DE202006020390U1 - Fan wheel - Google Patents

Abstract

Fan grinding wheel, which is rotationally drivable in one direction of rotation (16),
- With a support plate (5), the
A central axis (9),
• an inner hub (6) and
An annular edge region (8)
having,
- With grinding blades (1, 1 ', 1'',1''', 1a, 1'a, 1''a, 1 '''a), the
In the basic shape of a triangle with three main edges, namely an outer edge (2, 2 ', 2a, 2'a), an inner edge (3, 3', 3a, 3'a) and a trailing edge (4, 4 ' , 4a, 4'a) are formed and
• are arranged on the edge region (8) to form an annular abrasive lamella package (13) at equal angular intervals such that
The outer edge (2, 2 ', 2a, 2'a) delimits a part of an outer edge (14) of the grinding lamella packet (13) and
The inner edge (3, 3 ', 3a, 3'a) runs from an inner edge (19) of the grinding lamella packet (13) to the outer edge (14) and is partially guided by grinding lamellae (1, 1', in the direction of rotation (16) 1 '', 1 ''', 1a, ...

Description

• – mit einem Tragteller, der • eine Mittel-Achse, • eine innere Nabe und • einen ringförmigen Randbereich aufweist, und
• – mit Schleiflamellen, die • auf dem Randbereich unter Bildung eines ringförmigen Schleiflamellen-Pakets befestigt sind.

The invention relates to a fan-grinding disc which is drivable in one direction of rotation,

• - With a support plate, which • has a central axis, • an inner hub and • an annular edge region, and
• - with abrasive flaps, which are • fixed on the edge area to form a ring-shaped abrasive lamella package.

Such a fan-grinding wheel is from the EP 1 142 673 B1 known. In this known fan grinding wheel, the grinding blades are square. They have two mutually parallel straight edges and a concave and a convex edge. The convex and the concave edges are each in the form of a circular arc whose radii are the same, but the centers of the radii are offset from each other on a line parallel to the straight edges. The advantage of this embodiment of the grinding blades is that they can be cut without waste, so waste free from a grinding belt with mutually parallel edges. The abrasive flaps are attached overlapping each other on the edge region of the support plate, whereby a portion of the outer edge of the abrasive flake package is formed by the convex edge of each abrasive flake.

Of the Invention is based on the object, a fan grinding wheel the above-mentioned type designed so that their Life is further increased.

These The object is achieved by the features of claim 1 solved. By the invention Embodiment is achieved that in the radially outer Area of the sanding lamella package especially a lot of sanding lamella material is concentrated, which achieves a particularly long service life becomes high aggressiveness, that is high abrasive intensity. The waste produced when cutting the abrasive flaps becomes accepted in total because - over the life the fan grinding wheel considered - little abrasive belt material, So few sanding blades, used for a grinding task becomes. In particular, by the inventive Design also the grinding blades located on the support plate almost completely consumed, leaving little waste to dispose of.

The advantageous development according to claim 2 and in particular claim 3 causes the outer edge of the sanding lamella package through the grinding lamellae is delimited clean circular. Of course need the outer radius of the sanding lamella package and the radius of the curved outer edge is not absolutely identical, but only essentially the same. The Embodiment according to claim 4 improves the Abtrags behavior during Grinding applications. An embodiment of the trailing edge according to claim 5 is basically possible and offers advantages when cutting the sanding lamella, as a straight cut basically easier to do than a curved one Cut, at least when cut with punching or cutting knives becomes. The embodiment according to claim 6 but is for the Grinding insert more advantageous.

Especially The development according to claim 7 causes the in the area of the trailing edge located abrasive active area of each grinding blade from the beginning has an optimal shape, especially in combination with the embodiment according to claim 6 is the case. Under a opposite to the radius open angle is to be understood here, that the angle in the direction of rotation relative to the radius leading is.

The Claims 8 and 9 give advantageous embodiments of Inner edge again, the embodiment according to claim 8 has the advantage has that sanding lamellae save space from a sanding belt can be cut. The embodiment according to claim 9 is particularly preferable when the grinding blades are not from ribbons of a roll, but from bows be cut, so there can be nested.

The Subclaims 10 to 12 give further advantageous embodiments again.

The Claims 13 and 14 relate to the grinding blades have a true triangular shape, so that in each case two main edges, indifferent whether straight or curved, in an intersection to cut. In contrast, the claims relate 15 and 16 in a particularly preferred embodiment, according to which the corners of each triangle are rounded, namely by convexly curved side edges whose radii of curvature are significantly smaller than the radii of curvature of the main edges. The advantage of this embodiment is that both the production the punching tools as well as the detachment of the grinding blades is simplified after punching from the strip material. The production of real Sharp corners in the punching tools is more complex. Also, the dissolution of a triangular in the true sense Abrasive blade from the strip material is more difficult than the release a grinding lamella with rounded corners. The designs according to claims 13 on the one hand and 15 on the other hand also mixed forms between these two embodiments.

Further Advantages, features and details of the invention will become apparent the following description of exemplary embodiments based on the drawing. It shows

1 a grinding lamella in plan view,

2 a fan grinding wheel according to the invention in plan view,

3 a cross section through the fan grinding wheel after 2

4 a sanding belt from which sanding lamellae are to be cut successively,

5 a modified embodiment of a grinding blade,

6 a further modified embodiment of a grinding blade,

7 a further modified embodiment of a grinding blade,

8th one of the illustration in 1 similar grinding blade with rounded corners,

9 one of the illustration in 5 similar grinding blade with rounded corners,

10 one of the illustration in 6 similar grinding lamella with rounded corners and

11 one of the illustration in 7 Similar sanding blade with rounded corners.

In the 1 illustrated grinding blade 1 is triangular in shape. Your three edges are according to their subsequent location on a support plate of a fan grinding wheel as an outer edge 2 , Inner edge 3 and trailing edge 4 designated. The edges 2 to 4 are formed as circular arc sections with a corresponding radius of curvature R2, R3 and R4. The outer edge 2 and the trailing edge 4 are - based on the grinding blade 1 - Convex formed while the inner edge 3 is concave. Even with such geometric shapes are triangles, since according to the rules of spherical geometry, the boundary lines of a triangle need not be rectilinear, but can also be curved; It is crucial that two side edges intersect at one point of intersection, ie form a corner.

As is clear from the 2 and 3 results, a fan-grinding disc has a support plate 5 with a hub 6 on, which has a centric, circular opening 7 having. The carrier plate 5 has an outer annular edge region 8th for holding the grinding lamellae 1 on. This edge area 8th is with the hub 6 over one in the direction of the middle axis 9 of the carrier plate 5 projecting ring land 10 connected. The border area 8th is radially outward against the ring land 10 inclined, like 3 is removable. As a result, the work surface 11 the one on the carrier plate 5 to be arranged grinding lamellae 1 again essentially radially and perpendicular to the central axis 9 runs. This geometry results from the fact that from the inside out more and more grinding lamellae 1 overlap each other or how they overlap 2 is removable. The sanding blades 1 are on the edge area 8th of the carrier plate 5 by means of an adhesive layer 12 attached.

In particular 2 is removable, are the grinding blades 1 on the carrier plate 5 arranged at equal angular intervals, in each case rotationally symmetrical in the same position to the support plate 5 , In the in the 2 and 3 illustrated embodiment corresponds to the outer radius R13 of the on the support plate 5 attached grinding lamella package 13 the radius of curvature R2 of the outer edge 2 so that the outside over the edge area 8th protruding outer edge 14 of the sanding lamella package 13 is circular.

In 2 is a grinding lamella 1 shown in dashed lines, although their respective abrasive area 15 only from its trailing edge 4 until the next in the direction of rotation 16 the grinding wheel leading edge arranged 4 extends.

As before 2 is removable, form the tangent 17 to the trailing edge 4 at the intersection 18 with the outer edge 2 and the radius R13 through the intersection 18 an angle α> 0 °, where the tangent 17 opposite the radius R13 in the direction of rotation 16 leads. For this angle α is 5 ° ≤ α ≤ 35 °.

For this embodiment, R2 ≃ R4 and R3> R2 and R3> R4. Because of the inner edge 3 - related to the grinding blade 1 - is concave, is the number of overlaps of adjacent grinding lamellae 1 in the area of the inner edge 19 of the sanding lamella package 13 much smaller than in the outdoor area and only increases to the outside significantly, as the hatched area in 2 is removable.

As before 2 is removable, the outer edge extends 2 every grinding lamella 1 over an angle β of the annular abrasive lamella package 13 where 25 ° ≤ β ≤ 90 °. For the number n of grinding lamellae 1 10 ≤ n ≤ 80.

Out 4 can be seen, as the grinding blades 1 from a sanding belt 20 get cut. The width a of the abrasive belt 20 is so ge chooses that point of intersection 21 the outer edge 2 and the inner edge 3 on a longitudinal edge 22 of the sanding belt 20 lies during the intersection 23 between the inner edge 3 and the trailing edge 4 on the other to the longitudinal edge 22 parallel longitudinal edge 24 lies. The point of intersection 18 between the outer edge 2 and the trailing edge 4 abuts the inner edge 3 the adjacent cut-off grinding blade 1 at. By this way of cutting the grinding lamellae 1 arise Zwickelverschnitt sections 25 . 26 , This blend does not lead to any disadvantage, as the from outside to inside - based on the direction of rotation 16 - trailing arrangement of the trailing edge 4 on the carrier plate 5 at the beginning of grinding with a new fan grinding wheel on optimal, ie minimal removal of the grinding lamellae 1 leads. Incidentally, the concave configuration of the inner edge 3 to a reduction of the waste.

Variants of the grinding lamellae result from the 5 to 7 , In the 5 illustrated grinding blade 1' has the already described outer edge 2 and trailing edge 4 on. The inner edge 3 ' but is straightforward. Their radius of curvature R3 'is therefore infinitely long.

As it turned out 6 results, has the grinding blade shown there 1'' an already described circular arc section-shaped outer edge 2 and also described above rectilinear inner edge 3 ' on. The trailing edge 4 ' is also rectilinear, but for their arrangement on the support plate 5 the above statement on the angle α remains valid. The radius of curvature R4 'therefore has an infinite length

Finally, it turns out 7 nor the design of a grinding blade 1''' where not only the inside edge 3 ' and the trailing edge 4 ' but also the outer edge 2 ' are formed straight. Their radius of curvature R2 '' therefore also has an infinite length.

The embodiments of the 8th to 11 in their basic structure correspond to those according to the 1 . 5 . 6 . 7 , where instead of the sharp-edged intersections 18 . 21 . 23 each rounded corners are provided. These abrasive slats thus each have the basic shape of a triangle. The main edges forming outer edges, inner edges and trailing edges are thus connected to each other by convexly curved side edges whose radius of curvature r each is significantly smaller than the radius of curvature R of the mentioned main edges. The main edges forming outer edges, inner edges and trailing edges are in the 8th to 11 with the same reference numerals as the corresponding edges in the 1 . 5 . 6 . 7 in each case an "a" is added for the differentiation, the same applies to the curvature radii R.

The side edges are provided with the same reference numerals as the intersections 18 . 21 . 23 , where also these are added to distinguish an "a." The same applies to the description of the radii of curvature r of the minor edges.

For this in detail the following:

At the grinding lamella 1a to 8th are all three main edges, namely the outer edge 2a , the inner edge 3a and the trailing edge 4a curved formed, namely the outer edge 2a and the trailing edge 4a convex, while the inner edge 3a is concavely curved. The radii of curvature are R2a, R4a and R3a. The main edges are each with three side edges 18a . 21a respectively. 23a interconnected, which are convexly curved and have radii of curvature r18a, r21a and r23a, respectively.

The grinding blade 1'a to 9 is different from the after 8th in that the inner edge 3'a is formed rectilinear and therefore the radius of curvature R3'a this inner edge 3'a has an infinite length.

The grinding blade 1''a to 10 differs in turn from the after 9 in that also the trailing edge 4 'a is formed rectilinear and therefore their radius of curvature R4'a has an infinite length.

At the grinding lamella 1 '''a to 11 Finally, all three main edges are rectilinear, including the outer edge 2 ' whose radius of curvature R2'a consequently has an infinite length.

The Curvature radii R of the main edges are significantly larger as the curvature radii r of the minor edges. The following applies: 3 ≤ R / r and preferably 10 R / r. As far as the main edges are not rectilinear, applies to the ratio of the radii of curvature R of the main edges to the radii of curvature r of the minor edges: 3 ≦ R / r ≦ 20 and preferably 10 ≦ R / r ≦ 20.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - EP 1142673 B1 [0002]

Claims (17)

Fan grinding wheel, which is rotating in one direction ( 16 ) is rotatably drivable, - with a support plate ( 5 ), which is a central axis ( 9 ), • an inner hub ( 6 ) and • an annular edge region ( 8th ), - with grinding blades ( 1 . 1' . 1'' . 1''' . 1a . 1'a . 1''a . 1 '''a ) in the basic form of a triangle with three main edges, namely an outer edge ( 2 . 2 ' . 2a . 2 ' ), an inner edge ( 3 . 3 ' . 3a . 3'a ) and a trailing edge ( 4 . 4 ' . 4a . 4 'a ) and • on the edge area ( 8th ) to form an annular sanding lamella package ( 13 ) are arranged at equal angular intervals such that • the outer edge ( 2 . 2 ' . 2a . 2 ' ) a part of an outer edge ( 14 ) of the sanding lamella package ( 13 ) and • the inner edge ( 3 . 3 ' . 3a . 3'a ) from an inner edge ( 19 ) of the sanding lamella package ( 13 ) to the outer edge ( 14 ) runs and partially from in the direction of rotation ( 16 ) upstream grinding lamellae ( 1 . 1' . 1'' . 1''' . 1a . 1'a . 1''a . 1 '''a ) is covered. Fan grinding wheel according to claim 1, characterized in that the outer edge ( 2 . 2a ) is formed convexly curved with a radius of curvature Ra or R2a. Fan grinding wheel according to claim 2, characterized in that the outer edge ( 14 ) of the sanding lamella package ( 13 ) has an outer radius R13 equal to the radius of curvature R2 or R2a of the curved outer edge ( 2 ). Fan grinding wheel according to one of claims 1 to 3, characterized in that the trailing edge ( 4 . 4 ' . 4a . 4 'a ) is open and - based on the direction of rotation ( 16 ) - from the inner edge ( 19 ) to the outer edge ( 14 ) of the sanding lamella package ( 13 ) is leading. Fan grinding wheel according to one of claims 1 to 4, characterized in that the trailing edge ( 4 ' . 4 'a ) is formed in a straight line. Fan grinding wheel according to one of claims 1 to 4, characterized in that the trailing edge ( 4 . 4a ) is formed convexly curved with a radius of curvature R4 or R4a. Fan grinding wheel according to claim 5 or 6, characterized in that a tangent ( 17 ) to the trailing edge ( 4 . 4 ' ) in an intersection ( 18 ) between outer edge ( 2 . 2 ' ) and trailing edge ( 4 . 4 ' ) and a radius R13 from the center axis ( 9 ) through the intersection ( 18 ) one in the direction of rotation ( 16 ) enclose open angle α with respect to the radius R13. Fan grinding wheel according to one of claims 1 to 7, characterized in that the inner edge ( 3 . 3a ) is curved concavely with a radius of curvature R3 or R3a. Fan grinding wheel according to one of claims 1 to 7, characterized in that the inner edge ( 3 ' . 3'a ) is formed in a straight line. Fan grinding wheel according to one of claims 1 to 9, characterized in that for the number n of the on a support plate ( 5 ) arranged grinding blades ( 1 . 1' . 1'' . 1''' ): 10 ≤ n ≤ 80. Fan grinding wheel according to one of claims 1 to 10, characterized in that each grinding blade ( 1 . 1' . 1'' . 1''' ) over an angle β of the annular grinding lamella packet ( 13 ) for which applies: 25 ° ≤ β ≤ 90 °. Fan grinding wheel according to claim 7, characterized in that for the angle α is: 5 ° ≤ α ≤ 35 °. Fan grinding wheel according to one of claims 1 to 12, characterized in that at least two main edges are in an intersection ( 18 . 21 . 23 ) to cut. Fan grinding wheel according to claim 13, characterized in that all the main edges are in an intersection ( 18 . 21 . 23 ) to cut. Fan grinding wheel according to one of claims 1 to 12, characterized in that at least two main edges by a convexly curved side edge ( 18a . 21a . 23a ) are interconnected. Fan grinding wheel according to claim 15, characterized in that all the main edges by convexly curved side edges ( 18a . 21a . 23a ) are interconnected. Fan grinding wheel according to one of the claims 1 to 16, characterized in that for the radii of curvature R of the major edges in relation to the radii of curvature r of the minor edges is: 3 ≤ R / r and preferably 10 ≤ R / r.