WO1998024395A1 - Gripping element designed for grasping by the human hand - Google Patents

Abstract

The invention relates to a gripping element designed for grasping by the human hand (24), the surface structure of which provides an area of support for the palm of the hand curved concavely around the axis of curvature of the palm, the inner sides of the fingers curved concavely around the axis of curvature of the fingers and, if required, for the inner surface of the thumb. The gripping element (24) has an axis (A) that is substantially parallel to the axis of curvature of the palm and the axis of curvature of the fingers. The invention provides for the gripping element (24) to have a fin (25), whose active lateral faces (26, 28) provide a support area for the inner surface of the ball of the thumb and/or inner side of the thumb.

Description

 Handle body designed to be gripped by a human hand

description

The invention relates to a grip body designed for grasping by a human hand with a surface design which offers the possibility of contacting the inside of the hand, which is concavely curved around an axis of the palm of the hand, the inside of the fingers, which is concavely curved about an axis of curvature of the finger, and, if desired, also the inside of the thumb, the grip body offering an approximation to the palm of the hand curvature axis and the finger curvature axis parallel handle body axis.

Such grip bodies are used wherever the human hand has to grasp a device or auxiliary device and hold it securely, for example on crutches (forearm walking aids), mountain and hiking sticks, two-wheeled handlebars, walking sticks, ski sticks and mountain sticks, but also on work tools that must be carried out by hand, for example wheelbarrows, brushcutters, lawn mowers, fish whips and the like.

Various forms of handle bodies have been developed, all with the aim of enabling ergonomically improved detection by the human hand. However, none of the handle bodies known hitherto fully met all requirements.

The invention is based on the object of specifying a handle body which lies optimally in the hand, allows optimum introduction of forces into the device connected to the handle body and with continuous detection does not cause any significant signs of fatigue or pain.

To achieve this object, it is proposed according to the invention that the handle body has a fin, which offers an active possibility with an active fin side surface of the inner surface of the thumb ball and / or the inner surface of the thumb, and with its rear surface of the fin faces at least part of the fingertips approximately in the circumferential direction about the handle body axis.

A major advantage of the design according to the invention is that a support of the thumb and / or the inner surface of the thumb is created without - as in conventional grip bodies - the provision of the support for the inner surface of the thumb ball or the inner surface of the thumb results in such an enlargement of the grip body cross section that an optimal curvature of the palm and fingers for gripping the grip body is hindered.

Since the area required for the system on the active fin side surface decreases from the ball of the thumb to the tip of the thumb, it is possible that the fin projection can be decreased in a direction of progression from the ball of the thumb to the tip of the thumb, in accordance with the course of the thumb, which gives the handle body an overall relatively slim and shapely structure without losing grip ergonomics. It also reduces material consumption.

As a rough dimensioning rule when designing fins, the fin projection in relation to the adjoining surface of the handle body in the area of the juxtaposition of the fingertips and the back of the fin corresponds at least to the finger thickness in the tip area of the fingers. Depending on the size of the hand and in particular the length of the fingers, the fingertips come into contact with the back of the fin or are at a distance from the back of the fin. The fin also ensures protection for the fingertips, especially if the fin projection is equal to or greater than the finger thickness in the tip area of the fingers.

In order to obtain a shapely and touch-friendly design, it is recommended that the fin edge runs into the handle body at an approximately acute angle and / or approximately continuously towards the tip of the thumb. This is also recommended for the end of the fin near the thumb root, for the same reasons.

In accordance with the greatest contact surface requirement in the area of the thumb ball, it is recommended that the fin projection in the rear area near the ball has a maximum.

Again with regard to a touch-friendly and shapely structure of the handle body, it is proposed that the fin edge has an approximately continuous course with sections of different radii of curvature, the radius of curvature in the area of maximum projection, i.e. is the smallest in the area intended for the ball of the thumb.

In order to ensure a low and therefore painless surface pressure in the transition area from the palm of the hand to the thumb, in particular in the area of the thumb ball, even with strong and long pressure, it is proposed that the active fin side surface - viewed in a section orthogonal to the axis of the handle body - in its rear, in particular surface area intended for the application of the ball of the thumb passes almost continuously and preferably approximately in a straight line into the surface of the handle body. In order to further determine the position of the thumb itself on the grip body in an orthopedically tension-free position and thus - if necessary - to ensure force transmission through the thumb, it is proposed that the active fin side surface - viewed in a section orthogonal to the grip body axis - in its front area, in particular intended for the contact of the inner surface of the thumb, with an obtuse angle decreasing in the direction towards the tip of the thumb, merges with the surface of the handle body curved there, preferably in a circular arc, around the handle body axis.

Furthermore, a comfortable placement of the thumb can be promoted by the fact that the active fin side surface — viewed in a section that is essentially parallel to the handle body axis and essentially orthogonal to it — has a slightly convex curvature.

It is further recommended that the handle body - viewed in each case in sections orthogonal to the handle body axis - has a maximum cross-section in a central finger contact area for the inner surfaces of the finger body in relation to the longitudinal extension of the handle body axis and a smaller cross section in connection areas on both sides of this central finger contact area.

This design has proven to be physiologically favorable with regard to the curvature possibilities of the human hand and fingers, also with regard to the long-term detection of the handle. In addition, an advantage of this design is that by axially displacing the hand encompassing the grip body along the axis of the grip body, an adjustment can be made depending on the individual hand format: With a large-format hand, the user of the grip body can grasp it so that the center of the palm of the hand and the separation gap between the large finger and the small finger are approximately in the cutting plane of the maximum grip body cross section. Has a If a user uses a smaller hand, he can grasp the handle further forward, ie closer to the end area near the thumb tip, where the cross section is smaller.

For a casual grasping of the grip body, it is also advantageous if - viewed in sections orthogonal to the grip body axis - the curvature of the grip body surface in the contact area of the ball of the thumb and / or thumb root has a relatively small radius of curvature - and then a relatively large radius of curvature in the contact area of the palm of the hand and on it then again has a smaller radius of curvature in the contact area of the inner surface of the fingers. This applies in particular in the area of the maximum cross-section.

The possibility of multidirectional force input into the handle body can be further improved in that the handle body surface in the area of the index finger has a stop for the outer side surface of the index finger and / or in that the surface of the handle body has a stop for the edge surface of the hand remote from the thumb owns.

Preferably, the distance between the contact area of the index finger and the stop for the edge surface of the hand which is distant from the thumb is adapted to the average size of the hand of an adult person, so that when properly grasped the hand is quasi positively fixed between the two stops and regardless of the surface friction of the Hand cannot slip on the surface of the handle. In addition, because of the decreasing cross-section towards the stop for the index finger, there is a tendency for smaller hands to always maintain contact between the outer side surface of the index finger and the associated stop. However, even with smaller hands, the contact of the edge surface of the hand that is distant from the thumb with the associated stop is not lost but is maintained by a hand deformation and / or hand rest variation on the handle body that is still in the area of natural hand posture. In the case of crutches with a handle body according to the invention, the tendency of the outer side surface of the index finger to rest against the associated stop can also be favored by the inclination of the handle body axis relative to the course of the forearm section of the crutch.

The surface design of the handle body according to the invention is fundamentally possible in connection with all materials which have hitherto been used to produce handle bodies for the human hand, namely: wood, metal, hard plastic, soft plastic, rubber. Preferably, the handle body is made of rubber-elastic material at least on its surface, e.g. Natural rubber, synthetic rubber, softly made polyurethane, elastomer plastics. "On the surface" is to say that it is also conceivable to cover a base body made of hard material, for example wood, hard plastic or metal, with a rubber layer, the rubber layer optionally being able to have approximately constant wall thickness, but it is also conceivable to profile the

Contribute surface by different wall thickness of the rubber layer. The rubber layer can be formed from an elastic coating, which is pulled over the base body and tensioned in the process, so that it is held on the base body. However, it is also conceivable that the coating is preformed as a three-dimensional structure, for example by injection molding of plastic or by vulcanization. It is also possible that the handle body is made of solid rubber. Solid rubber means that the entire handle body is made of rubber, with recesses in the handle body for receiving a rod-shaped carrier element being of course permitted. In the case of carriers of complex shapes in particular, it is also contemplated to spray or vulcanize the handle body onto the respective carrier. To produce an ergonomically comfortable and non-slip surface, it is proposed to choose a Shore A hardness in the range from 25 to 70. With such a setting of the hardness, an elastic adaptation to the handshake is also possible.

The handle body can be provided with a surface profile at least in a partial area of its surface. If one speaks here of surface profiling, its structuring can primarily be based on the fact that the greatest possible slip resistance is guaranteed. But there are also surface profiles

Structure conceivable that the elastic deformability of the handle body is influenced by the profiling. Material elasticity and formula elasticity due to the surface structure require mutual coordination. If the material-related hardness is relatively high, a suitable elastic deformability can be obtained by appropriately pronounced surface profiling and vice versa.

The surface profiling can e.g. be formed by incisions which run approximately in the circumferential direction about the handle body axis. With such incisions, a considerable influence on the elastic deformability of the handle body can be made possible.

However, it is also conceivable to provide a finely structured surface profile, only to change the roughness, so to speak, and thus to improve the slip resistance.

Surface profiling will be provided in particular in the area intended for the application of the inside of the fingers and, if desired, also in at least part of the surface area intended for the application of the palm of the hand. The connection of the handle body with the respective structure, on which the user acts or on which he wants to be supported, can be established in any way. For example, the handle body can be provided at one or the other or at both ends with a shaft which is inserted into the structure to be gripped in each case, or with a flange which is screwed or glued to this structure. In particular, however, it is contemplated that the handle body is designed as a hollow body with a cavity that runs essentially parallel to the handle body axis for receiving a carrier of the handle body, or that the handle body is sprayed or vulcanized onto the carrier.

An application for the grip body according to the invention has already been mentioned: crutch or forearm walking aid. Crutches and especially forearm walking aids require an ergonomically particularly favorable one

Design because large forces have to be permanently transmitted when walking over longer distances. The handle bodies according to the invention are also particularly suitable for cranked forearm walking aids in which the handle body is attached in the cranking area. Crank area is a crank-like central section of the walking aid, which is followed by a standing section at the bottom and a forearm section at the top. When the grip body according to the invention is attached to such a cranked forearm walking aid, the grip body can continue into the standing section and / or into the forearm section via an end curvature, so that even if the grip body is not ideally gripped, the hand does not strike the standing section or can hit the forearm section. Accordingly, at least one of the end curvatures can serve as a stop for the index finger or for the edge surface of the hand remote from the thumb or can be specially shaped. If the handle body according to the invention is used in a forearm walking aid, for example according to DE 1 95 03 565 A1 or in particular in forearm walking aids of the type known from DE 1 95 47 484 A1, a preferred embodiment consists in the fact that it is attached to the forearm walking aid, in particular a forearm walking aid that is cranked in a walking aid plane, is arranged in such a way that when the forearm is approximately parallel to the forearm section of the walking aid and when the long cross-sectional axis of the forearm cross section is approximately parallel (viewed just before entering the wrist), the opposite the forearm in an approximately rest position can properly grasp the grip body, the thumb ball inner surface and the inner thumb surface resting in an approximately rest position relative to the forearm on the areas of the active fin side surface intended for their contact. The force can then be introduced into the handle body in the straight extension of the forearm. The wrist is stressed relatively little, which is particularly advantageous for rheumatics and older patients. The need for a forceful, active gripping of the handle body is generally not necessary and can be reduced to special situations. As already explained above, adaptation to different hand shapes and sizes is possible, in particular because of the varying cross section of the handle body.

In a development of the above application of the grip body according to the invention on a forearm walking aid, it is provided that the in

Position of use of the forearm walking aid is the highest surface area of the handle body extension near the standing section, which is designed as an end curvature and is designed as a support threshold for the index finger root / thumb root transition arch area of the hand, or a corresponding threshold is attached in another way. The inclination of the handle body axis with respect to the axis of the forearm section of the walking aid is preferably set such that when force is applied to the hand due to pressure on the forearm, the outer side surface of the index finger approaches the associated stop and / or index finger root / thumb root transition arch area to the support threshold is favored.

If a stop and a support threshold are available, it is recommended that the stop and the support threshold are matched to one another such that when the force is applied to the hand due to pressure on the forearm, an essential, preferably predominant part of the movement of the hand along the handle axis in the direction forces which inhibit the standing section are applied at the point of engagement between the support threshold and the index finger root / thumb root transition arch region. It has been shown that this coordination can optimally take into account the sensitivity to pain and the durability of the hand.

In previously known forearm supports, the mandrel or the offset section was regularly formed from a hard elastic material with a very smooth surface. In contrast, another aspect of the invention is that the handle body attached to the forearm walking aid, i.e. the handle body attached to the mandrel or to a crank-like central section intended for hand gripping, at least in parts of its areas that can be grasped by the properly placed hand, is made of rubber-elastic material, this rubber-elastic material preferably having a Shore A hardness in the range of 25-70.

It has been shown that the manufacture of the handle body from such a rubber-elastic material improves the grip of the hand on the handle body and gives the hand a pleasant feel. Even with permanent loads The risk of pain or a hand wound is reduced.

Furthermore, the grip body according to the invention is excellently suited to be attached to the upper end of a ski pole or mountain hiking pole or to be designed for attachment to such a pole. The handle axis can coincide approximately with the ski pole or hiking pole axis.

In this application too, the grip body with its fin is dimensioned such that the fingertips rest on the rear surface of the finger or are at a distance from the rear surface of the fin. This is advantageous compared to known grip shapes on ski poles and mountain hiking sticks, in which the grip, which is usually too thin, requires the thumb to be gripped strongly over the extensive fingers and the access is thereby weakened.

Even with mountain hiking sticks, the use of elastic material within the above specifications is advantageous because it adapts to the hand, so that the pressure required to hold the

Griffs does not require unnecessary effort. Again the surface of the handle is made rough, so that slipping is prevented or in any case not prevented by the loop alone. In extreme cases, gripping the elastic and rough-surface material allows the entire body weight to be transferred by the hand gripping the grip body. The problem of slipping when grip is gripped using gloves, e.g. Woolen gloves, is solved.

The handle body can also be injection molded on ski poles and hiking poles. An embodiment in which a throat is incorporated in the upper region of the handle body for the index finger leads to additional force transmission capability in the axial direction of the respective stick.

The fin ensures a secure and comfortable fit of the handle on the hand.

A loop can also be used. It serves, for example, to protect against losing. In principle, however, the loop can also be dispensed with if a handle body according to the invention is used.

The handle body according to the invention is also suitable for use on two-wheelers on two-wheel handlebars. This applies in particular to end sections of a two-wheel control arm that cannot be rotated in operation or can only be rotated slightly. The handle can also be assigned to a functional handle, such as is used for brake actuation or gear shift actuation. If a handle according to the invention is used in connection with, for example, a brake lever, it is advisable to inevitably fix the relative angular positions of the handle body and the brake lever, for example by means of a common carrier, so that the relative angular position is predetermined and cannot be changed.

The use of the handle body according to the invention on two-wheel control arms offers advantages over the handles made of plastic or hard rubber that are commercially available there. In particular, this solves the problem that exists in both bicycles and motorcycles, which results from the need to exert considerable force on the hands. The hands are generally strained by vibrations depending on the pace and road conditions. A special capturing force is also required for ascending and descending sections. handle design according to the invention can be easily achieved. The risk of slipping, especially when wearing woolen gloves, is reduced, as is the risk of slipping between the palm of the hand and the grip body when welding is applied. When the handle body is designed in accordance with the invention, the vibrations are no longer transmitted to the wrists as hard as before. The occurrence of cramps on the hand gripping the handlebar is reduced.

The wrists are also relieved in this application. Active and passive safety is increasing. Slipping even with wool gloves is impossible.

Furthermore, the handle according to the invention is also suitable for use with walking sticks, the handle axis then running essentially orthogonally to the longitudinal axis of the walking stick.

A non-slip hold is also made possible in the walking stick application and the safe guidance of the stick is greatly improved. In this application, too, a throat is advantageous for the index finger. The dependency on the hand size is particularly helpful, which is achieved in that the handle can be grasped at various points along its length.

The above information on the essential features of the invention apply equally to handles for detection by the right hand and to handles for detection by the left hand. As a rule, for optimal adjustment for the left hand and for the right hand, one will choose separate designs which are separated by reflection. However, compromise solutions are also conceivable, especially if the ends of the handle are interchangeable.

Further features of the invention emerge from the subclaims. The accompanying figures explain the invention using exemplary embodiments. They represent:

1 shows a forearm walking aid as an application example for a grip body according to the invention;

1 a shows the view of a right hand to visualize that the grip body according to FIG. 1 is a grip body for a right hand and for later representation of the correspondence of individual surface areas of the right hand on the one hand and individual surface areas of the handle body on the other hand;

Fig. 2 is an enlarged view of the handle body of FIG. 1 in the same viewing direction as there, namely on the

Position II of Fig. 1;

2a the associated right hand;

Fig. 3 is a plan view in the direction of arrow III of Fig. 2;

3a the associated right hand;

3b shows a top view corresponding to FIG. 3 in a network construction as it results from a computer-based 3D representation;

Fig. 4 is a section along line IV-IV of Fig. 3;

4a the associated right hand;

Fig. 5 is a view in the direction of arrow V of Fig. 3; 5a the associated right hand;

6 is a side view of the handle of a forearm walking aid for the left arm;

6a the associated left hand;

Fig. 7 is a plan view in the direction of arrow VII of Fig. 6;

7a the associated left hand;

. Fig. 7b is a plan view corresponding to Fig 7, again in SD ^¬ Compu ter-like manner;

Fig. 8 is a view in the direction of arrow VIII of Fig. 7;

8a the associated left hand;

9 shows a grip body on the ski stick or mountain hiking stick;

9a the associated left hand;

Figure 1 0 a grip body on the handlebar of a bicycle.

Fig. 1 0a the associated left hand;

Figure 1 1 is a view of a handle body according to the invention at the upper end of a walking stick.

Fig. 1 1 a the associated right hand; Figure 1 2 shows a modified embodiment of a handle body according to the invention on the walking stick.

Fig. 1 2a the associated left hand.

In Fig. 1 a forearm walking aid is shown, which is generally designated 1 0. This forearm walking aid includes a stand part 1 2 with a foot part 14 and an extension option at 1 6; it further comprises a forearm part 1 8 with a forearm embracing clasp 20 which is open to the right and a cranking section 22 which connects the stand part 1 2 and the forearm part 1 8 and which is provided with a grip part 24.

The handle body 24 is shown enlarged in FIG. 2. The handle body 24 is designed as a tube-like handle body which is interspersed with the coherent linkage of the forearm walking aid which forms the base part 1 2 and the forearm part 1 8. 1 is cranked in a plane that coincides with the second plane according to FIG. 1. In FIG. 3, the drawing plane of Fig. 1 corresponding level is indicated by dash-dotted lines and designated with GHE ^¬ net. The wearer of the walking aid 10 grasps the grip body 24 with his right hand according to FIGS. 1 and 1a, while the forearm U is received by the forearm brace 20. The joint axis HG of the wrist lies approximately as shown in dash-dotted lines in FIG. 1. The cross section of the forearm, which has a longer axis I, is designated UQ. The longer cross-sectional axis I lies approximately parallel to the plane of the drawing, ie to the plane GHE according to FIG. 3. The longitudinal direction of the forearm U runs parallel to the longitudinal axis of the forearm part 1 8 of the walking aid.

Now consider FIGS. 2, 3, 4 and 5 simultaneously. The handle body 24 has a fin 25. On this fin 25 there is an bearing surface 26 for the installation of the thumb ball inner surface 1 26 attached. Furthermore, the fin 25 has a contact surface 28 for the inner surface 1 28 of the thumb. The contact surfaces 26 and 28 together form an active fin side surface 26, 28.

When the grip body 24 is gripped by the hand, the palm of the hand 1 30 is concavely curved with an axis of curvature 1 32. The fingers 1 34, 1 36, 138 and 140 are when gripping the grip body 24 with their inner surfaces (1 35, 1 37, 1 39 , 141) is also concavely curved, specifically around the finger curvature axis 142. The palm of the hand 1 30 then lies against the contact area 30, while the inside of the fingers 1 35-141 lie against the contact area 35 - 41 (FIG. 4). The finger tips 1 44-150 of the fingers 1 34-140 are in contact with the contact surface 44-50 in the state of the grip body detection or are opposite this contact surface 44-50 in the curvature direction KR with a small distance. It can be seen from FIG. 2 that in cross-sectional planes Q1, Q2 and Q3 placed orthogonally to the handle body axis A, the cross-sectional area content of the handle body 24 is different. The cross-sectional area is maximum in the cross-sectional plane Q1.

When the hand grips the grip body 24, the outer side surface 1 52 of the index finger 1 40 lies on or close to a stop surface 52 of a grip body extension 54 which surrounds the base part 1 2 (FIG. 2). Furthermore, the distal edge surface 1 56 of the hand can strike a stop surface 56, which is formed by an extension 58 of the handle body 24 which surrounds the forearm section 18. It should be pointed out that only with very large-sized hands does a stop occur simultaneously on the stop surfaces 52 and 56. As a rule, the hand will rest against the stop surface 52 with the side surface 1 52 of the index finger 140 for ergonomic reasons. The

Depending on the size of the hand, the user can shift his hand in the direction of the handle body axis A, so that he can bend his finger most comfortably can each include the cross-sectional area corresponding to this curvature of the finger.

It can be seen that the active fin side surface 26, 28 narrows towards the contact region 28 of the inner surface of the thumb 1 28 in the direction of the thumb tip 1 29. This ensures an overall slim configuration of the fin 25. The fin edge 60 runs essentially continuously; at 62 and 64 it runs into the handle body 24 (FIG. 3) at an acute angle and has different radii of curvature, namely R1, R2 and R3, the radius of curvature R1 being the smallest in the region of the maximum projection a of the fin 25. 4 shows the course of the cross-sectional limitation with a curvature of a relatively small radius of curvature S1 in the contact area 62 of the thumb root 1 62, with a substantially larger radius of curvature S2 in the contact area 30 of the palm of the hand 30 and then again with a smaller radius of curvature S3 in the contact area 35-41 of the inner fingers 1 35 - 1 41.

4 and 5 that the active fin side surface 26, 28 with a slightly convex curvature runs in a sectional plane T (FIG. 4) which is orthogonal to the active fin side surface 26, 28 and is parallel to the handle body axis A. In Fig. 3 sections IVa and IVb are still indicated. In section IVa, the contact surface 26 merges into the handle body 24 essentially in a straight line, while in section IVb there is an obtuse-angled transition, which is concave in the view in FIG. 3. The straight-line transition in section IVa is indicated by a dashed line 65, while the obtuse-angle transition is indicated by a kinked line 66 with an angular inclusion of approximately 120 °.

It should be noted that the axis A includes an acute angle a of, for example, 25 ° with the horizontal when the stand part 12 is held essentially vertically (FIG. 2). The handle body 24 is made of a rubber with a Shore A hardness of approximately 40. In the area of the contact surface 35-41 for the inner surfaces of the fingers 1 35-141 there are slots 68 in the rubber material, which prevent slipping and influence the softness of the rubber material. The slot width is approx. 4 mm, the slat thickness is approx. 5 mm, the maximum slot depth is approx. 6 mm (Fig. 5).

The maximum projection of the fin 25 is shown both in FIG. 3 and in FIG. 5. In FIG. 3, the maximum overhang on the active side 26, 28 is denoted by a; In Fig. 5, the maximum throat on the fin back surface 44-50 is denoted by a '.

6 - 8a, which represent a forearm walking aid for the left hand with a correspondingly adapted handle body 24, analog parts are designated by the same reference numerals as in FIGS. 1-5.

The handle body 24 according to FIGS. 6 - 8a corresponds to the handle body 24 according to FIGS. 1-5, but is constructed in mirror image compared to the handle body 24 of FIGS. 1-5 and additionally has a support nose 70 for forming the stop surface 52.

With reference to FIGS. 1, 2, 2a and 5, the following should also be pointed out: the curved handle body extension 54 forms with the curvature region 31, which is highest in the use position of the forearm walking aid, a support threshold on which, when properly put on, of the hand on the grip body 24 of the index finger root / thumb root transition arch region 1 31 so that slipping of the hand in the direction of the standing section 1 2 is prevented. The threshold 31 and the stop at 52 interact in this sense. The threshold 31 is preferably designed such that it has an essential, extremely can preferably absorb the major part of the supporting force. The user can switch off the contact pressure between the index finger side surface 1 52 and the stop 52 completely by means of appropriate finger pressure, or he can alternately support himself against the stop surface 52 and the threshold 31, which leads to a particularly gentle load on the hand.

9 to 12 show further embodiments, with analog parts there having the same reference numerals as in FIGS. 1-5 and additionally each with the index "a", "b", "c" or "d" are provided.

In FIG. 9, a grip body 24a for the left hand is designed to be essentially rectilinear in adaptation to the straight shape of a mountain or ski stick 72a, the axis B of the grip body 24a running essentially parallel to the axis of the ski stick 72a. In order to prevent the handle 24a from slipping out of the hand, the handle body 24a is provided with a throat 73a for the index finger 140a and is additionally designed with a securing loop 74a.

10, a handle body 24b according to the invention is arranged on a handlebar 76b of a bicycle (not shown), the handle body 24b being essentially straight and the axis C of the handle body 24b being essentially parallel to the axis of the handlebar 76b. The handle body 24b is attached in the respective handlebar end regions in such a way that the supporting fin 25b is directed towards the body of the cyclist and downwards, while the slots 68b are directed approximately in the direction of travel. In the transition area between handle body 24b and handlebar 76b, a brake actuation lever 78b can be seen as part of a brake system. In addition, the handle body 24b can be formed in one piece with handlebar end pieces 80b or with corresponding covers for end pieces already provided on the handlebar in order to For example, to enable gripping and shifting of the body's center of gravity in the direction of the handlebar.

In Fig. 1 1, the handle body 24c is provided at the upper end of a walking stick 82c. The walking stick 82c has a standing part 1 2c and a grip section 84c which is orthogonal to the axis of the standing part 1 2c and on which the grip body 24c is provided. Adapting to the straight-line shape of the grip section 84c, the grip body 24c is designed essentially in a straight line, a grip body extension 54c enclosing the arcuate transition region between the horizontal grip section 84c and the vertical base part 12c.

The embodiment of the handle body 24d for a walking stick 82d according to FIG. 1 2 differs from the handle body 24c according to FIG. 1 1 only by a more undulating course of the handle portion 84d.

In all embodiments, an approximately helical shape of the fin can be seen in relation to the handle body axis A or B or C or D or E.

Claims

Expectations

1 . Handle body (24) designed to be gripped by a human hand with a surface design that is around a

Palm curvature axis ( 1 32) concavely curved palm ( 1 30), the inner finger surfaces ( 1 35-141 ) which are concavely curved around a finger curvature axis ( 142 ) and if desired also the inner surface of the thumb ( 1 28) offers a contact option, the handle body (24) has a handle body axis (A) approximately parallel to the palm curvature axis (1 32) and the finger curvature axis (142), characterized in that the handle body (24) has a fin (25) which has an active fin side surface (26, 28 ) the inner surface of the ball of the thumb ( 1 26) and / or the inner surface of the thumb ( 1 28) offers a contact option.

2. Handle body according to claim 1, characterized in that the fin (25) with its rear fin surface (44-50) faces at least part of the fingertips (144-1 50) approximately in the direction of rotation around the handle body axis (A).

3. Grip body according to claim 1 or 2, characterized in that the fin projection (a, a') decreases in a direction of progression corresponding to the course of the thumb from the ball of the thumb (1 26) to the tip of the thumb (1 29).

Handle body according to one of claims 1 - 3, characterized in that the fin projection (a') - measured on the back surface of the fin (44-50) - corresponds at least to the finger thickness in the tip area of the fingers (1 34-140).

Handle body according to one of claims 3 - 4, characterized in that the fin edge (60) runs into the handle body (24) at an approximately acute angle and/or approximately continuously towards the tip of the thumb (1 29).

Handle body according to one of claims 3 - 5, characterized in that the fin projection (a, a') is maximum in the rear, i.e. in the area (26) closer to the ball.

7. Handle body according to one of claims 1 - 6, characterized in that the fin edge (60) has an approximately continuous course with sections of different radii of curvature (R1, R2, R3), the radius of curvature (R1) being in the maximum range

Projection (a,a') is smallest.

8. Handle body according to one of claims 1 - 7, characterized in that the active fin side surface (26, 28) - viewed in a section (IVa) orthogonal to the handle body axis (A) - in its rear, in particular for the contact of the inside surface of the thumb ball (1 26) certain surface area (26) merges approximately continuously and preferably approximately in a straight line (line 65) into the surface of the handle body (24).

9. Handle body according to one of claims 1 - 8, characterized in that the active fin side surface (26,28) - each viewed in a section (IVb) orthogonal to the handle body axis (A) - in its front area (28), in particular for the contact of the inner thumb surface (1 28). in the direction of the tip of the thumb (1 29) decreasing obtuse angle (line 66) merges into the surface of the handle body (24) which is curved in an arc, preferably in a circular arc around the handle body axis (A).

0. Handle body according to one of claims 1 - 9, characterized in that the active fin side surface (26, 28) - viewed in a section (T) which is essentially parallel to the handle body axis (A) and essentially orthogonal to it - is a has a slightly convex curvature.

1 . Handle body according to one of claims 1 - 10, characterized in that the handle body (24) - viewed in sections orthogonal to the handle body axis (A) - has a maximum cross section (Q1) in a middle one - based on the longitudinal extent of the handle body axis (A). Finger contact area for the inner finger surfaces ( 1 35-141 ) and each smaller cross section (Q2,Q3) in connection areas on both sides of this middle finger contact area.

2. Handle body according to one of claims 1 - 1 1, characterized in that - viewed in sections orthogonal to the handle body axis (A).

- The curvature of the grip body surface in the contact area of the ball of the thumb (1 26) and/or the root of the thumb (1 62) is relatively small radius of curvature (S1), followed by a large radius of curvature (S2) in the contact area (30) of the palm of the hand (130) and then again a smaller radius of curvature (S3) in the contact area of the inner surfaces of the fingers (135-141).

13. Handle body according to one of claims 1 - 12, characterized in that the handle body surface in the contact area of the index finger (140) has a stop (52) for the outer side surface (152) of the

index finger (140).

14. Handle body according to one of claims 1 - 13, characterized in that the surface of the handle body (24) has a stop (56) for the edge surface (156) of the hand which is remote from the thumb (127).

15. Handle body according to claims 13 and 14, characterized in that the stops (52, 56) for the outer side surface (152) of the index finger (140) or for the edge surface (156) of the hand remote from the thumb (127). their distance is adapted to the average shape and size of the hand of an adult person in such a way that the side surface (152) of the index finger (140) and the edge surface of the hand away from the thumb simultaneously touch the respective stop (52 or 56) when the grip body is properly grasped. issue.

16. Handle body according to one of claims 1 - 15, characterized in that the handle body (24) consists of rubber-elastic material at least on its surface.

1 7. Handle body according to one of claims 1 - 1 6, characterized in that the Shore A hardness of the rubber-elastic material is in the range of 25 - 70.

1 8. Handle body according to one of claims 1 6 and 1 7, characterized in that the handle body (24) consists of solid rubber.

1 9. Handle body according to one of claims 1 - 1 8, characterized in that the handle body (24) at least in a partial area of its

Surface has a surface profiling (68).

20. Handle body according to claim 1 9, characterized in that the surface profiling is formed by incisions (68) or by slats located between successive incisions (68), which run approximately in the circumferential direction around the handle body axis (A).

21. Handle body according to claim 1 9 or 20, characterized in that the surface profiling (68) is designed such that the elastic deformability of the handle body material under hand pressure is facilitated.

22. Handle body according to one of claims 1 9 - 21, characterized in that the surface profiling (68) in the area (35-41) intended for the contact of the inner surfaces of the fingers (1 35-141) and - if desired - also in at least part of the surface area (1 30) intended for the contact of the palm of the hand (1 30). 30) is provided.

23. Handle body according to one of claims 1 - 22, characterized in that the handle body (24) as a hollow body (23) with a cavity (23) which runs essentially parallel to the handle body axis (A) for receiving a carrier (10) of the handle body (24) is formed.

24. Handle body according to one of claims 1 - 23, characterized in that it is vulcanized, sprayed or mounted on the carrier (10).

25. Handle body according to one of claims 1 - 24, characterized in that it is arranged on a crutch (10), in particular on a forearm walking aid (10), or is designed to be attached to one.

26. Handle body according to claim 25, characterized in that it is arranged essentially on the mandrel or on a crank-like central section (22) of the walking aid (1 0) intended for hand gripping, on which a standing section (1 2) extends downwards ) and connect a forearm section ( 1 8) of the walking aid ( 1 0) upwards.

27. Handle body according to claim 26, characterized in that the handle (24) continues into the stand section (1 2) and/or into the forearm section (1 8) via an end curve (54, 58).

28. Handle body according to claim 27, characterized in that at least one of the end curves (54, 58) is designed with a stop (52, 56) for the index finger (140) or for the edge surface (1 56) away from the thumb.

29. Handle body according to one of claims 26 - 28, characterized in that it is on the forearm walking aid (1 0), in particular one in one

Walking aid level (GHE) cranked forearm walking aid (10), is arranged in such a way that when the forearm (U) is approximately parallel to the forearm section (18) of the walking aid (10) and when the long cross-sectional axis (I) of the forearm cross-section is approximately parallel (UQ) (just before entering the wrist

(HG) viewed) the hand, which is in an approximately rest position relative to the forearm (U), can properly grasp the handle body (24), with the inside surface of the thumb ( 1 26) and the inner surface of the thumb ( 1 28) in an approximately rest position relative to the forearm (U) rest on the areas (26,28) of the active fin side surface (26,28) intended for their installation.

30. Handle body according to claim 29, characterized in that in the position of use of the forearm walking aid (1 0) the highest surface area (31) of the handle body extension (54) close to the standing section (1 2) and designed as an end curvature or another component of the handle body is designed as a support threshold (31) for the index finger root/thumb root transition arch area (1 31) of the hand.

31. Handle body according to claim 29 or 30, characterized in that the inclination of the handle body axis (A) relative to the axis of the forearm section (1 8) of the walking aid (10) is adjusted such that when force is introduced into the hand due to pressure on the forearm, the approach of the outer Side surface ( 1 52) of the

Index finger ( 140 ) to the associated stop ( 52 ) and / or index finger root / thumb root transition arch area ( 1 31 ) to the support threshold ( 31 ) is favored.

32. Handle body according to claim 31, characterized in that the stop (52) and the support threshold (31) are coordinated with one another in such a way that when force is introduced into the hand due to pressure on the forearm, a significant, preferably predominant part of the displacement of the Hand along the

Grip axis (A) in the direction of the standing section (1 2) inhibiting forces is applied at the point of engagement between the support threshold (31) and the index finger root/thumb root transition arch area (1 31).

33. Handle body (24) designed for detection by a human hand on the mandrel or on a crank-like central section (22) of a forearm walking aid (10) intended for hand detection, in particular in conjunction with further features according to claims 1 - 1 5 and 1 7 - 32, characterized in that the handle body (24) is made of a rubber-elastic material, at least on those parts of its surface that can be grasped by the properly placed hand.

34. Handle body according to one of claims 1 - 24, characterized in that it (24a) is arranged at the upper end of a ski pole (72a) or mountain hiking pole or is designed to be attached to such, the handle axis (B) being approximately aligned with the ski pole. or mountain hiking pole axis coincides.

35. Handle body according to one of claims 1 - 24, characterized in that it is arranged on a two-wheel handlebar (76b) or is designed for attachment to such, in particular on an operationally non-rotatable or only slightly rotatable end section of a two-wheel handlebar (76b) and if desired in association with a functional handle, such as a brake actuation handle (78b), the axis (C) of the handle body (24b) being essentially parallel to the axis of the respective end section of the handlebar (76b).

36. Handle body according to one of claims 1 - 24, characterized in that it (24c) is arranged on a walking stick (82c) or for

Attachment to such is designed, with the handle axis (D) running essentially orthogonally to the longitudinal axis of the walking stick (82c).