DE4311529A1 - Grinding wheel for hand-held grinding machines, in particular cutting wheel - Google Patents

Description

The invention relates to a grinding wheel according to the preamble of the saying 1.

Such grinding wheels are only used up to a range of 50 to 70% of the original diameter worn. So it will be considerable not used part of the grinding wheel. This one not used The proportion of the grinding wheel is in a range of 30 to 50% of the Original weight of the grinding wheel. This remaining remainder must be over Hazardous waste landfills are being disposed of, which poses increasing problems since the number of hazardous waste landfills is declining and there the cost for this rises sharply.

The reason for the relatively high remaining The rest of the unused grinding wheel is that the grinding discs on the grinding spindles or shafts of hand-held grinding machines inserted between flange plates lying on the end faces be stretched over a considerable part of the diameter extend the grinding wheel. The grinding wheels are clamped necessary because the fabric reinforcements only then the tang that occurs can absorb tial forces if they have a sufficient radial area - starting from their inner recess - are clamped. Furthermore, these reinforcement layers are necessary because such grinding wheels for hand-held grinding machines to a considerable extent must be able to absorb forces, namely when used as a roughing Grinding wheel as well as a cutting wheel. In addition, you can do not immerse the flange plates in the workpiece when grinding. In addition, the part of the radially projecting over these flanges Cutting wheel not used, which corresponds to the workpiece thickness speaks.

The invention has for its object a grinding wheel of the gat to create the appropriate type in which the amount of waste to be disposed of is greatly reduced.

This object is achieved by the features in the characterizing part solved part of claim 1. By the embodiment according to the invention tion, the support body can either be reused or closed be recycled at least; in addition, the slip ring can be practical completely processed, i.e. used up. For use as Cutting-off grinding wheel, the further development according to claim 2 is expedient, to be able to use up the slip ring completely. The supporting body only needs to be cleaned slightly and can then be reused uses or be sent to an existing recycling process for example as steel scrap. The further developments according to claims 3 to 6 indicate how the connection between Support body and slip ring in a particularly simple and particularly durable rer way can be designed.

Claim 7 gives a particularly simple design for the support body at. Claims 8 and 9 represent another possibility, the Manufacture support body and connect with the slip ring.

Claims 10 to 13 give particularly advantageous refinements for Reinforcement layers that enable the slip rings to be covered to give large recess on the outer diameter, which in turn the The reason for this is that if the slip ring is completely used up is achieved.

Claim 14 specifies a further embodiment of a support body, the is designed to be particularly thin, which ensures that the grinding a disc for use with hand-held grinding machines receives high bending elasticity, so that occurring parallel to the axis Lateral forces can be absorbed without the slip ring from Edge of the support body breaks off. Through a special way of manufacturing it is possible to have a particularly intensive interlocking of slip ring and To achieve support body according to claim 15. The selection of the binder of the slip ring according to claim 16 causes the slip ring one  is hard enough so that it does not smear and at the same time is self-sharpening; on the other hand is the necessary bending elasticity given and the necessary strength of the connection between grinding ring and support body. Claim 17 gives a measure for improvement the adhesion between slip ring and support body.

Further features, advantages and details of the invention emerge from the following description of exemplary embodiments using the Drawing. Show it

Fig. 1 is an abrasive cutting-off wheel cut with glued in the support body in cross-,

Fig. 2 shows a partial section of FIG. 1 in an enlarged scale,

Fig. 3 is a plan view of a reinforcement formed in Dreieckslegung location for the abrasive cutting-off wheel,

Fig. 4 is a plan view of a reinforcement layer formed in Spirallegung for separating grinding wheel,

Fig. 5 shows another embodiment of an abrasive cutting-off disc having a molded support body in cross-section,

Fig. 6 shows a partial section of Fig. 5, on an enlarged scale

Fig. 7 is a partial cross section through a further embodiment of a cutting wheel and

Fig. 8 is a partial section of Fig. 7 on an enlarged scale.

In Fig. 1, a grinding wheel is shown, which is a cut-off grinding wheel for a hand-held grinding machine. It has a ring-cylindrical slip ring 1 , into which a likewise ring-cylindrical support body 2 is glued. The slip ring 1 has an annular recess 3 , which is concentric with the central longitudinal axis 4 . In this recess 3 , the support body 2 is set. The diameter of the recess 3 , ie the inner diameter Di of the slip ring 1 , is a few tenths of a millimeter larger than the outer diameter d of the support body 2 . The slip ring 1 has an outer diameter Da, where the following applies to the ratio Da / Di:
1.4 <Da / Di <2, ie the slip ring 1 has a relatively large recess 3 with respect to its outer diameter Da.

The thickness a of the slip ring 1 in the direction of the axis 4 is greater than the thickness b of the support body 2 in the direction of the axis 4 , so that the grinding ring 1 with both end faces 5 , 5 'over the end faces 6 , 6 ' of the support body 2 protrudes. Basically, the thickness of the support body 2 in the direction of the axis 4 can be equal to the thickness of the slip ring 1 , in which case the slip ring 1 and the support body 2 are arranged plane-parallel to one another; for cutting disks, however, it is advantageous if the thickness b of the supporting body 2 in the direction of the axis 4 is somewhat less than the thickness a of the slip ring 1 , in order to enable or facilitate immersion of the cutting wheel in a workpiece to be cut. The slip ring 1 and the support body 2 are connected to one another by means of a suitable adhesive, preferably epoxy resin. In order to make the adhesive bond between slip ring 1 and support body 2 as firm as possible, the gap 7 formed due to the difference in diameter of D and d is between the cylindrical inner peripheral surface 8 of the slip ring 1 and the cylindrical outer peripheral surface 9 of the support body 2 with a thin, ring-cylindrical adhesive layer 10 filled. Furthermore, the gusset 11 formed due to the axial projection of the slip ring 1 with respect to the support body 2 are filled with adhesive seams 12 which, on the one hand, attack the exposed parts of the cylindrical inner peripheral surface 8 and, on the other hand, the adjacent regions of the end faces 6 , 6 '.

The support body 2 has a concentric to the axis 4 receiving opening 13 for the drive shaft of a hand-held grinding machine, on. The support body 2 is made of metal, usually made of steel. It is made from sheet metal by punching or turning.

The slip ring 1 has - as shown in FIG. 2 - the usual basic structure, that is, it has in the region of the end faces 5 , 5 'each have a coating layer 14 ; 14 ', which is designed in a manner yet to be described. Between the reinforcing layers 14 , 14 'there are abrasive grain 15 , preferably made of aluminum oxide, silicon carbide, zirconium corundum, solgel grain or mixtures thereof, and binders 16 in the form of pure or modified synthetic resins and fillers 17 , such as, for. B. pyrite or cryolite. The abrasive grain 15 has a nominal grain size in the range from 315 to 1000 μm.

Fig. 3 shows a reinforcement layer 14 or 14 'described in DE 38 19 199 C2, which preferably rings instead of a fabric in such grinding rings 1 , in particular in hand-cutting wheels to be used. Such a reinforcement layer 14 or 14 'is formed from one or more reinforcing threads 18 which counteract optimally tangent and radial expansions of the slip ring 1 . In the area of a central opening 19 , the reinforcing threads 18 run exactly tangentially; they then run radially tangentially to the outer circumference and are deflected there and in turn returned straight to the opening 19 , where they are guided tangentially. They thus run essentially in accordance with the actual stress on the rotating slip rings 1 . The greatest main tension of a rotating slip ring is in the tangential direction. The tangential tension, that is to say the tangential force, has its highest value in the area of the opening 19 , that is to say radially on the inside in the area of the inner circumferential surface 7 of the slip ring 1 , which value decreases continuously towards the outside. For this reason, it is also justifiable that the reinforcing threads 18 run exactly tangentially only in the area of the opening 19 , but that they receive a radial component between the opening 19 and the outer edge in order to counteract the radial tension which is also strong in this area. The reinforcing threads 18 are connected to each other at the respective crossing points 20 , namely by a synthetic resin. The reinforcing threads 18 who soaked the before laying to the pattern shown in Fig. 3 with a synthetic resin solution. After laying, the reinforcing threads 18 are pressed hot, whereby this synthetic resin hardens, so that a connection of the reinforcing threads 18 occurs at the crossing points 20 . The reinforcement layer 14 or 14 'is thus sufficiently inherently stable to be used for producing a slip ring 1 . With the exception of the area of the outer deflection points 21 and the inner deflection in the area of the opening 19 , the reinforcing threads 18 run in a straight line. The inner diameter D'i of the reinforcement layer 14 or 14 'corresponds essentially to the inner diameter Di of the slip ring 1st The same applies to the ratio of the outer diameter D'a of the reinforcement layer 14 or 14 'in relation to the diameter Da of the slip ring 1st The apex angle c of the reinforcing threads 18 in the region of the deflection points 21 are directed, if the radius of curvature (not shown) in the region of the deflection points 21 is neglected, exclusively according to the ratio of D'a to D'i. Since the reinforcing threads 18 are arranged essentially like the legs of an isosceles triangle, this is also referred to as a triangular arrangement.

In Fig. 4, a reinforcement layer 14 or 14 'is shown, which are particularly preferred be rings instead of a fabric in the abrasive described 1 of cutting wheels for hand-held grinding machines to be added. In this embodiment, the reinforcing threads 18 are each laid from the central opening 19 in accordance with the resultant of the main tension direction. In Fig. 4 the course of such a reinforcing thread chen is shown in reinforced lines. It begins - with a mirror-symmetrical design - tangentially in the area of the opening 19 and is guided in a little more than a half-spiral rotation to the outer deflection point 21 in such a way that it already has an approximately tangential course there. As can be seen in FIG. 4, a reinforcing thread 18 is approximately only punctiform at the central opening 19 . It follows that there is no excessive accumulation of material of the reinforcing threads 18 in the region of the opening 19 . This fact and the described course of the reinforcing threads make this reinforcement layer 14 or 14 'appear even more advantageous than the reinforcement layer according to FIG. 3.

In the embodiment of a grinding wheel according to FIGS. 5 and 6 of the grinding ring 1 is configured in the same manner as in the Ausführungsbei game according to FIGS. 1 and 2. The support body 2 'is also slices shaped as shown in Fig. 1, wherein the above statements apply to the thicknesses a and b. It consists of die-cast zinc and is produced by injection into the recess 3 of the slip ring 1 .

Here, the zinc penetrates according to the enlarged detail in Fig. 6 in the region of the recess 3 in cavities 22 between the abrasive grain 15 or binder 16 and fillers 17 , whereby a high-strength positive connection between the support body 2 and grinding ring 1 is effected.

The following is the production of a grinding wheel using three examples games explained:

Example I

There is a reinforcement layer 14 'inserted in a press mold. Subsequently, a consisting of abrasive grain 15 , filler 17 and binder 16 existing grinding granulate is entered into the mold and another reinforcement layer 14 is placed. A pressure of 500 to 4000 N / cm ² is then exerted on this package, as a result of which the slip ring 1 is compressed. During this compression, an adhesive bond occurs, which is referred to as green strength. During this pressing, the abrasive granules, ie abrasive grain 15 , binder 16 and filler 17, each push through the reinforcing layer 14 or 14 'to the outside.

These compressed but not yet hardened slip rings are between steel plates stacked and placed in an oven for hardening where Depending on the desired degree of hardness, they can withstand temperatures from 120 ° C to 200 ° C be set.

In each of these finished hardened slip rings 1 , a support body 2 is glued in the manner already described. The adhesive forming the adhesive layer 10 and the adhesive seams 12 is then cured in a continuous furnace at approximately 120 ° C.

Example II

The manufacture of the slip ring 1 until compression takes place as in example I. Subsequently, before the hardening of the slip ring 1, the support body 2 is glued in in the manner described. The grinding wheel consisting of slip ring 1 and support body 2 is then stacked between steel plates and given for hardening, as in Example I, in an oven, with the binder 16 of the slip ring 1 and the adhesive of the adhesive layer 10 and the adhesive seams 12 at the same time at temperatures between 120 ° C and 200 ° C - depending on the desired degree of hardness - cured.

Example III

The slip ring 1 is produced as in Example I. Then this slip ring 1 is inserted into an injection mold of a zinc injection molding machine and the support body 2 'is produced by injection. Because of the high cooling rate of the zinc, there is no thermal damage to the slip ring 1 and, in particular, to the binder 16 .

Instead of outer, ie in the area of the end faces 5 , 5 ', lying arming layers 14 , 14 ', the slip ring 1 can also have an inner reinforcing layer in a known manner.

The grinding wheel can be used until the grinding ring 1 has been completely processed, in particular also when used as a cutting grinding wheel, since it can be immersed in a gap produced by grinding on the workpiece without collisions between the support body 2 and the machined workpiece can.

Remnants of the slip ring 1 and the adhesive layer 10 and the adhesive seams 12 can be removed by heating the remaining support body 2 and by subsequent brushing with steel brushes. The support body 2 can then be used again. If they are damaged, they can be easily recycled.

In the grinding wheel with injected support body 2 'made of die-cast zinc, the remains of the slip ring 1 and support body 2 ' are separated by heating the zinc to the melting temperature.

FIGS. 7 and 8 show a hand-held abrasive cutting-off disc, on the one hand has a grinding ring 1 and on the other hand a support body 2 ''. The grinding ring corresponds in structure to the structure described above, wherein it is provided with reinforcing layers 14 , 14 ', as shown in Fig. 4 and described above for this purpose.

The support body 2 '' consists of relatively thin sheet of steel, where appropriate, stainless steel, aluminum or brass, for its thickness e applies 0.4 mm e 1.0 mm, whereby for practical cases applies 0.5 mm e 0.8 mm.

Around the receiving opening 13 around it radially to the axis 4 he extending ribs 23 are formed, which have only the purpose of clamping the support body 2 '' on the usual recordings of the spindles of hand-held grinding machines.

At the outer edge of the very thin supporting body 2 '' is flanged to a ringzylindri's edge 24 , the extent b in the direction of the axis 4 is equal to or slightly less than the thickness a of the slip ring 1st On the annular cylindrical edge 24 an outer peripheral surface 9 '' is formed, which is connected to the slip ring 1 . The slip ring 1 is attached directly to the outer peripheral surface 9 '' of the ring-cylindrical edge 24 , which he will explain in the following description of the manufacture. The abrasive cutting-off wheel, as provided in FIGS. 7 and 8 represent is against lateral forces, that is against forces fen on the grinding ring 1 at a radial distance to the support body 2 '' parallel to the axis 4 angrei, so elastic that a Breaking the grinding wheel, especially in the area of the edge 24 can not occur. The support body 2 '' itself is also parallel to the axis 4 flexible. The entire grinding wheel is flexurally elastic as a composite body, ie in the case of side bending forces there are no jump points in the course of the bending stress in the region of the edge 24 , so that the risk of bending failure is not present due to side forces acting parallel to the axis 4 . On the other hand, the slip ring 1 is flexible for such forces, which is due on the one hand to the synthetic resin bond of the slip ring 1 and on the other hand to the presence of the reinforcing layers 14 , 14 '. For the aforementioned reasons, the thickness e of the support body 2 '' must be small; On the other hand, the edge 24 is necessary so that the outer peripheral surface 9 '' a sufficient axial extent has b to the grinding ring 1 fro on the support body 2 '' to be transmitted torsional forces and also he mentioned page bending forces from the slip ring 1 to the support body 2 '' to be able to wear. The thickness a of the slip ring 1 of cut-off wheels is in the range from 2 to 4 mm. It follows that the thickness e of the support body 2 '' is considerably less than the thickness a of the slip ring 1st 0.1 ae 0.25 applies. For the axial extent b of the edge 24, it applies that it should only be insignificantly smaller than the thickness a. Here 0.8 applies from 1.0 a.

The ratio Da / Di 2 and in particular 1.4 Da / Di 2 also apply to this cut-off grinding wheel. The special spiral arrangement according to FIG. 4 makes it possible to make the recess 3 of the slip ring 1 very large relative to the outer diameter Da, which in turn leads to the fact that the slip ring 1 can be completely used up during cut-off, to the extent that no residues of the slip ring 1 remain at the edge 24 . This is due to the fact that until the end of the grinding insert in the slip ring 1 there is a reinforcement, the reinforcing threads 18 of which are purely tangential in this area and can therefore absorb the high tangent forces occurring here in a particularly advantageous manner. So that the fixed connection between the support body 2 '' and slip ring 1 on the outer circumferential surface 9 '' is not adversely affected, the support body 2 '' should have been subjected to a surface treatment which counteracts surface oxidation, in particular rust formation in non-stainless steel. For this a nickel plating or copper plating of the support body 2 '' comes into consideration, but in particular also a plasma polymer treatment of the support body 2 '', since such treatment on the one hand results in extreme cleaning and on the other hand a particularly high adhesiveness is achieved, which is for the outer peripheral surface 9 '' is particularly cheap.

The manufacture of the cutting wheel according to FIGS. 7 and 8 is explained below by way of example:

Example IV

The outer peripheral surface 9 '' is provided with a thin layer 25 of elastifi ed phenol-formaldehyde adhesive, which has the function of an adhesion promoter and is not absolutely necessary. Then the support body 2 '' is inserted into a mold, it being placed with its end faces 6 'facing away from the edge 24 ''on the bottom of the mold, ie the edge 24 is high. Then a reinforcement layer 14 is inserted, the opening 19 of the support body 2 '' is completely filled. Then grinding granulate is filled into the mold and combed or knife. This abrasive granulate consists of the abrasive grain 15 already described with a nominal grain size in the range of 600 μm binder 16 and filler 17 , the binder also being a phenol-formaldehyde adhesive, which is generally identical to that from which the layer is made 25 exists. In any case, it should be a curing polycondensation adhesive. The second reinforcement layer 14 is placed on the combed or a doctored layer of the grinding granulate. Then the grinding granules are pressed with the support body 2 '' under a pressure of 500 to 4000 N / cm ² . In this pressing process, abrasive grain 15 presses on the one hand into the layer 25 and on the other hand into the outer peripheral surface 9 '' of the edge 24 , whereby a particularly firm tooth-like connection between the grinding ring 1 and the support body 2 '' is achieved. These compacted but not yet hardened grinding wheels are stacked between steel plates and placed in an oven for hardening and hardened at temperatures between 120 and 200 ° C depending on the desired degree of hardness. The manufacture len the connection between slip ring 1 and support body 2 '' on the one hand and the hardening of the grinding granulate on the other hand is done in one operation.

For the selection of the binder 16, applies that the grinding ring 1 should have itself a hard possible binder 16, on the one hand to prevent smearing during the grinding process and on the other hand an early breaking of the abrasive grain 15 ensure, so that a self-sharpening of the grinding wheel is achieved. On the other hand, the binder must not be so hard or brittle that the slip ring 1 can break off from the supporting body 2 ''. Polycondensation adhesive with numerous modification options have proven to be particularly advantageous here.

As can be seen in Fig. 8 and as can be seen from the above-described production method, the end face 5 , the slip ring 1 is flush with the end face 6 ''; while the end face 5 of the slip ring 1 protrudes slightly beyond the edge 24 in the direction of the axis 4 .

The dimensions or dimensional ranges and proportions given above apply not only - as in the exemplary embodiments described above - for cutting-off grinding wheels, but also for grinding grinding wheels, with the exception that for grinding wheels 1 applies to the thickness e of the grinding ring 4 , 0 mm and 10 mm.

Claims (17)

1. grinding wheel for hand-held grinding machines, in particular cutting-off grinding wheel, with an inner support body ( 2 , 2 ', 2 '') and with one connected to this, at least one reinforcing layer ( 14 , 14 ') and a synthetic resin bond of the abrasive grain ( 15 ) Sliding ring ( 1 ), characterized in that the grinding ring-shaped grinding ring ( 1 ) has a recess ( 3 ) formed concentrically to a central longitudinal axis ( 4 ), in which the supporting body ( 2 , 2 ', 2 '') Arranged and connected to the slip ring ( 1 ). 2. Grinding wheel according to claim 1, characterized in that the slip ring ( 1 ) protrudes at least with one end face ( 5 ) over one end face ( 6 ) of the supporting body ( 2 , 2 ', 2 ''). 3. Grinding wheel according to claim 1 or 2, characterized in that the slip ring ( 1 ) and the support body ( 2 , 2 '') are glued together. 4. Grinding wheel according to one of claims 1 to 3, characterized in that between the outer peripheral surface ( 9 ) of the support body ( 2 ) and a recess ( 3 ) delimiting inner peripheral surface ( 8 ) of the slip ring ( 1 ) with an adhesive layer ( 10 ) filled gap ( 7 ) is formed. 5. Grinding wheel according to one of claims 1 to 4, characterized in that the recess ( 3 ) delimiting inner peripheral surface ( 8 ) of the slip ring ( 1 ) and / or the outer peripheral surface ( 9 , 9 '') of the support body ( 2 , 2nd '') Are cylindrical. 6. Grinding wheel according to claim 3, characterized in that the slip ring ( 1 ) and the support body ( 2 ) are glued together by means of epoxy resin. 7. Grinding wheel according to one of claims 1 to 6, characterized in that the support body ( 2 , 2 '') consists of sheet metal. 8. Grinding wheel according to claim 1 or 2, characterized in that the supporting body ( 2 ') in the recess ( 3 ) of the slip ring ( 1 ) is injected. 9. Grinding wheel according to claim 8, characterized in that the supporting body ( 2 ') consists of die-cast zinc. 10. Grinding wheel according to one of claims 1 to 9, characterized in that the reinforcing layer ( 14 , 14 ') consists of reinforcing threads ( 18 ) which are tangential in the region of a central opening ( 19 ) and radially tangential to the outer circumference and which are deflected on the outer circumference. 11. Grinding wheel according to claim 10, characterized in that the reinforcing threads ( 18 ) tangential and radial-tangential each run in a straight line. 12. Grinding wheel according to claim 10, characterized in that the reinforcing threads ( 18 ) from the central opening ( 19 ) to the outside start in the form of a partial spiral. 13. Grinding wheel according to one of claims 1 to 12, characterized in that the reinforcing threads ( 18 ) are glued together at their crossing points ( 20 ). 14. Grinding wheel according to claim 7, characterized in that the thickness (e) of the support body ( 2 '') is significantly less than the thickness (a) of the slip ring ( 1 ) and that the support body ( 2 '') on its outer circumference with an essentially ring-cylindrical edge ( 24 ) is provided, the extent (b) of which in the direction of the central longitudinal axis ( 4 ) is greater than the thickness (e) of the supporting body ( 2 '') and on the outer peripheral surface ( 9 '' ) the slip ring ( 1 ) is attached. 15. Grinding wheel according to claim 14, characterized in that the abrasive grain ( 15 ) in the outer peripheral surface ( 9 '') of the edge ( 24 ) is partially pressed. 16. Grinding wheel according to one of claims 1 to 15, characterized in that the slip ring ( 1 ) has a polycondensation adhesive as a binder ( 16 ). 17. Grinding wheel according to one of claims 14 to 16, characterized in that the outer peripheral surface ( 9 '') of the edge ( 24 ) is provided with a layer ( 25 ) of adhesive which is the binder ( 16 ) of the slip ring ( 1 ) is similar.