DE10349415A1 - Screwdriver bit and method for production, comprising use of separate moulds for head and shaft stub - Google Patents

Abstract

The profiled tip (2) is cast of a material mixed of hard metal powder and a thermoplastic synthetic and the shaft stub (11) of a metal powder of a metal to be hardened. Each of the moulds used in the process is provided with a multitude of cavities in the complementary shape of the tip (2), the shaft stub (11) respectively. In first step the molds for the shafts (11) are filled, the molds for the tips (2) positioned on top and filled from above in a second step. The blanks are moved to the next station for being sintered, creating a firm connection between both parts (2, 11).

Description

The Innovation concerns screwdriver inserts with a functional tip made of hard metal and a process for their preparation.

Out G 92 11 907.7 screwdriver inserts are known in the injection molding with subsequent sintering made in one piece from carbide are. It has been shown that the Production in one piece Parts by pressing a blank of hard metal powder press technical difficulties prepares. Also during injection molding of Blanks, using a thermoplastic material as a binder for the metal powder, difficulties occur in the highly profiled Area of the functional tip to achieve a homogeneous microstructure. Consequently the durability of the functional tips is unsatisfactory.

Out PCT / DE 01/00 852 screwdriver inserts are known in which the Function tip made of tungsten carbide as a separate part and with a shaft part made of suitable steel by soldering or weld together connected is. The durability of the function peaks is satisfactory, however, the cost of connecting the functional tip to the shaft greatly increases the screwdriver insert.

In DE 4 243 608 C2 a screwdriver insert is described in which the shaft portion has a lower torsion spring constant than the working area, the functional tip. This is shown in the example as the tip of a Phillips screwdriver. The fact that the shank portion has a different torsion spring constant than the working range is achieved by making the shank portion of a softer material than the working or driven portion. The output section consists of a core of softer material encased in the harder material. The objective here is to form a shank portion between the hex drive shaft and the driven portion so that it degrades torque peaks occurring by use of Torsionsfederung in use of the screwdriver bit. The connection between the shaft portion of the soft material and the output portion is made in such a way that the shaft portion protrudes into the output region and forms its core, which is covered by the harder material of the output region. The screwdriver inserts made of the two materials are produced in multicomponent injection molding machines in a known procedure as blanks and then sintered. Very disadvantageous in this embodiment appears that the projecting into the driven area core of the shaft portion due to the given cross-sectional profiles of cross tips can only have a small diameter and at higher torques whose transferability seems questionable.

The The task is a manufacturing method and training the connection from profiled tip and drive shaft to develop through the one secure transmission the torques occurring in practice is achieved. These Task is solved in the manner described below.

at the method of manufacturing screwdriver bits according to the invention the profile tips preferably made of hard metal powder, with thermoplastic Plastic as a binder and the drive shafts made of metal powder curable Sprayed steel. For an economic production, the forms have a plurality of wells and are part of a mold system that rotates in an injection molding machine is installed with two injection units. After the drive shafts in the first injection mold are sprayed and cooled have reached a sufficient strength, switches the molding system by turning into a second station. Before that, mold cores are used in the first injection mold withdrawn, the front faces the drive shafts to shape. In the second station are the front end faces of drive shafts free in the direction of mold cavities a second injection mold, the mold cavities sealing to the front faces connect. These mold cavities have the shape of the profile top. In the second station the wells filled the profile top. The profile tip connects directly to its base surface with the front face of the drive shaft.

The compound is expediently improved and reinforced that non-circular shape elements are formed as anchoring elements on the front end face of the drive shaft, which project either raised from the end face or recessed into it. When spraying the tread tip is made by the non-circular shape elements and a positive connection between the drive shaft and profile tip. Profile tips with non-round shape elements on the base surface as anchoring elements are known per se from PCT / DE 01/00 852. These profile tips are pressed from hard metal powder and subsequently sintered. They are connected by soldering, welding or gluing with the separately produced drive shaft. The anchoring elements are required in this embodiment, because only by additional positive connection, the required torques can be transmitted when the Connection otherwise by soldering or gluing done.

At the injection molding The blank is increased by the non-circular shape elements, the contour surface. These is melted during injection of the second part and it comes in the melting zone to a good precursor in the microstructure of the two Parts.

The Profile peaks injection-molded parts cool in the second station, then the molding system switches in a third station on. There is the blank of the complete screwdriver insert taken. The order of injection molding of the two parts can also be the other way round by first spraying the profile tip, wherein the drive shaft facing the end face the anchoring elements would have. The order in which the drive shaft is first injected is cheaper, because he is the bigger mass and the longer one cooling time needed.

Then be the blanks compacted in a sintering process, wherein an intimate Connection in the metallic structure of profile tip and drive shaft in the area of the connecting surfaces occurs. The profile tip made of carbide is then ready to use. The drive shaft from a steel alloy is, if necessary, in an automatic Induction hardening machine cured, being a cure the boundary layer is sufficient. To avoid after-hardening and a particularly homogeneous microstructure in the region of the connection point, in one embodiment, too the drive shaft made of hard metal. The connection of Drive shaft and profile tip according to the innovation over the whole base area the profile tip and the same size of the front face the drive shaft, in particular with an additional positive connection, is highly resilient and transmits in the Use of screwdriver bits occurring torques.

The Production of the screwdriver inserts in the multi-stage injection molding process is economically cheaper as the separate production of profile tip and drive shaft and the subsequent connection of the two parts. Of special Advantage in the injection molding process according to the innovation, that this Cross-sectional profile of the drive shaft in a variant is changed by the design of the injection mold so that to one the cross-sectional area gets smaller, on the other hand, the surface larger. As a result, the cooling time is greatly reduced, the Overall production cycle time is shorter and material is saved. The reduction of the cross section profile and the enlargement of the surface is achieved by the fact that in the drive shaft in the longitudinal direction extending grooves are formed. These grooves can only in the area of the hexagonal profile be formed, but in consistent pursuit of the design purpose extend to the area between the hexagon profile and the profile tip. In order to enable the radial demoulding, the cross-sectional profiles may the grooves have no undercut. In the four oblique to Entformungsrichtung lying hexagonal surfaces the cross-sectional profile of the grooves is therefore preferably different as in the grooves in the two perpendicular to the Entformungsrichtung lying surfaces. The grooves in the surfaces perpendicular to the Entformungsrichtung can deeper be formed, as the grooves in the inclined surfaces. It can but also all six grooves have the same cross-sectional profile. The grooves in the area between hexagonal profile and profile tip run in front of the connection point of drive shaft and profile tip out, so that between the junction and outlet of the grooves a short cylindrical Section remains. The cross-sectional profile of these grooves can be also in the longitudinal direction change, especially towards the outlet. The grooves in the hexagon profile and the Grooves in the area between the hex shank and the profile tip can be different Have cross-sectional profiles or depths. At different depths creates a step at the transition the groove in the hexagonal profile and the groove in the area between hex shaft and profile top.

A Such design of the drive shaft brings no technical Disadvantages, because for transmission Torque is the hexagon profile commonly used with screwdriver bits not required in total. It is enough if along the Edges of the hexagon surface strip remain with the load of the screwdriver insert with a torque at the hexagon inner profile of the receiving chuck come to the plant. Between the hexagon outer profile of a screwdriver bit and the hexagon inner profile of the receiving feed is usually anyway a certain dimensional tolerance available. This leads to that, too a normal hexagon outer profile essentially in the area of the edges to rest on the inner profile comes.

By the reduction of the cross-sectional area of the drive shaft, the associated reduction of the material mass to be cooled and the Magnification of the in cooling effective surface, can the production cycle times are reduced so much that the Production of the screwdriver insert blanks in one piece, ie in an injection molding process, is economical. However, then the entire parts must be made of carbide become.

In In the drawings, the subject of innovation is exemplified. Show it

1 a side view of a screwdriver with cross point, partially cut. In it are:

1

of the drive shaft

2

the profile tip

3

the Connection point of drive shaft and profile tip

4a, 4b

the mutually facing faces

2 a plan view of the front end face of the drive shaft. In it are:

4

the front face

5

anchoring elements

3 a side view of the drive shaft. In it are:

1

of the drive shaft

4a

the front end surface of the drive shaft ( 1 )

5

sublime protruding anchoring elements

4 a schematic representation of the first injection mold in section, in the first injection molding station. In it are:

1

one drive shaft

6

the Lift-off and rotatable mold carrier plate

7a, 7b

Mold inserts with the cavity for the drive shaft

8th

one Core for forming the end face of the drive shaft

5 a schematic representation of the first injection mold in the second injection molding station, connected to the second injection mold. In it are:

1

of the drive shaft

2

the profile tip

7a, 7b

the mold inserts for the drive shaft

9

of the Mold insert for the profile tip of the second injection mold

10

the cavity in the mold insert for the profile top

6 a side view of a screwdriver insert in the embodiment with grooved drive shaft. In it are:

2

the profile tip

11

of the drive shaft

11a

the surface strips along the edges of the hexagon profile

11b

the Hexagonal profile of the drive shaft

11c

the area of the drive shaft between hexagonal profile ( 11b )

and profile tip ( 2 )

12a, 12b

the grooves in the drive shaft ( 11 )

7 a cross section along the line AA through the hexagonal profile of the drive shaft ( 11 ) according to 6 , In it are:

11

of the drive shaft

11a

the surface strips along the edges of the hexagon profile

12a, 12b

the grooves in the hexagonal profile ( 11b ) of the drive shaft ( 11 )

C-C

the unmolding

8th a side view of a screwdriver insert according to 6 but the grooves extend into the area ( 11c ) between hexagonal profile ( 11b ) and profile tip ( 2 ). In it are:

2

the profile tip

1

of the drive shaft

11c

the area of the drive shaft ( 11 ) between hexagon profile

11b

and profile tip ( 2 )

12a, 12b

the grooves in the hexagonal profile ( 12a ) of the drive shaft

13

Steps at the transition of the grooves ( 12a . 12b ) and ( 14a . 14b )

14a, 14b

the grooves in the area ( 11c )

9 a cross section along the line BB through the area ( 11c ) between hexagonal profile ( 11b ) and profile tip ( 2 ). In it are:

11c

the area of the drive shaft ( 11 ) between hexagon profile

11b

and profile tip ( 2 )

14a, 14b

the groove

Of course, screwdriver inserts can also with a different profile tip than the cross-tip shown in the example be prepared by the method described.

Claims (10)

Screwdriver bits and method for producing screwdriver bits, consisting essentially of a profile tip ( 2 ) and a drive shaft ( 1 . 11 ), made of metal powder with thermoplastic as binder, molded and solidified in the multi-stage injection molding process and by subsequent sintering, wherein in a first station in a first injection mold, the first part, the drive shaft ( 1 . 11 ) or the profile tip ( 2 ) is sprayed, in a second station in a second injection mold, the second part, the profile tip ( 2 ) or the drive shaft ( 1 . 11 ) is injection-molded, characterized in that in the second station, the end face of the molded part in the first station is flush and sealingly connected to the cavity of the second mold and the injection-technical connection of the two parts ( 1 . 11 and 2 ) on the mutually facing surfaces ( 4a . 4b ) at a connection point ( 3 ) he follows. Screwdriver bits and method for producing screwdriver bits according to claim 1, characterized in that the drive shaft ( 1 . 11 ) and the profile tip ( 2 ) at the junction ( 3 ) are joined together by the injection molding of the respective second part in the second injection mold and the subsequent sintering of the blank thus produced in the metallic structure. Screwdriver bits and method for producing screwdriver bits according to claims 1 and 2, characterized in that the part injection molded in the first injection molding part faces the second part facing end surface, projecting from the end face or recessed into it, non-circular anchor elements ( 5 ) through which both parts ( 1 . 11 and 2 ) are also positively connected with each other. Screwdriver bits and method for the production of screwdriver bits according to claim 1 to 3, characterized in that in the hexagonal profile ( 11b ) of the drive shaft ( 11 ) longitudinally extending grooves ( 12a . 12b ) are formed. Screwdriver bits and method for producing screwdriver bits according to claims 1 to 4, characterized in that the grooves ( 12a . 12b ) have different cross-sectional profile. Screwdriver bits and method for producing screwdriver bits according to claims 1 to 5, characterized in that the longitudinal grooves ( 12a . 12b ) into the area ( 11c ) between hexagonal profile ( 11b ) and profile tip ( 2 ) as grooves ( 14a . 14b ) continue. Screwdriver bits and method for producing screwdriver bits according to Claims 1 to 6, characterized in that 11c ) extending grooves ( 14a . 14b ) have a different cross-sectional profile than the grooves ( 12a . 12b ). Screwdriver bits and method for producing screwdriver bits according to claims 1 to 7, characterized in that the profile tip ( 2 ) made of hard metal and the drive shaft ( 1 . 11 ) consists of hardenable steel. Screwdriver bits and method for producing screwdriver bits according to claims 1 to 8, characterized in that the profile tip ( 2 ) and the drive shaft ( 1 . 11 ) consist of hard metal. Screwdriver bits and method for producing screwdriver bits according to claims 4 to 7 and 9, characterized in that the profile tip ( 2 ) and the drive shaft ( 11 ) are made in one piece in an injection molding process.