working position there is an electrically conductive connection between the contact connections 8 and 9 via the first spring section 4a, the lowermost turn 10 of the second spring section 4b and the counter contact 3.

When the button 11 is released, the push button returns to the rest position by the spring force of the first spring section 4a. When the key tappet moves in the direction of the arrow R, the driver nose 5 lifts the lowermost turn 10 of the spring section 4b from the contact surface of the mating contact 3. The lowermost turn 10 of the spring section 4b then lies on the driving lug 5 with a prestress corresponding to the contact pressure when contact is made. When the rest position is reached, the uppermost turn 18 of the second spring section 4b comes to lie on the contact surface of the mating contact 16 with the required contact pressure, which corresponds to the pretension on the driving lug 17. This is achieved in that the underside of the driving lug 17 comes to lie above the contact surface of the mating contact 16. The upward movement is limited by the top of the collar 2, which abuts the key cover 14. In the idle state, there is the conductive connection via the contact elements 16, 4b, 4a and 9.,

Fig. 4 shows a sectional view of the key switch with a protective collar against the effects of the solder bath.

A protective collar 19, which is open to the solder bath, is formed on the plunger guide 7 'on the plastic housing 6 of the button. With the help of this protective device designed as a protective collar 19, the plunger guide 7 is prevented from being deformed when the button with the circuit board 12 is immersed in the trailing or immersion solder bath under the action of heat from the solder, and the guiding function is thus impaired.

When the button with the circuit board 12 is immersed in the solder bath, an air cushion is formed in the cavity between the plunger guide 7 and the protective collar 19, which Penetration of the solder into the cavity formed by the protective collar 19 is prevented and acts as a heat insulator, which prevents heat damage to the plunger guide 7. In order to prevent the solder from penetrating up to the plunger guide 7, it is necessary for the protective collar 19 to protrude beyond the plunger guide 7. When soldering in an immersion solder bath, the protective collar 19 only has to protrude slightly beyond the point to be protected, namely the plunger guide 7. In contrast, when soldering in a trailing solder bath, for example a wave solder bath, it is necessary for the protective collar 19 to protrude so far beyond the plunger guide 7 that the formation of an air cushion is ensured. A warping or damage to the protective collar 19 is of no importance since it has no influence on the function of the button. It is also conceivable to remove the protective collar 19 after the soldering process. To facilitate removal, the protective scraper 19 can be detachably connected to the button, for example.

In the simplest case, the protective collar 19 is arranged in a ring around the point to be protected, namely the tappet guide 7. It is also conceivable for it to have the shape of other geometric figures. It is expediently formed from the same material as the underside of the key switch.

Claims (16)

1. Key switch, in particular for keyboards in typewriters and similar devices, for example teleprinters and data stations, with a key tappet which can be moved from the rest position into the working position when the key is pressed against the spring force of a helical spring attached between the key housing and a contact surface of the key tappet, wherein the spring forms the movable contact piece, which is brought into contact with a stationary counter-contact when the contact is made, and whose key plunger can be moved even further after the contact, characterized in that the helical spring (4) has two sections (4a, 4b) , of which the first section (4a) is designed in a manner known per se as a compression spring for returning the key tappet (1) at the working position to the rest position, that the second spring section (4b) on the side facing away from the first spring section (4a) the support surface (2a) with egg ner certain bias is present, and that the counter-contact (3) is arranged in the range of movement of the helical second portion (4b) of the spring, which is carried over the bearing surface (2a) of the key tappet (1). 2. Key switch according to claim 1-,
characterized in that the two spring sections (4a, 4b) of the helical spring (4) have different winding diameters. 3. Key switch according to claim 2,
characterized in that the first spring section (4a) has a smaller one and the second Spring section (4b) has a larger winding diameter. 4. Key switch according to claim 1,
characterized in that the second spring section (4a) consists of at least one turn. 5. Key switch according to claim 1,
characterized in that the lowermost turn (10) of the second spring section (4a) rests under tension on a driver nose (5) fixedly attached to the key tappet (1). 6. Key switch according to claim 5,
characterized in that the driver nose (5) releases the second spring section (4b) when contact is made. 7. Key switch according to claim 5,
characterized in that a first and a second driving lug (5, 17) are arranged on the key tappet (1), between which the second spring section (4b) is arranged, that in the idle state the lowest turn (10) of the second spring section (4b) the first driver lug (5) rests under tension, that the uppermost turn (18) rests under tension on the first mating contact (16) and that in the working position the top turn (18) of the second spring section (4b) under tension on the second driver lug ( 17) rests and the lowermost turn (10) of the second spring section rests under prestress on the second counter contact (3). 8. Key switch according to claim 1,
characterized in that the contact surface of the second spring section (4b) and the contact surface of the mating contact (3) are coated with a layer which increases the conductivity of the contact points. 9. Key switch according to claim 6,
characterized in that the key tappet (1) still has a wake after contact. 10. Key switch according to claim 1,
characterized in that the end of the second spring section (4b) facing away from the bearing surface (2a) dampens the push of the key tappet on the return movement from the working position into the rest position on the key cover (14). 11. Key switch according to claim 1,
characterized in that the preload corresponds to the required contact pressure when making contact. 12. Key switch according to claim 1,
characterized in that the two spring sections (4a, 4b) of the mating contact (3) and the part of the key tappet (1) having the bearing surface (2a) are arranged in a chamber (6, 14) which is closed on all sides. 13. Key switch according to claim 12,
characterized in that the chamber is closed by a snap-in key cover (14). 14. Key switch according to one of claims 1 to 13, with a protective device in order to protect the part protruding through the printed circuit board against the effects of the solder bath,
characterized in that a protective collar (19) is arranged around the point (7) to be protected on the key switch, which is open in the direction of the solder bath and projects beyond the point (7) to be protected. 15. Key switch according to claim 14,
characterized in that the protective collar (19) is arranged in a ring around the point (7) to be protected. 16. Protective device according to claim 14 or 15, characterized in that the protective collar (19) consists of plastic and is molded onto the housing (6) of the key switch.

Images