WO1995026661A1

WO1995026661A1 - Hand support or hand rest for users of keyboards, especially of electronic keyboards

Info

Publication number: WO1995026661A1
Application number: PCT/EP1995/001144
Authority: WO
Inventors: Roman Koller
Original assignee: Roman Koller
Priority date: 1994-03-25
Filing date: 1995-03-27
Publication date: 1995-10-12

Abstract

A hand support pad assembly for keyboards has a separate pad for the right hand which moves on a guide. The sliding surface is specially subdivided into separate individual sliding surfaces, to impart a particular mobility to the pad, which may in addition ensure the following supplementary optional functions: zero power compensation both for longitudinal displacements and for rotation of the pad by means of a common cable drive for both functions; conversion of the pad displacement into incremental signals equivalent to a mouse function; follow-up function of the tilting movement of the hand, even when the hand no longer lies on the pad; elementary subdivision of the pad into a pad located to the front of the wrist and into a pad located to the back of the wrist for relieving the hand resting pressure; conversion of the potential hand resting energy into kinetic energy by means of a specially designed tilting pad used as arm support; and adjustability of the distribution of the hand resting pressure on the front pad in relation to the arm resting pressure on the rear pad.

Description

A HANDREST CLEANER. SUPPORT DEVICE

FOR KEYBOARD USERS, ESPECIALLY ELECTRONIC KEYBOARDS

DESCRIPTION: The present invention relates to a hand support or support device for users of keyboards, in particular electronic keyboards (for example for computers, data entry and typewriters and telephones). As shown below, the invention relates to both wrist and

Macaw supports; also the applicability for use for general handicrafts.

Support devices for arm rests and wrist rests are according to the prior art

known, which is the movement of the pad over the writing area of the keyboard

enable. * Corresponding devices use linear or rotating mechanisms for the all-round movement of the support, for example: DE 4025143 and DE 4230935. DE 4025143 uses a support device for the wrist support, which can be moved in both coordinate directions over the entire keyboard by means of rail guidance, and as another Alternatively, the use of one on both sides of the keyboard

Telescopic linkage. DE 4230935 only uses a linear rail guide parallel to the keyboard front, whereby a swivel arm is used for the movement guidance towards the keyboard, or away from the keyboard, which is absolutely necessary when typing, without which the device cannot manage. * The state-of-the-art motion mechanics have the following disadvantages: * You need a fit guide, low-friction precision bearings (for coordinate slides or telescopic linkages or swivel levers) such as e.g. also ball joints and rail guides. The prevailing frictional forces due to this structure prevent the support device from following the hand movements during typing without resistance;

Furthermore, the usual structure of such movement guides involves a large moment of inertia with a disruptive effect on hand movements. * The object of the present invention is to eliminate these disadvantages with motion control without fitting parts, i.e. Without ball joints, without sliding shafts, without plain bearings and without sliding bushes and with a particularly low hatred moment of inertia. The low mass moment of inertia of the movement of the pillow is retained even when using large-volume pillows, when an air pillow is preferably used. * In an optional design variant, such an air cushion with all-round freedom of movement due to flexible or twistable support attachment according to G 9315 362.9 from 03.02.94 according to the principle of a cushion rocking on a rocking line (e.g. air or water cushion made of a foil bag) is used, but with Heiterbildungssaflnahaen according to the invention for the more intensive formation of the mipper roller, which results from the measurement of the cushion filling level and supports a rolling movement of the cushion with appropriate deformation of its envelope (e.g. the film bag). The further training measure according to the invention relates to the guiding property and generation of the resilience of the kis-sensor for the contact surface of the hand (with hand support) or the macaw (with macaw support), which consists of two

Co-component is pre-oasised: a) the filling pressure of the filling fluid (e.g. air or hater with air) and b) the clamping force generated by a tensioning device, the cushion having a low filling pressure with guide trough formation, which is by hand -or Ars rest against the rahen (or pillowcase) tensions the pillow. * As described in exemplary embodiments described later, the frame is preferably formed by the cushion cover itself; with four overlap strands, which form a window covered with a fleece material and are attached to it with Velcro. Of course, Daneoen has the option of making the rahaen entirely or partially (for example, »bracket support) from resilient, solid material. * An exemplary embodiment is also described below, in which the pillow support of the pillow relates to the inclined upward positioning of a pillow base by a strip, as a result of which an ice-ice trough is formed between the strip and the rocker line fixation of the pillow for the pad surface. which supports the formation of a hipp roller. * In a special version, the trough (83) forms a trough (83) due to the total effect of the cushion's elasticity, especially if the longitudinal fold (or longitudinal seam) of the foil pouch is also used as a support surface for the hand or macaw , as described below for (Fig. 61 and Fig. 61 .. {. * Overview of the inventive measures for solving the technical problem and inventive cheer training configurations: * The inventive task not only concerns the improvement of the movement of the support device, but also in an inventive design of a cheerful training additionally the solution to the technical problem of significantly reducing the pressure on the hand rest of the pillow and significantly improving the breakdown of forces for the compressive forces acting on the hand from all sides. * For improving the movement control of the support device and, in particular, significant reductions Generation of the moment of inertia while avoiding weighty bearing parts (e.g. in connection with air cushions) and universal mobility of the rail-guided part, a ruler surface designed as a sliding surface is provided, on which separate (small) sliding surfaces slide, which slide directly on the underside of the cushion or on another support surface of the cushion (hereinafter referred to as slide plate) are fastened, one or more sliders being or being guided tightly by a guide line running in the longitudinal direction of the ruler or in a correspondingly loose play. Variants are described below, in which the guide line running in the longitudinal direction of the ruler is designed either as a guide slot or as an outstanding guide web, and runs along the longitudinal center line of the ruler, a projecting edge side of the ruler also being included as a guide web in the movement guide of the cushion can. The sliding surface of the ruler can be adapted to the fora

Keyboard also have any fora, including curvatures in aehrdimensional directions (parallel to the keyboard front line or concave or convex to the keyboard front line); in a further option, a variant is provided for the rotatable cushion cover, in which the e.g. with elastic band

The zero position of the angle of rotation formed is adjusted according to a predetermined function via the displacement path of the cushion (cf. Fig. 38). * Two basic variants are provided for the movement control, one of which runs the support surface of the cushion (or underside of the cushion) on several lines using parallel guide lines (guide slot, guide web), and a second variant in which the support surface of the cushion (or underside of the cushion) is single-line with only a guideline is led. In a preferred embodiment, in the single-line version only one sliding element is guided as a guide element from the guide line (for example, designed as a pin), which due to its mobility on the guide line (for example as a pin sliding along the guide groove) also serves as the axis of rotation forms and the other sliding elements only provide a sliding support on the sliding surface of the support surface of the cushion. The guide element has a trigger protection, for example. in the fora of a sliding plate, which slides enclosed in a guide groove below the sliding surface, or for example. slides between two parallel guide bars that have a protruding upper edge that prevents the plate from being pulled off. On the other hand, in the multi-row version, measures are provided for rotating the cushion on a slide plate, in particular also using elastic bands. * In order to reduce the hand rest pressure and improve the breakdown of forces for the pressure forces acting on the hand from all sides, it is provided that for each hand there are several cushions arranged in a row, which is practical due to the fact that the cushions are hardened compared to the prior art application is favored. * Examples of cheerfulness options of the invention are: a sensor system is used which is extremely cost-effective and with which the control of the cursor (cursor) and the image functions (scrolling the pages) or any mouse functions can be carried out very advantageously. . * For this sensor technology, two different design variants are described below, which can also be combined well with one another, the first of which generates control signals depending on the way the pillow is pressed by the applied hand, and a further variant, at the direction-dependent incremental steps are generated for a function assignment selected using the keyboard key (e.g. image key or cursor vertical or cursor horizontal), which are carried out during the displacement of a pillow (e.g. right pillow) via the rail by scanning the length of the displacement path are generated. In this context, use is made in a further developed embodiment variant of an activation signal which is generated via the first variant of the control signal generation for a detection which indicates whether the pillow is pressed by the placed hand: ie the hand lies on or not. In a simplified version, the activation signal is triggered directly by an actuation button located in the area around the pillow and is also switched back or by determining a time lapse since activation.

* The activation signal fulfills the purpose of the sensor electronics to indicate whether the key press of a key concerns the function assignment for the pillow insertion function, or whether the key was only pressed during a program function of the computer. Further details on this are explained in the later part of the description (cf. also FIG. 28 and FIG. 29). * Further preferred measures, which are explained in detail in the following part of the description, relate to an embodiment in which the handrest cushions can be displaced in relation to the movement guidance within a game, this displacement is sensed by sensors and used for a motor-driven tracking control of the cushion movement in such a way that by means of zero force compensation Cushions follow the hand movements smoothly. For this variant, the length sensing of the displacement path can also be recorded directly via the drive path of the motor-driven overrun control (e.g. by uncoiled cable length using a tachometer generator, optical disc or arming measurement on a spiral spring or measurement of the inductance prevailing in each case due to the coiled cable length on the isolated reel , where one tap, for example, on the metal axis of the winding reel and another tap by means of an metallic pressure roller of the uncoiled cable) * For a variant in which this is not done, the length sensing of the displacement path is preferably measured by a capacitive length scale. * More details on the length measuring system are described for the figures in the following part (see Fig. 49) of the description. * Further preferred details relate to the manufacture of the pillows: * For the air cushion design, it is preferred that an inflated bag made of gas-tight film is used as the air cushion, e.g. Made of a material that the food industry uses for vacuum bags (COLAMIN PA / PE tubular film, etc.). * In a special form of cheerfulness, the air cushion is additionally filled with hater or another liquid for cold storage, which makes it possible to pre-cool the cushion in the cool box or refrigerator on hot days. * For this variant, a horizontal partition is inserted as an option in the air cushion, which forms a separate chamber for the liquid and a chamber for the air, which prevents the liquid from sloshing in the cushion. * In a preferred embodiment, the foil bags are welded together on the one hand by wider holding seams (using a heat band) and further a separating seam (using heat wire) is provided on the outside of each holding seam, which on the one hand creates an absolutely gas-tight connection and at the same time separates the film material. * In the following, exemplary embodiments and cheerful developments of the invention are described with reference to FIGS. 1 to 60. * Fig. 1 shows an exemplary embodiment {rail guide not shown) with division of the hand rest into 2 pillows, for left hand {1}, and right hand {2} with hippband {15} provided for each pillow, over which a pillow is only used peel stripe {7] adheres to the support and can be rocked against the keyboard front or along the hipp line (= center line) {7b}. The hippband is fixed to a support surface of the pillow {3}, preferably via a Velcro connection. The support surface of the cushions or sliding surface of the rail guide is set up freely in front of the front line of the keyboard {8} or immovably fixed to a common installation surface {9} via Velcro tape connection with the keyboard. {1} and {2} ... pillow case, e.g. Leather. * Fig.2 shows an embodiment with Luftkamaernunterteilung {cylinder 10b}. As indicated in Fig.l as an option, these strung cylinders can also run somewhat obliquely towards the keyboard front line ({10b ... air hoses for right hand and left hand with mirror-image oblique symmetrical to the middle of the keyboard). In Fig.2 two versions for the formation of the hipp line are shown: {7} ... a hippband as described in Fig.1, or a Velcro strip connection provided along the hipp line {11}, e.g. a strip of mushroom tape as Velcro tape {11} forms the hippie line {11} and is glued to the support surface of the Kisoeri in the longitudinal direction of the keyboard and the cushions in question have a soft material underside that is attached to the Velcro tape strips. * Fig. 3 illustrates the variant of a further exemplary embodiment corresponding to Fig. 2 with the option of making the support on the underside of the pillow more elastically twistable along the tilting line (for example by making incisions at the connection points from both longitudinal edges of the pillow to the hip line , on which the inflated air cylinders {10b} are lined up {18, blackened). The incisions are only made so far inward that a hippy tape remains across the width of the hippie line {11} of the pillow in the direction of the pillow length (hatched in FIG. 3), and is attached to the support {3} by means of a preferred Velcro tape connection; the option is to cover the air cylinders lined up like lamellae with a thin film (17). {1} and {2} ... pillow case, e.g. Leather. * For the air cushion version, the air cushion made of welded foils is filled with air in one gas-tight manner before welding, or a valve is provided for readjusting the air pressure. As described below in exemplary embodiments, there is also the possibility in the valve-free version of regulating the hardness of the hand felt by the hand with a pressure plate or by adjusting the level to the applied hand, in particular using a number of cushions arranged in a row. * Fig. 4 illustrates the hipp process and a further embodiment for training the hipp stiffener {7} or the hipp line {12}. In the top left quadrant of the figure, the back and forth (incl. Hinkel {@}) of the air-foil cushion {10} with the moving hand at the pressure points [U] and the center line {m} is illustrated. An air-filled hose {ldb} is shown at the top right in FIG. 4, which, as an option, achieves the same effect by gluing hoses strung together along a band {11}, e.g. by cutting the connecting lines as shown in Fig. 5 (hatching in Fig. 4 corresponds to glued tape, e.g. made of fleece material). * Below is a variant of the Velcro version, in which a StofFoand is used as a hippband (two superimposed and sewn in the longitudinal center line Bands folded into a U-profile, whereby the longitudinal seam {12} results in a kind of hinge over the hipp bandwidth {11}). * The pillow (air cushion 10 with cover 1 or 2) is shown at the very bottom in FIG. 4, with hipp tape {7} or Velcro tape {11} on support surface 3 and fleece underside {4}; and: {9}, {8} see Fig. 1 to 3. * Fig. 5, see Fig. 4. * Fig. 6 relates to an optional version with an increase in the hipp line by inserting wooden slats and an angled support {ß} along the hipp line with a tension band axis as the fulcrum {198 8}, including rotation angle {ß}; {1} ... pillow case. The hippband support {15} has corresponding tabs {16b} into which wooden strips {16a} are inserted for stabilization. This means: 102 ... stops on strips 16a, by means of which, in an optional embodiment, the angle of the hippband can be increased depending on the rotation (wooden strip glides over stops). {V} ... Direction parallel to the keyboard front line corresponds to the first tilt line of the cushion, Kinkel {ß} .- .. Inclination angle, among other things, that the cushion can be rocked sideways.

* Fig. 7 to Fig.lö illustrate cheering, as a variant for the direct rotation of the pillow guide, e.g. for parallel guidance. Hiebei is a verforabbar attachment of the pillows on their support surface by the formation of an elastically resilient flexible surface in the fora of rubber bands. * Fig. 7 shows a variant with 2 rubber bands {38a) which are clamped parallel to the bearing surface {3}, connected by a cross band. The cross band has tab slots {54} through which the rubber bands are inserted so that the cross band {38b] can lie on the longitudinal center line of the contact surface {3}. It means: {V} ... direction parallel to the keyboard front line corresponds to the first tilt line of the cushion, Kinkel {ß} ... angle of inclination, among other things, that the cushion can be rocked sideways; further: 38b cross tape {3Sb} coated with mushroom tape (Velcro tape); {32b} ... optional mushroom tape adhesive surfaces for the underside of the loop tape. {101} ... sliding elements fixed on the underside of the slide for support on the slide rail, cf. Description of the following figures (Fig. 30 and Fig. 32), wherein the support surface {3} = support plate {100}. * Fig. 8 shows a variant in which the user can configure 2 options: a first in which the fleece side of the pillow is placed directly on the mushroom tape strip {32d} of the hipp line on the contact surface {100}; or a second one, that is, the underside of the pillow is placed on the mushroom tape strips of the contact surface {100} on the underside with short fleece surfaces {32dx} on the underside, the middle of the elastic band remains freely stretchable (cf. Kinkel {wß}) and is also coated on the top with a mushroom band surface on which the underside of the pillow is placed. In a further option, the mushroom band strip of the tilting line is not continuous, but is only designed as short adhesive surface pieces, one of which is provided in the middle for an immediate placement of the underside of the cushion and two on the side edges for an application of the elastic band. * For this variant, another option can be selected, for extending the hipp area in an oblique direction, in which a fora body (e.g. a strip with a square surface {207}) under the point where the cushion is placed on the elastic band. is underlaid and also attached with Velcro fastener; {207} .. ..is a sliding surface of the fora body with which it can move as smoothly as possible on its unattached side. The upper figure in Fig. 8 shows the option with the elastic band attached, the lower figure the version without the band. * In addition to the possibility of the individual sliding elements directly on the underside of the To attach cushions, this is provided for further developed exemplary embodiments on the underside of a slide plate {100} as the support surface of the cushion, the movement of the cushion along the keyboard over the individual sliding elements on the sliding surface, and the cushion movement in the direction of the keyboard front, by the hipp movement of the Pillow and / or further sliding movement takes place. * A side view is shown on the right in Fig. 8, where {123} means the underside of the cushion and 32b the adhesive surface of the mushroom tape. * Fig. 9 shows a further variant in which, in contrast to Fig. 8, the elastic band {38} is placed crosswise on the Velcro strips {32d} of the hippeline of the mushroom band placed on the support surface {100}. In addition, there is also an optional possibility of increasing the adhesion point on the underside of the pillow, but this is done with an air foil pillow (cylinder {207}}. Fig. 9 shows in sequence the covering of the mushroom tape strip applied to the pillow support surface, then the elastic band & ls transverse strip placed on it {38} and furthermore the twistability of the elastic band in the middle of the band {wß}. * {V) in Fig. 8 means the direction of movement of the slide plate {100} along the keyboard front. * If the underside of the pillow has a relatively large area of fleece material, it is planned to cover the areas of mushroom tapes that should not adhere to the fleece band with strips of fleece band (see {32 Z} in Fig. 9). * Fig.lö illustrates two further design examples for the twistable, elastic and flexible fastening of the underside of the cushion to the contact surface {3 or 100). In the example shown above, elastic bands {38} are stretched across the support plate {3} transversely to the longitudinal direction, on which the mushroom band surfaces are attached directly to the bottom of the fleece band cushion {32b). In the example shown below, the cushion is placed on a cross belt. * In cheerfulness, the elastic band or the pillowcase itself has a fine metal fabric, which is used as a surface for direct sensory sensing by means of coils, cf. later in the description. * FIGS. 11 to 15 illustrate exemplary embodiments for optional design variants of the air cushion, in particular for foraging, a simple cushion without multiple chambers being lined up being produced for this preferred variant. * Fig. 11 shows how a fora stencil {19} is inserted into the foil bag {10} before inflation, this fora stencil can support different fora of the inflated cushion. The upper part shows a top view with two dashed lines of the inserted fora stencils (e.g. cardboard), in the lower part a representation of the side view is made, in which the fora stencil is only inserted, and in the lower part the fora stencil one side of the film bag is additionally glued in places or over the entire underside, which means that after inflation, the air cushion has a flatter or flat contact surface. * Fig. 12 shows a proposal in which the air cushion has a stabilizing bar outside {19} or inside. * Fig. 13 explains a proposal for inflating the air cushion, cf. also identical positions in Fig. 11. Starting from a roll with a film tube, the rectangular piece of tube shown in Fig. 13 is cut off on the broad side ({55) ... folded long sides of the S tube) and the first broad side is welded with a separating seam by means of hot wire and cut off at the same time; Furthermore, another holding seam {20} for welding the relevant film sides is made at this point directly next to this seam with a heat band. * The piece of film cut from the roll is (among other things {30]) slightly longer than the air cushion when inflated, taking this extension {30} into account, the holding seam {24} is first welded with the heat band, whereby this holding However, on one side of the seam there is still a blank channel {23} to the interior of the welded-on foil cushion. In a next step, another holding seam {21} is welded approximately perpendicular to the last weld seam {24} which is set so that it crosses this seam {24} at the point where the shallow channel is kept free {23} is, so that this additional seam {21} results in an injection nozzle for the cushion {26,55,24,55}, into which an injection nozzle {22} for filling (or inflating) can be inserted. After inflation, immediately next to the holding seam {24}, which the

Injection channel {23} has, on the inside {27} and / or on the outside {26} another welded weld which closes the injection channel {23}. Then the protruding part of the pillow, which was only needed for the injection nozzle, is separated by a separating seam using a hot wire. As a further option, a holding seam {20} can be welded with heat band along the folded side of the bag {55}. * As a further alternative, in the version shown in Fig. 13, the film bag is also a welded release film or a smaller bag to form a further layered camera, which is filled with a liquid for storing cold. Other options are to use 2 foils of unequal thickness or 2 particularly thin foils instead of the bag, which are interposed with foil strips for reinforcement at the points of the welded and separating seams. * Fig. 14 illustrates a further variant for the air-foil cushion, in which the foil sides are welded to one another in places or points by short broad-band dash seams {63}, among other things to keep the cushion more narrow. * Fig. 15 relates to a variant with beveled pillow corners {204} (after the inflated plastic bag has been inflated, pressed in, corresponding to the bottom illustration of Fig. 15); see. also Fig. 13 and 14 for further reference designations. * For COMPLETENESS, measures for the formation of the pillow cover with rounded corners (e.g. with pillows according to Fig. 15) are illustrated in Fig. 16 to Fig. 20, whereby a pillow with non-rounded corners is preferred in particular, corresponding to Fig .21 to Fig. 21d and as described in the later part of the description for Fig. 23 to Fig. 25 and Fig. 61 to Fig. 61CN, further with Fig. 97. * Fig. 16 shows an oblique view of the cushion covered with leather cover {1} with diagonals {202} (shown on the left in detail) and straightened sides {203} as well as rounded corners.

* Fig. 17 shows the open cover (net) from the inside with the double-sided adhesive tapes {205} glued on from the corners, folded on the inside or glued, causing the cushion cover to be pulled up on the diagonals. * Fig. 18 shows a top view of the top of the pillow with bulging {lD}. * Fig. 19 shows a plan view of the window side of the pillow case, covered by the fleece cloth (132), which forms the soft side of the pillow; the preferred structure also applies to the variants according to Fig. 21 to Fig. 26

Usage: {la, 1b, 1c and ld} are overturned side parts, which are attached with mushroom tape strips {133} on

Faulchtuch {132} stick. * {203} ... illustrates the gluing points by which the sides of the cushion cover (corresponds to the frame sides of the foil cushion) are stabilized. * Fig. 20 shows front and side views for an optional rounded fora of the pillow; {RB} ... radius, {RL}, {RS} ... dome curvature. * Fig. 21 to Fig. 26 illustrate the preferred variant of the cushion WITHOUT ROUNDING the corners, and the storage of the cushion on the support surface {3} or {100}. The pronounced protruding corners after filling (inflating or with liquid) the rectangular foil bag cushion favor the hipp roller, if the pillow is used as a hip pillow; the pillowcase corresponds to the version as described in Fig. 19, but without rounding the corners; whereby for the variant of the preferred embodiment of an intensified hipp roller, the window opening of the cushion covered with fleece material {132} is used as the support window; Special applications are described in the later part of the description for Fig. 23 to Fig. 25 and Fig. 61 to Fig. 61CN, further described with Pig. 97, a fine felt-cellulose mixed fabric with an alternative further covering of felt being preferred as the reference material. * Fig. 21 generally corresponds to Fig. 19, but without rounding the corners (after the side parts {1a, 1b, 1c, 1d} have not been folded over {300}. The top view of the pillow is shown in Fig. 21 on the left. {301 } ... s represents the Uariδ of the not yet unbeaten side parts {without pulling up the diagonals). * Fig.21d ... version with a leather saddle blanket inserted in the trough (83), with cover made of mixed tissue made of cellulose.Felt; Trough (83) is created by measuring the filling pressure of the pillow in relation to the fora-providing edging by the pillowcase (see the preceding part of the description and the exemplary embodiments described below and Fig. 61 to Fig. 61CN). * Fig. 22 illustrates the open pillow case with the underside {132} attached by Velcro strips {133}; Below is a side view of the finished pillow with dimensions and a hand placed on it, which tilts the pillow in the direction of the keyboard {( _. } (KLT. ... Velcro fastening = tilt line, 3 ... contact surface). Fig. 23 to Fig. 25 see later part of the description (also described with Fig. 61 to Fig. 61CN. * Fig. 26 illustrates how the protruding tip corners of the pillow are decoratively covered with cabbage cones {95} for the exemplary embodiment described; {96 } ... Double adhesive tape for attaching.

* Fig. 27 illustrates an option in which the support plate {3} of the cushion can be rotated with respect to another support and the cushion with its fleece underside {132} either directly or via another hippband intermediate layer (see right) {12} onto the support surface {3 } is to be set up; Hipp hand liner also with appropriate mushroom tape {32bd) and fleece tape stiffeners {132b} for a direct insertion between mushroom hand {32b} of the cushion pad and fleece material on the underside of the cushion {132}); furthermore ... {40} ... fleece tape strips placed on mushroom hand strips and removable if necessary to cover unused adhesive surfaces. * Fig. 28 shows a top view of the rail guide {99} set up in front of the keyboard {8} with: {39) ... plugs inserted into the groove ends or fitting pieces which prevent the sliders from sliding out of the groove; Furthermore, with an optional rail guide, which means that the slide groove is slightly curved towards the center of the alphanumeric keyboard {a) at a distance from the front of the keyboard, with the purpose of compensating for the shortening of the fingertips' resistance to the corresponding rows of keys, caused by holding the hands at an angle or pressing the keyboard . * At the bottom left an option is shown how, if necessary, the cushions with Velcro can be adjusted by means of cross-over Velcro / fleece connection: Hipp line {40b} of the cushion adheres to {40a] contact surface; ditto the rail guide can be attached to a shelf of the keyboard with Velcro, or it can be fixed directly on a common support surface {9}, or it can also be set up loosely in front of the keyboard without the use of a further support surface {9}; {34} syabolizes a coil that is under the pillow on the

Pillow support, or when using a rail guide, is provided on the bottom of the rail guide (or also on the slide plate, see later) and the Hirbelstroaverluste generated by a piece of metal (e.g. sealing foil) in the air cushion for the purpose of locating the deformation of the cushion cover by touching the hand, as described in detail below with regard to Fig. 48 and Fig. 54. * Fig. 29 illustrates a further exemplary embodiment using the control of cursor and image functions by the cushion movement already explained at the beginning, optionally using a sensor coil {34} for generating the activation signal and using the length measuring system to determine the displacement path of the cushion, e.g. E.g. right pillow. Coaputer mouse {43} and keyboard connection are looped through {{}} the housing {41} flanged to the right-hand end of the rail guide or to the port connections of the microprocessor, which performs the Ua switching function; where: {42} ... keyboard connection of the keyboard and {44} keyboard connection of the mouse. The switching of the input functions. As already explained above, the keyboard and the mouse are carried out via the activation signal, wherein when the activation signal is switched off, the computer keyboard and the mouse immediately perform their function, while when the activation signal is switched on, the cursor control or mouse signal generation takes place via the pillows. As an option, e.g. a mode that can be configured via software or switch position can also be provided, which optionally controls only the cursor functions, or only the mouse functions, or both via the pillow input. * In addition to the large number of control options, the following control is particularly preferred: * When the coaputer is switched on (applying the supply voltage to the electronics housed in the housing {41} of the rail guide), the software of the microprocessor starts with a status that assumes that the left cushion the hand does not rest, which can optionally be used to calibrate the evaluation. The same applies to the electronic scale, which operates on the same sensor principle in the later parts of the description and which controls the adjustment of the hand-rest pressure by level control of an additional snap-in support (implemented by a further rear cushion). * Furthermore, any change in the detector signal in the coil {34} is evaluated as to whether the hand is pressing or lifting the cushion. Each time a call is taken off, a time is started with the query as to whether or not a function control key on the keyboard has been pressed within the time, whereby the reverse trigger sequence can also be queried as a pre-trigger function, whether within a certain time immediately after the relevant key is pressed Time the hand was on the pillow or not, among other things to avoid overlaps in the evaluation. * If this is the case, then the electronics switch to pillow input ^' among other things, depending on which key is pressed (e.g. "X / V key for coordinate positioning or"<>"keys for image key function) corresponding modes are executed, e.g. For example, control of the XY coordinate movement using the mouse function, whereby the X / Y keys are pressed alternately with the left hand to shift the pillow of the right pillow and corresponding incremental impulses are generated that correspond to the heg that has been traveled and that corresponds to the sign the X movement or Y movement of the image control function to simulate key presses or mouse signals. * To activate the activation signal, it is sufficient that the relevant hand (e.g. left hand) is raised immediately before the key is pressed, the hand can be placed on the pillow again after pressing the button and the activation signal remains on until a switch-off condition of the activation signal is recognized. * If, on the other hand, no key or a key other than the function control key provided is pressed, the original mouse function and cursor input function are retained. The intended function control keys continue to be pressed when the activation signal is switched off, ie when the key was placed on the cushion when the key was pressed, the key code is used normally by passing it on to the Programa via the looped microprocessor circuitry of the keyboard connection. In Fig. 29 also mean: {98 a, b, c, d} ... support elements or sliding elements of the slide for the longitudinal movement of the rail guide. * Fig. 30 to Fig. 36 illustrate the design examples of the rail guide already discussed at the beginning, Fig. 37 to Fig. 43 the explanation also anticipated in the preceding part of the description for a path-dependent possibility of rotation of the cushions and, independently of this, or as a supplement, the preferred one Curve curvature of the rail guide. * Fig. 30 illustrates the previously discussed embodiment with sliding elements fixed on the underside of a slide plate and a rail guide, in which only one sliding groove {106} is provided, in which a single sliding element {98} slides and rotates and at the same time the fulcrum of the Carriage {100} forms. The slide is supported by further sliding elements {e.g. Skids 101} on the rail surface (ruler surface of {99}) which, as shown in FIG. 30c, can be designed identically to a sliding element of the pivot point {98}, but rails are not guided directly. * The angle of rotation is limited by the strip {102} attached to the long side of the sliding surface. As shown in Fig. 30a, in addition to an injection-molded version, the rail can also be made from separate materials (wooden profile {103} with attached strip guide {103}) and attached PVC strips {99}, in contrast to Fig. 30b using two plastic Ruler strips {99} with a steel plate underneath, or a completely injection-molded plastic version, or laminated cardboard {103} underneath, the edges of the cardboard being covered by the wooden strips {102}, which are raised at the sides. The PVC glide strips (or glide strip cover) {99} are made of one piece or optionally placed on wooden strips (cross hatched) (see dashed horizontal lines in the profile according to Fig.30b), with guide slot X, whereby the underside of the cardboard, which is laminated with paper and plastic film, can still be printed with information. * The lateral frame {102}, which at the same time forms the stop for the support elements {101} in the longitudinal direction of the rail guide when the slide {100} is rotated, holds on its front broad sides the end fittings inserted laterally in the guide grooves {X} (e.g. For example, strips also made of wood see {39} in Fig. 29), as will be described in detail later with regard to Fig. 71a, Fig. 71b, and Fig. 71c, whereby the sliding surface (ruler) on all sides through the üarahaung ( e.g. wooden strips) and has insertion slots on the broad side for inserting the sliding elements of the slide plates (with the end pieces removed). * As shown in Fig. 30a to Fig. 30c, the height of the guide-guided slide element {98 is guided by correspondingly determining the distance of the underside of the slide {100} from the surface of the sliding ruler {99F} (corresponding to the height of the sliding elements {101}) } held so that the guide-sliding element is guided only in the longitudinal direction and does not rest on its upper and lower plate surfaces, ie does not provide any support, although for the variant described below, in addition to a cushion for the hand rest, a cushion for the macaw pads is flanged to the cushion support, the lower plate surface (from {98]) lies on another lower sliding surface with a frictional friction, at least at the edge of the plate on the underside of the guide slot. Due to the separation of the guiding and sliding functions of the cushion cover, the friction is particularly low. * However, if the preferred length measuring system using a rail-guided slider is used for capacitive length sensing, the height of the guided slider element is selected so that the upper or lower sliding plate of the sliding element on the surface (top or bottom) of the rail during Sliding firmly, which is reinforced by spring force if necessary (cf.

Fig.5ö). * Heiters mean {132.32} .. .. the underside of the cushion {1} on the mushroom ribbon. * To Fig. 31: if necessary, this can be done in Fig. 30

illustrated embodiment are modified in such a way that a second sliding element {98A and 98B} slides in the guide groove, whereby the slide is secured against rotation on the one hand and has sinimal friction on the other. A further suggestion for closing the guide groove by means of plugs {107} is shown (besides the insertion of adapters, cf. {39} in Fig. 29). * Fig. 32 illustrates an exemplary embodiment in which the coordinate guidance takes place via cross slides, that is to say that a further cross-guided slide is present for the slide guidance of the first slide. A parallel rail guide (tangentially parallel) of two guide grooves is provided for the embodiment according to FIG. 32. It is evident that the variants described for Fig.3ö and Fig.31 can also be combined as a cross slide, with e.g. the lower slide is guided against rotation as a longitudinal slide parallel to the keyboard and the upper slide is guided towards the keyboard and allows immediate rotation. * The slide guide according to Fig. 32 is the one already described. Embodiments identical, only that it takes place through parallel guide grooves, in which the guided slider support the slide plate at the same time, ie slide with the underside of their upper sliding plate on the rail surface, which, for example. is advantageous for the variant with a preferred length measuring system. As an alternative, however, sliders could also be provided for separate non-rail-guided support of the slide plate, cf. FigJöc. * It means: {100} slide plate, which of the support corresponds to the surface of the cushion and is guided over the further rail guide {99B}, which is also the slide for the first (lower) rail guide {99A). {99A] is guided or set up parallel to the keyboard front. * It is evident that the slide guides described from Fig. 30 can also be used independently for any other application, regardless of the subject matter of a pillow for hand support, in particular with the length measuring system described below and a power supply control signal rail, which is also particularly reliable as a cheap solution is claimed. For such other applications, the accuracy improvement of the rail guide is interesting, which is why those sliding elements that provide an anti-rotation device for the slide plate by means of a slide groove guide are braced against each other by means of spring force (e.g. as shown in Fig. 32, top left, cushion) shown in front view), by a flat spring {200}, under which the sliding elements are glued and which is attached with its top to the underside of the slide. * Fig. 33 illustrates a profile section for the variant in which the slide plate can be rotated directly on the rail guide, with profile {{103}, wood) according to Fig. 34, {99} PVC strips. * Pig.35 illustrates a profile cut for the variant in which the slide plate is guided against rotation, with a profile ({103}, wood) according to Fig. 36, {99} PVC strips. * Fig. 37 illustrates the optional rotation control {ß} of the cushions over the length of the slide guide (in center M); {KBS} keyboard page, {OPS) ...-

Operator side.

* Fig.3ß relates to a variant in which the angle of rotation adjusts itself according to the displacement path of the cushion in accordance with the curve of the rail guides or the width of the guide groove, in that the axis of rotation of the rotatable cushion support is guided by a guide made along the center line of the rail guide Rotary lever is guided. This rotary lever has sliders on both ends of the lever, which are each supported on the inner edges of the guide, the rotation of the rotary lever being caused by changing the distance between the inner edges of the guide (ie slot width). The rail guide corresponds here to Fig. 37, the middle groove being kept so wide that the sliding elements (opposite each other) slide on one of the two groove edges to both groove edges and, depending on the groove width, depend on the groove width {{67}, {68}, {67}) adjust this lever {77} mounted on an axis {82}. The axis rotates the pillow cover. * Fig. 39 shows the axis {82} of the cushion cover, which rotates the cushion with press disks on a film {81], the nubbed underside of which is used as a sliding surface. * Fig. 40 illustrates a variant in which the rail guide in front of the keyboard is installed in a recess so that it never becomes can be used on extendable load supports. The rail guide is preferably accommodated in the trough in such a way that the cushion height is matched to the keyboard height and can be covered by a flat cover, which instead of the hand cushion cushion cover forms the usual cover cover {{8c} shown in broken lines) and covers the hand cushion cover. * Fig. 41 illustrates a variant in which metal strips underlaid on the rail guide, which are contacted via contact connections K1 to K4, have a capacitive length coding, cf. also Fig. 49 and Fig. 50. Heiters twistable cushion pad {81} with spring {79}, {80}, which presses on the sliding element {98S} for lever adjustment of the axis of rotation as a restoring force (see. {F)} in Fig. 38. Heiters mean: {76} sliding elements, which take over the rail guidance of the slide plate, cf. also Fig. 38. * Fig. 42 shows the rail guide {99} with optional housing {41). * Fig. 43 shows the manufacture of the return spring, cf. {79.80} in Fig. 41. * Fig. 44 shows a suggestion for a cable drive {54, 45, 46} the carriage. * Fig. 45 shows a proposal for the detection of the angle of rotation by means of spool pulleys of the cable pull from Fig. 44, the radial rotation of the cable pulley pulling up a spiral spring, at the ends of which the inductance is measured as a measure of the rotation, e.g. according to the principle of resonance via oscillator circuit (OSZ) or also as a needing size, in which case the coil spring is fed by a metal disc {disc, Fig. 45} placed parallel to it and the needing changes due to the changing effective coil size. {52,53} ... Switch-on points of the oscillator for the parallel resonance circuit consisting of inductance of the spring and capacitor C. * Fig. 46 shows the cable drives for the variant according to Fig. 44. * Fig. 47 shows the attachment of the cables to the sled belonging to Fig. 46. * Fig. 48 illustrates the preferred principle for the detection of a signal which indicates the hipp movement of the pillow or the deformation of the pillow. Depending on the requirement criteria, it may be sufficient to attach a sheet of foil to the inside of the air cushion on the floor {33}. For alternative evaluations, a sheet metal strip is attached on the inside {33B], which, for example, is bent downwards (e.g. also for measuring the contact pressure). For both variants, an air coil is placed underneath the pillow support or under the rail guide at the point where the entry option is provided by the respective pillow (e.g. far left, see generation of the activation signal above), e.g. in a flat hollow area on the underside of the rail guide support (see also {34} in Fig. 32). If the cushion in question is located above the air coil, it is subjected to a Hirbelstroabedapmung by the sheet metal piece glued in the pillow, which is a tapping of the resonance oscillator amplitude

noticeable eight. The evaluation is carried out, for example, in such a way that the signal of the parallel circuit oscillator under load is fed to a voltage-dependent oscillator (VCO), the frequency of which is fed into a microprocessor by means of averaging, or also by prior rectification at the input of the VCO, the change values for the respective change in the need for the coil forms, these change values on the one hand indicate whether the hand placed on the pillow is rocking back and forth, that is, on the other hand, the sign direction of the respective change or maximum scanning indicates whether the hand is lifted off the pillow. Kenn yes then starts a mono time within which it is tested whether an appropriate keyboard signal is present at the microprocessor (uP) (not shown in Fig. 48). If more sensors are required, the use of parallel resonance oscillators for the supply circuit of the sensor coils proves to be very advantageous because of the direct filter effect for different measuring frequencies of the coils. Heiters mean: {35} supply inductance, ditto capacitance, which is contained in the resonant circuit inductance of the coil connections {34, 36} and the parallel resonant circuit capacitance. The connection of the

Bedäapungsaessung at the input of a microprocessor by means of VCO can also be used for the voltage divider measurement for Fig.Sla described below, in addition to the other circuit suggestions for capacitive Mafistabssassung.

* Fig.49 and Fig.5ö explain the principle and design examples for the preferred length measuring system based on the principle that metal strips (e.g. sheet metal strips) run on both sides of the slider guide (e.g. the guide groove) and the metal strips through one The electrode surface applied to the guided slider, which is guided in the guide slot, is capacitively bridged, whereby the capacitance measured between the metal strips is a measure of the movement of the slider along the slider guide (capacitance between electrode connections K1 and K2). * In Fig. 49 at the top left is a piece of the rail guide {99} with slide films or very thin PVC strips (which are drawn transparently in Fig. 49), shown, the metal strips {69A, 69B) under the PVC strips having a sawtooth pattern frayed toward the inner edge of the guide slot. The sawtooth oyster enables direction-dependent evaluation for the derivation of the incremental pulse corresponding to a sawtooth by means of edge differentiation. The increase distinguishes the direction of movement, with the periodic sequence of spontaneous increase in capacity and slower decrease corresponding to the direction towards the trailing edge of the sawtooth, and the sequence of spontaneous decrease in capacity and slow increase corresponding to the direction towards the flatter rise of the sawtooth. * These fraying or surface recesses of the sheet metal strip are bridged by the sliding element {98} sliding in the guide slot, the underside of the upper sliding plate on the one hand presses against the sliding surfaces of the PVC strips, and on the other side also has a metal electrode that holds the guide slot , or bridged the slide groove. * Fig. 50 shows such a sliding element (shown upside down) with a serrated groove {73} on the underside of the upper sliding plate, in which this metal electrode is embedded as a scalloped strip. This version is suitable if the sliding element slides non-rotatably in the guide groove of the rail guide, e.g. if a parallel guide with two guide grooves is provided, cf. see left figure below in Fig. 49. However, if the guided sliding element also forms the axis of rotation, then instead of a strip, a circular electrode is embedded in the sliding element ({98a in Fig. 50, drawn in broken lines); it is also provided for this version that the guided sliding element is mounted on the underside of the slide {100} via a spring (leaf spring {400}), whereby the capacitive contact of the insulated sliding element electrode is pressed against the sheet metal strips of the rail guide, depending on the direction of the spring this as. Pressure force can be made, or also as tensile force, if the capacitive contact is arranged instead of the upper plate {98a} on the lower plate {98c}, ie on the pull-off protection of the sliding plate (also on the inside) (option), the contact plates { 69A, 69B) are then under the PCV strips of the sliding support of the other gliders. This version has the advantage that the sliding surface can be kept thicker on the upper side. The principle for the scanning of the capacitive scale can be seen in the figure at the bottom right in Fig. 49. * Fig. 49 also shows a top view of the coding plates with a frontal front view and an enlarged view of the frontal view with the sliding element inserted. * The plates {69 A, 69B) are contacted with the contacts K1, K2 on the face of the rail where the housing for the evaluation electronics {41} is flanged.

* Fig. 51a shows the replacement circuit diagram to explain the measuring principle: * {Cp} is the capacitance that prevails between the rails without the bridging electrode of the slider. {Cgl] is the additional capacitance due to the bridging by means of the sliding electrode, the capacitance {Cgl} varying depending on the effective cross section of the electrode sheets bridged, corresponding to the sawtooth fora. * An incremental Iapulse is then generated for each sawtooth flank via the evaluating microprocessor circuit for controlling the mouse or button functions, whereby intermediate interpolations and the determination of the number of Iapulses per driven length can still be generated by software, with evaluation of the inclined flank of the sawtooth coding of the scale (e.g. For example, superimposition or fraying of the inclined flank by further sawtooth corrugation. * As shown in Fig. 51a, the rail capacity with a series capacitance Ck is switched to a capacitive voltage divider, the tap of which corresponds to the capacitance curve of the length scale (e.g. Via VCQ, voltage frequency converter handler fed to a microprocessor (see above) In addition to the option of using the sine voltage of a parallel resonance circuit as a supply voltage, an option can be used Pig.51b using a compensated voltage divider (R1, R2) with the measuring capacitance as a component of its co-compensation capacitance, the measuring capacitance is measured via the deformation of the rectangular feed signal, with aonostable time windows being triggered by the rectangular flank of the feed signal; Blanking signals (at coincidence gates MC1 ... MC3) blank out a window signal which corresponds to the comparison of the rectangular signal and the signal tapped at the voltage divider (adapted by level converter A, VCC). * If the corresponding test times (t1 ... t3 of the aonostable stages) are exceeded, the capacitance value corresponding to the quantized signal is output via MC1 ... MC3 to the microprocessor inputs according to the quantized signal. * Fig. 52 shows the microprocessor circuit on the left with further signal connections {P1, P2, P2} for integration into the functions explained and on the right an alternative for generating the activation signal for switching to the pillow input function: Instead of detecting whether the hand rest has been made on the pillow , an end stop contact is provided on the front of the rail, which presses against a contact spring and switches on the activation signal as long as the contact spring is pressed by pushing it against the cushion, it means: {107} each contact spring, 98x sliding elements with electrically connected stop contacts to the Contact springs, whereby the contact connection switched on at the fastening ends of the contact springs is conductive when the carriage strikes the springs, otherwise is interrupted. * Fig. 53 shows a variant in which the bee guide has a hollow surface {104} on the underside for accommodating the described sensor coil {34, option] or an alternative spring plate {106}, which is slightly pressed on the cushion when pressed by the hand rest deflects and performs a steaming variation on an air coil underneath, for the purpose of generating the activation signal for the pillow input function. * Fig. 54 shows a variant in which four sheet-metal foil strips are attached to a pillow in accordance with the coordinates, each of which has Hirbelstroahedapung to four air coils underneath, so that pressing on the surface of the pillow in accordance with the coordinates allows signal detection in accordance with the coordinates or displacements of the pillow in accordance with the coordinates can be scanned (see later part of the description). Instead of the needles scan, e.g. Direct vectorial pressure sensing by means of semiconductor sensors can also be carried out, inter alia, to obtain a directional variable in accordance with the coordinate system, in particular also with a follow-up control for zero force compensation of the cushion movement.

* Fig. 55 shows the corresponding circuit for this (Fig. 54), each with a parallel resonance oscillator of different frequency for the arming measurement, furthermore with optional connection of bus signal rails to the microprocessor, which makes it e.g. The oscillator circuit with the coils would have to be accommodated directly on the slide plate, or electrical drives on the slide plate should be provided together with control signals. In Fig. 55, three signal tapping rails are provided: the two rails VCC and GND for the power supply, as well as a bidirectional serial BUS signal rail. As an alternative, the bus signal rail can be aodulated into the strobe signal rail, e.g. by frequency coding or modulo-2 coding of a data signal, from which the supply voltage is then recovered by rectification and the strobe supply is bridged by a capacitor on the supply voltage for the duration of the bidirectional connection to send back serial data streams (according to a protocol) ( see also later part of the description). * Fig. 56a, Fig. 56b, and c show suggestions for the signal supply on the preferred carriage: * In Fig. 56a, the rail guide has three parallel guide slots, of which the two outer ones are used for guiding the carriage and for signaling, and the middle only for signal routing. The signal is routed via a contact inserted in the guide groove on the bottom sheet metal strips {BUS, GND, KC), each of which is tapped via a contact spring sliding thereon in the guide groove according to FIG. 56c or, in a further alternative, via a ball grinded on a short metal chain {FIG. 56b}; in Fig. 56c, b, mean: {64] + {100} printed circuit board placed on slide plate; the circuit board contains all self-sufficient co-components of the slide, e.g. Inductors (see Fig. 54 with {lC] ... over the Lissen cover) or drives. * Of course, when using the cross slide version, the contact rails of the uppermost slide can be looped through to the lower rail, whereby the slide can be used in any position using the contact pick-up spring {Fig. 5c} and if necessary by attaching the sliding elements, which support the Carriage on its undersize, on springs (see sheet leather above) a tensioning of the carriage guide and thus an astonishing precision can be achieved for the little effort. * Fig. 57 illustrates an exemplary embodiment for raising the keyboard, especially if there is no stand-up table for the keyboard, e.g. 40 is provided. The upper illustration shows how mushroom tape strips {40b} are glued to the underside of the keyboard along the front front line on both sides of the keyboard. Velcro tapes {40c) are attached to these mushroom tape strips {40b}, which are aligned in the longitudinal direction of the keyboard, and folded over along a fold line {40d} facing the back of the keyboard, so that after folding, the fleece side rests on the mushroom tape {40b} for further attachment of a Velcro tape , {74b, 62}, and is used for a further Velcro hand on a block to raise the keyboard. By grading different heel heights, which are layered with fleece tape / Velcro strip connections, different heights of the keyboard can be set, in particular if the individual height elements, for example. each doubled as a multiple of 2, i.e. are binary graded. The back of the keyboard is also raised by such blocks. As a further alternative, a hinged row of feet of different adjustment heights is provided on the underside of the keyboard. * Fig. 58 above illustrates the placement of a cover plate over the existing Velcro hand connection of the support surfaces of the cushions, the cover plate {300} instead of the cushions in the respective edge position limited by the stop (on the far outside) of the slide being placed on the Velcro connection, so that the Slidability of the plate is fixed. * Fig. 58 below illustrates that the rail guide can also be kinked in adaptation to the modern keyhole fora (cushions {1} and {K2}]. * Fig. 59 illustrates the design of the air cushion as a hand cuff with Velcro fastener 199A, this cuff can not only be used independently, but in particular also in connection with the cushions for hand support. * Fig. 60 shows an example of a self-sufficient drive for the rail guide, which is supplied via the described power supply and control signal supply rails, which is also for 2 rails as a cross slide (from the bottom rail to the bottom) emiebe a motor {500} is provided on the support plate, which drives a halve, e.g. rubber roller {700}, via a belt drive {600}, which runs on the rail guide (through window {800 }), but as an alternative or supplement to the rubber roller, a toothed wheel can also be used in a rack handle tion of the plastic rail surface, which runs next to the sliding surface of the slider, intervene, this toothed rack fluting e.g. can also be produced by hot stamping. * This gives aan a rail guide that is not only ideal for the purpose of moving the cushion, but also for independent applications. * Another version is to enable the cross slide to be able to be used despite the blocked mechanical drive. By manual shifting via controlled overrun control: * For this purpose, another cross slide, which has a small amount of displacement (VSP) and can be made in preferred rail guidance, is placed on the top slide plate of the first cross slide, or the displacement path of the first cross slide immediately provided with a displacement play (VSP) of the slide guide, the displacement play being sensed and used for a motoric readjustment of the displacement of the first cross slide. For the cushion movement control, the rail guide is preferably made in one line in the longitudinal direction and in one line in the transverse direction, as will be described in numerous exemplary embodiments in the later part of the description.

For example, simple coil springs pretension the slide in a central position of VSP as opposing compression or tension springs, and their inductance must be measured. If the slide is moved manually in a coordinate direction, which is determined by detecting the centering spring relating to the change in inductance, then readjustment is carried out until the centering spring again has its value which corresponds to its rest position (in the central position). Variants for the sensor are described below. * Another variant is to bring the drive wheel of the feed into a latching lifting position by lever {900} with spring {1000}, among other things to make the feed optionally movable by hand. * The preferred rail guide can be used in any position, if necessary the sliding elements are spring-loaded against each other or against their support surfaces (see leaf springs {400} in Fig. 50 or {200} in Pig.32). A preferred application is to use the cross slide guide in conjunction with an image processing system, which composes the individual image sections from the image information, whereby this can be pre-oasis not only for image scanning, but also for expanding the travel path of precision machines if, for example, the very precise travel path of the Päzisiαnsaa - Is correlated by the respective acquisition of its exact measured value via the image content of the image scan.

In the following, further embodiment variants are described with reference to the figures for FIGS. 23 to 25x and 61 to 61x, which relate above all to the preferred variant for better support of the hipp roller, in which the hand is in the immediate area or at least in the nearer area is placed on a longitudinal fold (or on a longitudinal seam) of the tubular film cushion. * Variants according to Fig. 23 to Fig. 25e relate to an optional tensioning device for the cushion for regulating the air pressure, which is suitable for both horizontal and vertical position of the cushion: * In Fig. 23 the cushion shows an oblique view from below with the Trough {S3} of the long side of the pillow (with the longitudinal fold of the slightly inflated film tube underneath), which is used for the wrist-rest or wrist-rest or also a brace. Another application would be hand support for handicrafts. * The tensioning device consists of a pressure plate {93) with a flanged clamping screw {84], which, similar to a standardized clamping clamp, can be moved or rotated at the screw end by means of a ball and socket connection and presses against a flat side of the cushion, with the plate being supported by a thin one Plate {3} (e.g. made of plastic) is made, in the middle of which the screw is inserted in a thread, the plate adhering to the cushion (e.g. on a fleece window {123]) and being arranged above the pressure plate, optionally stabilized with a U-shaped or angled holding device {{8 85} .. made of plastic or bent sheet metal], into which the cushion is inserted and the screw in a window {86} (with longitudinal slot {88}), which ensures the tiltability of the pillow in the direction of the keyboard and thus the mobility of the clamping screw is ensured, is inserted, so that the rotary knob {84) protrudes and the holding device, for example, also about Flauschbandstreifenunter- page to the Kletthandverhindung (Mushroom tape strip 32b {]) of the support plate {100} is placed; * In a further option, the pressure plate {93} can be slid into the plate {3}, whereby the pressure plate (93) is centered in the serenity of the pressure plate by means of centering (ring or individual Velcro tape adhesive pads 93PZ), which adheres to a fleece surface of the cushion . In this variant, the plate {3} does not adhere directly to the fleece window of the pillow, but rather to a tension band, which is attached to the plate on the formwork side by means of Velcro and looped over the air cushion inside the cover; the pressure of the pillow is therefore also via the belt, cf. see Fig.25c and Fig.25d. * Fig. 24e shows the pressure plate {93} in detail, consisting of two discs {93A) and {93B} glued together with a flat countersink {93f} and {GH} and a cap {89b] which snaps into the hole in the flat countersink, to which those with counter nuts {89h and 89a], secured threaded rod {89} can be turned within the pressure plate. * Fig. 24d shows an embodiment with spacer adjustment GS for better cushion adjustment with KLTA ... Velcro tape adhesion of the plate3, cf. also Fig. 24c. * As a cheerful development variant, an U-steering (angled toothed wheel steering or Transaission 84 AT Fig.25c) is provided, with an optional option to provide an motorized drive instead of the manual drive of the clamping screw; an alternative for the articulation is to use a guided, inclined wedge surface. * The differences from Fig. 24a and 24b relate to the mounting of the threaded rod {89} in the holding device (in Fig. 24a in elongated hole {86], in Fig. 24h in thread {86}. * Fig. 25e shows an oblique view, Fig .25d Details. * In addition, in Fig. 23 to Fig. 25e mean: * BDH ... tension band, ASA .. incision of the pillowcase for tension band, H ... .hand or armrest, 132 ... fleece surface, 1. ..Leather cover of the cushion, 85K ... angle, 85 support device (or at the same time sled plate {100}), HIP ... Hipp Velcro connection with @ ... Hippwinkel, 84 FL optional

Wing screw, Y ... longitudinal direction to the keyboard front (X ... transverse direction); BDW-132BD ... lead-through hole of the belt with inserted tensioning screw (or threaded rod G) in Fig.25d; 132BDS ... Velcro connection of the Tension band on the pillowcase in Fig.25c.

* Fig. 19a and 21d, Fig. 21c, correspond to the previously described designs according to Fig. 19 and Fig. 21, with the expansion option that on the formed by the trough (see. 83, Fig. 24) on the upper longitudinal seam of the pillow Hand or macaw support surface (H on the wrist or behind the wrist) a leather surface (LD) is laid on like a saddlecloth. * Among other things, to support the hipp behavior generated by twisting the hand rest of the pillow, the fleece side (132 in Fig. 21d) is preferably used as the top of the pillow. * The pillowcase is made of fabric, e.g. made of particularly thin felt-cellulose fabric, and covered with another felt. The thin fabric cover adheres directly to the fleece cover 132 with its rolled-over side parts (la, lb, lc, ld), the further thicker cloth cover adhering to the outside of the rolled-over side parts. The liability takes place by means of Velcro, whereby for the sake of simplicity of manufacture, preferably fluffy material (e.g. velor) is used (e.g. ironed on) for both sides of the fabric to be connected and are stitched together by Velcro strips coated on both sides (e.g. with self-adhesive double Velcro strips). * A further variant, in which the pillowcase is made entirely of fleece material, is shown in Fig. 70a, with a tilt line (Velcro tape C adheres to slide plate 100), and a hand rest attached with Velcro tape (b), whereby another fabric cover with Velcro tape is attached to this fleece material can be pinned. * Fig. 61 shows an oblique view of a preferred embodiment: * 100 ... sled surface with Velcro strips (KLT) for attaching the hipp cushion (on the side next to the keyboard front) according to a fleece strip on the underside of the cushion as a hipp line, cf. KLT Fig. 62 and and to put the bar HSL on the user side to raise the pillow, also over a fleece underside of the bar as an adhesive surface. HSL ... leather-covered strip made of hard-look material, whereby the underside of the blanket also adheres to the Velcro strip. For the purpose of adjusting the spacing (VHSL) regarding the keyboard front line, the Velcro strips (40a) are crossed in relation to the rocking line aligned parallel to the keyboard front and the bar (HSL). (cf. also in Fig. 72b: HSL-KLT ... adhesive surface of HSL, ditto HKL-KLT for pillow = hipp line). * Cheers in Fig. 6l mean: la ... center line of the trough, which results from the low inflation pressure of the air cushion when the hand is on the hand. 2Q3 ... glue points of the fabric cover with the fold-over pages 1a, 1b, 1c and 1d (see 300 in Fig. 2D)). * Angle ß ... Angle of attack, among other things, that the back (towards the user) of the pillow is increased by the HSL bar underneath. By means of the described distance adjustment of the bar (HSL) by means of crossed Velcro strips (40a, 40b), this angle of adjustment (β) can be adjusted accordingly to the user. The one-sided elevation of the underside of the cushion with (HSL) creates a convex bulging outwards between the bar and the hipp line. * Fig. 61b shows a further variant with an air cushion film (LKBL, packaging material) underneath the saddlecloth (leather piece LD), whereby plates, e.g. from cardboard (PLK) Fig.6lc can be underlaid. 6lcN shows a variant in which a peel-like granule cushion (GNLT) is used as a base for the hand rest (granules floating in liquid, welded into further foil bags, see later part of the description). * Fig. 72a, (see also Fig. 61cN, oblique view with detail GNLT) relates to an embodiment variant in which the long side of the cushion, which is opposite the superscript support, ie is not supported and therefore lies lower, with a stop surface (WKL ) is supported with the following variants: that the stop surface is resilient, the stop surface is designed as an angled stiffener (e.g. plastic), in which an angled surface rests on the support surface of the cushion and the other angled surface supports the movement of the cushion towards the keyboard front, so that the Fastening the pillow, or pillowcase, is made on the inside of the ice along its bending edge, e.g. Velcro strip connection. Depending on the requirements, the angle WKl or the underlay for high HSL can be provided on the user side of the cushion or on the side of the keyboard front. * Fig. 72b, Fig. 72c, Fig. 72d relates to an embodiment variant in which the support surface of the cushion for the hand rest has terraced, layered bags (GNTÖ to GNLT2 Fig. 72d), which are filled with granules, with the bags forming a ridge have different lengths with gaps (window) of the stack, a hand or Arafora Fora corresponding across the surface (FB), so d ^'hand or Araauflage. Fig. 72B shows a top view with slide plate 100 (skids 101 and sliding surface 99), WKL ... support angle, 98 ... fulcrum, a ... center line.

* Fig. 62 shows a side view of the cushion placed on the slide plate (100, with the pivot point of the guide element 98 guided), the longitudinal sides of the slide plates on the side facing the keyboard front line being approximately congruent with the limitation of the rail guide. A later version of the description explains a variant of cheerfulness in which the side of the slide plate facing the user protrudes and another cushion is placed behind it. * KLT ... preferably on the front of the pillow, which is immediately in front of the front of the keyboard (8), Velcro strips running in the longitudinal direction of the keyboard as a hipp line. * 83S ... trough formation of the placed leather piece (LD); the piece of leather is, for example, also point-by-point via Velcro fastener or via an adhesive or adhesive strip running in the longitudinal direction of the keyboard on the crest (KP), or just next to the crest (e.g. below) the trough on the fluff top of the cover (cf. . {132} in Fig. 6l) and hangs down on both sides of this fastening strip (cf. also the dotted line LD on the right hand side of KP). * The use of a Velcro strip makes the leather pad interchangeable, which is practical for hygienic reasons and for the further variant in connection with an additional rear cushion. * As a further detail, which is optional, a leaf spring (33f) is placed under the cushion, which relaxes when the hand is raised. This changes the needing (e.g. left hand of the rail at the level of the X / Y keys on the outer edge to the left of the keyboard) of a sensor coil attached to the underside of the rail (see previous description) to generate an activation signal for the cursor - Movement by moving a pillow along the rail (e.g. the right pillow) or also to measure the contact pressure of the hand placed on the pillow, the variant shown in Fig. 62 also for a rear pillow for macaw support in addition to one front pillow can be used for the hand rest (see later part of the description, automatic adjustment of the height of the pillow). *See. also previously described length sensing by means of capacitively coded scales (e.g. after a sawtooth oyster) symmetrical on both sides of the guide groove and its capacitive bridging by an electrically conductive bridging surface provided on the guide element of the slide, the two connections of the capacitive scales being used, for example, as capacitive voltage dividers a further series capacitance is switched on and the capacitive voltage divider ratio is measured by means of a supplied oscillator voltage to generate the incremental pulses corresponding to the length shift of the cushion (for evaluation see, as already explained, with rectification and / or averaging via voltage-controlled oscillator, \ 'C0). * Fig. 63 shows the weld seams of the bag (20 ... wide seam, 28 ... end seam, 55 longitudinal folds of the film tube). * Fig. 64 shows a front view of the pillow. * Fig. 65 illustrates that in the case of slides (100) aligned parallel to the keyboard front line (not twisted), the cushions are slightly twisted (cf. @ -fix) via their Velcro connection. * Fig. 66 shows a variant in which different levels (with respect to the sliding surface) of the slide plates enable sliding into one another, in that the slide surfaces can be pushed into one another at the joints, or a slide surface can be pushed under the other slide surface; (100A) ... is a support surface of the cushion and is used directly as a sled plate, whereby the further support surface of the cushion (100C) is placed on a smaller slide plate (100B) underneath via an adhesive tape connection or Velcro connection (100f). * As shown in Fig. 67b, in a further preferred embodiment, a bevel (AS) is made on the long sides facing the keyboard, this being done in such a way that when the sled plates are turned to the respective stop positions, this bevel is parallel to the longitudinal front the rail contact surface as close as possible

Distance to the rail front is. KLT ... Velcro straps with KIEW for Hipplinie and KLT-HSL for

Raising bar. * The sled plates protrude slightly at the back, for the purpose of adding another cushion (see later part of the description) or can also be beveled accordingly. * Fig. 68a illustrates an alternative for fastening the sliders (101) or the guide element (98) located at the pivot point by means of a curved, punched sheet metal clamsheller (KLM). * Fig. 68b illustrates a variant with a coating of the slider (101) or of the guide element (98) located at the fulcrum with a slide film (101GL). * Fig. 67a illustrates a curved design for the guide slot (X), cf. also other variants in the following part of the description (102a, 102b ... side parts with insertion slots from X). * Another alternative for the production of the rail guide is a plate with corresponding longitudinal ribs made of plastic and correspondingly glued or latched sliding surfaces. * Other alternatives for the execution of the foil pouch are: * The advantage of the foil pouch is that it is cheap to manufacture and that the material does not stretch. If stretching were desired, the material for the bag could be e.g. Gunai can be used. As an additional option for the bag, a valve for inflation would be provided. * For the use of a foil bag e.g. In a further development of PA / PE film it is also provided that the film is coated with a sound-absorbing fabric cover, for which the preferred embodiment example is the fabric cover made of a fleece material (e.g. velor), as is also used for adhesive purposes for Velcro fasteners, is used, in a special further embodiment such that the fabric cover is glued to the film with an adhesive which is thermally heated by ironing when the material is glued onto the film. * Other alternatives for the design of the sliding surface for the slide plates of the cushion pads in conjunction with variants for the guide are: * In a further option, the leadership of the slide plates can also with an outstanding over the sliding surface (99) guide rail ^• (to replace or supplement zua guide slot ) along the longitudinal center line of the sliding surface, for example. The side elements guided through the bar on both sides of the bar form the guide element. * For the alternatives described, the guide element also forms the fulcrum of the slide plate, with the plate being secured against being pulled off in the guide slot by a plate of the guide pin sliding underneath the guide slot. When using an individually protruding guide bar (or guide bar) with sliding elements sliding on both sides of the guide bar at the pivot point, which are located at a short distance from the bar and are separated and guided by the bar, the trigger is secured by lateral projection at the top of the bar, e.g. also by means of sliding plates, whereby the trigger protection can also be carried out or supported by means of magnetic adhesion: e.g. via a mapet, which is attached directly over one or more of the sliding elements, and to an iron plate, which is under the sliding surface, adheres non-magnetically. * As a further alternative, an embodiment is preferred in which the slide plate is omitted and the sliding elements are glued directly onto the underside of the cushion. * In a further alternative, it would also be possible, in an individual version, to completely omit the linear guide, so that the cushions slide freely within the engagement of the sliding ruler surface.

Complementary to the already proposed capacitive length sensing of a rail guide with a guide slot, for the variant with a guide bar, the capacitive scale in

Fora of a sawtooth-shaped longitudinal strip attached to the upstanding sides of the guide bar and capacitively touched by the sliding elements by means of isolated cylindrical metal surfaces which are attached to the respective sliding elements. * Further options are shown in Fig. 33b, Fig. 71b, Fig. 73 to Fig. 75: * Fig. 71a and 71b relate to exemplary embodiments for securing the slide plate guide element (cf. 98, for example in Fig. 33), where in Fig. 71a, the end strip ZPF inserted into the guide slot X has no end T-piece and in Fig. 71b such a T-piece (LA), cf. also the following part of the description for Fig. 71c and Fig. 81 (BND ... raised band as a stop). * For the rail guidance, a protruding bar (BND band) on one long side is sufficient as a twist stop for the slide plate (100). * Fig. 73 to Fig. 75 relates to the further design of the cushion support with an additional slide guide in a further coordinate direction with 99.. sliding surface with a guide slot for slide plate 100 and sliding elements 101; further sliding elements (GLE) of the upper slide plate 100-0 and with sliding rails RM, 1 ... cushion. In addition, in Fig. 73 means: Outside of slide runners RM guides slide elements (GLE) of the top slide plate (100-0) towards the keyboard. In the interior of the carriage, one or more sliding elements (GLM) slide which forms the stop for the movement of the attached slide in the direction of the keyboard. * Another option is on one of the sliding elements, e.g. a magnet is placed on the middle one (GLM) and the inner part of the RM roof is lined with an iron plate, which forms a trigger lock, optionally with the option of using a guide groove. Another alternative to this version is described in the later part of the description of Fig. 69a. * As Fig. 73 also shows, for the generation of an activation signal which indicates the (brief) lifting of a hand (e.g. left hand) (in connection with an actuation of a selection key for the cursor or at this time interval) Mouse function), the spring for lifting the slide plate is arranged as a further variant directly on the sliders (slider arranged on leaf spring) (option: 101.400b) or a plastic spring sliding on the rail surface (option 400c) is provided. (Lifting off the slide plate with the cover plate {33} attached to the underside generates a signal at the scanning coil lying under the sliding surface, as already explained in the preceding part of the description). This needling measurement can also be carried out for a large number of scanning points (cf. sheets 33 with scanning coils 34A to 340 in FIG. 54) with different frequencies of the coil measurement signals (filtered by parallel resonance circuits of the coils), which means, for example, the displacement or rotation of the cushion (1 ) within the area (RM) for the purpose of generating a taxipal for the follow-up control of the upper and lower Carriage plate is measured, or the contact pressure of the hand placed on the cushion, as will be described in the later part of the description of exemplary embodiments. * Fig. 74 shows a development in which, while maintaining the principle, in addition to the sliding elements (GLE), which, for example. the guide is on the inside of the carriage, the outside of the carriage is provided with two grooves which hold magnetically mounted balls (KGL) in the grooves on which the uppermost slide plate (100-0) rests. FE ... non-magnetic iron plate (MAG) to GLM, as already explained above. * It is evident that, in principle, the bottom slide plate can also be supported with roller balls (e.g. spring ball bearing or non-magnetic ball rail). * Pig.75 shows a top view of the rail with the cushion and an example of the dimensions: 2.7mm ... guide slot; 70mm ... rail width of the sliding surface, (option variant: 85mm X 65mm cushion dimensions, lRUS ... ruffle edging, 1 ... thin, light cushion material made of mixed felt, cellulose, bag ... 1 filled with granulate)); Rail 540 mm long. * The lower and upper slide plates each have a rectangular fora with rounded corners. * The lower slide plate (100) has the same width as the rail, the length is covered by the frills of the rectangular cushion. The upper slide plate is not visible in FIG. 3 and is held approximately congruent with the lower slide plate. * Fig. 24, Fig. 24a, h, c, d, e; Fig.25, Fig.25a to e: Fig.24 and Fig.25 ... already in the previous. Part of the description explained, * Fig.25a and Fig.25b, like Fig.24a and Fig.24b, differ in the version in which the push rod {89} of the turntable is screwed into the U-stand support of the cushion and is only led through an elongated hole. * Fig.25c, Fig.25d, Fig.25e refer to further details for the variants described for Fig.25, as shown in Fig.25d as by means of a centering (ring or individual Velcro adhesive pads 93PZ), which adhere to a fleece surface of the pillow , the pressure plate (93) is centered. Much more is on the threaded rod G), which presses the pressure plate against the pillow (screwed into plate 3, Fig.25c) a band (e.g. made of fabric or leather) inserted (BDS), which the air cushion (or Hater cushion) and by pressing the pressure plate against the cushion (via the threaded rod screwed into the plate) press the band and plate against the cushion, or loosen them in the opposite direction of rotation of the threaded rod, whereby the pressure in the cushion can be adjusted. 25e shows a further variant in which the tilt of the cushion can be adjusted with a wing screw within a guide slot (86) of a support device. * In Fig. 6lb and Fig. 25c it is further illustrated how instead of the handle (84) a drive wheel (84AT) is flanged to the threaded rod and the adjustment can be motorized (84M) by means of a corresponding transaission. * Cheerful optional cheek training designs: Fig. 60d shows a further design variant for the pillows (with entered dimensions in mm) with the detail that short seams are welded inwards from the long sides {4a, 4b, 4c], which are the superimposed foil surfaces Hold the bag together at these points so that fora-giving troughs (10) on the side of a crest MB (size 12) adapt well to the hand or Macaw coverage guaranteed. * Figures 60a, 60b and 50c illustrate one

Development variant in which a resilient restoring force is generated for the rotation of the cushion, depending on whether the hand is placed on the cushion or not. The restoring force occurs when the cushion is relieved (reduction of the pressure on the hand or lifting of the hand). This is useful if the pillow loses its grip due to twisting during typing, whereby it is automatically turned back by relief. * If the hand rests on the kisen, the torque of the spring force, which returns the pillow to a certain rest position (e.g. parallel or diagonally to the keyboard front), is completely decoupled, so the hand's mobility is not impeded. * The technical problem was solved by special design of the guide or sliding element guided in the sliding slot of the rail surface, in such a way that a return rotating element of the slide generated by spring force is generated by lever action against the guide slot or web a coupling of the torque in such a way that * a) a spring force acting against the bearing force of the hand is provided, with a spring travel which, when the hand rest is removed (lifting the hand), increases the distance between the slide and the sliding surface by relaxing over the spring travel and * b) that the guide surface of the guide element {e.g. The outer surface of the slide pin between the top plate and the bottom plate of the trigger protection) has two different cross-sections over the spring travel: * b1) over the section of the guide surface that is guided by the guide rail (e.g. sliding slot) when the hand is resting on it, i.e. when the spring force is tensioned the cross-section of the guide surface (or the slide pin) is designed so that the slide element, among other things, this guide surface can be rotated (e.g.. sliding slide = axis of rotation of the slide), * h2) over the section of the guide surface which, when the hand is raised , i.e. relaxed spring force is guided by the guide rail (e.g. sliding slot), the cross-section of the guide surface (or the sliding pin) is designed so that the sliding element rests on an inclined surface (in the vertical direction), deviating from solder, and that the angle of this inclined surface based on the vertical position of the axis of rotation of the carriage, starting from its upper point of intersection with the axis of rotation opens downwards (triangle tip of the kink above, opening downwards), which means that by lifting the axis of rotation into the corresponding travel range by reducing the contact pressure of the hand or lifting the hand, the distance from the guide surface and inclined surface is reduced, ie a torque is applied to the sled plate by lever action on the inclined surface, so that the cushion is rotated in a fixed return direction. * Two design variants are described below: * Fig.60a and Fig.60b shows a side view of the variant in which the inclined surface or wedge surface runs over the entire length on both sides of the guide edges of the guide slot {106} in Fig. 60b) of the rail guide , on the other hand, the sliding element has no inclined surface outside and the pull-off protection of the sliding element forms a lever with two points of contact on each side of the slot (as already explained). * In contrast, in the version according to Fig. 60c, the plate surface provided as a protection against pulling off the sliding element is designed as a vertical wedge surface (corresponding to a triangle that has been set up), the inside guide slot edges having no inclined surfaces. * Variant according to Fig.60c is somewhat cheaper and

but requires a slightly higher height than the variant according to Fig.60a or Fig.60b. * To Fig. 60a and Fig. 60b: * Fig. la shows the position in which the pillow is relieved or the hand is raised. * Fig.1b shows the position in which the cushion is relieved or the hand is raised. * It means: * 103 ... cardboard plate laminated with foil paper (cellophane-coated cardboard), * 99 ... sliding surface strips running on both sides of the guide slot (106). 101..supporting sliding elements (with curved sliding surface on the underside), (103b ) .- .. Support bars for fastening 99 to 103. * 102 ... longitudinal edge strips, (cant on Edge - band = stop), * The wide strips on the front side of the rail guide are removed in the illustration according to Fig. 1, the wide strip has an opening as an option, which opens the guide slot (see 106 in Fig. 60b) for inserting the slide plates. * 400 ... optional, leaf spring or leaf spring pair, on which the guide element (98), which also forms the axis of rotation of the slide plate, is suspended, optionally available, e.g. as a pressing force when an electrode surface (concentric circular ring 73b, cf. previous part of the description) presses on a capacitive length measuring rod (69A, 69B). * The leaf spring is dimensioned so that when the slide plate is lifted (hand raised), i.e. the leaf spring is relaxed, it assumes the position shown in Fig. 60a, i.e. in the relaxed state it has an exact spring travel, which is characteristic of a leaf spring. * 400b ... also leaf springs or spiral springs, on which the supporting sliding elements (101) are suspended on the underside of the slide plate (100) and act like a shock absorber. * 98N .... modified trigger protection according to the invention of the guide element (101) used as the axis of rotation, the trigger protection having approximately a rectangular fora, the pairs of front corners of which are in each case the contact surfaces for a lever effect for generating a torque. This torque is generated by the upwardly tapered sloping surfaces (103S) of the inner edges of the guide slot (formed by reinforcing strips 103N), the engagement surfaces of the rotary lever (98N) being centered by these sloping surfaces when the slide plate (kl = Maximua) is raised, as a result of which the axis of rotation of the guided sliding element (98) is turned into the defined rest position. The slide plate is raised by the spring force of the supporting sliding elements (400b with 101) so far (q) that the surface of the trigger safety device (98N) on the underside of a narrow horizontal groove (103X) lies on the underside on both sides of the guide slot. Heiters down to the Aufaufliegeplatte (103) of the guide rail the distance is held so far that the guide element (98) can be pressed down. * Fig. 60b shows the (via Heg q), cf. Fig. 60a) pressed down sled plate with strained shock absorber springs 400b, in a rotational angle position (ß), which corresponds to the angular range of the sled plate (released by the downward opening of the bevel (103S) of the guide slot edge), whereby in this position in the torsion direction (ß) no spring force is effective! * The alternative design according to Fig. 50c corresponds to the function according to Fig. 1, however, the inclined surface is not realized by the edge of the guide slot, which extends downwards, but on the slide or guide element, in which instead of a plate edge acting as a trigger protection, the Edge surface of a vertically extending triangle extending downward is provided, at the upper tip of which the guide pin of the guide element (98) acting as the axis of rotation of the slide plate is flanged. If the pin is lifted upwards (direction of arrow), the triangular surface adjusts itself accordingly due to its inclined surface (angle of rotation in direction of arrow), whereby the cushion or the slide plate is brought into the reset position. A widening of the triangular surface (103S) or corresponding flange mounting of a further plate surface is provided on the underside as a trigger protection. * As a further variant, the combination of the exemplary embodiments from FIGS. 1 and 60c would also be possible (inner edges of the guide slot 106 with wedge surfaces 103S, and also wedge surface on the guide pin of the guide element 98). * A further exemplary embodiment with an expanded task is described below. * The cheerfulness fulfills the technical task that the pressure of the hand placed on the pillow, or the ball of the hand, or wrist, is significantly reduced. This is achieved by using several cushions (1-V, 1-H) arranged one behind the other, which can be moved directly to the keyboard front by forcing the cushions and / or by sliding the cushion support. * All of the execution components explained in the preceding part of the description can be used for this cheering, with particular suitability for the example described with a skate runner principle, with one or more cushions for the hand rest, the contact surface of which is in each case as a slide (100, see Fig. 69a), which on a sliding surface in the longitudinal direction of the keyboard front (99 or 99-0) by means of surface-separated sliding surfaces; (e.g. slides on both sides of a guide groove (X) or a guide bar and is guided through the guide groove (or the guide bar) via a guide element (98) and the rotatability of the guide element within the guide groove (or above the guide bar) at the same time the axis of rotation forms and for the cushion support of the front cushion {1-V with 100S ... upper slide} a further coordinate guide (99B) in a further coordinate direction (vT, see Fig. 69a) in the transverse direction to the guide direction of the guide groove (or the In a further preferred alternative, for the transverse movement of the rear cushion (1-H), as an alternative to the sliding principle of the front cushion (1-V), the tilting principle of a hipp cushion described at the beginning is used as a further design variant on the one hand to comply with the widespread condition, on the other hand to avoid a disturbing feeling of pressure on the arm at the support point on the back cushion In the following, further explanations or variants of cheerful development are described. * In addition to the possibility of arranging a large number of movable cushions in a row for each hand, with two cushions (1-V ... front, 1-H ... rear) there is already a very good effect for each hand in terms of technical Task accomplished. * Variants for the movement coupling of the back cushion (1-H) to the front cushion (1-V) are that the coupling is only mechanical (e.g. Fig. 79) or via electronic control (see Fig. 97), whereby in both cases the variant is provided to provide the mechanical connection by a static connection of the support surfaces, which can also be designed as a joint (with a horizontal axis), or directly by the arm of the correspondingly placed hand . * The front cushion (1-V ... for hand rest in front of the wrist), which glides directly along the keyboard front (from keyboard {8}) on the preferred sliding surface, is small and low, with preferred dimensions of about: 8 approx in the longitudinal direction of the keyboard, 4ca wide (BK) and and about 0.5 ca to lem high (h), cf. Fig. 97 so that it fits comfortably in the hand. As a further option, the front pillow is designed as a flat foil pouch (e.g. PA / PE), which is filled with granular plastic granules of a soft plastic that float in liquid (cf. front description) and thus adapts well to the hand placed on it (option:. corresp window opening {1-FV} for the leather covering of the film ^'pad Fig.97: option xxxxxxx = window margin with Velcro connection zua Granualtkissen on the underside of the leather cover LD2). The pressure on the hand placed on the front cushion (1-V) in front of the wrist is relieved by the macaw support of the cushion (1-H) arranged behind it, with the rear cushion (1-H), for example, as a preferred rocker cushion (see Fig. 77 ) and the front cushion (1-V) is designed as a cushion that can be moved against the keyboard front on a further sliding carriage (100S, Fig. 69a) in a further coordinate direction (vT). * The rear pillow (1-H), designed as a rocking pillow, is used as a macaw pad behind the wrist and is designed in accordance with the previous explanation and consists of a foil bag (e.g. PA / PE) that is only partially filled, e.g. . with gas (e.g. air! or a liquid (e.g. water) and through corresponding edition forms a guide surface into which the arm (see Fig. 97) can be inserted. According to the previous description, the cushion is raised slightly at the back, so that the trough is formed on the longitudinal seam or fold of the bag, as a result of which the tilting roller of the cushion is formed. Execution of the pillowcase (fabric folded upwards {1-H} covered with fleece tape {132} on top and with leather saddlecloth {LD}) corresponds to the front part of the description. * In order to bring the arm resting behind the wrist flat (corresponding to the palm rest of the front pillow) to the front pillow or the keyboard via the rear pillow, the rear pillow is designed to be higher than the front pillow , set a little lower (100M in Fig. 97, at a distance of 100V behind the front pillow).

* An exemplary embodiment is described below in which the sliding surface for the cushion arrangement of the front cushion is to be set up over the edge of the table on the table in front of the keyboard without the keyboard having to be raised and the cushions placed behind the hand rest cushion (1-V) for the Ara support (1-H, rear wrist), protrude freely from the tabletop, which means that the device can be set up on a table to save space and also provides a level adjustment for the Ara support (the rear cushion). * Two different variants are provided for coupling the displacement path of the front and rear cushion: * A first variant for a cheap version, in which the movement coupling of the front cushion {1-V, and rear cushion (1-H) is achieved by statically connecting the cushion contact surfaces takes place, and a second variant, in which the coupling of the front pillow and the rear pillow is carried out by a motor-driven movement drive with corresponding sensory movement sensing of the pillow (for example via displacement path) with regulation of the respective deviation from a desired position of the movement sensing. * The variant of the electronic adjustment of the rear cushion to the movement of the front cushion is of great advantage if the rear cushion instead of air, e.g. is filled with water, because then the moment of inertia of the rear cushion becomes very large. * Motor drive and scanning of the displacement of the support surfaces of the cushions takes place in accordance with already proposed exemplary embodiments of the front description part, with for linear drive of the slide plate in the longitudinal direction of the keyboard, additionally a drive for the movement of the upper slide plate in the transverse direction by means of the Carriage plate combination of autonomously arranged motors can also be carried out, ie a servo-controlled rotation control of the carriage plates. * In addition to the longitudinal rail guide (99 or 99-0}, a transverse rail guide (99B) is preferably provided for the front, flatter cushion, by means of which the flat cushion is moved towards the keyboard front during typing. The following detailed embodiment is particularly preferred: * The slide plate (100) sliding in the longitudinal direction of the keyboard front on a sliding surface (99) by means of surface-separated sliding elements (101) is also like the sliding surface on which it slides , designed as a sliding surface on which another slide (100S) slidably slides in the direction of the keyboard front, and is also supported by surface-separated sliding elements, placed directly on or over further sliding surface strips (cf. 99-0SL in Fig. 83 and Fig. 76b) is. * Are in optional training the sliding surfaces for both of the superimposed slides (100 and 100S) are inserted as interchangeable strips in a frame, as follows for FIG. 80 for the lower slide plate {100} and in FIGS. 83 and 76b for the upper slide plate {100S} still described. * The frame for the sliding surface of the lower slide plate consists of a foil-laminated cardboard plate ({103) in Fig. 80, cf. front description part), which forms the underside (footprint), on which raised by means of schaalen webs aligned parallel to the keyboard front (e.g. made of wood, {103b}), stripes {99} on both sides of the guide slot {X} in the longitudinal direction of the keyboard front line as thin plastic tapes are glued on. These plastic hands {99} form the contact surface for the replaceable, actual sliding strips (99-0), e.g. made of particularly smooth, hard transparent PVC), which snap into the slot of the sliding surface (102) or are also pushed under the support surface (option, cf. later). * The two long sides of the slot for the slide rail support (e.g. Strips made of wood or plastic) are dimensioned so that when the slide strips {99-0], which forms the slide surface of the slide, have an elevated band on at least one side for the stop of the slide elements when the slide plate is rotated (see front description part ). The side delimitation bar on the front broad side of the slide rail support is flush with the inserted sliding surface (see front description section), among other things to enable the slides to be inserted laterally into the guide groove, with a corresponding slot (B, Fig. 81) being inserted in the middle of the guide element {{98), Fig. 80), which also forms the fulcrum of the slide plate, is provided with push-in limit stops which can be pushed into the guide slot (strips ZPF, Fig. 81). * Furthermore, it is optionally provided that points made of mushroom tape (Velcro tape) are attached to the underside of the longitudinal stripes (99-0), which adhere to the fleece tape strips which are set into the support surface {99] accordingly. Instead of this adhesive connection, a magnetic adhesive connection can also be used, or an adhesive connection can also be dispensed with, or the catch (102), for example. have appropriate adhesive grooves for the lateral insertion of the sliding surfaces (99-0). * The cross slide that can be moved towards the front of the keyboard is designed in a special version as follows: * On the lower slide plate for longitudinal movement, the sliding support of the cross rail is provided on both sides with the

Slide plate center line in the direction perpendicular to the keyboard front of guide webs or ledges (ridges), each of which is covered with a further elevation, which protrudes from the longitudinal edge of the guide web, whereby the transverse rail guide is formed with an edge groove on the underside to prevent the cushion support from being pulled off. The guide edges of the cross rail guide are either enclosed on the inside of the parallel guide webs or on the outside by sliding elements, the vertical pins of the sliding elements being guided on the inside or on the outside along the edges of the top bar of the cross rail web and the aa lower end of the vertical pins on the sliding plate in the one below half of the guiding groove of the leading edges slide in the groove and are secured against withdrawal by the groove. The sliding elements for the transverse rail guide are then attached to the underside of the actual support surface for the cushion, or immediately below the cushion. * In addition to the possibility of providing wheels as sliding elements (see Fig. 94), the already explained sliding elements, e.g. . made of P0M (polyacethal resin) used in plate and pill forums. The anti-pull protection is formed by the plates of the sliding elements, the guide centering by the pins, whereby the plates can also provide vertical support on the sliding surface of the slide plate, or without vertical support, only a centering and anti-pull protection is made, using further skid-shaped sliding pills or mounted castors for vertical support. Variants are explained in Fig. 83 and 76b. * For the cross slide, the actual sliding surface is also interchangeable and an insert in the Fora one Inserted on the underside of the guide groove edge (99-OSL) made of the same material as for the sliding surface of the longitudinal rail guide (99-0). * This plate sticks to the sled plate, for example via Velcro and has aa front and rear edge of the stop limit

Sliding elements when the support surface of the front cushion is shifted towards the keyboard front or the typist, e.g. in the fora of a closing strip, or is inserted separately from these stops in the guide webs (Fig. 83, Fig. 76b). * "The attachment for the support surface {(100AP) of the rear cushion (lH) can either be done by simply extending the lower (100) or upper slide plate (100S) to the rear, or can be made interchangeable for a wide variety of needs, e.g. For the optional inclination of the support surface of the rear cushion with an inclined angle to the installation level of the keyboard. The interchangeability can be done, for example, so that two sled plates for the lower sled are stitched together by means of Velcro and the extension (100 V) for these two sled plates the support surface of the pillow is inserted and fixed via an interchangeable bolt connection or additional Velcro hand connection. * Another special feature is, after a distance, which

corresponds to the Freiraua for the rotatability of the slide plate (100V), aa plate edge an angle of the plate attachment (100M) for the support surface (100AP) of the rear cushion (1-H) to provide, e.g. in the right angle downwards (hand 100W in Fig. 109, or angle M in Fig. 77) and on the contact surface of the rear cushion also provide a corresponding bend (100N, Fig. 69a), the two bends using an elongated hole connection ( 100M in Fig.6 69a, Fig.78) or sliding connection or spindle drive are adjustable in height, which allows an adjustable height adjustment (100H, Fig.79) of the rear cushion relative to the front cushion for lowering; e.g. fixed with wing screws (701), the liability e.g. can be optionally reinforced by hook and loop connection between the superimposed flat surfaces of the angled plate edges, or by servo control, as described later. * The back pillow sticks to the plate along a hipp line, which is made by Velcro tape KLT aa cover of the pillow (see front description part). * The rail guide on the table is preferably fixed using tablecloth clamps (702) or screw clamps (702-ST) and / or by suction cups embedded in the support surface of the rail or by removable adhesive tapes. * The tablecloth brackets (702) have a Velcro or mushroom tape coating on their top that adheres to the fleece tape strips attached to the underside of the rail guide, or can be inserted into the long side parts of the sliding surface frame, as described below (Fig. 91a and Fig .91b). * According to the front part of the description, the guide groove of the rail guide is by no means aligned in a straight line, but can have a curved fora, such as that of the ergonomic fora of modern keyboards (see front part of the description and Fig. 107, Fig. 110, Fig. 88. Fig. 86) .- * Heiters right and left pillow can also run on split or angled rails, the left rail part is shorter because of the missing function key block. * For keyboards whose key blocks are lined up in a non-straightforward fora, the long side of the sliding surface, which corresponds to the rotation stop of the slide plate for the sliding elements, and the guide groove (or guide web) are adapted to this fora. * Another variant is to provide the underside of the lower cushion of the rear cushion with sliding elements and to support it on another sliding surface (Fig. 87b). This further sliding surface can, for example, attached to the underside of the rail guide (e.g. the foil laminated cardboard) (e.g. using Velcro), or inserted laterally, with level adjustment an adjustable height adjustment for the support plate of the rear cushion, between the further sliding surface and the rail guide, by means of set screws, or spacer plates, or an automatic adjustment by means of a horizontal joint connection axis (GLR in Fig. 87b}. * Other variants are that the further sliding surface is angled on an extension of the long side of the table that lies vertically downwards on the table edge Sliding surface ridges (102, 704 in Fig. 87b and Fig. 87c) to be attached via slot adjustment (701), or a motorized height adjustment of the rear cushion (lH), as will be described later (see Fig. 77). Another option is the further sliding surface of the rear cushion with its own rail guide (99-H), which is identical to the Rail guide of the front cushion (99-RV) is designed to provide (Fig. 87c). * Several variants are provided for the variant with readjustment by motor drive for motorized support of the cushion displacement: * a) front cushion and / or rear cushion have a hegaufnehaer (equivalent to Fig. 76h), * b) front cushion and / or the rear cushion are motor-driven (see Fig. 79, Fig. 89 and Fig. 93 with Fig. 78) * The two options from (a) and (h) can be combined according to the respective needs, e.g. by the Wegaufnehaer of the front pillow, the front pillow itself is motorized, and / or the rear pillow is also controlled accordingly; ditto optional, the rear cushion adjusts itself by another own Wegaufnehaer, or also participates in the adjustment function of the first cushion. * To generate a controlled variable, a small amount of movement {VSP} in the longitudinal direction of the keyboard (or also in other directions see later) is provided for the path of the cushion, in addition to the coordinate-compatible displaceability {VSP} of the movement guide, with sensory implementation of the displacement path within of this movement game, into a controlled variable. The additional displaceability (VSP) is generated by keeping the guide elements at a distance from the guide edge or by another slide attachment). * In a further exemplary embodiment, the movement play {VSP} is generated by a frame, the opposite sides of which form the guide webs for the displacement of the cushion to the keyboard front (perpendicular to the keyboard front) and the other sides (parallel to the keyboard front) the stops for the displacement. In a further development, this rail is inserted into a further outer rail, the inner rail having a play {VSP} within which it can be displaced to the guide sides of the outer rail (for example perpendicular to the keyboard font). The sliding ability of the inner frame on the slide surface can be further improved by sliding elements or balls. * The detection of the displacement of the cushion within the movement play {VSP} to the stationary guide webs on the slide plate is determined by an inductive sensor, e.g. Principle of the armoring measurement of a coil on electr. conductive substance, e.g. Sheet metal strip, use is made, and the sheet metal strips can also be attached directly in the cushion (air cushion) instead of the relevant frame (for example, also without the frame when directly scanning the frame) Rocking movement of the pillow or use of elastic straps for the pillow support, straps e.g. provided with metal mesh or pillow case itself with metal mesh). The sensor is designed in such a way that the following movements of the inner frame relative to the slide plate can be distinguished: displacement parallel to the right or left, or rotation. For this purpose, metal sheets are arranged on each corner of the Rahaens, with suitable scanning coils provided on the slide plate. The hedged vibration is converted into an actual value (see above), the actual sizes of the coils lying diagonally opposite as well as the coils directly opposite each other being given to a differential amplifier, so that a parallel displacement of the slide as well whose rotation is recognized as analog voltages of the differential amplifier outputs. Uses aan as actual size e.g. the output frequencies of voltage-controlled oscillators (VCO) as signal converters for the application measurement and measure the frequencies or their period with a microprocessor, then the difference can also be evaluated directly. * As described above, the motoric movement control of the cushions is carried out by means of cable pulls in such a way that the sensed displacement of the cushion is compensated for directly, or via its guide frame, whereby the displacement movement is controlled by hand on the one hand via a very small and low-friction displacement path (displacement play VSP) is (sensed by the sensor), on the other hand it is motorized (without the application of force of the hand) over long distances with constant adjustment of the displacement play (VSP). * It is evident that, in addition to the simple longitudinal displacement of the pillows, the twisting of the pillows can also be assisted by servo-motor, the twisting of the pillow movement by means of the frame or a specially provided radial twisting (by means of play and sensible scanning of the end points of the game) is scanned, a servo motor executing the rotation directly or via cable pulls accordingly. * Furthermore, it is evident that only simple stop contacts (for two-point control) or springs (e.g. inductance measurement of spiral springs) can be used for the sensor. * The current supply for the sensor scanning, if necessary also local drives, including their control signal supply and the signal routing of a serial digital sipal emitted by the sensors, is carried out in a further development variant with two poles via the pull cables (45, 46), which as the guide element (in the guide slot), which also each form the axis of rotation (98b) of the slide plate, pull on both sides (via sleeve 98S, Fig. 79). * For this purpose, for right and left pillow e.g. Separate guide slots (X1 and X2), which are separated from one another by an insulating web (99M) for the bare pull cables, can also be used (see Fig. 9ö), or the rails are divided accordingly (see Fig. 88) into areas for right hand and left hand, whereby on the inner ends of the rails, where the areas of the right and left hand meet, Uale rollers (49/48 UR) are provided for the pulling cables (45, 46 each for each side), the drives therefore on the outside can be attached to both sides of the keyboard (inside housing 54, Fig. 88 and Fig. 89). * The two-pole signal routing (KIS, K2S, Fig. 89) of the signal coupling of the supply voltage and sensor signals, which is carried out jointly via the pulling ropes, if necessary also control signals, for additional servomotors that are self-contained on the slide plates, takes place e.g. Via a central clock signal, which can also be supplied to several participants (on the sled plate electronics), for a short 2 to 1 intervals according to a time protocol, the clock dipal supplied otherwise by the power supply coupling of the pull cables is switched to bohemian and by participants connected to the pull cables., (cer Sledge ..? Lat- tenelektronik E der Kissen) is continued in a timely transmission. * The supply voltage is obtained from the rectified clock signal, furthermore the clock signal contains phase jump encodings (such as, for example, home a modulo-2 method or modulo-n), the duration of which indicates the use of the state indicated by the phase jump, for example, that the polarity of the serial data changes, or a defined pause follows, in which a participant transmits sensor data to the control center, or reset pulses for the internal counting clock of the participants, which e.g. by wired-or link to certain meter readings, transmit these meter readings to a central office, as an alternative or supplement to direct serial data transmission or addressing. The synchronization for the respective bus connection of the participants is carried out by the counting clock (= data clock, e.g. a modulo 2 process), with pauses according to a mandatory sequence in which the participants switch on one after the other and process a protocol. * Another form of cheerfulness relates to attaching a compartment to desks where the keyboard is set up, among other things to quickly accommodate the pillow device under the desk. It is customary to provide pull-out compartments for this tick. A preferred embodiment of the cheering education relates to the Merkaal, that the compartment for the installation of the pillow device can be pushed under the desk on the one hand, or, in an alternative further development, can be folded out of a use fixation, and in the inventive design can also be moved along the length of the table edge of the desk, so that the supporting device can be pushed along the desk at any time. The above-described sliding element principle is used as a rail guide, the sliding elements being supported on both sides by sheet metal

Rail rails are included which sandwich the sled plate that receives the cushion assembly. * Exemplary embodiments are described below with reference to the figures; the description is not made chronologically according to the figures, but expediently according to technical function. The dimensions entered in am are guidelines for preferred versions. * Fig. 97 shows an oblique view of the front (1-V) and rear (lH) pillows, with the rear pillow and front pillow each sliding on a rail surface (99 front and 99H rear). The rear rail is set at a corresponding distance (100V) to the rear and further down (100W), which gives the rotatability of the rear support surface of the cushion (100AP) space and also by lowering the rear support surface, the level of the rear cushion, which at of the hipp pillow version (hipp roller), to which the front low pillow is well adapted. This adjustment is carried out in different variants individually by hand, or motorized, or also motorized, adjustable. * Variant according to Fig. 97 relates to an embodiment in which the rear cushion follows the hand movement in the longitudinal direction of the keyboard front or the rail by means of an automatic servo drive. it is possible to fill the pillow with a liquid instead of air, since the high inertia of the pillow is compensated by the motor drive and does not strain the hand. * A very cost-effective variant with a combination in which the front cushion (1-V) is designed to slide on a sliding surface both along the keyboard and against the keyboard front in the form of a flat cushion, and the rear cushion (lH) as a hippkissen, especially filled with air, with a static coupling of the support surface of the rear hippkissen to the lower slide plate of the front cushion, guarantees the following advantages: * a) the hipping process of the rear cushion is transferred to the front cushion in this way, that much of the potential energy, which is caused by the weight of the hand, is converted into kinetic energy by the steered movement of the hand, * b) by the light design of the large-sized rear cushion as an air cushion and the small, low front cushion with the filling of a floating, soft round plastic granules, the back cushion follows the front cushion almost without inertia, furthermore the granulate filling of the front cushion results from the interaction of the granules floating in a liquid and the pressure applied by the rear hipp cushion, which is a fine hand massage due to the low Edition pressure is perceived as pleasant.

Fig. 87 a, b, c and Fig. 78 illustrate different design variants, whereby Fig. 87a shows a variant in which the support surface of the rear cushion is flanged to the support surface of the front cushion and the support of both cushions only on the sliding surface of the front Pillow is carried out, therefore the underside of the slide guard in the slide slot is loaded against the underside of the sliding surface, depending on the respective hand position. * * In Fig. 87b, on the other hand, the support surface (100-AP) of the rear cushion is additionally supported by a further sliding surface (100-UP), which is supported by the uprights (102) of the front sliding surface (via vertical extension 704) . * Fig. 87c shows the side view of a variant with double rail guidance, each with its own sliding surface rulers for front {1-V with 99-RV] and rear {l-H with 99-H] cushion, corresponding to the oblique view in Fig. 97. If, on the other hand, Fig. 97 is carried out according to variants corresponding to Fig. 87a and 87b, then the sliding surface ruler of the rear {99-H] cushion is omitted, or for the variant according to Fig. 87b, a ruler is used instead of the sliding ruler for the further sliding surface (100-UP ), see. also Fig. 115. * Fig. 78 shows the side view of an embodiment according to Fig. 87a, with this variant the sliding surface (99) of the rail guide both on its underside via the anti-pull protection (plate 98 or part edge) of the guide element aa edge of the guide slot (99-f , Slot X) is loaded, as well as from the top (via skids 101). Guide element {98} slides in slot X and at the same time forms the axis of rotation of the lower slide 100, on which the further slide for the transverse movement of the cushion (1-V) is placed in the direction of the keyboard front. * The pivot point is therefore made on the lower slide, while the upper slide allows the hand to be moved towards the keyboard (in conjunction with the tilting movement of the rear cushion) in any rotational position of the cushion. By optimizing that the pivot point of the front cushion is on the lower slide, it is possible to directly contact the support surface (100AP) of the rear hipp cushion (1-H) via the height adjustment (701) by a simple angling (via extension 100V) flanged the lower slide plate (100), thus allowing the rear hipp cushion to rotate well without an additional sliding surface for this cushion and also keeping the leverage for loading the trigger lock 98 (at point 99-f) low (Fig. 78), furthermore, by using a hipp pillow for the rear pillow as a macaw support, the leverage of the macaw moving back and forth in the direction of the keyboard front is limited when the hands are movable for typing. * Due to the simplicity of the design, the variant according to Fig. 78 corresponds to a cost-effective, function-optimized version. * Details for design variants of the upper slide (100S) for the front cushion (1-V), with slide runners (101-0S), placed on the lower slide plate (100), are shown in the figures Fig. 69a, Fig. 76b, Fig. 83 and Fig. 93. * Fig. 82, on the other hand, shows the lower slide plate (100) with the slide guide removed for the upper slide (cf. 100S in Fig. 69a) * The upper slide is guided according to a structure according to Fig. 83 or Fig. 76b so that the vertical pins (101b) of the guide elements (101-0S), each of which is closed with a plate acting as a trigger protection, for both

Guide sides of the upper slide are enclosed with side rail guide edges (99B), the front edge and rear edge of the lower slide stops (see stop bars or pins, 703 and 705 in Fig. 93, Fig. 97 and Fig. 69a) for the guide elements has to limit the displacement of the upper carriage. * In addition to the variant, the upper slide {100S} directly on the underside of the plates that act as a pull-off protection (101c in Fig. 83 or 98B in Fig. 76b) of the centering pins {102b from 202-OS, cf. Fig. 83] to slide on the sliding surface of the lower slide is, as a further variant, air.e spacing between the underside of the sliding plate (98B) and the sliding surface of the lower slide intended. This spacing is carried out by skids (löl-GS), which are attached to the underside of the upper carriage on the underside of the guide elements (101-OS) on both sides and only provide vertical spacing support. Lateral support is provided by pins {101h}. * In both variants, it is possible for the extension option of a motorized readjustment to provide the upper slide with a play of movement {VSP}, as explained above, and which is sensed by means of an inductive arming sensor, among other things to obtain a directional magnitude into which the lower slide Aotorically must be readjusted, among other things, to compensate for the frictional force between the lower slide and its sliding surface (99). * Designs according to Fig. 76b and Fig. 83 can be designed to slide in Paßfora either with sensor scanning of a movement game {VS?} Or without movement play. * The differences of the variants according to Fig. 76b and Fig. 83 relate to configurations in which, in Fig. 83, the lateral mobility (VSP) of the upper slide plate by appropriate distance of the guide elements (101-0S) from the cross rail guide edge (99B in the direction to the keyboard front) takes place directly through the guide elements (pins 101b from 101-OS), while in the variant according to FIG. 76b, the guide elements (101-0S) for the lateral rail guide (99-B) have a sliding fit fora, and the lateral rail guide as sides of a carriage (RM) are formed, within which the guide elements (101-0S) slide and lie against the inside of the carriage. For this purpose, the outer sides of the rahens (RM) have a movement movement (VSP in Fig. 76b) to further guide sides, which are placed on the lower slide plate (löö). In variant nan Fig. 76b there is also additionally a rail (RM) with movement play (VSP) inserted between the lower slide plate (100) and the upper slide plate (100S), this rail also on skids (RMGL) or balls (KGLn, Fig. 96) is supported, which slide on interchangeable slide plates, for example. * The scanning of the lateral movement of the upper slide plate within the movement play (VSP) is carried out for both variants in such a way that metal sheet strips (33), (in Fig. 83 on the underside of the upper slide plate 100S, in Fig. 76b on the underside of the frame) are applied , on which a (Hirbelstrom) arming measurement is carried out by means of coils (of electronics E), and the aaplituden armamentation carried out by electrically conductive sheets (33) is assessed as a measure of the displacement VSP. * The electronics (E) with the sensor coils are then housed, for example, inside the rail guide (99B) of the upper slide, which is placed on the lower slide {99), or in the remaining clearances of the lower slide plate. The signaling of the traction ropes to the sled plate takes place according to Fig. 79, whereby the guide element (98) has a hollow axis (98b) through which the contacted connections of the traction ropes (45, 46) lead from below (AZSU) upwards (AZSO) are. * Cheers can only. the sliding part of the pillow ball can be mounted in an additional movement game {VSP} (in ball grooves, see front description part) and by motor support of the steep movement elements mounted on sliding elements, the sensitivity of a ball-mounted support device for the movement of the pillow can be achieved for the seeded device (see Fig. 96). * Likewise, e.g. as an alternative, the rear cushion (2-H) can also be made displaceable in the direction of the keyboard front by means of rails-guided device, additionally or alternatively to the embodiment as a hipp cushion. * Fig. 76b shows an embodiment in a further development with a balance, by means of which the contact pressure of the hand aa front pillow (1-V) for the tick of an automatic adjustment of the height adjustment of the rear pillow (lH), (see Fig. 77 below), the following is measured: For this purpose, the upper slide plate for the support surface of the cushion (1-V) has a frame opening (or uses frames already provided for cushion guidance) which is covered by a flexible plate (633) made of spring sheet metal or a flexible plastic plate coated with metal, this plate (633) forming the contact surface of the cushion, with a deflection corresponding to the contact pressure of the cushion. This deflection is measured via an underneath coil (L6) arranged in the window of the support surface, which performs a de-arming measurement on the metal plate (633), as is the case for plaguing the displacement of the upper carriage plate within the VSP play (optional or supplementary) ) he follows. * Fig. 79 illustrates a proposal for attaching the pull cables (45, 46, see also advance notification) directly to the guide element (98) of the lower slide plate via a bushing (98S), in which the guide element extends via its vertical guide pin (98b ), is rotatably mounted. Fig. 82 shows an example of the plate of the lower carriage (100) (front cushion) according to the drawing in accordance with Fig. 69a. {703-KLT} and {705-KLT] are hook-and-loop fasteners to the fleece surfaces that adhere to them, for example, as shown in Fig. 93: these plates each have the stop bar (703 and 705) at their end to limit the displacement the upper carriage plate.

Fig. 82 further illustrates how the skids are inserted into the plate: the skids (101) each consist of slidable material (e.g. P0H) in pill form (Fig. 82b), which protrude from the underside of the plate towards the sliding surface. These pills are each inserted into a slot sawed into the edge of the plate (101 ES, see also Fig. 79 right), this slot being closed or covered on the top side of the plate (bar or sheet 101-HLA, FIG. 79) and is closed or covered from the edge on the underside (101-HLT, see also Fig. 84 and Pig.85), so that the pill on the one hand voa sawn slot (101ES) of the plate, on the other hand from the Cover strips is included. As shown in Fig. 82, the slot (101ES) for the sliding pills {101} is inserted in a kinkel {y], which is dimensioned such that the flat end face of the sliding pills abut the edge strip which acts as a stop for the sliding pills when the slide plates are turned to the stop position. The round cylinder sides of the pills act as skids or rollers, the sliding pills also being able to have rolling axes (for example also for cross slides) or being inserted in a fixed manner. * Below is a compilation of the Fipren, which relate to the previous chapter of the description, with further explanation of the reference names, if they have not yet been explained. * Fig. 69a shows a top view of the sled combination of lower (100) and upper (100S) sled with the pillow removed (Velcro hand connection KLT) with flange plate 100AP for the rear pillow. * Fig. 77 shows the continuation of Fig. 69a regarding the flanging of the rear cushion (lH) with top view and side view and rocker line KLT (loop tape, adheres to crossed Velcro / mushroom tape band 40a, leather-covered plastic strip (HSL) also adheres to the underside of the fleece at 40a (adjustable). * In Fig. 77, a proposal for the motorized height adjustment of the rear cushion (lH) is shown as an alternative to manual adjustment (see wing screw 701): for this purpose, the elongated slots of the height-adjustable parts joined together are shown (100M and 100N) replaced by a dovetail or a similar fitting of the parts, or directly by adjusting a motorized spindle drive (M5a, M5b) in an adjustable, static way (see Fig. 109), as is the case in Fig. Version 77 shows: two Motors arranged next to each other (M5b behind M5a; M5b is covered by M5a in Fig. 77, see also Fig. 109) rotate in opposite directions a threaded sleeve / spindle combination, one of which has a left-hand thread and the other has a right-hand thread, which means that the rotating ears of the Spiadela are the same linear feed paths are compensated. * The spindles are screwed into sleeves, with one end of the threaded spindle sleeve combination (LN) being flanged to the motor axis and the other end to the underside of the contact surface (100ÄP) of the rear cushion (see also Fig. 109). The motors are controlled by a circuit board (electronics E with ICs IC, see also Fig. 56a) arranged on the underside of the cushion support surface (100AP); the motors are attached to the lower extension (100K) of one of the two slides of the front cushion (e.g. lower slider 100). * For the variant of the motorized adjustment, a distinction is made between two variants, one in which the adjustment takes place with the hand raised and the device works with motors of lower power and light weight, and a second variant in which the motor power is sufficient, including an adjustment when the motor is on To be done by hand. In both cases, the threaded spindle sleeve combination (LN) is self-locking. * In Fig. 77 it is also indicated how the underside of the connecting surface of the contact surfaces (100M, 100N) of the rear cushion and front cushion at the point where the motors are mounted, with a further sliding surface which is fastened to the front rail guide is supported. In addition, the support of the support surface (100AP) of the rear cushion is still possible (with 100-UP in Fig. 87b) or by a further rail guide of the support surface of the rear cushion, as explained for Fig. 97. * In a further variant, the front cushion is equipped with a pressure sensor that eats the contact force of the hand placed on it, whereby this can be done absolutely, or relative to the contact force of the arm on the rear cushion, optionally via a further pressure sensor for the support of the rear cushion. * If sufficiently powerful motors are used for the height adjustment, the automatic readjustment can be carried out immediately based on a measured mean value of the contact force of the hand, if only small motors are used, then the adjustment can be activated in a separate process, e.g. when the user adjusts the height of his seat because this changes the distribution of the front and rear cushion contact forces. If the readjusting function is switched on and the measured mean value of the contact force distribution deviates from its target specification, an acoustic signal sounds from a piezo signal transmitter, whereupon the user removes his hands from the pillows. After the pressure sensor has determined this, the motorized level control begins immediately with the corresponding incremental adjustment, e.g. in approximation to binary weights (starting with the largest weight) after a successive apaaximation (corresponds to the well-known A / D converter principle). For each weighted approach step, the user is prompted with the signal to put his hands back on the pillow or to remove it after the approach measurement has taken place, the user being able to type a sample text into the keyboard, for example, during the measurement period. This adjustment takes place until the specified target value of the contact force is reached. * The adjustment procedure is initiated, e.g. at the push of a button. The signal to request to put your hands on the pillow corresponds, for example, to the rhythm of a free tone signal (official tone) from a telephone, and the request to remove your hands from the pillow again corresponds to the busy tone signal. When the adjustment process is finished, you will hear e.g. a mixed signal (short-long, etc). * Another variant is to install a voice signal chip for the instructions, e.g. furthermore for the acoustic announcement of Combinations of digits entered with the keyboard can be used, whereby the decimal point starts the announcement of the number before the comma and the second digit after the comma starts the announcement of the core after the comma. * Further details for the servo according height adjustment of the

rear pillows are described in Fig. 109. An exemplary embodiment for measuring the contact pressure aa front cushion is shown in FIG. 76b and has already been described for this figure in the preceding part of the description. It is evident that this principle can also be applied to the back pillow as a supplement or alternative. * Fig. 78 shows a side view of the combination and Fig. 69a and Fig. 77 with the areas HA for the wrist-rest aa or in front of the wrist and AA for the macaw-rest behind the wrist. * Fig. 79 shows an example for attaching the cables (45, 46) aa guide element (98) with contact feed-through from the bottom (AZSU) to the top (AZSO) to the slide plate. The cables are insulated on the sleeve 98S, which forms the pivot bearing for the guide element (98, rotatably inserted in 98S) of the lower slide plate (100) (for example, by plugging together two mutually insulated sleeve disks with a fastening disk for each one inserted between them Cable pulls (including soldering lugs for contacting); e.g. hooked into rings, results in contact through the opposite pulling force of the cable pulls (the differential force control of right and left cable pulls). * Fig. 80 shows a side view (section) for the preferred one Design using interchangeable plastic strips for the sliding surfaces, both for the top and for the underside of the rail guide surface. On the upper side, the strips (99-0) are inserted on the contact surface (99) of a rail (102) which is passed through the outside protruding edge strips (102) and on the inside by the rotation axes (or-F forming guide elements 98) of the lower slide plates, the lateral fixation of the strips (99-0). A further additional fixation is provided by the preferred stop strips (ZPF, Fig. 81), which are inserted as end pieces (ZPF, Fig. 81) at the lateral ends of the sliding surface in the guide slot. Since the axis of rotation guided in the guide slot (X) (from n 98, see also 98b in Fig. 79) with no sliding support of the rear cushion (see alternatives shown above) on its underside, with the sliding plate acting as a trigger safeguard (98) presses against the edge of the guide slot on the underside (cf. 99-f in Fig. 79), the narrow strip, which affects this process on both sides of the sliding plate {98} (underside), is designed as an exchangeable sliding surface strip: 99U in Fig. 80. For this purpose, the boundary webs, which support the edge of the guide slot on the inside (103c), including the thickness of these sliding surface strips, are kept lower, so that the lower sliding surface stiffeners (99U) enter the resulting slot between the upper side of the boundary webs and the underside of the support surface ( 99), can be inserted from the side. This is done through the slot (cf. B in Fig. 81), a side bar of the rail, which also forms the insertion opening for the guide axis (98) of the slide (100). The lateral fixation of the sliding strip (99U) inserted on the underside of the guide slot on the underside takes place along the guide slot by the axes of rotation (98) of the slide plates guided in the guide slot and the end pieces inserted into the slot (ZPF, Fig. 81) and also by the lower held Be - Border webs (103c) placed next to additional support webs for fixing the support strips (99) of the sliding surface (99-0). An alternative to the lateral insertion version of the exchangeable sliding strips is described in Fig. 110, in which the rail surface is open in the longitudinal axis. * Fig.δö also illustrates measures for the

Extension option in which the guide element (98) presses the axis of rotation of the lower slide onto a capacitive length scale (see front description section), which can be specified on the underside or on the top. The capacitive length rod (e.g. sawtooth oyster) is then applied directly to the underside of the relevant interchangeable sliding surface (from 99-0 or 99-U), which e.g. can also be carried out by printing with a paste within a double film, it being possible, as an alternative to evaluating the capacitance (cf. advance notification), to evaluate the ohmic resistance (measured via the capacitance of the guide element). {F98] ... or {98-GL} are correspondingly electrically conductive washers and pressed against the capacitive scale (insulated) by spring force. The detachable contacting of the capacitive scales on the exchangeable sliding surfaces (from 99-0 or 99-U) takes place e.g. via eyelet contacts or capacitively via large contact areas (to contact surface {99} which is contacted with a fixed connection). * The use of a capacitive scale, the capacitance value or ear-seer resistance value of which is capacitively short-circuited by an electrode of the guide element of the slide plate sliding on it, the stationary length of the short-circuited electrodes resulting in the length of the slide being driven is advantageous if the sled plates have no signal feed devices and no pull cables. (Alternative e.g. optical scale). For cursor control (see above, it is sufficient if the cushions are scanned for only one hand in their traveled path length). * If the pull rope variant is used using the trailing principle according to the invention, then the sliding path of the slide plates can also be tapped via the unwinded pull rope length for the purpose of cursor control (see advance notification) (see Fig. 45). * If necessary, the variant according to Fig. 79 can also be designed according to Fig. 80 with exchangeable sliding surfaces (99-0 and 100U). * Fig. 81 shows ^~ e the end pieces (ZPF) are inserted into the guide slot (X) at both ends of the rail guide (only one side shown). Preferably, the end piece (ZPF) designed as a short strip piece has a right-angled transverse bar (LA) for one side of the rail guide at its outer end end, through which the end piece forms a T-neck, the T-neck in the insertion slot (B) of the guide element of the relevant side bar is inserted {cross bar LA over length BZ according to FIG. 71c to match insertion slot B). * As a further special feature, Fig. 80 shows the return path for the U-steering of the cable (45,46) by means of a guide groove (XRF), if this variant is used (see Fig. 88, Fig. 89, Fig. 90) ); 103d ... rounding the inside of the web of the guiding slot X if cable pulls are used. * As shown in Fig.δl and in the oblique view according to Fig.71c the end strip in question, the cross bar (LA) is set slightly higher than it corresponds to the plug connector ZPF

(e 99-0 = plane of the upper sliding surface strip); the bottom edge of the connector strip (ST-1Ö2B) is therefore supported on the side frame strip (102B in Fig. 81). * The projecting shoulder of the T-piece (ST99-0) again forms the side cold of the sliding surface strip (99-0). * For the other side of the rail, a simple short bar without a T-neck is sufficient as an end bar. * Fig. 82 shows the lower slide plate without cross slide guide part (see 99B in Fig. 69a). * As a further special feature it is shown in Fig. 82 that the sliding pills (skids 101, see also Fig. 82b) are inserted into the slide plate at an angle (y) which is dimensioned such that their stop is aa planer. Margin (SRND in Fig. 82b) of the pills on the protruding longitudinal bar of the sliding frame (see bar 102 Fig. 69a), lies flat against the inner edge of the bar.

* Fig. 83 and Fig. 76b illustrate the cross slide placed on the lower slide plate in the variants already explained above. As a further special feature, a fastening sleeve HUS is provided in FIG. 83 for the formation of the rotational axis 98 made of POM (with spacer S) sliding in the guide slot (cf. X in FIG. 97 of the sliding surface), which fastening the fastening via adhesive or screw connection Axis of rotation reinforced on the underside of the slide plate. An alternative is to secure the upper fastening plate of the sliding element directly with screw fastening. Η Furthermore, it is shown in Fig. 83 (below) how the relatively thin vertical pins (neck) of the guide elements (101-0S, made of plastic POM) of the upper slide, each of which is closed with a plate acting as a trigger protection, prevent lateral bending by sheet metal or other Plastic plates (BLC1 and BLC2) are supported. For this purpose, plates are screwed onto the underside of the upper slide (iθOS), each of which has a slot (SLC) into which the neck (101b, Fig. 83 below) of the guide sliding elements (101-0S) used as guide pins is pushed in, the plate pressing onto or covering the heads (101-0S) of the sliding elements countersunk in the underside of the slide plate (100S). * Fig. 84 illustrates how the sliding pills are inserted into the underside of the slide plate (100) and thus form skids (101, same as 101-GS for 100S upper slide plate). * Fig. 85 shows the corresponding side view of Fig. 84, 101-ES means the incised slot for inserting the pills 101 (shown in Fig. 83 as cross-hatching). * Fig. 86 shows the use of the device on an ergonomic keyboard with a curved front line, the strip of the sliding surface of the rail guide (99-0) including the guide slot (X) and Rahaens (102) having a curve form parallel to it. SP ... intermediate area

Keyboard for right and left hand enables equivalent splitting of the splint into R part for right hand and L ... part for left H hand. Furthermore, the table edge TK is drawn in Fig. 86. * Fig. 88 shows an example with the splitting of the rail into two guide parts for right and left hand separately, which has the advantage that the flashing pull cables of the sled plates from the right hand and left hand do not need an insulation bridge (in contrast to the example shown in Fig .90). As shown in Fig. 88, the front long side of the curved rail of the rail sliding surface partially projects beyond the edge of the table, the underside of the rail sliding surface being supported by clamps, such as are used as tablecloth holder clamps (702), or the clamps (702ST) in serenity an additional screw support is still modified (see Fig. 114 below). * Fig. 90 shows the variant with an insulation web (99M) for the pull cables provided in the guide groove * whereby the articulated pull cables are returned on both sides of the long sides of the rail catch (see XRF in Fig. 80) and the bare on both sides of the insulation web , strobe-carrying cables run. The cables for the feed are contacted e.g. Via contact springs attached to the conductive traction sheave axles, the contacting of the slide plates is described in Fig. 79. Pig.87a, -b and -c illustrate side views according to the variants described above. KLT-702 ...- Velcro or adhesive connection holds the underside of the rail guide to table bracket 702. Furthermore, mean: KLT2 and KLT3 are Velcro or mushroom tape strips glued to the underside of the leather pad LD, which on the one hand aa fleece tape aa front edge of the top slide of the front pillow (1-V) stick (KLT-2, see matching fleece strip KLT-2 on the top slide plate in Fig. 69a), on the other hand stick to the fleece surface of the back pillow (KLT-3 to 1-H), whereby by Attaching several parallel Velcro strips (KLT3), the piece of leather from the front pillow to the rear pillow (LD) can be stretched accordingly (Fig. 87a), but as an alternative to this, separate leather pieces for the front and rear pillows (see LD2 in others) Pipren) can be used. Thanks to the Velcro strap, the leather cover variant for the front and rear pillow is easily exchangeable, in particular the variant for the support of the front pillow with a window (1-FV) with Velcro tape on the underside to improve the grip on the front granule pillow (see Fig. 9). Fig. 87b also illustrates the variant in which the support surface of the rear cushion (100-AP) is coupled to the front cushion via a joint (GLK, hinge with axis parallel to the keyboard front line) so that the rear cushion is connected to the additional support surface (100 -UP) slides safely. * Fig. 89 illustrates the deflection of the traction cables, which is always tensioned by counter-control of the drive rollers (48, 49), by means of deflection rollers 49UR and 48UR, which is particularly suitable for a split keyboard (see Fig. 97) (see the previous description), or also for a version according to Fig. 90. * K1S and K2S are sliding contacts or spring washers, which carry out the Sipal feed on the bare pulling cables (45 and 46) on the electrically conductive winding rollers or their axes. The uncoiled pull rope length can also be measured, for example, by means of the tapping measurement of a coil spring inductance, which lies against an insulated metal disc, as already explained in the front description part. * Fig. 97 shows an oblique view of the seeded device with separate sliding surface for the front and rear cushion, the rear cushion being slightly raised at the back to support the rocking roller of the cushion (1-H), which is only partially filled (bar HSL). Leather piece LD2 of the front pillow 1-V has a window through which the granulate pillow, which is filled with foil, protrudes, adheres with Velcro strips (hatched) aa window edge on the underside of the leather pad; LD2 is separate from leather LD of the rear pillow; or continuously connected LD2 to LD). * Fig.91a with Fig.91b and Pig.91c illustrate preferred variants for the tilt-proof fastening of the rail guide strip (99 with frame 102) directly above the table edge (TK). The variants have the following function in common: The usual tablecloth clips used as retaining clips (702 e.g. made of transparent plastic or steel sheet clip 702SΪ according to Fig. 114) hold firmly on the attached table edge, but would be unstable against lateral twisting. It is therefore intended to provide the underside of the rail guide strip with rubber seals GF, which press the upper bracket part (702-O) of the holding bracket (702, 702ST) firmly onto the table top. The further measure of a guide web (704) on both sides for the upper clamp part (702-0) within the rail guide strip ensures that the clamps are turned laterally and good adhesion of the rail guide strip is ensured with quick disassembly. Furthermore, the adhesion of the rail guide strip can be strengthened by means of removable adhesives (see Fig. 113) or improved by screw clamps (see Fig. 114). * Fig. 91c shows a variant in which the upper bracket part (702.-0) is attached to the outside on the underside of the rail guide strip (103), with side guides or webs (PF), which also, for example, also the pressure surface made of rubber (GF) can form. * Fig.91a with Fig.91b, on the other hand, illustrate a variant in which the upper bracket part is inserted into a slot {102-F), which is provided on the longitudinal part of the rail guide strip (102) at appropriate intervals, and on the bottom side of the Presses the rail guide strip on the upper side, FIG. 91a showing a top view from FIG. 91b below, with section SC-SD; and FIG. 91b below shows a side view with section SA-SB from FIG. 91a. Fig. 91b above, shows a side view of Fig. 91b on the right, which again represents a section through the table edge TK for both variants (see option of 702, 702-0). * The insertion slots (102-F) embedded in the long side (102) are preferably arranged so that the underside of the upper bracket part (702-0) rests on the top of the bottom (103) of the rail guide strip, as in Fig. 91b below shown, the webs (103b and 103c, see Fig. 80), which provide the support for the rail sliding supports (99), are dimensioned in such a height that an intermediate roughness (ZWI) is created above the upper bracket part, which is sufficient is, among other things, the lower sliding surface strips (99U) still slide over, where at the points where the clips are to be inserted into the insertion slots, the webs have interruptions, and among other things to facilitate the insertion of the clips, lateral

Cross guide webs (704) are provided in the insertion direction of the clamps (to the longitudinal direction of the rail guide). * Another preferred measure is to provide the underside of the rail sliding support (99) piece by piece with pressing surfaces above the insertion points of the brackets, which fill the intermediate area (ZWI) above the upper bracket part to such an extent that the upper bracket part in the insertion slot is firmly crimped from the top on the one hand is, on the other hand, outside of this pressure area of the intermediate area to insert the narrow strips of the lower sliding surface (99U) on both sides of the guide slot X; (cf. inner boundary lines of the lower sliding surfaces in Fig. 91a, within slot X, the lower sliding strips 99U not being shown (drawn out) in Fig. 91a. * Fig. 92 illustrates how the device (102) rail sliding supports (99 ) is inserted in another frame (99-ADPT) (e.g. with Velcro tape or checked by Klaamer), which is constructed like the rail sliding pad, but without a guide slot, and to increase the cushion device for use on typewriters is used by TK ... Table edge}. * Fig. 93 illustrates an example in which the lower slide plate (100) is covered with Velcro strips, for a surface to be adhered to the Velcro strips, at the ends of which the stops (705 or 703) which can be removed via these surfaces are inserted the upper slide plate are provided in the rail guide (99B). * Fig. 94 shows a variant in which rollers (RL) ver which include the sliding surface or rolling surface (corresponds to 99) like a sandwich (secured against rotation by parallel connecting webs 98), KGL being a ball bearing for the possibility of rotation of the slide plate. * Fig. 95a with 95b shows a circuit proposal for the two-pole (K1S / K2S) signal transmission via the pull ropes (45/46), whereby the electronics on the sled plate continue to be distributed as required and by continuing the two-pole cable pull busbar to other participants fixed transmission center (S housed in housing 54 in Fig. 88) can be interconnected. * The circuit of the participants corresponds to Fig. 95b, each with a microcontroller uP-E, which works in bidirectional nal direction a serial data signal DAT (for example, modulo 2 signal) sends or receives (SE / EP) and further the voltage supply of the subscribers from the serial power data signal received is fed (rectifier D with capacitor CS), during a return process of the receiver this supply voltage supply is switched off (via S, electronic switch), which means that the load on the receiver is too high. The receiver circuit is only supplied by the fixed transmitter {S} with a power data dipal, the voltage VCC rectified in the input receiver {EJ being fed to the electronics as a supply voltage via a step-down regulator or converter, and the (higher) voltage of the power data signal in a storage capacitor ( CS) is buffered. In addition, the receiver circuit has a watchdog timer circuit for monitoring the data signal over time, and if the transmitter circuit is interrupted (detected by time interval detection in the UP), the receiver circuits send them back to the fixed transmitter circuit at specified times in accordance with the protocol if they have been addressed beforehand . Data and addresses are arranged in a sequential order within the serial data. * OSZ feeds the sensor coils, the vaporized oscillation is fed into a VCO (voltage-dependent oscillator circuit), the frequency of which is evaluated by a microcontroller circuit (see description above). * The damping measurement for different displacement measuring points, weight measurements, height adjustments each have a parallel resonance circuit for each oscillator circuit has a different frequency, which ensures adequate decoupling of the measuring systems. * Other variants are: * The upper slide of the front cushion with its direction of movement between the user and the keyboard front (transverse to the longitudinal direction of the keyboard), also to be provided with a motorized cable drive: * This The variant is further illustrated in FIG. 93 with the two drive motors M1 and M2 (set lower behind the slide plate, after a distance of 100V, cf. 97) and FIG. 78, the drive motors being able to contain further subscriber circuits according to FIG. 95 and d the bus connection via the other cables of these drives is continued. The control for the height adjustment of the rear cushion (see M5, described above) including the sensor circuits can also be included in the bus circuit. * With the deflection pulleys UL1, UL2 and ULV, the rope is steered, cf. Fig. 78: first cable pull over ULV deflection pulley pulls carriage 100S forward with U-steering of rear pulley UL2 (see Fig. 93) and another cable pull over further rear steering pulley UL1 pulls carriage back, whereby both cable pulls are each pushing from M1 or M2 are driven, equivalent to the principle already explained according to FIG. 89. In Fig. 93, UL1 is driven by M2, and UL2 by Ml, each via horizontally mounted axes. * The sensor scanning for the drive in the further coordinate direction is then carried out with the design according to Fig. 76b, the Rahaen RM not only having a play (VSP) in the lateral direction to a lateral stop surface (rail guide), but also in the front (towards the keyboard font) and at the rear (for users) with a corresponding coding of the frame sides by means of plates (33) and associated Δbtastspulen {E] on the lower slide plate. * All drives are in soundproofed housings

housed, the traction cables over interchangeable insulated sleeves, e.g. pressed into the sleeve (with rope inserted into the side slot) with Eir.schraubgewinde for a corresponding housing bore out of the housing. * Fig. 96 shows a variant in which the Rahaen EM is not based on sliding elements, but instead slides in a ball groove (KGLn) (with lateral movement play VSP). * Works in a lateral direction the ball as a sliding element, whereby the underside of 100S is the sliding surface (optionally exchangeable via sliding strips); in the direction of the keyboard front, however, the roll function of the balls is given, the balls can e.g. also be made of POM (see above). * Fig. 98b to Fig. 105 show exemplary embodiments for a cable pull-in function if, for the purpose of adjusting the motorized height adjustment of the rear cushion, the slide plates are to be supplied with signals only temporarily, and no cable pulls for further servo control or no supply rails for signal routing, are provided. * Fig. 103 and Fig. 108 illustrate circuit measures in order to run switching sipals over a two-pole cable for this simplified version and voltage settings for a control element (switch or potentiometer) attached to the sliding surface, the microcontroller for the on the Electronics (IC, from E in Fig. 77) for the height adjustment of the rear cushion. The control element is used to specify which contact pressure for the front cushion should be specified as the setpoint by adjusting the height of the rear cushion, e.g. 3 switch positions (hard, media, soft strong (H), medium (M), weak (p )) are sufficient. * Fig. 104 shows the variant in which a two-pole cable can be pulled out against a return spring on both ends of the catch {102B}, the end of the cable each having a two-pole jack plug (907) as a connection, for direct insertion into suitable sockets ((cf. .901) of the slide plates (see Fig. 69a) on the outside.

* The cable routing for each of the two cables is in each case formed by an metallic tube (frame in Fig. 105), the first contact pole of which is the inside of the tube and the second contact pole of which is a busbar (906d ) is. A mini slide (906c) slides in the cavity between the inside of the pipe (Rah) and the busbar (906e), supported by a pair of contact springs, from which one contact (906b) rubs against the busbar (906e) and the other contact (906a) bears against the inside of the pipe. * The mini slide is centered by means of a disc segment (904) held by a sheet metal bracket (906aK), which is slidably guided in the cavity of the tube (between the inner wall and the conductor rail). At the front of the disc segment (904), the double-core connection cable (a, bL) is inserted through a through hole and aa sheet metal bump (906aK), which is designed as a strain relief piece (via a pair of holes with a pulled cable), is attached, each with one wire of the cable the contact poles of the sliding contacts (906a and 906b) of the mini slide (906c) are clamped or soldered on. A magnet (904) is attached to the pull side of the disc segment, which magnetically adheres to the end of the tube (RST, see Fig. 99), which is closed except for the through hole of the cable, as a stop after the cable has been pulled out. A rubber cord (GBR) is used as the return spring of the cable, which is attached to the opposite pulling side of the mini slide. The trigger for the automatic cable retraction by the return spring (GBR) is triggered by pulling a rod (911, Fig. 99) which, as an extension of the rubber cord, on the side of the sliding surface edge (102B) opposite the pulled cable in a guide hole (910) is guided and to which the rubber cord is fastened (e.g. via nuts 912, the rod having a corresponding threaded neck). The other end of the rod protrudes from the sliding surface edge (102B) and has a corresponding button (902aL in FIG. 99) for pulling it out. (The pulled-out position is shown in broken lines). The length of the rubber cord (GBR) is such that after a certain length of pull by pulling out the rod (911), the rubber cord (GBR) is fully tensioned and is not very stretchable, as a result of which the pulling path of the rod continues directly onto the cable fastening of the disc segment (904) and its maple adhesion on the end face of the tube breaks off, as a result of which the rubber cord leads the cable back into the tube guide by means of the mini slide (906c), ditto the pulled out rod. The minimum tension of the rubber cord (GBR) is such that the rubber cord is still tensioned when the rod is inserted and the cable (909 L for the left side and -R for the right side) is inserted. * As shown in Fig. 98, the plug contact connection of the cable has a corresponding end plate (909b), which bears against the pull-in hole (909) of the cable. * Fig. 98, Fig. 99, Fig. 100, Fig. 101 (contact tap 906), Fig. 102 (cable centering designed as screwable socket parts 905a and 905b) illustrate a further alternative using a separate tube for each connection pole, whereby In the reference designations (R) and (L) for the right and left side (or a and b) for the cable cores, the two-pole connections a and b are used. * In Fig. 104 two controls are arranged opposite each other on opposite sides of the frame for the sliding surface (102B): on one side a button (TN), on the other side a toggle switch (9ÖSS) with 3 positions (or alternatively a potentiometer) for specifying a reference voltage which corresponds to a predetermined contact pressure for the front cushion for the described adjustment of the height adjustment of the rear cushion. The circuit for this is shown in Fig. 103: The supply voltage (for example, supplied by a power supply unit {N}, plugged into the frame of the sliding surface at the side of the longitudinal bar 102 via connection STK102) is fed to the control electronics in two poles, this supply being carried out by the button TN (designed as a normally closed contact) can be interrupted at the push of a button. Keiters the supply voltage can be varied by the control element and selected so that it is above the value of the actual supply voltage in all variations {e.g. switchable via Zener diode circuit). * The circuit shown in Fig. 103 is housed on a small circuit board below the sliding surface support (in frame 102), the cable routing tubes for right and left cable (909L and 909R) are connected in accordance with the outputs of the circuit (bL, bR each in parallel for left and right cable, same as aL, aR = GND for right and left cable, see also option according to Fig. 100 for interconnection if wires are routed in single-pole cables). * Fig. 106: see Fig. 112, below. * Fig. 107 shows the application of the pillow device on a multi-dimensionally curved keyboard (8): The support surface {99} for the sliding support of the front pillow (IV) is placed on an already sloping handrest strip integrated into the keyboard in front of the keypad, over a soft surface {930], onto which metal clamps (929 with bending edges 929B) are fitted, which are adapted to the respective width and inclination of the hand rest strip, the underside of the metal clamps being inserted piece by piece on a support surface (103) which is placed under the keyboard (e.g. as a sandwich), whereby the inclination and width of the hand rest strip can change as desired over the length of the keyboard. * The side profile of the sliding support is designed so that the sliding surface and underside of the rail guide frame (930) converge on the long side, which is closest to the row of buttons. * Fig. 108 shows the electronic circuit housed under the support plates of the rear cushion (lH) with a piezo signal transmitter or loudspeaker: The supply voltage set with toggle switch 908S or a potentiometer (wire bL for the left slide plate or wire bR for the right slide plate, each inserted in socket 901, see Fig. 69a) is fed via a voltage divider to a VCO (voltage controlled oscillator), the frequency of which is supplied by a microcontroller It is assessed that a reference value for the permissible weight load of the front pillow is assigned to the tension value. * The reset line of the microcontroller is also connected to this voltage and generates a reset vector for each voltage interruption by pressing the TN button (Fig. 103) when the voltage of the microcontroller has returned {delayed via RC circuit, with discharge diodes for quick readiness, alternatively also by external pulse generation chip). In the microprocessor program, the reset vector initiates the adjustment method already described above for performing a successive appromaximation. OUT / IN are corresponding I / O ports signal lines of the microcontroller, BW (a, b) relates to an evaluation circuit for damping measurement of the scale for each slide plate (cf. L6 with metal spring plate 633 in FIG.); the loudspeaker or Signal transmitter connection of the microcontroller is not shown. * Fig. 109 shows another embodiment for the motorized height adjustment of the rear cushion (1-H), whereby an additional guide between the plate of the front cushion (100V, see also with bevel 100M) and the plate of the rear cushion (100AP) also omitted and can be formed directly by the spindle of the motor drive. Fig. 109 shows a corresponding version with a pair of vertically standing threaded sleeves (916), which are flanged to the motor drives (M5a, M5b) and in each of which a bolt is screwed into the internal thread, which supports the support plate of the rear cushion (100AP ) (screwed down with nuts 917). (Left: view seen by user, recnts: associated side view). The motors turn in opposite directions; accordingly, the spindles have common threads. Furthermore, the threaded sleeves are supported directly along the vertical hand of the lowering of the front slide plate (100W), the support being provided by cable clips (or ties) attached to the wall (100W) and the sleeves inside the clips are rotatably guided. To bring the motor axis close to the hand (100W), a punch is provided on the wall, in which the motors are inserted (supported on support plate 918); the continuous motor axis is also supported by a sheet metal spring (999) on the underside of the motor mounting. * The threaded sleeves (916) are preferably made of electrically non-conductive material, but the screwed-in threaded spindles (threaded rods 915) are made of metal. Heiters places a coil (inductance 913) over the sleeve (at hand 100W in a window), which depends on the screwed-in end of the threaded spindle, which affects the end of the threaded spindles screwed into the sleeves their respective screw-in depth, according to the respective height position of the bed plate (100AP) of the rear cushion. The synchronized operation of the two motors M5a and M5b, which drive the support, is regulated via the armoring measurement of the immersion depth of the threaded spindles, and the height adjustment made in binary weights (see above) is measured. In Fig. 109 and Fig. 77 there is also the two-wire connection cable (VKBL) between the contact surfaces of the front and rear pillows for connecting the electronic components (e.g. L6 in Fig. 80) housed on the front pillow support PCB (E) under 100AP. * Fig. 110 shows a variant for inserting the lower strip of the sliding surface, cf. also 99U in Fig. 80 and Fig. 81 (described above). This variant is well suited for curved shapes of the guide slot X, since then the lower sliding surface strips can no longer be easily inserted from the side: For this purpose, the corresponding points of curvature are in one Alignment line (m) below the guide slot X, on the bottom underside (103) of the rail support hinge joints (MGL) are provided, which allow the bottom underside to be folded down on both sides of the guide slot (with the underside lifted off from a support surface, the underside 103 e.g. For example, is placed on a further contact surface via Velcro)). This creates an insert opening on the top, into which the curved strips of the lower sliding surfaces (99U, see Fig. 80) can be placed on the support ridges provided for this purpose (ST-99U, hatched).

* Fig. 111 shows a variant for the already described support device for the cushion rail guide, whereby 610..plate, 98..guide sliding elements, 99.. rails, 634..support surface can be folded down over the joint (630); 631, 632 ... fulcrums of the A suspension bracket (633), whereby 632 ... by pulling towards the locking point or suspension that can be unlocked against a spring force, 103b ... support bars of the rail strips, support ... rail-guided plate for pivot point mounting of the support surface (634). * Fig. 112 shows a demonstration and test device for the automatic stress test of the pillow guide using the described principle of a sled plate (100DM) pulled over pulling ropes for each side of the hand: on a 102DM rail (see 98S), and a drive motor (MTST), whose control signals and supply voltage are transmitted in the manner described and drives a cylinder {928} flanged as a lifting rod with a flanged ball {928} (each made of wood) via a crankshaft {924} (for better movement adaptation in slot slot 325), which carries out a linear movement corresponding to the arab movement of a user, the ball resting on the front cushion (1-V) and the cylinder aa rear cushion (lH) and carrying out the movements typical of the cushion movement in accordance with the crank movement of the drive. 920 .. . is a swivel or servo for rotating the tripod (plate 921) of the crankshaft, according to the replica of a Swivel movement of the arms. In Fig. 106 a seed view of Fig. 112 is shown. * Fig. 113 shows how on the front of the rail support of the (102) cushion device pointing towards the front of the keyboard, the adhesion of the clip (702) inserted on the back is strengthened by means of a removable adhesive connection to the tabletop.

* Fig. 114 uses a steel bracket (702ST) with as little suspension as possible, whereby the bracket presses the rubber feet (GF) attached to the pressing points of the bracket on the underside of the rail support (102) and the lower bracket section upwards has a fixing screw (500) pointing towards the underside of the table to generate the pulling force and presses it via a plate or an intermediate layer (PLT) between the screw end and the underside of the table top. In this variant, too, the lateral rotation of the clamp (702ST) is provided by the interaction of the crossbars {704} described as Fig. 91a (as a guide) and the Gumai feet of the rail support (102) adhering to the table top, whereby the clamping clamp is easy to mount (because in the guide slots 102-F Fig. 92, Fig. 91 of the longitudinal strips 102) and must be dismantled again. * Fig. 115 shows a variant in which an extension table (AFL), on which the keyboard (S) is placed, presses against a flat extension (DT) of the underside of the slide guide {102} on the front of the keyboard and thus press the slide guide (102) onto the table top (together with bracket 702).

Fig. 125 to Fig. 229 relate to further variants for zero force compensation by the overrun control. Fig. 119 (top) shows a variant for the single-line longitudinal guidance of the slide plate (100), in which the guide element is designed similar to Fig. 79, with a disk (98S) acting as a bearing sleeve or bushing, one in the Hole of the disc inserted bolt (98b as a guide element, runs in slot X), which has a through hole for inserting a cable connection (AZSU, led from bottom to top, contact ...- K2SR), with the difference, however, that on the bolt (98b) a drive wheel (98WKL) is also flanged, with which the angular rotation of the cushion is made via the rotation of the guide element {= bolt 98b), and instead of the cables pulling on both sides of the bearing sleeve (98S) as in Fig. 79 , this is only done for one pull side on the bearing sleeve (98S) and for the other pull side a pair of cables is provided, which is looped (or laid) over the drive wheel (within a raceway), ie on the drive train d attacks. By controlling the lengths of the cables (45R, 46R, see Fig. 119 section AB below) of the cable pair placed over the drive wheel (98WKL) against the (single) cable (or double cable A45H46R + B45H46R) attached to the bearing sleeve (98S), the rotation (v) of the drive wheel or the guide element (98b) is made, on the other hand by further differential control of the (simple) cable (or double cable) attached to the bearing sleeve (98S) against common unwinding or unwinding of the cables of the cable pair on the drive wheel, the longitudinal displacement of the guide element (with mutually tensioned cables). In the figures Fig.116 to Fig.119: 45R, 46R ... pair of cables of the drive wheel for the slide plate of the right cushion, same as 45L, 46L for the left cushion; 45H46R ... cable of the bearing sleeve (98S) for the guide element of the right pillow, same as 45H46L for the left pillow, whereby two variants are provided for the cable pull attached to the bearing sleeve (98S): * In the first variant, the differential control of the cables of the Drive wheel attached pair of cables directly by the drives that pull the individual cables of the pair of cables for the purpose of the longitudinal movement of the guide element, therefore, for each of the two cables of the pair of cables assigned to the drive wheel, a spool reel with drive is provided (see six drive rollers in Fig. 117) . In the second variant, on the other hand, a common winding by common drive is provided for the incoming cable length, as for the returning cable length, according to the principle of a winding roll, as is e.g. is standard for the transport of print heads on typewriters and printers, the cable length of the incoming cable that is unwound on the winding roller corresponds to that of the wound cable that is wound up. In order to make this principle possible even in the case of the specified version in connection with the rotation of the drive wheel, the incoming cable pull e.g. the cable pair on the drive pulley and the returned cable corresponds to the cable on the bearing sleeve (disc 98S), the cable on the bearing sleeve (98S see also 45H46R in Fig. 117) is also a double cable (A45H46R.B45H46R, see Fig. 119) ), but without differentiated control of the cable length, but with parallel processing of the same cable lengths for the cables of the double cable. In Fig. 117 the option for the redirection (OP) of a double cable with paired deflection pulleys (UR + OP) is also drawn in (cables shown in dashed lines). The separating web ({XM} Fig.119) for separating the cables attached to the drive wheel is then broken through at the points where the cables are deflected (at the ends of the guide lines of the right and left pillows); Guide slot X is shown in dashed lines in Fig. 117. Due to the separating web {XM}, the following structure results for the guide element: a pin or bolt inserted into the guide slot {X} from above with the drive wheel flanged underneath and the drive wheel bearing underneath in a corresponding bushing or perforated disk. In a preferred embodiment, a drive (ML, MR for left and right pillow in Fig. 118a) is provided for the guide element of each cushion, the drive shaft of which each has a pair of co-driven winding rollers (cf. A-roller and B-roller on a common axis attached or coupled via belt drive, in Fig. 118a), whereby on the two winding rollers of a drive, each of which (cf. A-role and B-role in Fig. 118a) is assigned to a cable pull pair of the cushion relating to the drive, A cable pull from the pair of cable pulls (double cable pull) of the bearing sleeve is wound as a running cable pull and a cable pull from the cable pull pair of the drive wheel is wound as a return cable pull and the cable pulls of each cable pull pair are wound synchronously by the common drive of the two winding rollers. If the cable lengths that are guided and returned to the guide element for each pair of cable lengths, each consisting of a cable of the drive wheel and a cable of the drive wheel bearing (bearing sleeve 98S), are wound and driven on a common winding reel, then the differential control of the cable influence on the cable pair of the drive wheel takes place in addition to the pressure rollers provided for the kick rollers, which are actuated by an electric motor or electromagnet, whereby this is done via each rope of the pair of rope pulls by a pressure roller with a separate drive (electrically controlled differential control) or by a joint drive with mechanical coupling of the pressure rollers (mechanical differential control). Further details on Fig. 116 to Fig. 119 are explained below: The variant according to Fig. 119 relates to a version in which the traction cable attached to the bearing sleeve is designed as a double cable pull (A45H46R and A45H46L) with associated drives ML (for left cushion ) and MR (for right pillow) according to Fig.118a; the stroke maps with the pressure rollers DR carry out an electrically controlled differential control (HMGLa and HMGLb for the left, or HMGRa and HMGRb for the right cushion) with the detail HMG shown in Fig. 118c (below) for the pressure rollers, the lifting magnets HMGLb and HMGRb can be omitted if a mechanical differential control is carried out, such as. shown in Fig. 116a, with pressure rollers (DR) mounted on a common bearing bracket (cf. sheet metal Fig. 115b), which press the cable pulls on both sides of the cable pull pair concerned within variable slack loops (supported against support rollers SR) by moving the pressure rollers together, or shift the slack asymmetrically, based on a symmetrical slack for both cables, so that the slack of one of the two cables increases and that of the other decreases, according to the motor-driven displacement of the pressure rollers. The asymmetrical displacement of the slack then causes the slide plate (100) to be rotated accordingly via the guide element bolt (98b) on which the pair of cables relating to the drive wheel is flanged (corresponding to Fig. 119). In a simplified version, it is sufficient to control the sag on only one cable of the pair of cables (but with the same pulley dimensions only gives half the angle control for the cushion). In addition to the possibility of shifting the pressure rollers by means of a lever driven by an electric motor (see lever attachment AP in Fig. 116a and 116b) or using a solenoid, it is preferred that the shifting by means of a moving coil (e.g.

in accordance with the usual loudspeaker production) on which a lifting rod (with AP point of attack) for controlling the displacement of the pressure rollers is flanged accordingly. Fig. 116c shows a proposal for a spring-tension suspension of the motor drive (M together with drive rollers hidden behind sheet metal, cf. A-roller and B-roller in Fig. 118a), ABL being a side plate of a sheet metal frame in which Slot guide (LS) engaging in the slot guide on opposite side cups Pins of another sheet metal frame used (INBL) are slidably inserted and the inner sheet metal frame (e.g. via the pins) against the outer (ABL) by tension springs in one direction against the pulling direction of the pull cables (cf. 45R to B45H46R; R stands for right, ditto L .. for left in further figures) is prestressed along the elongated hole guide, the inner frame (INBL) being used as the chassis for the attachment of the drive (M) relating cables for a cushion side. In Fig. 117 the option is drawn, in which all the cable pulls are wound on reel spools (e.g. pretensioned in a rest position by spiral spring force), whereby instead of the six drives these can also be replaced by the arrangement according to Fig. 1118a; SP dividing line from the range of movement of the right and left pillow. For the drives after

Fig. 117 can e.g. the inductance of the cable that is being wound up can be measured directly by tapping rollers (URLM, over its axis) and winding rollers relating to the axis; for the variant according to FIG. 118a, the coupling of a tachometer generator (or optical disc) to each of the two drive motors and / or actuators ungsaessung according to Hegaufnehaer preferred according to Fig. 45, with calibration of the initial value by stop contact at the end of the sliding surface. As an option, preferred capacitive measurement can also be used to record the displacement for the length displacement of the pillows or as end contacts. The regulated stroke length of the solenoids is e.g. measured via their inductance or only via the sensory measurement of the cushion twist (cf. diagonally opposite measuring points of the cushion guide for the transverse direction shift in the

previous part of the description) measured and transmitted via the cable contact (from the slide plate of the cushion to the motor control). For the exemplary embodiment according to Fig. 119, the cable pull contact is made on the guide element for a contact point (K2SR) by isolating the disk acting as a bearing sleeve and a fastening pin (98 BS) inserted into the disk (each) for fastening the cable pull (or double cable pull) Corresponding implementation of the cable contact to the slide plate upwards (K2SR) and the further measure that the bare cable pair, which is placed around the drive wheel, forms a contact with the electrically conductive drive wheel, which continues via the axis of the drive wheel (98b) to the slide plate ( contacted) (with solder connection K1SR). So that the two cables of the double cable attached to the bearing sleeve do not get tangled, a separating web (XM) is provided, which runs along the center line of the guide slot of the longitudinal guide line of the sliding ruler and is placed on the bottom side of the sliding ruler and is dimensioned in this way is that, on the one hand, the cables that are set lower on both sides of the separating web (XM) by the fastening pins (98 BS) are separated by the separating web and, on the other hand, the disc that forms the bearing sleeve (98S) of the guide element that is pulled by the cables is separated by the web ( XM) can still slide away without touching the dock. In Fig.119 is also shown (below): Section C-D (bottom center) relates to the insulated bearing washer for the axis of rotation of the drive wheel, which also forms the guide pin (98b) (slides in guide groove X); Section A-B concerns the immediate top view of the drive wheel with optional fenders (ZBL) to prevent the cable from slipping out, e.g. the tension spring bracket (SPF) of the drive (see Fig. 116c) is loosened (assembly aid). Fig. 117 relates to the special case that the drives for both pillow sides are made on the left side in order to keep the sliding ruler of the pillow free on the right. As a result, the redirections (UR) shown are required. Indicates the guideline (or

-slit {X}) radii, then rollers or rollers are provided at the corresponding points of curvature on both sides of the guide slot, in order to steer the cables according to the curvatures. Fig. 118a shows a suitable housing for the cover of the drives and control electronics, which is preferably transparent and placed on a base plate extending over the entire length of the sliding ruler st; ABS ... concerns the required distance for the freedom of movement of the left arm and can still be used to house a control panel (e.g. capacitive keypad, etc.). Fig. 118c relates to Detail KG, a proposal for centering the pull ropes via spring-loaded balls (KG) with ZS ... pull ropes, in addition or as an alternative to a centering guide of the pull ropes carried out by means of rollers. Other special features are: The use of the pressure sensing (scale) explained in the previous part of the description for measuring the hand or macaw pressure continues to be used in such a way that the readjustment of the cushion movement by the motorized drive is only activated when the hand or the Poor, because otherwise the control loop would be open. In a further training option, in the case of a sensory statement that the hand or arm is not lying on the pillow, the control does not switch off, but rather switches over to a further sensor, which in addition to the displacement movement detection of the pillow (see sensor in the game VSP or vector pressure sensor in preceding part of the description) is still present and the position of the hand and / or macaw position is also sensory when the hand or arm is not placed on the corresponding pillow and this sensory position indicator for the continuation of the regulation of the tracking control of the pillow is used. Depending on the type of sensor used (optical, inductive or capacitive using sheet metal electrodes), the sensor is attached to the front or rear cushion. Fig. 97 shows an example of the rear pillow, e.g. On both sides of the cushion support surface (100AP) on the side (PS) and / or at the rear (PSH at the corners of the rear edge of the support surface) there are optical reflection sensors that scan the contours of the arm, e.g. front and rear cushions are each equipped with a sensor for generating a hand or arm signal or not, and are designed with a sensor-controlled displacement play (VSP) and, in addition to a large number of possible combinations for the control, the following variant is preferred is: a) the palm rest on the front pillow is confirmed by sensors, because the cushion movement of the front cushion is regulated independently according to the sensor within the displacement play (VSP) of the front cushion and the cushion movement of the rear cushion is regulated independently according to the sensor within the displacement play (VSP) of the rear pillow, b) if the palm rest on the front pillow is not confirmed by sensors and the macaw rest on the rear pillow is still confirmed, then the cushion movement of the front pillow and the rear pillow is regulated according to the sensor inside the Rear cushion displacement play (VSP) , c) is the palm rest on the front pillow and the arm rest on the back

Cushions not confirmed by sensors, then the sensor on the rear cushion is switched to the contour scanning of the placed arm and the regulation of the front cushion and rear cushion after this contour scanning so that the sensor scanning of the arm contour is always within the contour limitation of the scanning, the concerned So follow the pillow of the macaw. This is, for example, such that the reflecting knives arranged on both sides at the rear edge of the slide plate are arranged at a distance which is dimensioned (and, for example, made adjustable with a Velcro fastener) such that both reflecting eaters are reflected by the arm, when the arm is centered through the trough of the air cushion. If this is no longer the case, then the arm moves in relation to the reflectometers, that at the relevant border area the relevant reflection meter no longer reflects the arm, which in relation to the other reflection meter (relative evaluation) results in an asymmetry which is compensated for by corresponding movement control of the cushion, the cushion following the moving arm. It is evident that instead of optical sensors, capacitive sensors or inductive sensors can also carry out this relative evaluation.

In addition to this option, a contour scan of the hand can of course also be carried out for the front pillow, with correspondingly autonomous control of the front pillow. An embodiment variant with a control method according to steps a, b and c above contains the following electronic components: for each front cushion, a small printed circuit board with four parallel resonance oscillators for four scanning coils for measuring the damping over metal corners at the corners of the sliding frame of the cushion support described in the previous part of the description (with Game VSP), an oscillator for measuring the contact force on the corresponding spring plate and a microprocessor circuit for evaluation and transmission of the measurement signal to the tapped two connections of the guide element of the lower slide plate (see also Fig. 95a and Fig. 95b). The sled plate of the rear cushion has identical components. The control electronics, which are separated from the slide plates and fed with sensor signals via the traction ropes, contain, in addition to the reception and evaluation electronics and control circuit control of the drives, the control described above for the level adjustment between the front and rear cushions, which in this version is not directly between the contact surfaces ( see M5a and M5b in Fig. 109) but via spindle adjustment of the level between the front {99} and rear {{99H], cf. Fig. 97) Sliding ruler (done, e.g.

also on a vertical guide wall (ie {704} in Fig. 87c corresponds to {100W} in Fig. 109), with the two sliding rulers on their vertical or inclined sliding wall (at a suitable support distance from one another or two of the described sleeve-threaded spindle combinations) ( see. {100W}) connect.

Furthermore, it is planned to create a care table for the aotor longitudinal displacement of the rear pillow (macaw pad behind the wrist), which enter the health aspect of an ergonomic hand position, such as that described in Already enable progressive keyboards (cf. keyboard from Microsoft ... registered trademark), carry out a suitable path control of the rear cushion as a function of the displacement path and / or rotation of the front cushion according to an electronically stored function. Identical sliding rulers with identical drives can be used both for the front handrest cushion and for the rear armrest cushion, the relative height of the two sliding rulers being made adjustable by means of the spindle control described (see also the previous part of the description). Another variant is to also use the rotation detection of the pillows as an input function, e.g. in the following application: In a simplified version, the incremental pulse generation when moving the pillow (e.g. to control the cursor functions) is coupled to the hand rest of the other pillow, i.e. if the hand is lifted from the other pillow, the incremental pulse generation is prevented, so that Cushions in front of each Iapul chain can be brought into a desired starting position. An alternative to this is to generate a short rotary movement with the other cushion before pushing the cushion on and to decode it accordingly, in which case the following sequence of the incremental impulses generated by moving the corresponding cushion is not evaluated, and the evaluation after expiry a certain (retriggerable monostable) trigger time of the pulses is switched back again. Advantages of the invention: The basic solution variant according to approach 1 already has the advantage that the cushion cover is inexpensive to manufacture, has the best sliding and movement properties and adaptation to the hand position when typing; and, above all, in a wide variety of expansion stages, from a particularly cost-effective version to particularly demanding designs. * For the sake of completeness, it should also be pointed out that as an alternative to the described capacitive measurement for scanning the displacement path of a cushion, the sawtooth-shaped frayed sheet metal strips can also be used for a damping measurement, above the guide element, which also forms the fulcrum, and in the capacitive scanning capacitive bridging of the sheet metal strips, a sensor coil is inserted as a cylindrical coil and a damping measurement is carried out on the sheet metal strips, the damping of the coil being varied by the sawtooth-shaped fraying of the sheet metal strips, also according to the displacement length of the coil. The signal is supplied to the coil either directly via the cables with printed circuit board electronics that are self-contained on the slide plate or only inductively via direct contacting of the metal strips (as in the case of capacitive measurement).

* In summary, the invention therefore relates to a cushion for a hand rest for typing keyboards, which has a support cushion that glides on the sliding surface for each hand (in optional serenity with identical gliding and guiding points), with the following optional features: * the hand movement during the typing process adapted skaterunner (glide-skid-movement) - storage of the cushions by small, separate sliding surfaces * exact height adjustment of the cushions for the hand rest with floating granules, * pressure relief of the placed hand by another integrated wrist movement-optimized detent support, * pressure relief through implementation from potential energy to kinetic energy, in particular by using a rocker pad for the rear cushion, * The slide strips are easy to grow due to the interchangeability of the slide surfaces for the rail guide, * rail guide can be used for any ergonomics of the keyboard in multiple dimensions Tensional curvature are carried out, * electronic measurement of the target contact pressure of the hand (also while writing) and automated adjustment for level compensation between the hand support cushion and the macaw support, thereby always electronically determining optimal conditions before the user does it too late by long-term writing in the event of incorrect adjustment detects (electronic sensitization fulfills a health monitoring function of the product), * movement amplifier by means of a zero-force servo control of the cushion movement with sensor scanning of the hand movement during typing, by corresponding movement scanning of the cushion movement, e.g. by means of path scanning (movement play) of the cushion movement or pressure sensing, or both (e.g. via spring travel or inductive scanning of flexible belts provided with metal mesh) * Problem-free signal feed, cheap version with integrated cable feed and various combinations of design variants according to user needs, * best Possibility to adapt to modern ergonomic keyboard forums, * Quick to assemble and disassemble thanks to quick-release clamps, * Little space required, since the largest part of the area outside the table top is used for the cushion support. * END of the description.

Claims

PATENT CLAIMS

1. Support device for users of keyboards, in particular electronic keyboards (for example for computers, data entry and typewriters and telephones) or support device for general handwork, with a cushion-supported hand rest, whereby separate cushions can be provided for right and left hands and for the keyboard application the cushions in front of the keyboard front are set up separately or integrated into the keyboard, and with a sliding guide in the longitudinal direction as a feed, which is located in front of the keyboard front and has a guide parallel to the keyboard front, on which the relevant cushions are movably guided along the keyboard front with Another possibility of movement of the cushion in the direction of the keyboard front, characterized by the following features for the sliding guide: a) the sliding guide in the longitudinal direction consists of small, separate support surfaces which act as sliding elements (that is, gliders or sliding plates or the sliding pills or balls or rollers or wheels) are arranged directly on the underside of the relevant cushion or another separating support ({slide plate) of the cushion and slide on a plane forming the sliding surface (sliding surface), b) the sliding surface is designed as a strip corresponding to a linear plane , which is oriented in the longitudinal direction of the keyboard and on which the small, separate support surfaces of the cushion affecting the sliding elements slide, the sliding surface also being able to have a multidimensional curvature, c) the sliding surface has a guide line in the longitudinal direction parallel to the keyboard front, which has at least one sliding element leads as a guide element displaceable along the guide line, if necessary this guide can have a play and, deviating from a straight line, can also have radii of curvature, d) the cushions sliding on the sliding elements are secured against triggering supports.

2. Support device according to claim 1, characterized in that the further possibility of movement of the cushion in the direction of the keyboard front is made by a further displacement device by means of sliding surfaces.

3. Support device according to claim 1, characterized in that the further possibility of movement of the cushion in the direction of the keyboard front is made by a rocking movement of the cushion.

4. self-supporting device according to claim 1, characterized in that the further possibility of movement of Pillow is made in the direction of the keyboard front by a further displacement device, which is ball or roller or wheels mounted.

5. Support device according to one of claims 1 to 4, with a feed which is located in front of the keyboard front and in addition to a parallel to the keyboard front guidance of the cushion has a sliding guide in the transverse direction to the keyboard front, characterized by the following features for the cushion guide: a ) the sliding guide for the transverse direction consists of support surfaces that are separated from each other in terms of area, which act as sliding elements (these are sliders or sliding plates or sliding pills or balls or rollers or wheels) for the transverse movement directly on the underside of the relevant cushion, or a further separating support (upper slide plate) of the cushion, are arranged, the sliding elements sliding on a further upper sliding surface and this upper sliding surface resting on the separating support which performs the sliding guide in the longitudinal direction (= lower slide plate), and the sliding guide for the longitudinal direction on the lower one n Sliding surface (= line level of corresponding strips) on further surface areas separated from each other

Support surfaces glides, b) the further, upper sliding surface has a transverse guiding line in the transverse direction to the keyboard front, which guides at least one sliding element as a guiding element along the transverse guiding line, if necessary this guide can have a play of movement, and the sliding surface also one more - Can have dimensional curvature, c) The cushions sliding on the sliding elements are supported against the trigger.

6. Support device according to claims 1 to 5, characterized by the following features for the cushion guide: the guide line of the sliding elements is formed in one line by a guide slot or protruding guide web let in in the longitudinal direction of the strip.

7. Support device according to claims 1 to 5, characterized by the following features for the cushion guide: the guide line of the sliding elements is formed in several lines by guide slots inserted in the longitudinal direction of the strip or projecting guide webs.

8. Support device according to claim 6, characterized by the following features for the cushion guide: only one sliding element is guided through the guide line and at the same time forms the pivot point of the cushion for its rotation on the sliding surface.

9. Support device according to claims 1 to 8, wherein the guide of the sliding elements is made by a recessed guide slot, characterized in that the trigger protection of the cushion is formed by a sliding plate which is enclosed by the guide slot and by on both sides of the center line of the guide slot projecting edges of Slide surface is secured against deduction.

20. Support device according to claims 2 to 8, wherein the guiding of the sliding elements is carried out by protruding guide web, characterized in that the trigger protection of the cushion is formed by a sliding plate which is enclosed by protruding renders of one or more parallel guide webs and secured against withdrawal or by Several sliding plates that enclose a guide bar on both sides (also in a game).

11. Support device, in particular according to claims 6 or 8, or claims 9 or 10, characterized in that only the sliding element is secured against withdrawal, which also forms the guide and the fulcrum, the further sliding elements only make a sliding support against the secured slide element.

12. Support device according to claims 1 to 11, characterized in that the guide line of the sliding elements runs on the longitudinal center line of the ruler strip.

13. Support device according to claims 1 to 12, characterized in that a longitudinal side edge of the ruler strip is included in the movement of the sliding elements directly or as a stop.

14. Support device according to claims 1 to 13, with a sliding guide as a feed, which is located in front of the keyboard front and in addition to a parallel to the keyboard front cushion guide (lower sliding surface) of a lower carriage still has a cushion guide in the transverse direction to the keyboard front (upper sliding surface) , characterized in that the sliding guide of the cushion on the upper sliding surface is made in several directions in the transverse direction to the keyboard and that the sliding guide of the lower slide on the lower sliding surface is made in one line with a common pivot point and guide point along the guide line running in the longitudinal direction of the keyboard.

15. support device according to claims 2 to 24, with a one-line guide, characterized in that the canting support of the underside of the pillow, or possibly its slide plate, by the surface-separated sliding elements, which the corner points of the Form support surface against the trigger protection of the guide element arranged within the support surface, which also forms the fulcrum.

16. Support device according to claims 1 to 14, with a multi-line guide, characterized in that the canting support of the underside of the pillow, or possibly its slide plate, by the area-separated sliding elements, which form the corner points of the support surface, against a trigger safety device is formed directly from the amount of sliding elements is made.

17. Support device according to the preceding claims, characterized in that the cushion is guided on a slide plate and is connected to the slide plate by elastic and / or flexible bands.

18. Support device for users of keyboards, in particular electronic keyboards (for example for computers, data entry and typewriters and telephones) or support device for general handicrafts, with a cushion-supported candle pad, wherein separate cushions can be provided for right and left hands and for the keyboard application, the pillows in front of the keyboard front are set up separately or integrated into the keyboard, and with a movement guide for the pillow, or support device according to claims 1 to 17, characterized in that a displacement sensor is provided for registering the displacement path for the pillow of one hand and that for the pillow of the other hand, a device for generating an activation signal, sensory via the pillow (e.g. by relieving pressure, or shifting against spring contact, or pressing in a certain way, etc.) and / or directly by an actuation button in the effective range of the kis sens, is provided and that the signal of the Wegaufnehaers with the activation signal is linked in the following manner by control electronics: a) the control electronics, the key signals are looped through for evaluation and conversion, or the control electronics is connected to the keyboard input of the computer, b) optional, (if used in software), the control electronics are the mouse signals for evaluation and Conversion looped through or connected to the mouse input of the computer, c) a valid activation signal, possibly triggered by one hand (e.g. left hand), which affects the activation signal generation, controls in conjunction with one by the other hand (e.g. right hand) movement of the pillow along the keyboard follows the following sequence in the control electronics: d) a key press made at the time of a valid activation signal (e.g. also with the left hand) is intercepted by the control electronics and is not evaluated by the software of the computer and decoded by the control electronics as assignment information relating to the intended use of a sequence of incremental impulses generated by the displacement of the cushion with the other hand, e) according to the decoded intended use of the incremental impulses, the incremental impulses are fed to the software of the computer (e.g. via keyboard and / or Mausa connection) and processed according to the purpose of use, f) the activation signal is switched back by pressing a key and / or by the expiry of a time interval if, immediately after the activation signal has been triggered, no key that relates to the assignment of the activation signal (ie indication of use) is pressed within a certain time has been.

19. Support device according spoke 18, characterized in that the following keys are coded for the activation signal for the following purposes: a) the X key for line-by-line image mark movement, which corresponds to a mouse or cursor movement in the X direction, b) the Y key for column-by-column image mark movement, which corresponds to a mouse or cursor movement in the Y direction.

20. Support device according to claims 18 or 19, characterized in that for the decoding of the intended use of a valid activation signal, the cushion movement is evaluated against a path overcoming decoding (for example in the transverse direction and / or deformation of the cushion and / or stop coding).

21. Support device according to claims 18 to 20, characterized in that a capacitive length measuring system is used as a displacement sensor for the cushion displacement, consisting of two along the scanned cross-section length (in the longitudinal and / or transverse direction) aligned electrical conductors, which by a on the sliding element The pad mounting electrode is capacitively bridged, the displacement length of the cushion being measured as a capacitance value measured between the conductors in the form of incremental pulses, which are capacitively coded via the displacement path by shaping the conductor spacing (e.g. according to a sawtooth pattern).

22. Support device for users of keyboards, in particular electronic keyboards (for example for computers, data entry and typewriters and telephones) or support device for general manual work, with a cushion-supported hand rest, separate cushions for right and left hands can be provided and for the keyboard application the pillows in front of the keyboard front are set up separately or integrated into the keyboard, and with a movement guide for the pillow, or support device according to claims 1 to 21, characterized by the following features: a) the movement guide of the pillow has a motor drive and a sensory pressure or movement sensing of the cushion blocked by the coupling of the drive (e.g. balance, pressure sensor, path detector in a displacement play, optical scanning, capacitive scanning, inductive scanning, ohmic scanning), b) that on the cushion against the coupling of the drive sensory g Measured movement forces control the drive so that the drive compensates for the forces of movement occurring on the pillow against the hand.

23. Support device according to claim 22, characterized in that the sensory pressure or movement sensing of the pad blocked by the coupling of the drive by a small, by hand against the coupling of the drive to move (free) movement is made and that the Bewepng, or The displacement of the cushion within the free movement is sensed against the coupling of the drive and controls the drive so that the drive compensates for the manual displacement of the cushion within the free movement.

24. Support device according to claim 22 or 23, characterized by the following design of the motor drive for the cushion movement: the drive of the cushion movement takes place via cables attached to the respective slide device of the cushion (directly on the cushion or on slide plates or a slide element in question), which leads to both long sides of the guide line are tensioned and motor-driven.

25. Support device according to claim 24, characterized in that the cables are live, the voltage supply with superimposed control or data signal transmission to electronics via the cables. components of the moving cushion cover is made.

26. Support device according to claims 1 to 25, characterized in that a sensory measurement by eddy current damping measurement on the electrically conductive surface (for example, sheet metal) is carried out by means of a coil, with a plurality of sensors, each coil having its own measuring frequency Corresponding filter property (e.g. parallel resonance circuit) is fed, characterized in that the sensor is used for one or more (depending on the design variant) of the following measuring applications: a) Generation of an activation signal by decoding the cushion movement or deformation or the contact pressure, b ) Detection of directional components for the cushion movement, c) Detection of directional components for the cushion movement, d) Detection of directional components for the cushion deformation, e) Measurement of the contact pressure of the hand on the cushion in the vertical direction, the electrically conductive surface being resilient, f) Measurement of the edition pressure of the hand on the pillow in the lateral direction, the electrically conductive surface being resilient, g) measurement of the immersion depth of (electrically conductive) threaded spindles screwed into (non-electrically conductive) sleeves, which as motor-driven linear drives make a corresponding adjustment of the pillow position and / or Carry out pressure ratios on the cushion, h) Measure the unwinded rope length by rotating the winding rollers, the winding rollers have a coil spring as an inductor, which is laterally damped by an electrical surface, depending on the size of the coil spring, i) Measurement on with metal mesh provided tapes or pillow cases for locating the movement of the tapes or pillow cases.

27. Support device according to one of claims 6, 8 or 14, characterized by one or more (depending on the embodiment variant) of the following features:

(a) that a slide plate is provided for each cushion as a support surface, and / or (b) that the sliding elements which support the slide plate against the guide element of the pivot point of the slide plate on the sliding surface are designed as pills (sliding pills) which are inserted vertically into the underside of the sliding plates and slide with their rounded cylinder side on the sliding surface, wherein the sliding pills have an axis of rotation for rolling or are firmly inserted into the slide plate, and / or

(c) that the stop for the rotation of the slide plate is limited by the side surfaces of the slide pills on a protruding longitudinal edge strip of the slide surface, the slide pills being inserted at an angle which is dimensioned such that the side surfaces of the pills are flat on the slide plate when it is screwed in Line up on the inside of the longitudinal edge strip and / or,

(d) that the slide plate of a pillow on its long side, which faces the front line of the keyboard, has an angular bevel that is dimensioned such that when the sled plate is screwed in, the long side in question is aligned parallel to the keyboard front line for the purpose of saving space, so that the sliding surface strip can be brought closer to the keyboard.

28. Support device according to claims 1 to 27, with a deformable, flexible or twistable material for the pillow, wherein the relevant pillow is attached to its bearing surface along a hipp line oriented transversely to the rocking direction (direction of movement) of the pillow with movability of the pillow in the direction of the keyboard and / or in the lateral direction, characterized in that the seesaw line consists of a Velcro strip connection strip attached between the underside of the cushion and the support surface.

29. Support device according to claims 1 to 28, with a deformable, flexible or twistable material, wherein the relevant cushion is attached to its support surface along a rocking line aligned with the direction of movement (direction of movement) of the cushion, with the cushion being movable in the direction of the keyboard and / or in lateral direction and the pillow consists of a bag filled with gas (e.g. air) or with a liquid (e.g. water), characterized in that its pressure pad for the hand or arm pad is composed of two components : (a) from the filling pressure and (b) from a framing of the bag, which consists in the form of a pillow case stretched with Velcro fasteners and that the framing of the pillow on the hand or arm support surface forms a guide trough.

30. Support device according to claim 29, characterized in that the framing of the cushion (tenter frame) consists of a cover placed on one side of the cushion, the projecting sides of which are turned over to the opposite (still open) other side of the cushion, the projecting sides are dimensioned so that a window remains free on the relevant side, in which a fleece material (e.g. velor) is inserted as an adhesive for a Velcro hand connection, which are fixed to the inside of the folded-over side parts of the cover.

31. Support device according to claim 30, characterized in that

the fluff side (window side) of the pillow is used as a support surface for the hand or arm and that the side of the pillow opposite the fluff window is used as a support surface with the rocking line.

32. Support device according to claims 28 to 31, characterized in that the cushion is inserted with the underside in a trough which is formed by the rocking line adhering to the support surface of the cushion on the side of the cushion which faces the keyboard and by a Increase (e.g. by means of a bar on a flat surface or recess) on the pillow side, which is facing the user.

33. Support device according to claims 28 to 31, characterized in that the cushion is inserted with the underside in a depression which is formed by the hipp line adhering to the support surface of the cushion on the side of the cushion which is facing the user and by a Raising (e.g. by means of a bar on a flat surface or recess) on the side of the cushion facing the keyboard.

34. Support device according to claims 28 to 33, characterized in that the upper hand or macaw support surface of the cushion forms an insertion trough.

35. Support device according to claim 34, characterized in that the insertion recess for the hand or arm is covered with a leather saddlecloth and that the cushion cover is made of fabric.

36. Support device according spoke 28 to 35, characterized in that the cushion is made of a film-tubular film bag (e.g. PA / PE), the longitudinal seam or longitudinal fold of which is in the area of the hand or macaw support, so that the film is pulled apart or tightened on both sides of the fold by the tension pressure of the cushion.

37. Support device according to claims 28 to 36, characterized in that the cushion is made from a film-tubular film bag (for example PA / PE) and has a sound-absorbing coating.

38. Support device according to claims 28 to 37, characterized in that the sound-absorbing coating is pre-shaped by means of a fleece band which is ironed onto the film with heat-soluble adhesive.

39. Hand support device according to claims 1 to 38, characterized in that a foil cushion is used which has at least two different weld seams, of which the outermost is a separating seam, which is welded and separated by means of a hot wire, to which one or more internal seams which cover the side surfaces of the Keep the foil bag together, are welded.

40. Support device according to claims 1 to 27 or claim 39, characterized in that the cushion consists of a flat small foil bag which is filled with a granulate floating in a liquid.

41. Support device according to claim 40, characterized in that the granulate is a spherical plastic granulate made of soft plastic.

42. Support device for users of keyboards, in particular electronic keyboards (e.g. for computers, data entry and typewriters and telephones) or support device for general handwork, with a cushion-supported hand rest, separate cushions for right and left hands can be provided and for the keyboard application, the cushions in front of the keyboard front are set up separately or integrated into the keyboard, and with a movement guide for the cushions, or support device according to claims 1 to 41, characterized in that the relevant cushion, which is (each) assigned to a hand from several in succession (in a row arranged from the keyboard front to the user) there are cushions which can be moved directly by shaping and / or sliding movement and / or by guiding movement of the cushion support in a corresponding coordination with one another.

43. Support device according to spoke 42 with a front pillow provided for one hand (in each case) and pillows also arranged behind the front pillow, characterized in that

(a) that two cushions are provided for one hand,

(b) that the front cushion (located directly in front of the keyboard) is designed as a hand support cushion for support in front of the wrist and the rear cushion is designed as an arm support cushion for support behind the wrist,

(c) and that the coupling of the displacement path of the rear pillow to the displacement path of the front pillow is carried out by means of a fixed static connection between the front pillow and the rear pillow on the same movement.

44. Support device according to claim 42, with a hand (in each case) provided front pillow and pillow further arranged behind the front pillow, characterized in that

(a) that two cushions are provided for one hand,

(b) that the front cushion (located directly in front of the keyboard) is designed as a hand support cushion for support in front of the wrist and the rear cushion as an arm support cushion for support behind the wrist is

(c) and that the coupling of the displacement path of the rear cushion to the displacement path of the front cushion by means of a motor drive for the front and / or rear cushion takes place via electronic regulation of the displacement path on separate movement control, with at least one of the following being used as the actual setpoint comparison for the regulation Sizes are used: c1) the displacement path of the front cushion regulates the displacement path of the rear cushion, and / or c2) the displacement path of the rear cushion regulates the displacement path of the front cushion, and / or c3) regulates a sensory pressure or movement sensing of the front cushion the displacement of the front cushion, and / or c4) a sensory pressure or movement sensing of the front cushion regulates the displacement of the rear cushion, and / or c5) a sensory pressure or movement sensing of the rear cushion regulates the displacement of the rear cushion, and / or or c6) sensory pressure or movement sensing of the rear pillow regulates the displacement of the front gravel.

45. Support device according to one of claims 42 to 44, characterized in that an adjustable level adjustment is provided for adjusting the (vertical) height difference between the support of the front and rear cushions for the purpose of adjusting the contact pressure distribution between the hand and arm support cushions.

46. Support device according to claim 45, characterized in that the level adjustment is carried out manually (for example by screw fixation).

47. Support device according to claim 45, characterized in that the level is adjusted by an electric motor drive.

48. Support device according to claims 45 to 47, characterized in that a measuring device is provided for measuring the absolute contact pressure or the relative contact pressure conditions for the hand or arm support on the relevant pillow (e.g. with a scale in the pillow support for the front pillow and / or for the back pillow).

49. Support device according to claims 42, 43, 45, 45, in particular with a manual height adjustment between the front and rear pillows, characterized in that the (lower) slide plate of the front pillow, which executes a longitudinal movement parallel to the keyboard front, has an extension toward the rear toward the user side with an angle in the vertical or oblique direction, and that matches that Angling of another support surface for the rear cushion for the purpose of height adjustment is slidably created and fixed by manually releasable or loosenable connecting elements (e.g. slot screw connection or plug-in grid connection).

50. Support device according to claims 42, 43, 45, 47, in particular with an electronically controlled height adjustment between the front and rear pillows, characterized in that the (lower) slide plate of the front pillow, which runs parallel to the keyboard front, one towards the rear towards the user side Extension with an angle in the vertical or oblique direction, and that fitting, the angle of a further bearing surface for the rear cushion for the purpose of height adjustment slidably and fixed by linearly shifted connecting elements.

51. Support device according to claims 42 to 50, in particular spoke 44 {c), characterized in that for the cushion movement in the longitudinal direction of the front cushion and rear cushion, each with its own, parallel, fixed sliding surfaces are provided for each cushion.

52. Support device according to claims 42 to 50, in particular spoke 43 (c), characterized in that the bearing surface of the rear cushion is slidably supported on a further sliding surface which runs parallel to the sliding surface of the first cushion.

53. Support device according to claims 42 to 52, characterized in that the rear cushion is flanged to the upper slide plate of the front cushion instead of on the lower slide plate and is moved accordingly by the front cushion.

54. Support device according to claims 42 to 53, characterized by a hinge with a vertical axis, which is provided at the junction of the contact surfaces of the front pillow and rear pillow.

55. Support device according to claims 42 to 54, characterized in that the front cushion is designed as a longitudinal and transverse rails guided flat hand support cushion and that the rear cushion as a rocking cushion with direction of movement towards the keyboard (see claims 28 to 39) for the armrest is.

56. Support device according to claims 42 to 55, characterized in that the front and rear pillows are covered with a continuous or individual leather pad, the leather pad depending on the variant is interchangeable by means of Velcro (for example. With a window or without a window).

57. Support device according to one of claims 42 to 56, characterized in that the front and / or rear cushion has a sensory contact pressure measurement, by means of which the principle of a successive sive appromaximation by adjusting the relative height between the front and rear pillows, a contact pressure distribution between the handrest of the front pillow and the armrest of the rear pillow is carried out, with each step of the successive approach to relieve the drive for the height adjustment, the hand from the pillow can also be removed and for this option a signal transmitter (e.g. acoustic type) is provided to display the process steps.

58. Support device according to claims 42 to 57, characterized in that in the event that no busbars or cables are provided for signal transmission to the servo drives for height adjustment, the signal supply to the cushion support via pull-out cables, which are inserted in the sliding ruler for the longitudinal movement of the pillows have occurred, and via the cables the voltage supply and / or control signal supply in accordance with a setpoint value specified by means of a central input for the hand rest pressure, to which the electronics accommodated on the cushion rest are made.

59. Support device according to claims 1 to 58, characterized in that the sliding ruler for the longitudinal guide on the side end with the catch (e.g. strip) ends flat, so that the slide plates with their sliding elements can be placed laterally and pushed in that the lateral framing of the sliding ruler (in each case) is provided with an insertion slot for inserting the guide element of the slide plates and that fitting pieces for insertion and fixing are provided at the end of the guide line (for example the guide slot) which prevent the slide plates from sliding out.

60. Support device according to claims 1 to 59, characterized in that the sliding surfaces are designed and interchangeable as strips placed on a supporting or supporting surface, the sliding surfaces relating to at least one of the following sliding surfaces: a) on the supporting surface of the longitudinal guide ruler on both sides of the guide line applied (upper) sliding strip surfaces, which are framed by the framing of the longitudinal guide ruler and bordered by the boundary of the guide line (e.g. guide web or guide element sliding within a guide slot), and / or b) below the contact surface of the longitudinal guide ruler on both sides of the Guide line underneath (lower) sliding strip surfaces, which are bordered by boundary strips of the guide line designed as a guide slot and by the limitation of the guide line (e.g. guide web or guide sliding within a guide slot ungselementes) are bordered, and / or c) on the bearing surface of the cross guide ruler sliding surface strips.

61. Support device according to claim 60, characterized in that the lower sliding surface strips can be inserted from the front narrow side of the longitudinal guide.

62. Support device according to claim 60, characterized in that the lower sliding surface strips can be inserted by opening a hinge joint which is provided continuously or in parts on the guide line.

63. Support device according to claim 25, characterized in that the cable pulls are bare steel cables, that the signal coupling of the cable pulls takes place via contact (e.g. sliding contact or via the axes of the winding rollers), that the cable pulls in the guide slot concerned sliding element, via which also the further contacting of the cables is made, are guided and, if necessary, a return groove is provided for the cables, and that the cables of the two cushions are separated by an insulating web in the guide slot of the sliding elements of the cushions.

64. Support device according to claim 25, characterized in that the cable pulls are bare steel cables, that the signal coupling of the cable pulls takes place via contact (e.g. sliding contact or via the axes of the winding rollers), that the cable pulls in the guide slot concerned sliding element, via which also the further contacting of the cables is made, guided and, if necessary, a return groove is provided for the cables, and that the cables of the two cushions are separated by dividing the sliding ruler into an area for the right pillow and an area for the left pillow and by deflection the drives are fed accordingly.

65. Support device according to one of claims 22 to 64, characterized in that the transverse displacement of the cushions is also supported by a motor with a sensory movement sensing in the corresponding direction.

65. Support device according to claim 22 or claim 65, characterized in that the drive for the cushion movement is arranged autonomously on the support surface of the cushion, or on the sled plates provided (for example with rubber rollers on the sliding surface) and with corresponding current guide rails appropriate tap are provided.

67. Support device according to one of claims 18 to 20 and 24 to 56 or claim 65, characterized in that the displacement path of the cushion over the cable length that has been unwound in each case (for example by means of an optical disk or tachometer generator or inductance measurement of the cable that is still wound up , ditto damping measurement) is converted into corresponding incremental pulses for the relevant control functions.

68. Support device according to one of claims 42 to 67, characterized in that the front pillow is designed as a flat hand support cushion (for example according to speech 40) and the rear cushion as a macaw support according to one of claims 28 to 39.

69. Support device according to one of claims 5 to 68, characterized in that the cross slide has a multi-cell Q'jerschienenführung with guide elements for centering without vertical support and that additional sliding elements are provided for vertical support (e.g. sliding pills, or balls or rollers or wheels, see also speech 27, paragraph b).

70. Support device according to one of claims 5 to 69, characterized in that the multi-line transverse rail guide is in each case formed by a (transverse) guide groove for each guide line, the projecting side of the guide grooves in each case projecting trigger securing surfaces (for example sliding means) of the guide elements covers and by the edges of the guide grooves, the trigger securing surfaces are enclosed directly or via attached guide pins to form a centering guide.

71. Support device according to claim 69 or 70, characterized in that the sliding plates used in the (transverse) guide grooves as a trigger protection have a distance from their underside support on the (lower) slide and do not rest on this support and that the support for compliance the spacing of these sliding plates takes place via a further support by further sliding elements or balls or rollers or wheels, which are arranged on both sides of the guide centering ring (for example the guide pins) on the inside or outside; (e.g. on an exchangeable sliding surface).

72. Support device according to claim 69 or 70, characterized in that the sliding plates used in the (transverse) guide grooves as a trigger safeguard are at a distance from their underside support on the (lower) slide and do not rest on this support and that the support To maintain the position of these sliding plates, further support of the relevant contact surface of the cushion is carried out by means of ball grooves provided on both sides of the centering of the guide pins (row of balls in guide grooves).

73. Support device according to one of claims 23 to 72, characterized in that the (free) movement play for a sensory scanning takes place by a frame guide of the cushion support and the frame guide is carried out in a further frame guide passage with a side clearance corresponding to the movement play of the relevant guide edges , the further frame guide being made movable on corresponding sliding elements or balls with low friction.

74. Support device according to one of claims 1 to 73, characterized in that the sliding ruler aligned parallel to the keyboard front aa longitudinal edge of the user side has provided insertion slots, each with an insertion guide (e.g. webs), into the table clamps on the underside of the sliding surface from the table edge side are pushed against the underside of the sliding ruler from above and are held against rotation by the insertion guide, so that the underside of the sliding ruler has non-slip surfaces (for example Gumai feet) which are pressed against the table top by the table clamps, the table clamp is supported on the underside of the table top.

75. Support device according to claim 74, characterized in that the lower clamp part of the table clamp (in each case) has a thread with .Holding screw that presses against the underside of the table top (via intermediate layer or holding plate).

76. Support device according to claim 51, characterized in that the separate sliding surfaces (sliding rulers) for the cushion movement in the longitudinal direction are made adjustable in their sliding height by spindle drives.

77. Support device according to claim 47 or 50 or 76, characterized in that the motor-linearly displaced connecting elements are formed by a pair of threaded sleeves forming the corner-side support points made of non-electrical material with screwed-in threaded rods made of electrically conductive material, the threaded rods being driven in opposite directions by a motor and opposite threads that the drive motors with the threaded rods on one half and the sleeves on the other half of the mutually displaced parts are attached and that over each sleeve a coil is translated, by means of a damping measurement, the immersion depth of the threaded rod in question for the purpose of regulation of the drive measures.

78. Support device according to claim 24 or 25 with a guide element according to claim 8, characterized in that the cables on the guide element, which also forms the fulcrum of the cushion pad, are attached to both sides of the train.

79. Support device according to claim 78, characterized in that the guide line is designed as a guide groove or guide slot, that the guide element is designed as a pin or pin guided in the guide slot, which underside of the sliding surface is held in a bearing (e.g. bushing) held by the cable pull ) is rotatably mounted and the traction cables are fastened to the socket for both traction directions.

80. Support device according to claim 78, characterized in that the guide line is designed as a guide groove or guide slot, that the guide element is designed as a bolt or pin which is guided in the guide slot and which underneath the sliding surface is held in a cable pull (for example, bushing) ) is rotatably mounted and has a drive wheel, a pull and drive loop is placed over the pull cable for a pull direction for the purpose of an additional twist drive of the bolt, and that for the other pull cable side cable pull is attached to the bearing of the drive wheel (bushing) that by differential control of the length of the double cable on the side of the cable where the cable is placed over the drive wheel, the rotation of the drive wheel or the guide element is made, the drive wheel being held by the cable attached to the end of the cable and that by Differential tax The drive wheel or the guide element is moved along the guide slot on both sides of the drive wheel on both sides and on the cable lengths that attract the bearing (bushing).

81. Support device according to one of claims 24 to δö, characterized in that a drive is provided for the guide element of each pillow with provided for each drive pair of jointly driven winding rollers (placed on or coupled to a common axis) that the at the storage of Drive wheel (e.g. socket) attached cable pull as a double cable pull (pair of cable pulls) with synchronous flushing of the cable lengths, and that on the two Sickelrolie .. of a respective drive, a cable pull from the double cable pull of the bearing sleeve and a cable pull from the cable pull pair of the drive wheel is wound as a traction cable, the cable pulls of each cable pull pair being spchronically wound by the common drive of the two winding rollers.

82. Support device according to spoke 80 or 79, characterized in that for the pair of cables of the drive wheel a pull length variation of the cables is made relative to one another, by means of electromotive or electromagnetically operated pulling or pressing elements (for example pressure rollers).

83. Support device according to one of claims 24 to 80, characterized in that the cables are tensioned and moved by individual motor-driven winding rollers.

84. Support device according to one of claims 22 to 82, in particular claims 22 or 23, characterized in that the pressure or movement scanning for generating a vectorial directional dipal for the cushion movement is carried out by the respective respective sensors assigned sensors (for example four pieces) that the differential evaluation of the sensors lying opposite each other provides a measured variable for the corresponding lateral displacement of the cushion, and that the differential evaluation of diagonally opposite sensors provides a measured variable for the rotation of the cushion.

85. Support device according to one of claims 22 to 84, characterized in that a sensor is provided which indicates whether the hand (or arm concerned) is in each case placed on a cushion or not and that the signal for switching off the drive function for the Pillow movement support is used, the switch-off takes place when the hand (or arm) is not on the relevant pillow.

85. Support device according to one of claims 22 to 84, characterized in that, in addition to the pressure or movement sensing for regulating the drive function, a sensor system is also provided which detects the hand or arab movement relative to the cushion and that a sensor is provided which indicates whether the hand or arm is placed on a pillow or not and that the signal is used to switch the drive function for the pillow movement support, the control of the drive function being controlled by this additional sensor when the hand or arm is not in place.

87. Support device according to claims 1 to 86 with a guide slot as a guide line of the sliding ruler, characterized by a strip piece inserted into the guide slot at the end of the sliding ruler, which forms the stop for the guide element sliding in the guide slot.

88. Support device according to claims 1 to 87, characterized in that the guide line of the sliding ruler has curves in the longitudinal direction, wherein in the case of the optional cable drive, the cables are guided along the guide line on the curves by rollers.

89. Support device according to claim 61 or 62, characterized in that the insertable sliding surface strips are inserted slightly movable in the vertical direction and are held by the lateral end pieces and by the guide element of the guide slot.

90. Support device according to claim 30, characterized in that the adhesive connections of the cushion cover, which relate to the folded-over parts of the fabric, are made by means of Velcro strips and that the adhesive attachment is made by means of the Velcro strips so that detachable strips which have a Velcro coating or mushroom tape coating on both sides ( e.g. designed as Velcro strips glued together on the side coated with adhesive), loosely inserted as an adhesive between materials designed as adhesive fabrics (by ironing on or immediate execution as adhesive fabric, e.g. window inlay of the folded-over fabric side parts, e.g. velor) (e.g. on the inner edges of the fabric side parts of the pillow case wrapped in a velor window insert).

91. Support device according to claims 1 to 90, with a serial data bus in which the current generation of connected subscribers of the data bus is obtained from the data bus signal, or modular data bus connection in its own application, characterized in that the subscriber circuits which supply the power supply from the data bus signal relate, a shutdown of the power supply during the period in which the subscriber circuits perform a transmit function is carried out.

92. Support device according to claims 42 to 91, characterized in that the support device is designed so that the front cushions for the hand rest are on the edge of the table and the rear cushions for the arm rest are located outside the table from the table edge.

93. Support device according to claims 1 to 92, in particular claims 28 to 41, characterized in that the underside of the cushion is curved outwards (convex) and is rocked along the rocking line via this curvature.

94. Demonstration and test device for support device according to one of claims 1 to 93

Movement mechanisms guided by sled according to one of claims 1 to 93, for the purposes of the automatic actuation of a pillow on a supported palm rest, separate pillows can be provided for right and left Hend and for the keyboard application the pillows are placed separately in front of the keyboard front or in the keyboard are integrated, and a sliding guide is provided in the longitudinal direction as a feed, which is located in front of the keyboard front and has a guide parallel to the keyboard front, on which the relevant cushions are movably guided along the keyboard front with a further possibility of movement of the cushion in the direction of the keyboard front, characterized that the slide-guided movement mechanisms of the demonstration and test device are aligned parallel to the advance of the cushion movement in the longitudinal direction and that the motor-driven slide plates of the demonstration and test device have crankshaft drives with respective s have a crank for right and left rows of pillows, the ends of which are placed on the pillows of a row of pillows, one after the other.