DE1301366B - Contactless key switch device for generating electrical impulses - Google Patents

Description

The invention relates to a contactless key switch device for Generation of electrical impulses with a on a non-magnetic key plunger seated magnetic plate, with a fixed, on displacements of the magnetic plate appealing induction coil and with a reset element for the key plunger.

Because key switch devices with electrical contacts due to deterioration the contacts are subject to high wear and tear, are already magnetic key switch devices known.

The German Auslegeschrift 1101 498 describes a key switching device where magnetized disks sit on the key tappet and are arranged according to the respective code assigned to the key in question. The key tappets are moved past a magnetic read head at a predetermined speed, which emits code signals according to the arrangement of the magnetic disks. This arrangement is only applicable to a specific code. In addition, the level of the output pulses is comparatively low. Finally, for each key switch device, a drive device is required which moves the key plunger past the magnetic head at a constant speed.

It has been shown that it is more appropriate to use the coding from the Separate key switch device. The German Auslegeschrift 1073 030 describes a key switch device in which a permanent magnet is inside a toroidal core is tilted with a coil when the button is pressed. This tilting device has an instability that becomes noticeable in continuous operation because the Change the characteristics of the output pulses over time. In addition, this key switch device a comparatively large extension transversely to the axial direction of the key plunger, because the tilting arrangement consists of several lever and spring elements.

Another key switch device according to the German Auslegeschrift 1186 497 works with toggle switches to trigger keys, whereby a magnet is pivoted through the armature gap of a coil yoke via a toggle device. This device is unsuitable for a keyboard because a keyboard uses pushbuttons.

The German Auslegeschrift 1 145 225 shows a key switch device of the type mentioned. There, the electrical output pulse is picked up by a coil, past which a magnet moves, so in the manner of a magnetic read head. The output pulse is therefore comparatively weak. In addition, in this arrangement, several permanent magnets must be precisely matched to one another so that reliable actuation is obtained.

The object of the invention is such a design of a key switch device of the type mentioned, that you get a high output pulse and that the setting the key switch device is not critical.

This object is achieved according to the invention in that the plate, a cylinder core and a yoke closed in the waiting position of the key plunger Form magnetic circuit with the plate or the cylinder core as a permanent magnet and that the induction coil is wound around the core.

The surprising progress of the invention is achieved by that one works with a closed magnetic circuit. On hold of the key this magnetic circuit is kept closed. When the button is pressed, the magnetic circuit torn open, causing the magnetic resistance of the same momentary and erratic; largely independent of the speed of movement of the key plunger, changes. This gives the induction coil a voltage that is more constant Size. The output pulses are thus each the same size without additional Precautions must be taken to ensure an even adjustment speed of the key plunger to be observed. The arrangement is largely insensitive to signs of aging. The induction coil does not detect movements of the key tappet, but rather the change in magnetic resistance when the closed magnetic circuit is torn open.

Preferred embodiments of the invention are set out in the subclaims specified.

The invention is in typewriters, teleprinters, calculators and the like applicable.

Details of the invention emerge from the following description of exemplary embodiments with reference to the drawing. It shows F i g. 1 shows the perspective view of an exemplary embodiment of the invention, FIG. 2 shows a section through the FIG. 1 shown device, FIG. 3 shows a top view of an exemplary embodiment of the keyboard according to the invention, FIG. 4 A, 5 A, 6 A and 8 A different examples of key switching devices which are used in the invention, each in their rest position, FIG. 4 B, 5B, 6 B and 8 B shown in FIGS. 4 A, 5A, 6 A and 8 A key switch devices shown in the depressed position, FIG. 7 shows the side view, partly in section, of a further exemplary embodiment of a key switch device, FIG. 9 shows the circuit of the induction coil with an auxiliary coil, shown with circuit symbols, FIG. FIG. 10 is a diagram of the timing of the pulses, which shows the functioning of the functions shown in FIGS. 7, 8 A, 8 B and 9 keys shown.

The F i g. 1 and 2 show the most important parts of a keyboard, with a large number of individual keys 1, which can be arranged in any shape. If the keyboard is to be used for a teleprinter, the keys correspond to 1 a the respective letters, and there are other keys 1 b and 1 c provided, the serve other functions. The keys 1 a, 1 b and 1 c are in a base plate 5 attached, over which a cover plate 4 spans. The whole arrangement is from a cover 2 covered. As in FIG. 2 can be seen below the buttons 1 plates 6 with printed circuit with their connection contacts 3 a be arranged. The output signals from the keyboard can be output via the plug contact connection 3 can be removed. The base plate 4 is preferably made of magnetically conductive Material made so that adjacent keys do not interfere with each other. But since the output voltage is relatively high (e.g. several volts), is it is also possible to use magnetically non-conductive material.

On the basis of FIG. 4 A and 4 B, the structure and the mode of operation of a key switch device shown by way of example is described, which is composed of a key push button 110, a cylindrical coil core 12, a plate 13 and an induction coil 14. The key tappet 10 is made of magnetically non-conductive material, such as brass or plastic, and the key top 11 is also made of plastic on its upper end. The plate 13 is a magnetically conductive material, such as iron, and with known fastening means, such as a nut 19 in this example, is arranged at the lower end of the key tappet 10 approximately at right angles to its axis. The key tappet 10 penetrates the cylindrical core 12, around which an induction coil 14 is wound coaxially with the key tappet 10. Flanges 17, 18 are arranged on both sides of the core 12. The flange 18 and the cylindrical coil core 12 are fastened to the plate 5, which consists of magnetically non-conductive material, with conventional fastening means. Between a stop pin 16 and the base plate 5, a compression spring 15 surrounding the key tappet 10 is arranged. This spiral spring 15 acts on the key tappet 10 in such a way that the plate 13 is pressed against the cylindrical coil core 12 at the lower end. If, as described above, a coil flange 17 is provided, the plate 13 rests against this flange 17 at the lower end of the coil core 12. The plate 13 is magnetized, specifically parallel to the axial direction of the key plunger 10. F i g. 4A shows an embodiment in which the plate 13 is a permanent magnet.

In such an arrangement, the penetrates through the plate 13 Induced magnetic flux the flange 17 and the coil core 12 and the flange 18 and the surrounding air. In addition, the disk 13 is due to the magnetic Attraction force to the flange 17 is used.

When the key top 11 is pressed in, the key plunger 10 and the Plate 13 moved against the force of the spring 15, as shown in FIG. 4 B reproduces, so that the permanent magnet plate 13 is torn from the coil flange. Through this the course of the magnetic flux generated by the plate 13 is predominantly in the air misplaced. The magnitude of the flux coupled to the induction coil 14 increases instantly so that a voltage pulse is induced in the coil.

After the force is removed from the key top 11 again, the key plunger 10 returns to its starting position, which is shown in FIG. 4 A is shown by the action of the spring 15 back. During the return movement, a voltage is also induced in the induction coil 14, since the coupling of the induction coil 14 with the flux becomes closer again. However, the voltage induced during the reset time is polarized in the opposite direction to the voltage generated first. Thus, the voltage generated during the indentation can be easily removed from the induction coil 14 with the aid of a rectifier.

In the arrangement that has just been described, the plate 13 only detaches from the flange 17 when the force acting on the key tappet 10 is greater than the force of the helical compression spring 15 and the force of attraction between the plate 13 and flange 17. If only a small force is accidentally applied to the key top 11, the key plunger 10 is not yet pressed down. In addition, the plate 13 separates from the flange 17 at a considerable initial rate. As a result, the level of voltage that is generated in the induction coil during the indentation will always exceed a certain value.

The voltage in the induction coil 14 can be increased according to the invention by adding a simple part. The F i g. 5 A and 5 B show a yoke 20 which connects the plate 13 to the flange 18 on the outside across the coil 14. The yoke 20 is slidably connected to the flange 18. As a result, when the key is in the idle state, a closed magnetic circuit is formed via the flange 18, the magnetic core 12, the flange 17, the plate 13 and the yoke 20. However, if the plate 13 is pressed off the flange 17 as a result of pressure on the key top 11, the magnetic circuit between the flange 17 and the plate 13 is opened. This results in a very strong change in the magnitude of the magnetic flux which passes through the induction coil 14 , which is expressed in a high value of the induced voltage in the induction coil.

In the F i g. 6 A and 6 B is a similar example of a key switch device shown in which the magnetic closure circuit through the cylindrical coil core 12, the flange 18, an outer cylindrical yoke 21 and the plate 13 are formed will. In this example, the flange 17 of the previous examples is omitted. Compared to the key according to FIGS. 5 A and 5 B is this key with a complete magnetic closing circuit equipped. Therefore also the induced Voltage higher compared to previous examples.

The F i g. 7 shows a further embodiment of a key switch device, in which the key tappet 10 is divided into two parts 10 a and 22. Part 22 has a cylindrical bore 26 into which one end of the plunger part 10 a is inserted is. The key tappet 10 a is in a hole 27 of an L-shaped holder 24, the is attached to the plate 5, performed. The standing force acts on the key top 11 and the elastic restoring force of the compression coil spring 15 on part 22 of the Key tappet. Only when the elastic force is the force of attraction between the plate 13 and the flange 17 predominates, the plate 13 and the part 22 detach from the flange 17. So the key has some leeway until it takes effect, similar to the usual one Key of a typewriter. A flange 23 on the tappet section 22 serves as a delimitation for the downward movement of this section. The restoring force for the ram part 22 is obtained from a compression spring 28, which is in the most depressed position is compressed to its smallest length. If the ram part 22 is now in its When the initial position is pushed back, the spiral compression spring 15 presses the upper tappet section 10 a in its rest position so that it rests with a stop collar 16 on the holder 24.

In this example and in the example according to FIGS. 8 A and 8 B, the key switch device also has an auxiliary coil core 12 a with flanges 17 a and 18 a and an auxiliary coil 14 a , which have essentially the same dimensions and properties as the core 12, the flanges 17 and 18 and the induction coil 14. Here, the induction coil 14 and the auxiliary coil 14 a are connected in parallel via a diode Do, as shown in FIG. 9 reproduces. The curve shape (1) in FIG. 10 gives the time course of the induced voltage in the induction coil 14 and the curve shape (2) in FIG. 10 shows the time course of the induced voltage in the auxiliary coil 14 a again. The polarity of the pulses P1 and P3 is opposite to one another, since the direction of the change in the concatenated fluxes for the coils 14 and 14a is different. If the magnitude of the induced voltage e1 is equal to the voltage e, the resulting voltage pulse PS will only have the duration t, which is significantly shorter than the pulse duration t1 of the pulse P1. The pulse P4 that occurs when the button is reset is blocked by the diode Do, and the pulse P is blocked by the diode do. Consequently, only one impulse of short duration (for example 1 msec), which acts in one voltage direction, occurs at the output terminal 25 of the key switching device each time the key is pressed down. If such aids are attached which shorten the pulse duration significantly, the keys arranged on the keypad can be struck one after the other at considerable speed without influencing one another.

In an embodiment in which the induction coil with 4000 turns was equipped, the peak value of the pulse voltage was more than 2 V when the force applied to the key top 11 is 50 g exceeded.

Claims (5)

Claims: 1. Contactless key switch device for generating electrical pulses with a magnetic plate sitting on a non-magnetic key plunger, with a fixed induction coil responsive to displacements of the magnetic plate and with a reset element for the key plunger, characterized in that the plate (13) has a cylinder core (12) and a yoke (20; 21) form a magnetic circuit, which is closed in the waiting position of the key plunger, with the plate or the cylinder core as a permanent magnet and that the induction coil (14) is wound around the core (12). 2. Key switch device according to claim 1, characterized in that that a rectifier (do) is connected to the induction coil (14). 3. Key switch device according to claim 1 or 2, characterized in that the cylindrical core (12) is on both sides Has end flanges (17,18). 4. Key switching device according to one of claims 1 to 3, characterized in that an auxiliary core (12 a) and an auxiliary coil (14 a) are provided around the auxiliary core (12 a), the plate (13) in the depressed state of the key plunger ( 10, 22) on the auxiliary core (12 a), and that the induction coil (14) and the auxiliary coil (14 a) are connected in parallel via a second rectifier (Do). 5. key switch device according to claim 4, characterized in that the key plunger is divided into two parts (10 a, 22) , the two parts (10 a, 22) are connected by a first elastic member (15) and on the section (22) another spring member (28) engages, which provides a restoring force for this section (22).