EP0597216A1 - Hand-operated screwdriver - Google Patents

Abstract

A hand-operated screwdriver (1) having a blade (3) and a handle (5) is proposed, which is characterised in that the surface of the handle (5) is provided, at least in certain areas, with sharp-edged points which can be produced by means of an abrasive-blasting process, said points, during handling of the screwdriver, shearing off a liquid film of water and/or oil between hand and handle surface. This produces an optimum grip, with the result that even large torques can be transmitted without fatigue. <IMAGE>

Description

The invention relates to a hand-operated screwing tool with a blade and a handle. Tools of the type mentioned here are understood to mean screwdrivers, nut drivers, socket wrenches which have blades or plug-in or plug-in blades which are firmly connected to a handle.

It is known to design the handles of such hand-operated screwing tools with a special shape so that the highest possible torque can be transmitted without fatigue. It is important on the one hand that a certain form fit or static friction is ensured between the surface of the handle and the palm of the hand. On the other hand, the palm of the hand must not be subjected to excessive loads or shear forces, as otherwise an overload of the skin is practically unavoidable.

It has been found that these criteria can only be met inadequately with conventional hand-operated screwing tools.

It is therefore an object of the invention to provide a hand-operated screwing tool with which high torques can be transmitted without fatigue and without overloading the palm of the hand.

This object is achieved in a screwing tool of the type mentioned with the help of the features listed in claim 1. The fact that the surface of the handle of the screwing tool is at least partially provided with sharp-edged tips that can be produced by means of a blasting process ensures that when handling the screwing tool an existing liquid film between the hand and handle surface is sheared off or pierced. So there is a good so-called grip, which on the one hand enables the transmission of high torques and on the other hand avoids overloading the palm of the hand.

An embodiment of a screwing tool is preferred in which the tips are formed on the surface in such a way that when the tool is handled they protrude at least with their head region from the liquid film. This means that a liquid film made of sweat or oil, for example, is penetrated by the tips. When handling the screwing tool, the liquid is displaced into the spaces or valleys between the tips, so that the latter enable the screwing tool to be handled in a non-slip manner.

An embodiment of the screwing tool is preferred in which sharp-edged material particles are allowed to act on the surface of the handle by means of a blasting process. The material particles tear particles out of the surface of the handle so that the sharp-edged tips mentioned remain. The sharpness of the tips is ensured by the use of sharp-edged material particles.

A screwing tool is preferred in which the surface of the handle is processed with the aid of corundum, preferably cast steel corundum. The material particles can be reused, if necessary after carrying out a cleaning process, and therefore enable particularly economical use.

A screwing tool in which approximately 80% of the handle surface is provided with tips is particularly preferred. It is possible that the tips are arranged in strip-like areas that span the handle in the longitudinal and / or transverse direction. Ultimately, this means that the grip of the screwing tool can be adapted to the desired application in a wide range.

Further refinements of the screwing tool result from the remaining subclaims.

The invention also relates to a method for producing a hand-operated screwing tool.

Methods of the type mentioned here are known. To enable fatigue-free transmission of torques, handles of such screwing tools are equipped with a four-sided or polygonal base body. However, it has been found that on the one hand there is a high load on the palm of the hand, and on the other hand that there is often no fatigue-free transmission of high torques.

It is therefore an object of the invention to provide a method for producing a hand-operated screwing tool, with the aid of which tools can be produced which do not have these disadvantages.

To solve this problem, a method is proposed which is characterized by the features listed in claim 9. In this manufacturing process, the surface of the handle is subjected to a blasting process, at least in some areas, in order to form sharp-edged tips which are arranged so closely that injury to the user of the tool is excluded, but on the other hand a high grip is ensured.

Particularly preferred is an embodiment of the method, which is characterized in that a nozzle is used in the blasting method, which is guided over the surface of the handle in such a way that excessive heating of the surface is excluded. The nozzle is preferably guided in an oscillating manner.

An embodiment of the method in which sharp-edged material is particularly preferred alparticles are used whose grain size is in the range from 0.8 mm to 1.25 mm. Sharp-edged particles of this size tear particles out of the surface of the handle when the blasting process is carried out, so that a desired roughness is achieved in that the sharp-edged tips remain. These ensure non-slip handling of the screwing tool, even if the user has wet or oil-soiled hands.

Further embodiments of the method result from the remaining subclaims.

• Figur 1 ein erstes Ausführungsbeispiel eines handbetriebenen Schraubwerkzeugs;
• Figur 2 ein zweites Ausführungsbeispiel eines Schraubwerkzeugs mit gegenüber Figur 1 geändertem Griffbereich und
• Figur 3 ein weiteres Ausführungsbeispiel eines Schraubwerkzeugs.

The invention is explained below with reference to the drawing. Show it:

• Figure 1 shows a first embodiment of a hand-operated screwing tool;
• Figure 2 shows a second embodiment of a screwing tool with a modified grip area compared to Figure 1 and
• Figure 3 shows another embodiment of a screwing tool.

The hand-operated screwdriver described below is designed as a conventional screwdriver. However, the invention relates to all types of hand-operated screwing tools, in addition to screwdrivers, nut drivers, socket wrenches, tools with fixed blades and those with reversible blades are equally covered. In addition, so-called clamp lifters, scrapers, rolling tools, reamers and pre-cutters are also recorded. The tool shown in the figures is designed for Phillips screws. Of course, normal screwdrivers can also be implemented here.

The screwing tool 1 has a fixed blade 3 and a handle 5, which has a voluminous, essentially spherical base body for the fatigue-free transmission of larger torques. The surface of the handle has been subjected to a blasting process in an area hatched for clarity, as a result of which sharp-edged tips are formed which, when handling the screwing tool, shear or pierce a liquid film of water or oil present between the hand and handle surface. The surface structure of the area 7 is designed in such a way that the tips are very close together and therefore do not pose any risk of injury to the user. However, they are designed so that they protrude at least with their head area from the liquid film when handling the screwing tool and thus represent a good frictional connection between hand and handle. The liquid film is displaced into the valleys lying between the peaks, so that water or oil can affect the grip of the screwing tool 1 very little.

The handle 5 of the screwing tool 1 is polygonal, the edges running essentially in the direction of the longitudinal axis of the tool being at different distances from one another, so that strips of different widths are formed.

FIG. 2 shows a further exemplary embodiment of the screwing tool 1 according to FIG. 1. The same parts are provided with the same reference numbers, so that reference is made to the description of FIG. 1. The screwing tool 1 in turn has a blade 3, which is designed to be stationary here, and a handle 5. This has — shown here hatched — transverse strip-shaped regions 7 a, which are arranged at a distance from one another, transversely to the longitudinal direction of the tool. The number, spacing and width of the strips can be varied as desired, so that the grip of the tool can be adapted to the application. The regions 7a can in turn be produced by a blasting method already mentioned with reference to FIG. 1.

Finally, FIG. 3 shows a last exemplary embodiment of a screwing tool 1, which in turn has a fixed blade 3 and a handle 5. This is again provided with, in turn, marked by hatching, essentially strip-shaped regions 7b, which here, however, extend practically parallel to the longitudinal direction of the tool. The strip-shaped regions 7b are in turn produced by means of a blasting process.

The longitudinal extent of the strip-shaped regions 7b, their width and the spacing of the strips from one another can be adapted to the particular application of the tool. The regions 7, 7a and 7b, as mentioned, are produced by means of a blasting method in which a gas, preferably air, which is under pressure is used as the carrier and / or transport medium. The medium serves to blow sharp-edged material particles against the surface of the handle 5. Corundum, preferably cast steel corundum, but also glass splinters and / or glass shot are used as material particles. The sharp-edged material particles blown against the surface of the handle 5 by the transport medium at high speed remove particles from the surface or tear them out of the handle surface. When using sharp-edged material particles, tips remain on the handle surface, the size and spacing of which depends on the use of the size of the material particles which are blown against the surface by means of the carrier medium.

When using cast steel corundum, the material particles can be used several times, if necessary after a cleaning step. Finally, the material particles will wear out and lose their sharp edges, so that the tips formed on the grip surface in regions 7, 7a and 7b no longer have the necessary sharp edges.

It is also possible to mix cast steel corundum with glass splinters and / or glass shot. The glass particles can also be used in pure form. However, it has been found that broken glass and broken glass can preferably only be used once. When used, the glass particles usually break down into such small particles that reuse is not possible.

A grain size of the sharp-edged material particles which is in the range from 0.4 mm to 1.6 mm is preferred. However, grain sizes of 0.8 mm to 1.25 mm are particularly preferred.

During the blasting treatment of the handle surface, a continuous area 7 can be exposed to sharp-edged material particles, as shown in FIG. 1. However, it is also possible to subject only strip-shaped areas to a blasting process, which are interrupted or continuous, and, as shown in FIG. 2, run around the handle 5 transversely to the longitudinal direction of the screwing tool. It is also possible for the strips, as shown in FIG. 3, to run in the longitudinal direction over the handle surface and to be at a distance from one another. An interrupted embodiment of the strip-shaped regions 7b is also conceivable here. In addition, more or less punctiform areas that are subjected to a blasting process can be distributed over the surface of the handle 5. Preferably 60% to 90%, in particular 70% to 85% of the handle surface is subjected to a blasting process. In particular, embodiments are preferred in which approximately 80% of the handle surface is treated with a blasting process and is therefore provided with tips. This results in an optimal grip of the tool.

Screwing tools 1 are preferred, the handle of which is made of an impact-resistant plastic. When carrying out the blasting process, excessive heating of the handle surface must be avoided so that the sharp-edged tips produced in the blasting process do not melt. Therefore, when carrying out the method for producing a screwing tool 1 of the type described here, a nozzle is used which is guided over the surface of the handle 5. The nozzle is preferably moved in an oscillating manner over the surface, that is to say the surface is processed in quasi-linear fashion in adjacent strips. The nozzle is preferably guided so that the small sharp-edged material particles used in the blasting process strike the surface of the handle 5 approximately perpendicularly. This results in particularly sharp-edged tips on the handle surface.

From the above it is readily apparent that the manufacturing process can be implemented very inexpensively, especially when using cast steel corundum, because these material particles can be fed to the blasting process several times, possibly after a cleaning step.

The blasting process itself is particularly easy to implement since it only requires the use of a pressurized gaseous transport or carrier medium. Compressed air is preferably used which flows out through a nozzle and entrains the sharp-edged material particles. The gas jet emerging from the nozzle is guided together with the entrained material particles onto the surface of the handle 5 of the screwing tool 1, the outflow rate being adaptable to the base material of the handle. It must be ensured that particles are torn out of the handle surface by the impacting material particles, so that sharp-edged tips remain there that are so close together that on the one hand injury to the user is excluded, but on the other hand it is ensured that a liquid film of water remains or oil is penetrated by the tips when the screwing tool is used.

It is clear from the explanations relating to FIGS. 1 to 3 that only the force transmission area requires the blasting treatment. In particular, the end region of the handle 5, that is to say opposite the blade, remains untreated so that the shear forces acting on the skin of the user remain minimal when the screwing tool is used. The front region of the handle 5 facing the blade 3 is preferably also untreated, that is to say it has a smooth surface. The sensitive fingertips are thus subjected to lower frictional forces, so that the tool can be used gently.

In the manufacturing process described here, in which material particles with a grain size of 0.8 mm to 1.25 mm are used, the following values result, for example, for the surface of the treated grip area:

1. Measurement in the longitudinal direction of the tool:

The maximum roughness R _max is 34.17 µm (0.96 µm), the average roughness depth R _z is 29.87 µm (0.74 µm), the arithmetic mean roughness value R _a is 5.66 µm (0.11 µm) , the roughness depth R _T , that is, the distance between the bottom profile and a reference profile given in one measurement is 39.59 µm (1.06 µm). Furthermore, the profile depth P _T measured between the top of a peak and the bottom of a valley is 48.40 µm (2.64 µm). Finally, the mean Rp is used to denote the mean smoothing depth, i.e. the distance between the highest point of the profile and the reference profile, for which a value of 11.26 µm (0.41 µm) was achieved. The values for conventional tools manufactured under the same conditions are given in brackets.

2. Measurement across the longitudinal direction:

The maximum roughness R _max is 55.40 µm (1.31 µm), the average roughness R _z is 41.32 µm (1.15 µm), the arithmetic mean roughness value R _a is 8.63 µm (0.19 µm) , the roughness depth R _T , that is to say the distance between the basic profile and a reference profile given during a measurement, is 59.60 µm (1.41 µm). Furthermore, the profile depth P _T measured between the top of a peak and the bottom of a valley is 70.18 µm (10.76 µm). Finally, the mean Rp is used to denote the mean smoothing depth, i.e. the distance between the highest point of the profile and the reference profile, for which a value of 17.71 µm (0.58 µm) was achieved. The values for conventional tools manufactured under the same conditions are given in brackets.

The values listed here as examples result in an optimal grip. This means that maximum torques can be transmitted without fatigue without excessive stress on the palm of the hand. The forces to be exerted on the handle of the screwing tool are reduced in that a good frictional connection is ensured, which results from the tips generated in the blasting process penetrating a liquid film of water and / or oil during handling of the screwing tool and the user having an optimal hold on the handle of the tool.

Claims (15)

1. Hand-operated screwing tool with a blade and a handle, characterized in that the surface of the handle (5) is at least partially provided with sharp-edged tips that can be produced by means of a blasting method, which, when handling the screwing tool (1), has a liquid film between the hand and the handle -Shear off or puncture the surface. 2. Screwing tool according to claim 1, characterized in that the tips are designed so that they protrude at least with their head area from the liquid film when handling the screwing tool (1). 3. Screwing tool according to claim 1 or 2, characterized in that in the blasting process as a carrier and / or transport medium under an overpressure gas, preferably air, can be used. 4. Screwing tool according to one of claims 1 to 3, characterized in that sharp-edged material particles act on the surface of the handle (5) in the blasting process. 5. Screwing tool according to claim 4, characterized in that corundum, preferably cast steel corundum, glass splinters and / or glass shot can be used as material particles. 6. Screwing tool according to one of the preceding claims, characterized in that the end region and / or the front region of the handle (5) facing the screwdriver tip has a smooth surface. 7. Screwing tool according to one of the preceding claims, characterized in that the surface of the handle (5) has interrupted or continuous strips (7a, 7b) with tips, the strips being oriented in the longitudinal direction or transversely thereto. 8. Screwing tool according to one of the preceding claims, characterized in that 60% to 90%, preferably 70% to 85%, in particular 80% of the handle surface are provided with tips. 9. A method for producing a hand-operated screwing tool, in particular a screwing tool according to one of claims 1 to 8, characterized in that the surface of the handle is subjected to a blasting process at least in regions to form sharp-edged tips. 10. The method according to claim 9, characterized in that gas, in particular air, is used as the carrier and / or transport medium. 11. The method according to claim 9 or 10, characterized in that in the blasting process sharp-edged material particles impact at high speed on the surface of the handle and tear out particles to form the sharp-edged tips there. 12. The method according to any one of claims 9 to 11, characterized in that a nozzle is used in the blasting process, which is preferably performed oscillating over the surface of the handle. 13. The method according to any one of claims 9 to 12, characterized in that the material particles used in the blasting process impinge approximately perpendicular to the surface of the handle. 14. The method according to any one of claims 9 to 13, characterized in that corundum, cast steel particles, glass fragments and / or glass shot is used as the sharp-edged material particles used in the blasting process. 15. The method according to claim 14, characterized in that the grain size of the sharp-edged material particles in the range of 0.4 to 1.6 mm, preferably in the range of 0.8 to 1.25 mm.

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