NO129427B - - Google Patents

Description

Electric switching device of slide selector type.

This invention relates to an electrical coupling device

for selectively interconnecting a plurality of input and output signal conductors.

Such coupling devices are used for programming purposes, e.g. when controlling industrial processes or machine tools, and is also used in computer terminal equipment for entering variable data for transfer to a calculator.

There are known sliding selector switch coupling devices of the "cross bar" type for such purposes where a contact part is used which is caused to be brushed over conductive printed circuit strips or strips on an insulating plate.

Usually, such coupling devices have a size that Kfr. kl. 21c-39/01 depends on the mutual distance between the conductive strips which is necessary to ensure electrical isolation between the strips.

One of the reasons for this is that the contact part is made to slide over the conductive strips and the insulating plate under a sufficient pressure to remove and smooth down small amounts of conductive material from the strips over the insulating plate between adjacent strips. Ultimately, this can cause a short circuit between the strips and failure of the coupling device. It is preferred in such a coupling device to have a step setting mechanism so that the contact part can be placed exactly in position.

More specifically, this invention relates to an electrical switching device of the sliding selector type, preferably with indication symbols, e.g. for use in the control of industrial processes, which selector comprises two opposite, parallel plates of electrically insulating material, which are attached to each other with a space for a plurality of sliding contact elements and on the opposite surfaces are printed a plurality of electrically conductive circuit strips with intermediate insulating material, and each is connected by a signal conductor, in addition to which the plates are attached to each other in such a way that the circuit strips on one plate extend perpendicular to the strips on the other plate, whereby the strips on one plate can be brought into electrical connection with the strips on the other second plate by means of the aforementioned sliding contact elements, which can be moved manually in guide slots in the second plate, one slot for each strip on it.

The new and distinctive features of the device according to the invention are specified in the patent claims. With the device according to the present invention, it is prevented that the contact part pulls over conductive material between the contact surfaces and this new device also results in an advantageous step setting effect.

The invention will now be described in connection with examples with reference to the drawings, where: Fig„ 1 is a perspective view of an embodiment of the coupling device according to the present invention.

Fig. 2 is a perspective view of a corner of the device in fig.

1 shown partially in section.

Fig. 3 is a longitudinal section through the device in fig. 1.

Fig. 4 is a perspective view of a contact part used in

the device in fig. 1.

Fig. 5 is a side view shown partially in section of the contact part on

fig. 4.

Fig. 6 is a section along the line VI-VI in fig. 3.

Fig. 7 is a plan view of a part of another embodiment

for a coupling device according to the invention.

Fig. 8 is a section along the line VIII-VIII in fig. 7.

Fig. 9 is a plan view of part of a third embodiment

for a coupling device according to the invention, and

fig. 10 is a section through the device in fig. 9.

The coupling device 10 as shown in fig. 1, is a coordinate selector and comprises a lower plate 12 of electrically insulating material with a plurality of conductive strips 14 on its upper surface (see Figs. 2 and 3). Board 12 may be a printed circuit board suitably etched to form parallel stripes or strips of conductive material. Above the upper surface of the plate 12 and the strips 14 is arranged a thin foil 16 of electrically insulating plastic material with a plurality of largely rectangular openings 18, as shown in fig. 2 and 3. The openings 18 are approximately as wide as the strips 14 and are arranged in accordance with the strips 14 so that a plurality of discrete contact surfaces are formed on each strip 14. The strips 14 extend to the edge of the plate 12 so that they can cooperate with a edge contact part 20 (fig. 1) comprising contact springs which are connected to signal conductors 22.

Another plate 24 is mounted above the plate 12 and has a plurality of conductive strips 26 (Figs. 3 and 6) which extend along the plate's lower surface perpendicular to the strips 14 of the plate 12. The plate 24 has a series of slots 28 each of which accommodates a sliding contact portion 40. which extends over the upper surface of the plate 24 to be grasped by an operator. The plate 24 is held rigidly at a distance from the plate 12 by means of spacers 30 at the corners of the two plates 12 and 24, and these two plates are attached to each other by means of screws, rivets or the like 32. The stripes 26 on the plate 24 extend to an edge of the plate 24, as shown in fig. 1, to be connected with an edge contact part 34 which is connected with signal conductors (not shown). The signal conductors which are connected to the contact part 34 and the signal conductors 22 which are connected to the edge contact part 20 can optionally be considered as input and/or output signal conductors depending on the application of the coupling device 10.

Each contact part 40 as shown in fig. 3 to 6, inclusive

a body of electrically insulating plastic material having an upper surface stepped as indicated at 42 to receive the operator's finger. The lower part of the contact part 40 comprises two separate rounded abutment surfaces 44 and 46 adapted to rest on the upper surface

of the insulating foil 16. Between the contact rafts 44 and 46, a contact spring 48 is mounted which has a lower contact part 50

and an upper contact portion 52.

As can best be seen from fig. 3, at the right contact part 40 shown there, the lower surface of the contact part 40 comprises a projection or a knob 54 which is dimensioned to fit into any opening 18 in the foil 16. The spring 48 is dimensioned so that the contact part 50 is placed in position near the middle of an opening 18 and the middle of the contact strip 14, and the upper contact part

52 to move towards the strip 26 on the plate 24. The spring 48 is

also dimensioned so that it is substantially loaded when it is enclosed between the plates 12 and 24.

Each contact part 40 is mounted so that it can be moved from one end of its associated slot 28 to the other, with the projection 54 engaging the openings 18 in the foil 16 to step the position by such movement to place the contact spring 48 in which preferably of a number of discrete positions which are determined by the openings 18. As can best be seen from fig. 5, when a contact part 40 is moved, the contact part 50 is pressed upwards by the intermediate parts 17 of the foil 16 between adjacent openings 18. When the contact part 50 is pressed up and out of contact with a given strip 14, it is both coated by the edges of the intermediate parts 17 and prevented from pulling or leading conductive material from the strip 14 over to the adjacent strip 14. Moreover, the contact part 50, when it leaves an intermediate part 17, will fall down under spring force on the next strip 14 with a snapping effect that improves the electrical connection. As can best be seen from fig. 6, the projection 54 and the contact portion 50 have an opening 18 in common, so that the step setting effect is tied to the special connection that is formed. This considerably simplifies the construction of the device and its tolerance requirements.

Fig. 7 and 8 show another coupling device 60 according to the invention. As shown in fig. 7, the device comprises an upper plate 62 with slits 64 which have a similar function and construction to the slits 28 in fig. 1 and 2. A series of conductive strips 61 extend parallel to the slits 64 on the lower surface of the plate 62. The device also comprises a thin insulating foil 65 with through openings 66 corresponding to the conductive

strips 68 on a lower plate 70, and a sliding contact part 72 similar to the contact part 40 in fig. 1 to 6. The plate 62 contains a number of openings 63 which are offset in relation to the slots 64.

Between the plates 62 and 70 and at one end, a spring-loaded roller 74 is arranged for each slot 64 and contact strip 61 =

Each roller 74 comprises an outer cylindrical member 74 mounted therein

a bearing block 78 of internal diameter large enough to receive the roller and a belt 80. Each roller 74 is mounted on a shaft 82 which is fixedly disposed relative to the block 78 and actuates a spring 84 attached to the roller 74 as shown in FIG. fig. 8. The spring 84 is designed to be wound up and loaded by rotation of the roller 74 in the clockwise direction. A common shaft 82 may be arranged with individual blocks 78 and rollers 74 for each of the bands 80

in the device. An individual mechanism may optionally be arranged for each band 80.

Each band 80 is attached to the corresponding contact part

72 in the manner shown in fig. 8, so that it is pulled from this when the contact part 72 is moved along the associated slot 64 to establish a mutual connection between a given pair of strips 61 and 68. As indicated in fig. 7, the band 80 has such a width that it runs clear of adjacent slits 64. On the upper surface of each band 80, a number of symbols are printed which serve to indicate the position of the contact part 72 which is assigned to the respective band. Each band 80 may be made of textile or plastic material or another flexible material. The tensile force exerted by the roller 74 should be just sufficient to keep the tape relatively flat when the contact part 72 is moved back and forth, but not so great that the contact part 72 is displaced from a rest position.

Fig. 9 and 10 show a further coupling device 90

in accordance with this invention and which largely corresponds to the devices described above. The device 90 comprises an upper plate 92 on the lower surface of which a number of conductive strips 94 are arranged and which plate comprises a plurality of slots 96. A contact part 98 is arranged in each slot 96 and has a design largely corresponding to the design of the contact parts 40 and 72 in fig. 1 to 8. The device 90 also comprises a lower plate 100 with a series of conductive strips 102, and with a thin foil of plastic material 104 placed on its upper surface. The foil 104 comprises a series of through openings 106 corresponding to the strips 102. Towards the left end of the device as shown in fig. 9, a number of openings 93 are arranged through which symbols which each indicate the position of a corresponding contact part 98 and are carried by a flexible band 110, can be seen. The tape 110 is occupied in a block 112 with a

circular internal bore 114 which is closed at one end by a wall 116 and at the other end by an adjacent block 112. Each block 112 includes a thin slot 118 just wide enough to accommodate the band 110 which though it is flexible, is sufficiently rigid to be substantially self-supporting when held at its ends. One end of the band 110 can freely twist up inside the bore 114 in the block 112 and the other end is attached to a contact part 98 as indicated in fig. 10.

A strip of "Mylar" (registered trade mark) with a thickness of about 0.38 mm has proved satisfactory. The band is sufficiently wide to permit placement of the symbols on one edge thereof so that they are displayed in the openings 93 and at the same time to extend below an adjacent slot 96.

If the bands 110 are relatively long, it may be necessary to support them between the ends. This can be done by providing a further slotted plate similar to plate 92 with a conductive strip arranged on its inner surface, each band 110 being arranged to move between this further plate and plate 92.

Each band 110 serves to cover an adjacent slot

96 to prevent foreign bodies from accidentally falling through this. The bands 110 also provide some protection against the introduction of contaminants such as dust and the like, and thus extend the applicability of the coupling device to environments that may contain such contaminants.

Position lights for the contact part can be placed behind the hands 80 or 110 in fig. 7 to 10, which bands are made of transparent material so that the symbols on them are illuminated.

Although each contact part in the above-described embodiments performs rectilinear movement, it will be understood that the specified features of the invention can also be used in other forms of coupling devices, e.g. in a device where a rotating contact part is arranged to come into contact with a plurality of contact surfaces arranged along a circle about the rotation axis of the rotating contact part.

Claims (3)

1. Electrical switching device of slide selector type, preferably with indicating symbols, e.g. for use in the control of industrial processes, which selector comprises two opposite parallel plates (12,24) of electrically insulating material, which are attached to each other with a space for a plurality of sliding contact elements (40) and on the opposite surfaces a plurality of electrical conductive circuit strips (14,26) with intermediate insulating material, each connected to a signal conductor; in addition, the plates (12,24) are attached to each other in such a way that the circuit strips (14) on one plate (12) extend perpendicular to the strips (26) on the other plate (24), whereby the strips (14) on one plate (12) can be brought into electrical connection with the strips (26) on the other plate (24) by means of the aforementioned sliding contact elements (40), which can be moved manually in guide slots (28) in the second plate (24) , one slot for each strip (26) on this, characterized in that the one plate (12) above the circuit strips (14) has an electrically insulating raster foil (16) with a series of, e.g. rectangular, openings (18) above each of these strips (14), where in each row there is the same number of openings (18) as there are strips (26) on the second plate (24), which openings (18) define a plurality discrete electrical contact surfaces on each of the strips (14) on one plate (12), so that one (50) of two opposing contact fingers (50,52) in a contact spring (48) in the sliding contact elements (40) when these are displaced in the slots (28), with a snap action engages with the openings (18) and is thereby accurately guided into the electrical contact position in certain uniform steps. 2. Connecting device according to claim 1, characterized in that an electrically insulating carrying and operating part of the sliding contact elements (40) in the direction towards the foil (16) has a projection (54) for engagement in the openings (18) therein to provide step registration of the contact element (40). 3. Coupling device according to claim 2, characterized in that the projection (54) is positioned such that it engages in the same opening (18) as the one in which the said contact finger (50) snaps into (fig. 3).