FI64477C - TRYCKKOPPLARE - Google Patents

Description

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(22) Hakemlspilvi - Ansöknlngtdig 29-11-77 '(23) Alkupllvl — Glltlghetsdag 29.11.77 (41) Become Public - Blivlt offentllg Ογ _ q6.76

National Board of Patents and Registration of Finland Date of issue and date of publication. -

Patent · OCh registerstyrelsen Anaökan utlagd och utl. »Krlfter> publlcerad 29.07.83 (32) (33) (31) Pyydetty etuoikeus — Begird prlorltet 06.12. 76 O6.i2.76 USA 7 * + 8026, 7 * + 8025 (71) RCA Corporation, 30 Rockefeller Plaza, New York, N.Y. 10022, USA (US) (72) Theodore Dennis Smith, Indianapolis, Indiana, USA (US) (7 * 0 Oy Kolster Ah (5 * +) Pushbutton - Tryckkopplare

The present invention relates to a push switch having a connection plate, an insulating spacer plate and an elastic, electrically conductive contact plate in a layered order, the contact plate of the switch being pushable into contact with the coupling plate through at least one opening of the spacer plate. The push switch of the invention can be used for calculator-type keyboards for various calculation and control functions. For example, they have been used in a television set to allow the viewer to select a particular channel and adjust functions such as volume, color and tonality. Such an application is described in the instruction manual "XL-100 Color Television - The CTC-81 Chassis", published by RCA Corporation, Indianapolis, Indiana.

The calculator type keyboard includes a system of keys (push buttons). Typically, each pushbutton corresponds to a decimal number or command. It is often desired that a calculator-type keyboard include switching contact mechanisms capable of directly converting decimal numbers and instructions to binary coding and not indirectly by an encoder formed by a logic circuit, in order to simplify the structure of the keyboard and reduce its cost. For example, to encode all decimal numbers from zero to nine in the well-known and frequently used binary coded decimal format (BCD), it is necessary that at least one of the switching contact mechanisms associated with the decimal numbers be able to activate at least three contact latches when used. In addition, it may be desirable to form a contact that is closed after the code contacts are closed in order to generate a signal indicating that the data has been properly input and is ready for further processing. It is further desirable that a push-button switch contact mechanism having direct encoding features be simple and economical to manufacture and incorporate into a calculator-type keyboard, and provide a tactile (known) indication of its operation to the user and include self-cleaning contacts.

When the contact elements have flat surfaces that contact each other without a sweeping effect, it may be necessary to coat their surfaces with a precious metal such as gold or silver. This is expensive. In addition, even if such a coating is used, a foreign substance is placed between the surfaces of the two contact elements, the closing of the contact does not take place because there is no sweeping action (sliding) available to remove the foreign substance.

To prevent foreign matter from easily settling between the two contact surfaces, one of the contact surfaces may be provided with a raised portion. A coupling contact mechanism including a contact with a raised portion is described, for example, in U.S. Patent 3,886,341. However, due to the way in which these raised parts are formed, for example by bending or otherwise deforming a separate piece of metal, they cannot be helically used with the contacts which are the conductors of the printed circuit board.

U.S. Patent 3,952,174 discloses a system of solid concave plates each connected to a thin conductive material so that they can be easily incorporated into a keyboard. When the plate is pressed, it bends in an "oil can" manner and thus gives the user a tactile indication of its operation. However, since these switching mechanisms are arranged to make contact with only one conductor, they are not useful for binary coding. In addition, since the only movement allowed for a solid plate is along its axis, this coupling mechanism does not include a self-cleaning effect.

Our U.S. Patent Application 670,800, March 26, 1976, discloses a 3,647,77 system of coupling contact mechanisms formed as an integral part of a conductive strip so that it can be economically fabricated and incorporated into a keyboard. Each coupling-contact mechanism includes intersecting support arms extending inwardly from the circumferential section of the strip. The support arms are deformed to form a domed shape. A plurality of contact sheets extend outward from the junction of the support arms. The strip is spaced from the circuit board by an intermediate member having an opening substantially aligned with the coupling contact mechanism. When the dome-shaped shape of the support arms is pressed downwards, the "oil-like" operation gives the user a tactile indication of its operation. When the contact sheets come into contact with the respective conductors formed on the circuit board, they slide along the surfaces of these areas, thus providing a contact cleaning effect. The switching contact mechanism is relatively reliable due to the redundancy provided by the multiple contacts. However, since these contact sheets cannot be uniformly made to make contact at the same time, the mechanism is not particularly suitable for direct coding applications.

U.S. Patent 3,941,964, issued to Alan C. Yoder on March 2, 1976, discloses a calculator-type keyboard equipped with individually mounted push-button switch mechanisms which are said to be used to generate binary coded signals. Each coupling mechanism includes a snap-acting membrane coupling element having a central contact well with outwardly directed branch members and contact portions positioned inwardly relative to the branch members. In order to support the film and provide code contacts, at least some of the branch members of each coupling mechanism are in contact with the end pads on the surface of the insulating plate. When the coupling mechanism is used, the normally open contact parts are closed and the code signals are applied to the terminal pads in contact with the branch members. Therefore, in order to prevent erroneous transmission of code signals to the terminal pads in contact with the branch members of the other coupling members, each coupling mechanism must be electrically isolated from the others and cannot be connected to a common strip member. Because the coupling mechanisms of the Yoder patent are separate units, they require individual placement and are therefore not very suitable for easy and quick incorporation into a keyboard. In addition, since in the Yoder patent, the branches 4 64477 are not part of the snap-action membrane and are not supported by the surrounding band, they do not participate in the "oil can" effect. In addition to this, the deflection of the "oil can" of the membrane itself is prevented by the central contact well.

The pressure switch according to an embodiment of the present invention is characterized in that the substantially planar contact plate has a cross-shaped structure formed in one piece with the contact plate in the inner region of the spacer opening. , the outer end region of which is inside the opening of the spacer plate by bridges connected to adjacent cross-arms and that the kvt field plate has at least one group of conductor pads substantially aligned with the outer ends of the contact fingers.

Figure 1 is an exploded isometric view of a portion of a calculator-type keyboard using switching contact mechanisms constructed in accordance with the present invention.

Fig. 1a is a detailed view of a part of the switching-contact mechanism of Fig. 1.

Fig. 1b shows a detailed view of a part of the contact structure that can be used in the switching contact mechanism of Fig. 1.

Fig. 1c is a cross-sectional view taken along line A-A of the contact structure of Fig. 1b.

Figures 2a, 2b, 2c, 3a, 3b, 3c, 4a, 4b and 4c are cross-sectional beliefs of the switching contact mechanism and associated parts in the various operating positions of the keyboard of Figure 1.

Fig. 5 is a table showing binary coding provided by the operation of the various switching contact mechanisms of Fig. 1.

Figures 6 and 7 are cross-sectional detail views of other contact structures that may be used in the switching contact mechanism of Figure 1.

The keyboard of Figure 1 has three openings 10a, 10b and 10c formed through the body 12 for three push buttons (not shown). For the sake of clarity, only the push-button actuators 14a, 14b, 14c are described in the drawing. The flexible fluid and oil shield 16 is located below the body 12 and has guide holes 18a, 18b, 18c and 18d axially aligned with the guide pins 20a, 20b, 20c and 20d. On the lower arrow of the liquid and dust cover 16 is a conductive strip 22, 5 64477 which is divided into a system of contact contacts 24a, 24b and 24c. Each coupling chain mechanism 24a, 24b and 24c is axially aligned with the actuator pins 14a, 14b and 14c. The strip 22 also includes guide holes 26a, 26b, 26c and 26d axially aligned with the guide pins 20a, 20b, 20c and 20d. Below the strip 22 is a non-conductive spacer 28 having apertures 30a, 30b and 30c substantially aligned with the coupling contact mechanisms 24a, 24b and 24c. The spacer plate 28 also includes guide holes 32a, 32b, 32c and 32d axially aligned with the guide pins 20a, 20b, 20c and 20d. Below the spacer 28 is a circuit board 34 of insulating material 36 formed with conductors terminating in contact pads arranged in groups 38a, 38b and 38c substantially aligned with the coupling contact mechanisms 24a, 24b and 24c of the conductive strip 22. The circuit board 34 includes guide holes 40a, 40b, 40c and 40d axially aligned with the guide pins 20a, 20b, 20c and 20d. The guide pins 20a, 20b, 20c and 20d have lower ends 42a, 42b, 42c and 42d, the lower tips of which fit into the guide holes 40a, 40b, 40c and 40d of the circuit board 34. The length of the ends 42a, 42b, 42c and 42d of the guide pins 20a, 20b, 20c and 20d is selected so that the conductive strip 22 and the spacer 28 are tightly but not held between the lower ends of the guide pins 20a, 20b, 20c and 20d and the top surface of the circuit board 34. for the reasons set out below.

Although the body 12 includes walls and other support members that form the complete structure of the keyboard, these portions are omitted from Figure 1 for the purpose of more clearly illustrating the present switching contact mechanism.

Since all the switching contact mechanisms 24a, 24b and 24c are identical, only the switching contact mechanism 24a and the associated contact pad group 38a are described in detail below. In the following, reference is made to Figures 1 and 1a simultaneously. The coupling contact chain mechanism 24a includes support arms 44a and 44b extending diagonally inward from the corners of the circumferential section 46 of the square section of the strip 22 and intersecting each other. The intersection of the support arms 44a and 44b is axially aligned with the mandrel 14a.

A portion 45 of a cross-mesh within the circumference 46 of the cut-out portion is shaped to form a dome-shaped shape defined by a boundary 60. The remainder of the support arms 44a and 44b are located in the plane of the strip 22. The contact sheets, i.e., fingers 48a, 48b, 48c, and 48d, extend radially outwardly from the intersection of the support arms 44a and 44b between these adjacent portions. The outer ends of the contact sheets 48a, 48b, 48c and 48d are connected by bridge members 50 to adjacent portions of the support arms 44a and 44b. The ends of the contact sheets 48a, 48b, 48c and 48d extend slightly past the bridge members 50. Contact points, i.e., pits 62a, 62b, 62c and 62d directed downward toward the circuit board 34, are formed at the tips of the contact sheets 48a, 48b, 48c and 48d.

As seen in Figures 1 and Ib, the respective contact pad assembly 38a includes contact pads 54a, 54b, 54c and 54d aligned with contact points 62a, 62b, 62c and 62d of the coupling contact mechanism 24a and a dome-shaped portion of the central contact pad 56 of the coupling contact mechanism 24a.

The printed conductors can be formed in various known ways. For example, printed conductors may be formed by chemically removing a conductor from a conductor (e.g., copper) coated insulating sheet from predetermined areas where the conductor is not protected by a solvent resistant material that has previously been printed on the sheet under a mask. Printed conductors can also be made by an additive process in which a conductor (e.g., copper) is chemically or electrochemically deposited on an uncoated insulating plate in predetermined areas previously printed on the plate according to a mask.

A crater-like recess 74 with a raised edge 76 is formed in the central guide pad 56 by striking the guide pad with a punch having a substantially spherical end. As seen in cross-sectional le 1 (taken along line AA in Figure 1), the punch has been struck with sufficient force so that the conductor and insulator in the center of the crater 74 are forced down the surrounding conductor and the insulator has moved upward to form a ridge 76 with a relatively sharp edge above the surface.

The operation of the coupling contact mechanism 24a is best understood by referring to Figs. 2a to 2c, 32 to 3c, and 4a to 4c, which are cross-sectional views taken in the direction of section lines 2-2, 3-3 and 4-4 in Fig. 1a. It is to be understood that the mandrel 14a is pressed down to a different length so as to provide the deviations shown in Figures 2a to 2c, 3a to 3c and 4a to 4c. Figures 2a, 3a and 4a illustrate the switching contact mechanism 24a in a normal, i.e. resting position. In Figures 2b, 3b and 4b, the coupling contact mechanism is illustrated in a position after being actuated by a sufficient force to bring the contact sheets 48a-48d into contact with the contact pads 54a-54d. The contact points 62a-62d of the contact sheets 48a-48d contact the conductor pads 54a-54d substantially simultaneously. This is because the bridge members 50 ensure that the contact sheets 48a-48d together move downward toward the circuit board 34. To further promote consistency in contact closure, the perimeter 60 of the domed portion 45 is radially inward from the perimeter 46 of the cut portion of the strip 22 from which the support arms 44a and 44b facing inwards. The circumference 46 of the cut-out portion of the strip 22 is substantially at the same location as the circumference 66 of the opening 30a of the spacer 28. Therefore, the support arms 44a and 44b are bent at the circumference 46. As a result, the contact sheets 48a-48d come into contact with the guide pads 54a-54d before any significant "oil can" deflection. occurs in the wear-like portion 45 of the coupling contact mechanism 24a, as described below, which could otherwise prevent one or more of the contact sheets 48a-48d from contacting the corresponding contact pad 54a-54d.

Although it could be thought that a half-wheel-like structure in the coupling contact mechanism 24a could be completely filled with a substance to form a solid dome with circumferential contact sheets protruding, it has been found in such a solid structure that one or more contact sheets stiffness of the dome.

This can be understood when looking at difficulties when trying to balance a four-legged table with legs of different lengths.

Figures 2c, 3c and ie show the position of the switching contact mechanism 24a when it is fully depressed. It can be seen that the apex of the domed portion 45 is in contact with the raised ridge 76 of the crater-like recess 76 of the central contact pad 56. 54a to 54d. As the coupling contact mechanism 24a is further depressed, the dome-shaped portion 45 tends to straighten, causing the support arms 44a to 44d to be forced outward and away from the top. This causes the strip 22 to tend to stretch.

,> 8 64477

However, because the strip 22 is limited to form a closed loop at the end portions 68 and 70, it cannot stretch (expand) and instead bends in an opposite curved shape together with the dome-shaped portion 45 to produce an "oil can effect", as shown in Figures 2c, 3c and 4c. When the "Oil Can Movement" occurs, the user senses a sudden release of stress on the engagement mechanism 24a, often referred to as a snap effect, and the user's fingertip provides him with a tactile indication that the engagement operation is taking place.

We have found it advisable to improve the "oil can effect" by allowing the end portions 68 and 70 of the coupling contact mechanisms 24a, 24b and 24c to rise slightly, as shown in Figures 2c, 3c, 4c when the coupling contact mechanisms 24a, 24b and 24c are fully depressed. To this end, in the embodiment of Figure 1, the guide holes 26a-26d of the strip 22 are located in the center of the regions on either side of the switches 24a, 24b and 24c to receive the guide pins 20a-20d so that the end portions 68 of the strip 22 can rise during operation of the coupling contact mechanism 24a, 24b and 24c. In addition, the guide pins 20a to 20d are dimensioned so that their end portions 4 2a to 42d allow the end portions 70 of the strip 22 to move slightly in the vertical direction.

In order to provide some degree of mechanical isolation between the switching contact mechanisms 24a, 24b and 24c without completely separating them, it is recommended that the ends of the boundary lines between the switching contact mechanisms 24a, 24b and 24c have cut-off portions 58. Fully separated switching contact mechanisms are manufacturing and placement thus increasing keyboard costs. In addition, separate switching contact mechanisms can move out of place, requiring keyboard repair. Due to the notches 58, the respective outer portions 68 of the strip 22, which abut each of the connection contact mechanisms 24a, 24b and 24c, can separately rise during operation without this rise being disturbed by the structure of the adjacent coupling contact mechanism.

Figures 2c, 3c and 4c also show that the contact sheets 48a to 48d have been held in contact with the contact pads 54a to 54d although the contact points 62a to 62d of the contact sheets 48a to 48d have moved longitudinally relative to their positions shown in Figures 2c, 3c and 4c across the pads 54a to 48d. 54d surfaces. This longitudinal movement cleans the contact areas and ensures sub-? 64477 t of a relatively small electrical contact resistor for a relatively large number of switching functions. Furthermore, by comparing Figures 2c, 3c and 4c with Figures 2b, 1b and 4b, it can be seen that the last contact, i. key,; associated with the central contact pad 56 closes only after all other contacts have closed. Such an arrangement is desirable because it can be used to generate a flag signal to indicate that all other contacts are closed, depending on which data can be reliably imported. Although no sweeping effect is available to clean the contact areas in the dome-shaped portion and the contact pad 56, these contact areas remain relatively clean because foreign matter such as dirt particles cannot easily remain on the relatively sharp edge of the ridge 76. In addition, with a certain amount of compression, the relatively sharp edge of the ridge 76 provides relatively little contact resistance compared to larger areas on flat or evenly curved contact surfaces conventionally used, due to the relatively higher unit pressure, i. pressure per unit area associated with the ridge 76. In addition to the performance advantages of the crater-like contact 74, it should be noted that it can be simply and economically formed as described above without having to deform and then install a separate contact.

The bridge members 50 are sized to be rigid enough to ensure that all contact sheets 48a-48d make and maintain contact with the contact pads 54a-54d before the apex of the domed portion contacts the central contact pad 56 and yet is flexible enough to allow the contact points 62a-62d to slide. - 54d.

Although the coupling contact mechanisms of the strip 22 are arranged in a row shape, according to the present invention, a rectangular system of coupling contact mechanisms can also be constructed.

In this case, it is desirable that sections similar to 58 be located at the ends of the boundaries between the coupling contact mechanisms in both the row and column directions.

The table in Figure 5 shows the format of the binary signals that can be used as a code with decimal numbers from zero to nine. "X" means a contact closure between the switching contact mechanism and the corresponding conductor. Wires A, B, C and D

associated with certain BCD code stations: A at position 21 ^ = 1; B to position 12 3 2 = 2; C at position 2 = 4; and D at position 2 = 8. Up to three of the 10 64477 conductors A, B, C and D may be arranged to be connected by the contact sheets of the switching contact mechanism. The conductor G is connected to a source of a fixed potential, such as ground or +5 volts DC, and is arranged to be connected by at least one contact sheet of the switching contact mechanism. Conductor F is associated with generating a flag signal to indicate that all contact sheets of the switching contact mechanism have contacted the respective conductors so that data can be introduced in, and are positioned to contact the apex of the domed portion. Assuming that the switching contact mechanism 24a corresponds to the decimal number 5, the switching contact mechanism 24b to the decimal number 6, and the switching contact mechanism 24c to the decimal number 7, the conductors A, B, C, D, F, and G may be arranged as shown in Fig. 1 to provide BCD and flag signals. For 5, 6 and 7. In this arrangement, assuming that the conductor G is connected to a direct voltage of +5 V, when the switching contact mechanism 24a is depressed, a direct voltage of +5 V (i.e., a logical "high") is applied to the conductors A and C.

After the apex of the dome-shaped portion 45 contacts the center conductor 56, a flag signal is generated.

It should be noted that since the fixed potential is connected to the BCD code conductors when the contact point between the respective contact sheet and the contact (conductor) G closes, it is not necessary to wire the strip 22 to the fixed potential source, which reduces the separate wiring used in the keyboard. Under these conditions, only three contact sheets are available to generate BCD signals. However, since only a maximum of three parentheses (for decimal number 7) are needed to represent decimal numbers in BCD format, this is sufficient and satisfactory. In addition, if it were desired to generate signals to represent the decimal numbers 10 to 16, the contact sheet associated with the conductor G could be used as the fourth contact sheet. In this case, the strip 22 should be wired to a fixed potential source.

Figures 6 and 7 show other contact structures with crater-like parts having the performance and fabrication advantages described with respect to the crater-like contact 74 in Figures 1 and Ib. Figures 6 and 6a, the latter of which is a cross-sectional view taken along line AA in Figure 6, show a crater-like contact structure 74 formed by striking a conductor pad with a die having a chisel-like end with sufficient force 11 64477 so that when a recess is formed in the conductor surface. 56 below, the conductor and insulator move upward to form a knife-like edge 68 above the surface of the conductor pad 56. By varying the force and the shape of the chisel head, two knife-like contact edges can be obtained. Figures 7 and 7a show a star-shaped contact structure having a plurality of radially spaced crater-like recesses, each raised as a knife-shaped contact edge 78. This contact structure may be formed by striking a contact pad 56 with a die having a plurality of radially spaced chisel members at its end.

Claims (14)

A pushbutton switch having a coupling plate, an insulating spacer plate and an elastic, electrically conductive contact plate in a layered manner, the coupling plate of the coupling being pushable into contact with the coupling plate through at least one opening of the spacer plate, characterized in that the substantially planar contact plate (22) has an opening (28) 30a, 30b, 30c) a cross-structure (45) formed integrally with the contact plate in the inner region, having two cross-arms (60) convex relative to the contact plate plane, each having interlocking contact fingers (48a-48d) extending radially outward from the intersection. (28) the end region inside the opening (30a, 30b, 30c) is connected by bridges (50) to adjacent cross arms (60) and that the coupling plate (34) has at least one group of conductor pads (38a, 38b, 38c) substantially aligned with the contact fingers. (48a-48d) with the outer ends. Push-button switch according to Claim 1, characterized in that the contact plate (22) formed with the at least two cross-structures (45) has lateral grooves (58) in the separation line of the cross-structure. Push-button switch according to Claim 2, characterized in that there are detents (20a-20d) in the region of the separation line between the cross-structures. Push-button switch according to Claim 3, characterized in that the detents (20a-20d) hold the contact plate (22) firmly but not immovably in contact with the spacer plate (28), so that the contact plate (22) can move slightly in a substantially perpendicular direction during operation of the switch. relative to the plane of the coupling plate (34). Push-button switch according to Claim 3 or 4, characterized in that the detents (20a-20d) have at least one guide pin (20a-20c) which extends in a substantially perpendicular direction from the coupling plate (34) and can in each case be received in the guide hole (26a-20a). 26d) arranged on the contact plate (22) between the cross-structures, wherein the guide pin (20a-20d) in each case has a part whose length allows the contact plate (22) to move in a predetermined area in the axial direction of the guide pin (20a-20d). 13 64477 Pushbutton switch according to one of Claims 1 to 5, characterized in that contact points (62a to 62d) are formed on the outer ends of the contact fingers (48a to 48d). Pushbutton switch according to one of Claims 1 to 6, characterized in that the coupling plate (34) has a group of conductor pads (38a, 38b, 38c), which group has a central conductor pad (56) which is aligned with the convex cross arms (60). with the intersection. Pushbutton switch according to Claim 7, characterized in that at least one conductor pad (38a, 38b, 38c) associated with the contact fingers (48a-48d) is connected to the conductor (A-F) for a binary code signal. Pushbutton switch according to Claim 7 or 8, characterized in that the central conductor pad (56) associated with the intersection of the convex cross arms is connected to a conductor (F) for a signal signal indicating the contact of all contact fingers (48a-48d). Pushbutton switch according to one of Claims 1 to 9, characterized in that at least one of the conductor pads (38a, 38b, 38c) is connected to a fixed potential source. Pushbutton switch according to Claim 7 or 9, characterized in that a crater-like recess (74) is formed in the central conductor pad (56) and has at least one edge (76, 68a, 78) which is raised relative to this conductor pad. Pushbutton switch according to Claim 11, characterized in that the edge (76) is a substantially circular ring. 12 64477 Pushbutton switch according to one of Claims 11 or 12, characterized in that the point of intersection of the convex cross arms is positioned to come into contact with the edge (76, 68a, 78). 14 64477