DE102004001546A1 - Tool - Google Patents

Abstract

In a tool having a support part (1) and a disk-shaped working part (2) for machining, the support part (1) has a contact surface (5) for the working part (2) and in the abutment surface (5) has a permanent Magnets (14) on. The working part (2) has a coupling part (19) made of ferromagnetic material which can be brought into magnetic holding connection when the counter-abutment surface (15) bears against the abutment surface (5) with the permanent magnet (14).

Description

The The invention relates to a tool with a support member and a disc-shaped working part for cutting Processing.

such Tools in which a support member or a base body respectively is connected to a working part, which is a wearing part, are in more diverse Design known. Such working parts are for example, abrasive on pad, polishing wheels, to Made of needled nonwoven with embedded abrasive Cleaning discs or felt discs. Supporting part and working part are usually driven in rotation. In known designs is at the working side opposite side a coupling part with a female thread attached, which is screwed onto a thread of a support member. In The rule is the connection and release of the working part of the support member laborious or time consuming or only with big ones Care to accomplish. This is especially true because such Working parts very often replaced after a very short period of use Need to become. Especially in such a case, the stack height of the working parts very large, since the coupling part with the female thread inevitably a considerable Height.

Of the Invention is therefore based on the object, a tool of the general Genus in such a way that the production and release of the compound between support member and working part is very fast and easy to carry out.

These The object is achieved by the Characteristics of claim 1 solved. The essence of the invention is that the working part is a coupling part has, which is held on the support member by means of magnetic forces.

By the development of claim 2 and in particular the other Embodiments according to the claims 3 to 5 will be added a form-fitting Torque transmission ability created. Due to the development according to claim 6 is also still created a mounting relief. The claims 12 to 14 give again, that on the one hand a large area, also tensile connection between coupling part and permanent magnet is created that on the other hand, the stack height the working parts is not significantly affected by the coupling part.

The further subclaims give advantageous embodiments again.

Further Features, advantages and details of the invention will become apparent the following description of an embodiment with reference to the Drawing. It shows

1 a plan view of the contact surface of a support member of a tool according to the invention,

2 the tool according to the invention in cross section in exploded view,

3 a plan view of the counter-abutment surface of the working part of the tool and

4 a section through an exploded view of a coupling part with a permanent magnet.

The tool shown in the drawing consists in its basic structure of a support member 1 in the form of a support plate and a working part 2 , The supporting part 1 has a made of elastic plastic support housing 3 on, which is a circular investment surface 5 having. On his the plant surface 5 opposite side has the support part 1 a concentric to the central axis 6 arranged threaded bore 7 in which a drive shaft 8th a tool drive, not shown, by means of a corresponding external thread 9 can be screwed. Such tool drives may be so-called angle-grinding machines or straight-grinding machines.

In the carrying case 3 , on the side of the plant surface 5 , is a holding body 10 arranged in which the bore 7 is formed and concentric with the axis 6 a shallow recess 11 having polygonal cross-section. In the present case, the recess 11 through flanks 12 an equilateral and equiangular polygon, such as a hexagon formed. At the interfaces of two adjacent flanks 12 is each a cut 13 intended.

In the recess 11 - and against the plant area 5 sunk - is a permanent magnet 14 arranged in the form of a flat disc and the holding body 10 , For example, by gluing, attached. The holding body 10 is suitably made of non-magnetizable material, but may also be made of ferromagnetic material or partially made of ferromagnetic material, for example in the form of a composite material.

The actual working part 2 is also formed circular disk-shaped and has a counter-investment surface 15 on, when attaching the working part 2 on the supporting part 1 against the plant surface 5 comes to the plant. The working part 2 has approximately the diameter or the circumference of the support member 1 on. In the present case, the working part 2 through an abrasive 16 on underlay 17 formed, with the counter-investment surface 15 on the abrasive 16 opposite side of the pad 17 is trained.

Concentric to the center axis 18 of the working part 2 is on the counter-investment area 15 a coupling part 19 made of ferromagnetic material. It has a polygonal shape, that of the recess 11 is substantially equivalent, ie in the present case, it is an equilateral and equiangular hexagon whose flanks 20 when inserted into the recess 11 for attachment to the flanks 12 the recess 11 come, creating a rotationally fixed connection between the working part 2 and supporting part 1 will be produced. As the coupling part 19 Made of ferromagnetic material, it is due to the magnetic attraction by the permanent magnet 14 firmly in the recess 11 held. The magnetic forces act in the direction of the axes 6 . 18 , As such working parts 2 , such as abrasives 16 on underlay 17 , or polishing discs or cleaning discs are used obliquely to the surface to be machined, so where the axes 6 . 18 are not perpendicular to the surface to be machined, the working parts 2 are at work, including the elastic support housing 3 bent, whereby between the coupling part 19 and the magnet 14 the coupling part 19 from the magnet 14 lifting forces are exercised. The magnet 14 must be strong enough to apply such forces. So it does not just serve to drop the working part 2 from the supporting part 1 to prevent.

On the counter-investment area 15 opposite side has the coupling part 19 a flat projecting circular centering approach 21 on, the one with the six flanks 20 of the coupling part 19 affected. When applying the working part 2 to the supporting part 1 First, this centering approach 21 into the recess 11 introduced, whereby the centering is made. Subsequently, the working part 2 with the coupling part 19 be twisted until the flanks 20 with the flanks 12 come in overlap, so that then the coupling part 19 to rest against the permanent magnet 14 or staying in the vicinity of a small air gap and the counter-investment area 15 against the plant surface 5 invests. The between support part 1 and working part 2 trained quick-fastening system thus has three sub-functions, namely the axial attachment of the working part 2 and its holder during work on the support member 1 by magnetic forces, the positive torque transmission between the flanks 12 and 20 and the centering during assembly by the between the flanks 12 usable centering approach 21 ,

For the ratio of the diameter D _{2 of} the working part 2 in relation to the largest diameter D _{19 of} the coupling part 19 the following applies: 1 <D ₂ / D ₁₉ ≤ 10, the small value of this ratio for particularly small diameters D _{2 of} the working part 2 for example, about 20 mm, while the large ratio is for large values of D ₂ , for example, in the range of 200 mm or more. For the practical diameter D ₂ : 20 mm ≤ D ₂ ≤ 250 mm.

Although the described quick-clamping connection between working part 2 and supporting part 1 Primarily used with rotating drivable working parts, it can also be used in primarily linearly driven working parts, for example, in orbital sanders. If there is only one clutch, the described embodiment protects against undesirable rotation of the working part relative to the support member.

How to continue 4 results, applies to the ratio of the largest diameter D _{19 of} the coupling part 19 to the axial thickness d _{19 of} the coupling part 19 5 ≦ D ₁₉ / d ₁₉ ≦ 100, and preferably 10 ≦ D ₁₉ / d ₁₉ ≦ 30. For the ratio of the largest diameter D _{19 of} the coupling part 19 to the diameter D14 of the permanent magnet: 1 <D ₁₉ / D ₁₄ ≦ 2 ,

From the above information it can be seen that the coupling part 19 based on its diameter D ₁₉ and its thickness d ₁₉ on the one hand and on the diameter D _{2 of} the working part 2 on the other hand is extremely flat. The stack height of the working parts 2 As wear and replacement parts is through the coupling part 19 so only slightly influenced.

Claims (14)

Tool with a supporting part ( 1 ), and with a disc-shaped working part ( 2 ) for a machining, wherein the supporting part ( 2 ) an investment area ( 5 ) for the working part ( 2 ) and in the plant area ( 5 ) a permanent magnet ( 14 ) and wherein the working part ( 2 ) when a counter-investment area ( 15 ) at the plant surface ( 5 ) with the permanent magnet ( 14 ) in magnetic holding connection can be brought coupling part ( 19 ) made of ferromagnetic material. Tool according to claim 1, characterized in that the permanent magnet ( 14 ) in a recess ( 11 ) of the supporting part ( 1 ) is arranged and that the coupling part ( 19 ) in the recess ( 11 immersed). Tool according to claim 2, characterized in that the recess ( 11 ) has a non-circular cross section and that the coupling part ( 19 ) a the cross section of the recess ( 11 ) has adapted non-circular cross-section. Tool according to claim 3, characterized in that the recess ( 11 ) and the coupling part ( 19 ) have a polygonal cross-section. Tool according to claim 4, characterized in that the recess ( 11 ) and the coupling part ( 19 ) have a cross section in the form of an equilateral and equiangular polygon. Tool according to one of claims 2 to 5, characterized in that the coupling part ( 19 ) one of the recess ( 11 ) adapted circular centering approach ( 21 ) having. Tool according to one of claims 1 to 6, characterized in that the supporting part ( 1 ) a carrying case ( 3 ) and one of this at least partially enclosed holding body ( 10 ) having. Tool according to claim 7, characterized in that the supporting housing ( 3 ) consists of plastic. Tool according to claim 7 or 8, characterized in that the holding body ( 10 ) consists of metal. Tool according to one of claims 1 to 9, characterized in that the supporting part ( 1 ) has a connection for a rotary drive. Tool according to one of claims 1 to 10, characterized in that the working part ( 2 ) as abrasive ( 16 ) on a base ( 17 ) is trained. Tool according to one of claims 1 to 11, in particular according to claim 8, characterized in that the support housing ( 3 ) consists of an elastically yielding material. Tool according to one of claims 1 to 12, characterized in that for the ratio of the largest diameter (D ₁₉ ) of the coupling part ( 19 ) to its thickness (d ₁₉ ): 5 <D ₁₉ / d ₁₉ ≤ 100. Tool according to one of claims 1 to 13, characterized in that for the ratio of the largest diameter (D ₂ ) of the working part ( 2 ) to the largest diameter (D ₁₉ ) of the coupling part ( 19 ): 1 <D ₂ / D ₁₉ ≤ 10.