DE29708764U1 - screwdriver - Google Patents

Description

WESTPHAL- MLtSSÖi^lsJG.i &

PATENT ATTORNEYS· EUROPEAN PATENT ATTORNEYS

hahO57

Willi Hahn GmbH & Co. KG

Obertalstrasse 3-7

7813 6 Schonach

S hrewdriver

The invention relates to a screwdriver according to the preamble of claim 1.

Screwdrivers of this type have a multi-edge engagement area, which is usually designed as a hexagon engagement area. The engagement area is designed as a multi-edge cylinder in the case of pin wrenches and as a multi-edge ball in the case of ball-head screwdrivers. The screwdrivers can be equipped with a handle or as an angle screwdriver. It is also possible to design them as a screwdriver insert that can be inserted into a screwing tool.

With the known screwdrivers, the engagement area of the tip engages with a more or less small amount of play in the internal polygon of the screw. The screw therefore does not have a firm hold on the tip of the screwdriver, which is disadvantageous if the screw has to be screwed in or out in a place that is difficult to access, so that it cannot be held in place.

The invention is based on the object of providing a screwdriver of the type mentioned at the beginning, in which a screw is held at the tip

D-78048 VS-Villingen · Waidstrasse 33 ■ Telephone 07721 56007 · Fax 07721 55164

can be.

This object is achieved according to the invention by a screwdriver with the features of claim 1.

Advantageous embodiments and further developments of the invention are specified in the subclaims.

The basic idea of the invention is to arrange at least one clamping element in the engagement area of the tip of the screwdriver, which extends beyond the outer contour of the engagement area and rests against the inner polygon of the screw under elastic force. When the tip of the screwdriver is inserted into the inner polygon of the screw, the clamping element creates a force-locking connection between the screwdriver and the screw, which holds the screw to the tip of the screwdriver. The elastic flexibility of the clamping element enables the clamping element to be displaced against the outer contour of the engagement area and preferably into it. The clamping element therefore does not hinder the positive engagement with little play of the engagement area in the inner polygon of the screw, which is necessary for good torque transmission from the screwdriver to the screw.

In order to enable the engagement area of the tip to engage the internal polygon of the screw with as little play as possible for optimal torque transmission, the at least one clamping element is preferably arranged in a recess in the surface of the engagement area. This allows the clamping element to be completely pushed into the recess so that the positive locking and torque transmission are not impaired compared to conventional screwdrivers.

The clamping element can be designed in different ways. It is essential that it protrudes far enough beyond the surface of the engagement area of the tip - that it can be

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elastic force can be applied to the internal polygon of the screw and that it can be displaced against the outer contour or into the outer contour of the engagement area to such an extent that it does not hinder an optimal form-fitting connection of the engagement area with the internal polygon for torque transmission.

Preferably ^, a plastic material which is elastically compressible is used as the clamping element. It is also possible to manufacture the clamping element from an incompressible, elastically deformable material, preferably metal, whereby the deformation leads to the clamping element deviating into the outer contour of the engagement area. Finally, it is also possible to use a rigid clamping element which, loaded by a spring, protrudes beyond the surface contour of the engagement area and is pressed into the surface contour against the force of the spring. Which design of the clamping element is preferred depends on the required clamping force, the required wear resistance and the required manufacturing costs.

The clamping elements can be designed as point-shaped projections, e.g. as plastic lugs or as spring-loaded balls. The clamping elements are preferably designed in a linear manner, whereby an increased frictional connection can be achieved. The linear clamping elements can run in the circumferential direction or in the axial direction. If clamping elements running in the axial direction are provided, several linear clamping elements are preferably arranged at the same mutual angular distance, whereby, as with clamping elements running in the circumferential direction, a frictional connection is evenly distributed over the circumference.

In the following, the invention is explained in more detail with reference to embodiments shown in the drawing.

Fig. 1 shows a first embodiment of the invention in a side view (a), a section along the line A-A (b), a view in direction B (c) and in a section

according to line C-C,

Fig. 2 a second embodiment of the invention in a side view (a), in a section along the line A-A (b) and in a section along the line B-B (c),

Fig. 3 is a representation corresponding to Fig. 2b of a third embodiment of the invention and

Fig. 4 shows a fourth embodiment of the invention in a representation corresponding to Figures 1d and 2c (a) and an enlarged detail (b).

Fig. 1 shows the tip of a screwdriver, the engagement area of which is designed as a hexagonal ball head 10.

In the six surfaces of the ball head 10, recesses 12 are incorporated, which start together from the front vertex of the ball head 10 and run straight in the axial direction in the middle of the hexagon surfaces. The recesses 12 extend in the axial direction beyond the area of the ball head 10 with the largest diameter. Clamping elements are arranged in the recesses 12, which are designed as plastic strands 14. As shown in particular in Figures Ib and Id, the plastic strands 14 each have an approximately circular cross-section, with part of the cross-section of the plastic strands 14 lying in the recesses 12, while the other cross-sectional part protrudes with a dimension X beyond the surface contour of the ball head 10. The length of the plastic strands 14 corresponds to the axial length of the recesses 12. The plastic strands 14 come together at the front vertex.

The plastic strands 14 consist of an elastically compressible plastic, e.g. polyurethane or TPE (thermoplastic elastomers) or other elastic materials, e.g. adhesive. The plastic strands 14 are

by injection molding, by vacuum casting or by immersing the ball head 10. The plastic strands 14 are held in the recesses 12 by adhesive bonding. It is also possible to form the recesses 12 with an undercut cross-section so that the plastic strands 14 are also held in a form-fitting manner.

The dimension X by which the plastic strands 14 protrude beyond the surface of the ball head 10 is slightly larger than the play that remains between the surface of the ball head 10 and the hexagon socket surface of the screw when the ball head 10 is inserted into the hexagon socket of a screw. When the ball head 10 is inserted into the hexagon socket of the screw, the plastic strands 14 are therefore elastically compressed and, under the effect of their elastic restoring force, come into contact with the hexagon socket surfaces of the screw. This creates a force-fit clamp between the hexagon ball head 10 and the screw, by which the screw is held to the ball head 10. Since the plastic strands 14 can also be compressed into the recesses 12, the positive locking required for torque transmission between the hexagon ball head 10 and the hexagon socket of the screw is not impaired by the plastic strands 14.

Fig. 2 shows a second embodiment of the invention with a hexagon ball head 10.

In this design, a recess 12 runs in the circumferential direction of the ball head 10 in the area of the largest diameter of the ball head 10. The recess 12 can be made as a recess in the ball head 10, so that the base of the recess 12 is circular in cross section (Fig. 2b). A plastic strand 14 is introduced into the recess 12, the cross section of which is essentially circular. The depth of the recess 12 and the diameter of the plastic strand 14 are coordinated so that the plastic strand 14 in the area of the hexagonal surfaces of the ball head

10 protrudes with a dimension X beyond the surface of the ball head 10, while the edges of the ball head 10 in turn protrude radially beyond the plastic strand 14.

Here too, the plastic strand 14 can consist of a suitable elastomer material that is self-retaining, self-adhesive or attached with an adhesive and is introduced into the recess 12 by injection molding, vacuum casting or immersion. In this design, it is also possible to produce the plastic strand 14 as a prefabricated O-ring, which is then pulled onto the ball head 10 and placed in the recess 12.

Fig. 3 shows a modification of the embodiment of Fig. 2. The ball head 10 and the recess 12 correspond to the embodiment of Fig. 2. In this case, however, a spring steel ring 16 is inserted into the recess 12 as a clamping element. The spring steel ring 16 is divided like a snap ring so that it can be compressed against its spring force while reducing its diameter. The spring steel ring 16 can be circular or can be bent into a wave-shaped ring from a wire, as shown in Fig. 3. The spring steel ring 16 is dimensioned so that in the relaxed state it protrudes by the dimension X over the surface of the ball head in the area of the hexagonal surfaces of the ball head 10, while in the area of the edges of the ball head 10 it lies within the surface contour.

It is readily apparent that the embodiment of Figures 2 and 3, in which the clamping element 14 or 16 is arranged in a recess 12 running in the circumferential direction, can be used not only with a tip whose engagement area is designed as a ball head, but also with a polygonal pin wrench whose engagement area is designed as a polygonal cylinder.

Also in the embodiments of ■ Figures 2 and 3,

When the ball head 10 (or the cylindrical engagement area) is inserted into the hexagon socket of a screw, the plastic strand 14 or the spring steel ring 16 is compressed in the radial direction against its elastic restoring force and, under the effect of this restoring force, is frictionally applied to the inner surface of the hexagon socket of the screw.

Fig. 4 shows a fourth embodiment of the invention, in which the tip of the screwdriver has a hexagonal-cylindrical engagement area 18.

In this embodiment, the recesses 12 are arranged in a star shape in the flat front surface of the engagement region 18, as shown in Fig. 1c, and lead in the axial direction centrally into the hexagonal side surfaces of the engagement region 18.

Plastic strands 14 made of an elastically compressible elastomer plastic are introduced into the recesses 12 and converge in a star shape in the front face. In the axially running sections of the recesses 12, the plastic strands 14 are thickened so that they protrude by a dimension X over the surface of the hexagonal side surfaces of the engagement area 18, as can be seen in particular in Fig. 4b. The plastic strands 14 do not completely fill the axially running sections of the recesses 12 up to their rear axial end, so that a displacement space 20 remains free in the recesses 12 between the axially rear end of the plastic strand 14 and the axially rear end of the recess 12, as can be seen in Fig. 4b. The axial length of the recesses 12 in the side surfaces of the engagement area 18 is shorter than the immersion depth Y with which the engagement area 18 is immersed in the hexagon socket of a screw when inserted into it.

If the tip of the screwdriver with the engagement area 18 is inserted into the hexagon socket of a screw,

the plastic strands 14 are elastically compressed in their areas protruding beyond the side surfaces of the engagement area 18 and preferably pressed into the respective displacement spaces 20. Due to the elastic restoring force of the elastomer material of the plastic strands 14, they rest against the inner surfaces of the hexagon socket of the screw in a force-fitting manner and hold them at the tip of the screwdriver. Since the immersion depth Y of the engagement area 18 is greater than the axial length of the plastic strands 14, an area is created axially behind the plastic strands 14 in which the hexagon engagement area 18 engages positively with the hexagon socket of the screw without any loss of torque.

List of reference symbols

10 Ball head 12 Deepenings 14 Plastic support 16 Spring steel ring 18 cylindrical hexagon 20 Displacement space X Overhang dimension Y Immersion depth

Claims (10)

&iacgr;&ogr;" ■ Protection claims 1. Screwdriver with a tip that has a polygonal engagement area for insertion into the internal polygon of a screw, characterized in that the engagement area (10, 18) has at least one clamping element (14, 16) which projects beyond the outer contour of the engagement area (10, 18) and, when inserted into the screw, is elastically deformed to form a frictional fit against the internal polygon of the screw. 2. Screwdriver according to claim 1, characterized in that the at least one clamping element (14, 16) is at least partially displaced into the outer contour of the engagement region (10, 18) under the elastic deformation. 3. Screwdriver according to claim 1 or 2, characterized in that the at least one clamping element (14, 16) is arranged in a recess (12) of the surface of the engagement area (10, 18). 4. Screwdriver according to one of claims 1 to 3, characterized in that the at least one clamping element (14, 16) is elongated and is arranged in a line shape on the surface of the engagement region (10, 18). 5. Screwdriver according to one of claims 1 to 3, characterized in that the at least one clamping element is arranged point-like on the surface of the engagement area. 6. Screwdriver according to one of claims 1 to 4, characterized in that the at least one clamping element (14) extends at least partially in the axial direction of the tip. 7. Screwdriver according to one of claims 1 to 4, characterized in that the at least one clamping element (14, 11
16) runs in the circumferential direction of the tip. 8. Screwdriver according to one of the preceding claims, characterized in that the at least one clamping element (14) consists of an elastomer plastic. 9. Screwdriver according to claim 8, characterized in that the at least one clamping element (14) is attached to the engagement area (10, 18) by gluing, injection molding, vacuum casting, dipping or pulling on. 10. Screwdriver according to claim 7, characterized in that the at least one clamping element is a spring steel ring (16) arranged in a circumferentially extending recess (12) of the engagement region (10, 18).