DE19724669A1 - Handle body designed to be gripped by a 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

The invention relates to a device for detection by a human hand trained grip body with a surface design, which the hand concavely curved around the palm of the hand inner surface, the concavely curved around an axis of curvature of the finger Inner surfaces of the fingers and, if desired, the inside of the thumb offers an investment opportunity, with the handle body approximately one the palm of the hand curvature axis and the finger curvature axis has parallel handle body axis.

Such handle bodies are used wherever people hand and hold a device or auxiliary device and hold it securely, for example with crutches (forearm walking aids), mountain and hiking sticks, two-wheel steering, walking sticks, ski sticks and mountain sticks, but also for tools that have to be operated by hand, for example wheelbarrows, brushcutters, lawnmowers, fish whips and the like

Different shapes of handle bodies have been developed, all with the claim of an ergonomically improved detection by the to allow human hand. However, none of the known so far handle body fully meets all requirements.

The invention has for its object to provide a handle body, which lies optimally in the hand, optimal introduction of force into each device connected to the handle body allowed and with continuous recording  no significant signs of fatigue or pain gene arises.

To solve this problem, the invention proposes that the handle body has a fin which has an active fin side surface of the thumb ball inner surface and / or the inner thumb offers an investment opportunity and with its fin back surface at least a part of the fingertips approximately in the circumferential direction the handle body axis faces.

A major advantage of the design according to the invention is that that a pad of the thumb or / and the inner surface of the thumb ge will create without - as with conventional handle bodies - by Provision of the pad for the inside of the thumb ball or the Such an enlargement of the grip body cross section of the inside of the thumb occurs that an optimal curvature for grasping the handle body is hindered by the palm and fingers.

Since the space requirement 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 in a direction of progression corresponding to the Let the course of the thumb decrease from the ball of the thumb to the tip of the thumb, which makes the handle body overall a relatively slim and shapely Maintains structure without losing grip ergonomics. In addition, the Material consumption thereby reduced.

As a rough dimensioning rule for fin design, that the fin projection against the adjacent surface of the Handle body in the area of the juxtaposition of fingertips and Fin back of at least the finger thickness in the tip area of the fingers corresponds. Depending on the hand size and especially the finger length the fingertips come into contact with the back of the fin or  are at a distance from the back of the fin. Through the fin is also a Protection for the fingertips guaranteed, especially when the Fin radius is equal to or greater than the finger thickness in the tip be reach the fingers.

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

According to the largest contact area requirement in the thumb ball area it is recommended that the fin projection near the rear of the bale area has a maximum.

Again with a view to being touch-friendly and shapely NEN structure of the handle body is proposed that the fin edge an almost continuous course with sections of different Has radii of curvature, the radius of curvature in the range maximum radius, d. H. in which for the application of the thumb ball certain area is the smallest.

In order to achieve a low and even with strong and long pressure therefore painless surface pressure in the transition area from the Palm of the palm of the thumb, especially in the ball of the thumb To ensure rich, it is suggested that the active fin sides surface - viewed in a section orthogonal to the handle body axis - in your back, especially for the application of the thumb ball certain surface area almost continuously and preferably almost straight into the surface of the handle body.  

To continue the position of the thumb itself on the handle body in one to determine the orthopedically tension-free position as possible and thus - at Need - also to ensure power transmission through the thumb, it is proposed that the active fin side surface - each in one Section viewed perpendicular to the handle body axis - in its front, in particular the area intended for the application of the inner surface of the thumb, with an obtuse angle decreasing towards the tip of the thumb the arc there, preferably circular arc around the handle body axis curved surface of the handle body passes.

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

It is also recommended that the handle body - in each case to the handle body Axis orthogonal cuts considered - a maximum cross section in one - with respect to the longitudinal extension of the handle body axis has the lower finger contact area for the inner surfaces of the fingers and each smaller cross section in connection areas on both sides of this middle finger area.

This design has proven to be physiologically beneficial in terms of Curvature possibilities of the human hand and fingers were considered sen, also with regard to long-term detection of the handle. About that In addition, an advantage of this design is that by axial Ver Storage of the hand enclosing the handle body along the handle body depending on the individual hand format can be: With large format hand, the user of the handle body grasp it so that the center of the palm and the separation gap between big finger and little finger approximately in the section plane of the maximum grip body cross section. Has a  If the user uses a smaller hand, he can move the handle further forward, i.e. H. Capture 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 still from Advantage if - viewed in cuts orthogonal to the handle body axis tet - the curvature of the handle body surface in the contact area of the thumb clench and / or thumb root a relatively small radius of curvature - on it then a relative in the contact area of the palm large radius of curvature and then in the contact area of the Finger inner surface again has a smaller radius of curvature. 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 System area of the index finger a stop for the outer sides surface of the index finger and / or that the surface of the handle body a stop for the edge surface away from the thumb the hand.

The distance between the contact area of the index finger and the Stop for the edge surface of the hand located far from the thumb to the medium size of the hand of an adult adjusted so that at properly grasped the hand between the two stops is fixed and regardless of the surface exercise of the hand cannot slip on the surface of the handle body. In addition, with smaller hands due to the stop for cross-section decreasing the index finger there is a tendency always prefers the contact between the outer side surface of the Index finger and the associated stop. Here But even with smaller hands there is no contact with the distal thumb not lose an edge of the hand with the associated stop,  but is due to a still natural hand position hand deformity and / or hand attachment variation on the handle body maintained. In the case of crutches with a handle according to the invention body can show the tendency to fit the outer side surface of the pointer fingers on the associated stop also by the inclination of the Grip body axis opposite the course of the forearm section of the Crutch are favored.

The surface design of the handle body according to the invention is basic additionally possible in connection with all materials that were previously used for Manufacture of handle bodies applied to the human hand have been, namely: wood, metal, hard plastic, soft plastic, Rubber. The grip body is preferred at least on its surface made of rubber-elastic material, e.g. B. natural rubber, Synthetic rubber, soft polyurethane, elastomer art fabrics. "On the surface" is to say that it is also conceivable one made of hard material, such as wood, hard plastic or To cover the metal body with a rubber layer, the rubber layer optionally having approximately constant wall thickness may have, but it is also conceivable for the profile design of the Surface due to different wall thickness of the rubber layer carry. The rubber layer can be made of an elastic coating be formed, which is pulled over the base body and tensioned so that it gets a grip on the base body. It is also conceivable that the coating is preformed as a spatial structure, at for example by injection molding plastic or by vulcanizing. It is also possible that the handle body is made of solid rubber. Solid rubber means that the entire handle body made of rubber there, of course, recesses in the handle body for receiving a rod-shaped support element are permitted. Especially at Intricately shaped straps are also thought of the handle body sprayed on or vulcanized onto the respective carrier.  

For making an ergonomically comfortable and non-slip It is proposed to have a Shore A hardness in the range of 25-70 to choose. With such an adjustment of the hardness is also one elastic adjustment to the handshake possible.

The handle body can at least in a partial area of its surface be provided with a surface profile. If here from Ober surface profiling is spoken, so this can be structured are primarily geared to the greatest possible slip resistance is guaranteed. But there are also surface profiles Structure conceivable that the elastic deformability through the profiling of the handle body is affected. Material elasticity and formula elasticity due to the surface structure, mutual coordination is required mung. If the material-related hardness is relatively large, you can a suitable elastic deformability by accordingly Get embossed surface profiling and vice versa.

The surface profiling can e.g. B. be formed by incisions, which run approximately in the circumferential direction around the handle body axis. With such incisions can have a significant impact on the elastic Deformability of the handle body are made possible.

But it is also conceivable to have a finely structured surface profile only to change the roughness and thus the Improve slip resistance.

Surface profiling is used in particular for the system of the inner areas of the fingers and if necessary also in at least part of the intended for the application of the palm Provide th surface area.  

The connection of the handle body with the respective structure on which the user can act or on which he wants to support himself in any way be produced in a manner. For example, the handle body on the one or the other or both ends with a shaft be inserted into the structure to be taken, or with a flange that is screwed or glued to this structure. In particular, it is contemplated that the handle body as a hollow body per with a substantially parallel to the handle body axis Cavity is formed for receiving a carrier of the handle body or that the handle body is sprayed or vulcanized onto the carrier is.

An application for the handle 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, as long-term when walking long distances Forces must be transferred. The handle body according to the invention are also particularly suitable for cranked forearm walking aids which is attached to the handle body in the offset area. Cranking area is a cranked middle section of the walking aid which is down a stand section and up a sub Connect the arm section of the walking aid. When attaching the fiction appropriate grip body on such a cranked forearm walking aid can the handle body in the stand section and / or in the lower Continue arm section over one end curve each so that even if the grip body is not ideally grasped, the hand is not can abut against the standing section or the forearm section. Accordingly, at least one of the end curvatures can be used as a stop for serve the index finger or for the edge surface of the hand far from the thumb or be specially shaped.  

If the handle body according to the invention in a forearm walking aid Is used, for example according to DE 195 03 565 A1 or in particular Forearm walking aids of the type known from DE 195 47 484 A1, see above a preferred embodiment is that he on the forearm-go help, especially a cranked under in a walking aid arm walking aid, is arranged such that with an approximately parallel course of the forearm to the forearm section of the walking aid and when approaching Parallel position of the long cross-sectional axis of the forearm cross-section (viewed shortly before entering the wrist) the opposite Forearm in approximately rest position, the handle body can properly grasp the inside of the thumb pad and the inner surface of the thumb in a near rest position compared to the lower poor in the areas of the active fins intended for your plant side face. The force input into the handle body can then in the rectilinear extension of the forearm. The wrist is used relatively little, which is particularly the case with rheumatics and older patients is of considerable advantage. The need for one forceful, active gripping of the handle body is in general not required and can be reduced to special situations. How nice explained above is an adaptation to different handfor Men and sizes possible, especially because of the varying cross section of the handle body.

Furthermore, the handle body according to the invention is extremely suitable attached to the top of a ski pole or mountain hiking pole to be trained or for attachment to such who the. The handle axis can approximately with the ski stick or Mountain hiking stick axis coincide.

The handle body with its fin is also so in this application dimensioned that fingertips plant on the back of the fin take or distance from the back of the fin. This is from  Advantage over known grip shapes on ski poles and mountain hikes sticks in which the handle, which is usually too thin, overlaps the Thumbs over the extensive fingers required and access thereby is weakened.

The use of elastic material is also used for mountain hiking sticks within the specifications given above is advantageous as it is the hand adjusts so that the pressure required to hold the Griffs does not require unnecessary effort. Again the handle designed rough surface so that slipping is prevented or at least not prevented by the sling alone. Grasping the In extreme cases, elastic and rough surface material allows that entire body weight through the hand gripping the grip body transfer. Also the problem of slipping when using the handle Gloves, e.g. B. woolen gloves is solved.

The grip body can also be used with ski poles and hiking poles be injected.

An embodiment in which a throat in the upper for the index finger Area of the handle body is incorporated, leads to additional force load capacity in the axial direction of the respective floor.

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

A loop can also be used. It serves, for example protection against losing. Basically, the loop can can also be dispensed with if a handle body according to the invention is used Application comes.  

The handle body according to the invention is also on two-wheelers on two-wheelers handlebars suitable for use. This applies particularly to operationally non-rotatable or only slightly rotatable end sections a two-wheel drive. The handle can also be a function handle can be assigned, such as for braking or Gear shift actuation is used. If an inventive Handle in connection with, for example, a brake lever for use dung comes, so it is recommended the relative angular positions of the hand handle body and the brake lever inevitably, for example define a common beam 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 plastic handles available there or hard rubber. This in particular solves both bicycles as well as problem with motorcycles that is necessary considerable force on the hands results. Hands are basically caused by vibrations depending on pace and road conditions. Even when climbing and descending stretch requires a special level of comprehension, which is invented by erfin handle design according to the invention can be easily achieved. The danger slipping, especially when wearing woolen gloves hen, is reduced, as well as the risk of slipping Welding application between the palm and the handle body. With fiction according to the design of the handle body, the vibrations are not transferred to the wrists more hard than before. The emergence of cramps on the hand gripping the handlebar is reduced.

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

Furthermore, the handle according to the invention is also for use with Walking sticks are suitable, the handle axis then essentially runs orthogonal to the longitudinal axis of the walking stick.

A non-slip hold is also used in the walking stick application enables and greatly improves the safe guidance of the stick. Also in In this application, a throat is advantageous for the index finger. The dependence on hand size is particularly helpful is achieved in that the handle at various points of his Length can be recorded.

The above information on the essential features of the Erfin apply equally to handles for detection by the right Hand and for handles for grasping by the left hand. Usually one becomes the optimal adjustment for the left hand and for the right Hand select separate designs that are separated by reflection emerge. However, compromise solutions are also conceivable, in particular the case when the ends of the handle are interchangeable.

The accompanying figures explain the invention with reference to Ausfüh examples. They represent:

Fig. 1 is a forearm walker as an application example of an inventive grip body;

Fig. 1a, the view of a right hand to visualize that the handle body of Figure 1 is a handle body for a right hand and for the later representation of the togetherness of individual surface areas of the right hand on the one hand and individual surface areas of the handle body on the other.

FIG. 2 shows an enlarged view of the handle body according to FIG. 1 in the same viewing direction as there, namely at point II of FIG. 1;

FIG. 2a, the corresponding right hand;

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

FIG. 3a shows the associated right hand;

. Fig. 3b is a plan view corresponding to Figure 3 in a tion Netzkonstruk as 3D representation resulting from a moderate computer;

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

FIG. 4a shows the corresponding right hand;

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

FIG. 5a, the corresponding right hand;

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

FIG. 6a, the corresponding left hand;

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

Fig. 7a the associated left hand;

Fig. 7b is a plan view corresponding to Figure 7, again in 3D computer manner.

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

FIG. 8a the associated left hand;

Fig. 9 shows a handle body on the ski pole or walking stick Berg;

Fig. 9a, the corresponding left hand;

FIG. 10 is a handle body on the handlebars of a bicycle;

FIG. 10a the associated left hand;

Figure 11 is a view of a handle body according to the invention at the obe ren end of a walking stick.

FIG. 11a the associated right hand;

Fig. 12 shows a modified embodiment of an inventive handle body SEN at the cane;

Fig. 12a the associated left hand.

In Fig. 1, a forearm walking aid is shown, which is generally designated 10 . This forearm walking aid comprises a stand part 12 with a foot part 14 and an extension option at 16 ; it further comprises a forearm part 18 with a forearm opening clasp 20 to the right and a stand part 12 and forearm part 18 connecting crank portion 22 which is provided with a handle 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 linkage of the forearm walking aid that forms the stand part 12 and the forearm part 18 . The forearm walking aid shown in FIG. 1 is cranked in a plane with the second plane of FIG. 1 coincides. In Fig. 3 the level corresponding to the drawing level of Fig. 1 is shown in dash-dotted lines and designated 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 hinge axis HG of the wrist is approximately as shown in dash-dot 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 18 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 is a contact surface 26 for the installation of the thumb ball inner surface 126 is introduced . Furthermore, the fin 25 has a contact surface 28 for the inner surface 128 of the thumb. The contact surfaces 26 and 28 together form an active fin side surface 26 , 28th

When the grip body 24 is gripped by the hand, the palm 130 is concavely curved with an axis of curvature 132 . The fingers 134 , 136 , 138 and 140 are also concavely curved when the grip body 24 is gripped with their inner surfaces ( 135 , 137 , 139 , 141 ), specifically around the axis of curvature 142 . The palm 130 rests against the contact area 30 , while the finger surfaces 135-141 contact the contact area 35-41 ( FIG. 4). The fingertips 144-150 of the fingers 134-140 lie in the state of the grip body detection on the contact surface 44-50 or face 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 handle body 24 , the outer side surface 152 of the index finger 140 lies on or near a stop surface 52 of a handle body extension 54 , which encloses the base part 12 ( FIG. 2). Furthermore, the distal edge surface 156 of the hand can strike a stop surface 56 , which is formed by a section 58 enclosing the forearm section 18 of the extension body 24 . 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 with the side surface 152 of the index finger 140 on the stop surface 52 for ergonomic reasons. Depending on the size of the hand, the user can shift his hand in the direction of the grip body axis A, so that he can encompass the cross-sectional area corresponding to this curvature of the finger with the most comfortable curvature of his hand.

It can be seen that the active fin side surface 26 , 28 to the investment area 28 of the inner surface 128 of the thumb becomes narrower towards the tip of the thumb 129 . 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 . In the section according to Fig. 4 shows the profile of the cross-sectional boundary having a curvature relatively small radius of curvature S1 in the contact area 62 of the thumb root 162, having a substantially larger radius of curvature S2 in the contact area 30 of the palm of the hand 130 and then again with a smaller radius of curvature S3 in the contact area 35- 41 of the inner fingers 135-141 .

From Fig. 4 and 5 it is seen that the active fin side surface 26, 28 extends with a slight convex curvature in a section plane T (Fig. 4) which is orthogonal to the active flipping side surface 26, 28 and is parallel to the grip 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 α of, for example, 25 ° with the horizontal when the stand part 12 is held vertically (in 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 finger surfaces 135-141 , slots 68 are let into the rubber material, which prevent slipping and influence the softness of deformation 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 radius 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 '.

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

Thereby, the grip body 24 6-8a 1-5 24 corresponds to FIG. The handle body shown in FIG. However, is constructed in mirror image relative to the handle body 24 of FIGS. 1-5 and comprises in addition a support lug 70 for forming the abutment surface 52.

In FIGS. 9 to 12 additional embodiments are illustrated, wherein there analogous parts designated by the same reference numerals as in Figs. 1-5 and in addition in each case with the index "a", "b", "c" and "d" are.

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

In Fig. 10, a handle body 24 b according to the invention is arranged on a handlebar 76 b of a bicycle, not shown, wherein the handle body 24 b is essentially straight and the axis C of the handle body 24 b extends essentially parallel to the axis of the handlebar 76 b. The handle body 24 b is attached in the respective handlebar end areas such that the supporting fin 25 b is directed towards the body of the cyclist and downwards, while the slots 68 b are directed approximately in the direction of travel. In the transition area between handle body 24 b and handlebar 76 b, a brake actuation lever 78 b can be seen as part of a brake system. In addition, the handle body 24 b can be formed in one piece with handlebar end pieces 80 b or with corresponding coatings for end pieces already provided on the handlebar, in order, for. B. on slopes to reach around and shift the center of gravity towards the handlebar.

In Fig. 11, the handle body 24 c is provided at the upper end of a walking stick 82 c. The walking stick 82 c has a standing part 12 c and a section 84 c running orthogonally to the axis of the standing part 12 c, on which the grip body 24 c is provided. In adaptation to the rectilinear shape of the grip section 84 c, the grip body 24 c is essentially rectilinear, with a grip body extension 54 c enclosing the arcuate transition region between the horizontal grip section 84 c and the vertical standing part 12 c.

The embodiment of the handle body 24 d for a walking stick 82 d according to FIG. 12 differs from the handle body 24 c according to FIG. 11 only by a more undulating course of the handle portion 84 d.

In all of the embodiments, one can see an approximately helical shape The course of the fin relative to the handle body axis A or B or C or D or E.

Claims (33)

1. For grasping by a human hand trained grip body ( 24 ) with a surface design, which of the palm surface curvature axis ( 132 ) concavely curved palm surface ( 130 ), around a finger curvature axis ( 142 ) concavely curved finger surfaces ( 135-141 ) and if desired, the inner surface of the thumb ( 128 ) also offers a possibility of contact, the handle body ( 24 ) having an axis of grip body axis (A) which is approximately parallel to the axis of the hand surface ( 132 ) and the finger curvature axis ( 142 ), characterized in that the handle body ( 24 ) has a fin ( 25 ) which, with an active fin side surface ( 26 , 28 ) of the inner surface of the thumb ball ( 126 ) and / or the inner surface of the thumb ( 128 ), offers a facility. 2. Handle body according to claim 1, characterized in that the fin ( 25 ) with its fin rear surface ( 44-50 ) faces at least part of the fingertips ( 144-150 ) approximately in the direction of rotation around the handle body axis (A). 3. Handle body according to claim 1 or 2, characterized in that the fin projection (a, a ') in a progressive direction accordingly the course of the thumb from the thumb ball ( 126 ) to the tip of the thumb ( 129 ) decreases. 4. 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 region of the fingers ( 134-140 ). 5. Handle body according to one of claims 3-4, characterized in that the fin edge ( 60 ) towards the tip of the thumb ( 129 ) runs approximately at an acute angle and / or approximately continuously into the handle body ( 24 ). 6. Handle body according to one of claims 3-5, characterized in that the fin projection (a, a ') in the rear, ie in the bale near area ( 26 ) is maximum. 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) in the region of maximum projection (a, a ') is the 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 their backward gene, in particular for the application of the thumb ball inner surface ( 126 ), the surface area ( 26 ) merges into the surface of the handle body ( 24 ) approximately continuously and preferably approximately in a straight line (line 65 ). 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, in particular for the installation of the inner thumb surface ( 128 ) certain area ( 28 ) with an obtuse angle (line 66 ) decreasing towards the tip of the thumb ( 129 ) into which there is an arcuate, preferably circular arc around the handle body axis (A) curved surface of the handle body ( 24 ). 10. Handle body according to one of claims 1-9, characterized in that the active fin side surface ( 26 , 28 ) - viewed in a substantially parallel to the handle body axis (A) and on it in the substantially orthogonal section (T) - one has a slightly convex curvature. 11. Handle body according to one of claims 1-10, characterized in that the handle body ( 24 ) - viewed in each case to the handle body axis (A) or thogonal cuts - a maximum cross section (Q1) in one - based on the longitudinal extension of the handle body axis ( A) - Middle finger contact area for the Fingerinnenflä Chen ( 135-141 ) and each smaller cross-section (Q2, Q3) in connection areas on both sides of this middle finger contact area. 12. Handle body according to one of claims 1-11, characterized in that - viewed in cuts orthogonal to the handle body axis (A) - the curvature of the handle body surface in the contact region of the thumb ball ( 126 ) and / or thumb root ( 162 ) has a relatively small radius of curvature (S1 ), then in the contact area ( 30 ) of the palm ( 130 ) has a large radius of curvature (S2) and then in the contact area of the inside fingers ( 135-141 ) again has a smaller radius of curvature (S3). 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 remote from the thumb ( 127 ) edge surface ( 156 ) of the hand. 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 ) remote from the thumb ( 127 ) of the hand in their distance to the average shape and size of the hand of an adult are adapted such that the side surface ( 152 ) of the index finger ( 140 ) and the distal edge surface of the hand at the same time when the grip body is properly gripped on the respective stop ( 52 and 56 ) 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. 17. Handle body according to one of claims 1-16, characterized, that the Shore A hardness of the rubber-elastic material in the Be ranges from 25-70. 18. Handle body according to one of claims 16 and 17, characterized in that the handle body ( 24 ) consists of solid rubber. 19. Handle body according to one of claims 1-18, characterized in that the handle body ( 24 ) has at least in a partial area of its surface a surface profile ( 68 ). 20. Handle body according to claim 19, characterized in that the surface profiling of incisions ( 68 ) or between successive incisions ( 68 ) located lamellae, which run approximately in the circumferential direction around the handle body axis (A). 21. Handle body according to claim 19 or 20, characterized in that the surface profile ( 68 ) is designed such that the elastic deformability of the handle body material is facilitated by hand contact pressure. 22. Handle body according to one of claims 19-21, characterized in that the surface profiling ( 68 ) in the area for the application of the inner finger surfaces ( 135-141 ) determined area ( 35-41 ) and - if desired - also in at least part of the for the plant of the palm ( 130 ) certain surface area ( 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 to the handle body axis (A) substantially parallel cavity ( 23 ) for receiving a carrier ( 10 ) Handle body ( 24 ) is formed. 24. Handle body according to one of claims 1-23, characterized in that it is vulcanized onto the carrier ( 10 ), sprayed on or drawn up. 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 for attachment to such. 26. Handle body according to claim 25, characterized in that it is arranged substantially on the mandrel or on a certain for hander detection, cranking-like central section ( 22 ) of the walking aid ( 10 ), on which a standab cut down ( 12 ) and connect up a forearm section ( 18 ) of the walking aid ( 10 ). 27. Handle body according to claim 26, characterized in that the handle ( 24 ) in the standing section ( 12 ) and / and in the forearm section ( 18 ) continues in each case via an end curve ( 54 , 58 ). 28. Handle body according to claim 27, characterized in that at least one of the end curvatures ( 54 , 58 ) is formed with a stop ( 52 , 56 ) for the index finger ( 140 ) or for the distal edge surface ( 156 ). 29. Handle body according to one of claims 26-28, characterized in that it is arranged on the forearm walking aid ( 10 ), in particular a cranked forearm walking aid ( 10 ) in a walking aid level (GHE), in such a way that with an approximately parallel course of the Forearm (U) to the forearm section ( 18 ) of the walking aid ( 10 ) and when the long cross-sectional axis (I) of the forearm cross section (UQ) is approximately parallel (viewed shortly before entering the wrist (HG)) which is opposite the forearm (U ) hand in approximately rest position can grasp the handle body ( 24 ) properly, the inner surface of the thumb ball ( 126 ) and the inner surface of the thumb ( 128 ) in a near rest position against the forearm (U) in the areas intended for their system ( 26 , 28 ) of the active fin side surface ( 26 , 28 ). 30. Handle body according to claim 29, characterized in that the inclination of the handle body axis (A) relative to the axis of the forearm section ( 18 ) of the walking aid ( 10 ) is set such that when force is applied to the hand by pressure loading the forearm, the approach of the outer side surface ( 152 ) of the index finger ( 140 ) to the associated stop ( 52 ) is favored. 31. Handle body according to one of claims 1-24, characterized in that it ( 24 a) at the upper end of a ski pole ( 72 a) or mountain hiking poles arranged or designed for attachment to such, the handle axis (B) approximately with the ski pole or mountain hiking stick axis coincides. 32. Handle body according to one of claims 1-24, characterized in that it is arranged on a two-wheel control arm ( 76 b) or is designed for attachment to such, in particular on an operationally non-rotatable or only slightly rotatable end portion of a two-wheel control arm ( 76 b) and, if desired, in association with a functional handle, such as a brake operating handle ( 78 b), the axis (C) of the handle body ( 24 b) being substantially parallel to the axis of the respective end section of the handlebar ( 76 b). 33. Handle body according to one of claims 1-24, characterized in that it ( 24 c) on a walking stick ( 82 c) is arranged or designed for attachment to such, the handle axis (D) substantially orthogonal to the longitudinal axis of the walking stick ( 82 c) runs.