EP0991500A1

EP0991500A1 - Flexible abrasive body

Info

Publication number: EP0991500A1
Application number: EP98937537A
Authority: EP
Inventors: Martin Eggert; Bettina Weiss
Original assignee: VEREINIGTE SCHMIRGEL- und MASCHINEN-FABRIKEN AG
Current assignee: VEREINIGTE SCHMIRGEL- und MASCHINEN-FABRIKEN AG
Priority date: 1997-06-26
Filing date: 1998-06-23
Publication date: 2000-04-12
Anticipated expiration: 2018-06-23
Also published as: CA2294953A1; AU744204B2; CA2294953C; DE19727104A1; ES2167093T3; DE59801981D1; WO1999000218A1; DK0991500T3; EP0991500B1; PT991500E; US6383064B1; CN1131130C; DE19727104C2; JP2002507155A; ATE207787T1; AU8629498A; JP4009664B2; CN1261302A

Abstract

The invention relates to a flexible abrasive body having a pliable support which exhibits one layer made from a pliable substrate on one side of which there is a full-coverage first metal coating and on this a second metal coating in which the abrasive material is at least partly embedded. In order to obtain an abrasive body of this kind with high thermal conductance, excellent flexibility, high dimensional stability and compactness, the support 9 consisting of substrate 2 and first metal coating 10 exhibits a constant thickness and the first metal coating 10 exhibits a flat, smooth surface and minimized coating thickness. The second metal coating 14 and also the first metal coating 10 are preferably provided with breaking points 18.

Description

Flexible grinding wheel

The invention relates to a flexible abrasive body according to the preamble of claim 1.

Flexible abrasives include, for example, coated abrasives, such as endless sanding belts and sanding sheets, which are equipped with a flexible carrier. For the durability of such a flexible abrasive body, it is crucial that the flexible carrier withstands the tensile, compressive and shear forces during the grinding process without damage and that the valuable abrasive grains do not come loose from the dressing too quickly and fall out during use. In addition, the thermal strength of the flexible abrasive with respect to the grain fixation and carrier strength must be sufficient to withstand the high temperatures that occur, especially in dry grinding operations. The super cutting materials diamond and CBN (cubic boron nitride), which are characterized by their high thermal conductivity and extremely high hardness, require particularly high heat resistance for grain embedding. Due to the high cutting quality of these abrasive grains, even when used against the hardest materials, it is particularly necessary to dissipate the cutting heat generated on the grain to the grain binder layer and into the flexible carrier in order to avoid excessive, harmful workpiece temperatures and thermally activated grain destruction. For this purpose, it is known to galvanically embed the abrasive grains in heat-resistant, resistant metal, especially nickel, cf. DE 1 059 794, EP 276 946, EP 0 263 785, EP 0 280 653, EP 0 013 486, DE 39 15 810, which are described in more detail below.

The electroplated abrasive coating has only one layer of abrasive. The growing metal or nickel layer emanating from the carrier envelops the grain that is gradually spread in parallel, whereby the embedding height of the desired free-cutting grain can be regulated exactly over the duration of the galvanic deposition. Galvanically bonded abrasive grains cannot be dressed due to the monolayer of the abrasive layer; at most, it is possible to compensate for differences in the grain peak elevation by touching. Because of the lack of the possibility of post-processing, it is a typical characteristic of galvanically bonded abrasive bodies that the measure of the abrasive layer is at best as good as the measure of the underlying carrier allows. A surface-covering, galvanic metal binder layer already has a thickness at the relevant grain sizes (approximately 20 to 600 μm with a corresponding galvanic embedding height of approximately 50 to 80%), which gives the sheet-like structure the physical character of a sheet. The flexibility of such layers or their alternating bending strength is higher, the thinner such a layer is, since the relative difference between compression and extension of the two sides of the fabric decreases and the fatigue fracture under alternating load is delayed. However, such thin metal binder layers in the range of a few μm are only able to adequately fix grain sizes of this size. The strength and flexibility of galvanic layers can vary greatly depending on the bath composition, temperature, current density and deposition speed, from tensioned to brittle and almost to the suppleness of stress-relieved rolled foils. Typically, however, film-thin metal layers always show a high sensitivity to impacts and Buckling loads as well as low resistance to tear propagation loads, which can be attributed to the low elastic deformability of the metal. Such irreversible, plastic deformations in a surface-covering, galvanic grain binder layer preclude their use as highly resilient, flexible grinding wheels.

From DE 1 059 794 it is known to form a flexible support in the form of a metal layer on a flexible endless steel strip, which is formed in a

Electrolyte liquid circulates and is connected as a cathode and abrasive grain scattered on its surface is bound by a galvanically applied metal layer. After this abrasive coating has been detached from the steel belt, there is already a usable sanding belt in the form of a metal foil with partially embedded abrasive grain. The level of strength and the mentioned problems of thin metal foils restrict the use of such sanding belts to the lightest sanding operations or, due to the limited flexibility, only the thinnest galvanic grain binder layers and the finest abrasive grains can be processed in this way to form flexible abrasives. This abrasive coating can be laminated onto an abrasive backing. Although this can reduce the sensitivity to kinking and increase the tensile strength when the surface-covering galvanic abrasive coating is laminated, the problem that the stretching ratios and the elongation behavior of the bonded layers are different generally arises in long-term use of laminated, flexible sanding belts. For example, when laminated belts are used on grinding machines in which deflection and straight running alternate, the layer facing outwards is always subjected to tension and load, whereas the inner layer is always subjected to compression and relief is charged. These different length ratios must be compensated for elastically by the laminating adhesive. In addition, the materially different outer and inner layers differ significantly in their expansion behavior, as in the case of the galvanic metal-grain layer that is laminated onto an abrasive backing discussed here. Durable, laminated, flexible grinding media are only obtained if the deflection radii are as large as possible and the laminated goods do not become too thick, because otherwise the inner and outer belt lengths differ too much and adhesives with mediating stretching properties must be used. As a rule, the adhesive is the weakest link in the composite system, so that local damage to the galvanic abrasive coating leads to peeling and decoating of the entire, coherent abrasive coating.

In order to solve the problem of the lack of flexibility and sensitivity of surface-covering, thin metal layers or metallic grain binder layers in flexible grinding wheels, various proposals have been made, the common feature of which is not to design a surface-covering galvanic grinding coating on the surface of the flexible grinding wheel, but only the grinding coating at discrete, separate positions, i.e. H. to form insulated island abrasive pads arranged in regular patterns on a flexible substrate, for example fabric, these insulated abrasive pads on the

Surface are arranged so offset to each other that they overlap or touch when viewed in the direction of use. The interruption of the rigid galvanic abrasive coating, which increases with increasing grain size and layer thickness, ensures that the desired flexibility is largely taken over by the underlying substrate, because this lies between the re- gularly arranged, discrete abrasive coating zones has the possibility of bending.

For example, EP 0 280 657 discloses a flexible abrasive body in which a thin metal, in particular copper, foil is used, which is laminated onto a flexible, electrically non-conductive substrate, so that a carrier in the form of a flat composite material is produced , one side of which is electrically conductive and the other side of which is electrically insulated. On the electrically conductive

First, an electrically non-conductive mask is applied, which has discrete openings, and then metal, preferably nickel, is applied galvanically together with abrasive grain. In the case of galvanic coating, the formation of the abrasive coating is then reduced to the discrete openings in the masking, so that an island-shaped, non-area-covering abrasive coating made of metal (nickel) and embedded grain is formed. The mask that delimits the discrete grinding zones is then removed and the underlying metal foil that is still present is etched away. Finally, the spaces are filled with resin and, if necessary, with silicon carbide powder. Instead of using a laminated metal foil, a metal layer can also be applied directly to the substrate by means of metallization processes (electroless electrodeposition, vapor deposition or sputtering) and, as described, further processed to form the flexible grinding wheel. The disadvantage is that, in contrast to a smooth, laminated metal foil, the possible unevenness of the underlying substrate is not compensated for by the metallizations, which is insignificant in the case of a flat, smooth substrate, for example foil or the like, for a substrate made of fabric, for example however, which is characterized by the yarn wraps and fabric waviness, is considerable. On one Wavy, metal-coated fabric substrate cannot be built up with a uniformly raised, inseiform coating, so that the embedded grain does not project uniformly high and free-standing over the flexible grinding wheel. The most serious disadvantage of this configuration is that due to the inseil-shaped coating, which represents a piling up of substrate, possibly laminating adhesive, metal layer and metal binder layer with grain, a tipping moment occurs due to shear on the islands during the grinding process, as a result of which they can easily be torn from the carrier. By filling the interstices of the island with resin or with resin and silicon carbide filler, an attempt is made to reinforce this weak point. The formerly continuous metal or The copper layer is interrupted, so that the island-shaped abrasive coatings, thermally insulated, only permit poor, interrupted heat introduction into the flexible carrier. EP 0 263 785 discloses a flexible abrasive body in which a fabric is used as the substrate, which is made electrically conductive by vapor deposition with metal or by weaving in metallic yarn or which is formed by a metallized resin grid. On this

A mask made of polymeric, electrically insulating resin is applied to tissue under pressure and heat, which contains discrete openings. Metal, in particular nickel, is electrodeposited in the presence of abrasive grains in the discrete openings, which in turn forms discrete abrasive coatings made of deposited metal (nickel) and embedded grain. However, the deposited metal adheres directly to the metallized fabric, so that the risk of shear-induced detachment of the in-soap-shaped abrasive coatings during grinding operations is reduced. The individual abrasive pads are thermally conductive over the metallized fibers Tending contact, the conductivity is small because of the small fiber cross section. A disadvantage of this design is that, according to the weave of the fabric, it is not possible to achieve a uniform elevation of the in-soap-shaped abrasive coatings. From this document it is also known to mask an electrically conductive or non-conductive substrate in the form of a fabric in the manner described above, so that openings are again created for the galvanic grain fixation. This masked fabric is immovably fixed on an electrically conductive drum. The smooth drum connected as cathode causes the metal or. Nickel is deposited from its surface through the discrete openings in the fabric and the grain is only scattered when the metal or nickel layer has completely grown through the fabric. After the galvanic scattering has ended, the flexible grinding body is detached from the drum and can be laminated onto a stronger reinforcement. According to EP 0 276 946, this method can also be carried out continuously if, instead of the rotating drum, an endless steel strip passing through the galvanic bath is used, which is temporarily in an immovable state with the masked tissue. The steel belt used as the conveyor belt and cathode inside the bath is separated from the flexible grinding wheel at the end of the galvanic coating outside the bath and takes up new tissue as a revolving belt at the beginning of the bath. An advantage of these flexible abrasive bodies according to EP 0 276 946 and the second embodiment of EP 0 263 785 is that the metal-based, island-shaped abrasive coating surrounds the fabric in a form-fitting manner from the underside to the top, and thus the risk of the in-soap abrasive deposits being torn off is reduced by the tilting moment occurring during the grinding process. As with all other designs island-shaped, discreet abrasive coverings, but here too the weak point of the grain-, metal- and nickel-free intermediate island areas can be found again. Again, the island-shaped abrasive pads are not in thermally conductive contact with each other, so that the heat generated in the grinding process accumulates in the island-shaped abrasive pads. It is also disadvantageous that only extremely thin, net-like, open, light fabrics can be uniformly interspersed with metal (nickel) in a form-fitting manner because the yarns per se represent defects in the electrodeposition and galvanic layers generally do not have any thickness and are free of defects are to be made thick. The island-like, disc-shaped metal or nickel deposits emanating from the smooth drum cathode or the smooth steel strip cathode lose more and more of true shape to the growth side, the thicker the layers become or at the moment when the tissue is positively overgrown. This means that the metal or. Nickel layer discs as the basis for the galvanically bonded abrasive grain are not flat and not uniformly thick. The flexible grinding body obtained in this way has a low strength level due to the limited fabric strength and limited fabric construction and must be laminated to a stronger reinforcement. This further increases the thickness tolerance of the flexible grinding wheel. In addition, lamination increases the compressibility of the composite in comparison to the individual components. Due to the relining, the practically incompressible, disc-shaped metallic abrasive coverings are on a more or less elastic basis, which precludes dimensionally accurate grinding.

A similar flexible grinding wheel is known from EP 0 013 486. On an electrically conductive An electrically non-conductive mask is applied to the drum, the discrete openings of which remain free for galvanic deposition. An electrically non-conductive tissue stretched onto the cathodically connected drum is only grown through by electrodeposited metal (Nikkei or copper) at the discrete positions specified by the mask. After penetrating the tissue, grain is sprinkled on the growing metal layer, which is then embedded. Finally, the flexible abrasive wheel from the

Drum released and processed. This flexible grinding body differs from the grinding body according to EP 276 946 essentially only in that the desired disc-shaped metal deposition is oriented only by the masking on the drum and no longer when the tissue grows through. This grinding wheel is therefore only suitable as a flexible carrier for particularly fine, mesh-like fabrics, for example for grinding lenses. In a modified embodiment of this method, an equally high grain flatness is generated on the flexible grinding body in a galvanic, but not single-layer grain layer. For this purpose, abrasive grain is first galvanically embedded in the mask openings on the masked drum. If sufficient grain is embedded, an electrically non-conductive fabric is placed on it and the galvanic metal deposition is continued. After breaking through the tissue and deposition of the metal with a certain thickness, it is broken off and the flexible grinding body is detached from the drum. The advantage of this configuration is that a homogeneous grain flatness is achieved, but the grain is practically completely embedded and not very sleek for galvanic grain binding and can therefore only be used in fine machining. The non-uniformity of the disc-shaped grinding surfaces is again on the side of the flexible grinding body that faces away from the grain. due to the growth caused by the galvanic _ interruption of tissue, which means that the flexible grinding wheel cannot be adequately tempered. From DE 39 15 810 a flexible grinding body is known which has a flexible support made of electrically conductive material (metal foil), with which bound or unbound reinforcing threads are connected, which are sewn to the conductive material by overlapping seams. The seams also connect a mat of non-conductive material arranged on the other side of the metal foil to the metal foil. The top is insulated in discrete areas with a cover such that areas of the metal foil remain free between the reinforcing threads, onto which galvanic metal is deposited, which forms protruding islands. A stabilizing coating of synthetic resin is then applied to both sides of the carrier, which covers the mat and fills the spaces between the islands and also covers the interior. The carrier is then ground off on the island side so that the metal islands are exposed. Then metal is galvanically deposited on the islands together with abrasive grains. The high oversize of the electroplated metal is disadvantageous, since the reinforcing threads and connecting threads have to be towered over before the galvanic abrasive grain is embedded. Two galvanic processes are necessary. The underlying metal foil is not permanently resistant to bending. Alternatively, the first galvanic application can also take place over the entire surface, the reinforcing threads representing galvanic defects; then the carrier has a very stiff, less flexible sandwich structure.

The object of the present invention is to provide an abrasive body of the type mentioned at the outset with high thermal conductivity, great flexibility, high dimensional stability and moderation, and a drive to specify its manufacture.

This object is achieved by the invention according to claim 1.

A method for producing the grinding wheel is specified in claim 20.

Advantageous and expedient developments of the task solution according to the invention are specified in the subclaims.

The invention proposes a substrate, for example a textile structure such as woven fabric, knitted fabric, fleece or the like, on one or both sides with hard coating compositions with a smooth, flat surface, on one side with an electrical conductive material, preferably metal, for example copper, and optionally additionally on the other side with an electrically non-conductive material, preferably a curable resin, for example phenolic resin. The substrate coated in this way forms a carrier for abrasive grain and is trimmed to a constant thickness so that the raised areas of the carrier are covered at least on the metal-coated side, even very thinly by metal. The rejuvenation points of the hard coating masses resulting from the reworking (dressing) give the carrier the necessary flexibility, on the other hand a high compression resistance is maintained perpendicular to the carrier. Such a configuration is particularly advantageous in the case of a textile structure as a substrate which has undulations which are caused by the yarn wraps, ie. H. the crosshair points. The

Coatings are positively connected to the threads. The highest thread elevations remain at least on the metal side wafer-thin, ie about 3 - 25 μm, metal-coated, while the majority of the electrically conductive material (metal) and the electrically non-conductive material is located between the thread crossing points. This so trained Carrier of constant thickness and smooth metallic surface forms an ideal, homogeneous carrier for a full-surface, galvanic coating with a metallic embedding material, preferably nickel, and with abrasive grain, whereby a flexible abrasive body can be produced, which is characterized by a uniform grain flatness and grain embedding.

The flexibility is further increased by the fact that the metal coatings are broken, as specified in claims 2, 3 and 10, without this affecting the electrical or thermal conductivity.

The invention will be explained in more detail below with reference to the accompanying drawing, which schematically shows the structure of a flexible device according to the invention

Grinding body based on its gradual manufacture shows.

Show it

Fig. 1 shows schematically a section in the warp direction through a single-chain one-shot

2 shows the substrate according to FIG. 1 with a metal layer applied on one side (on the front side),

3 shows the substrate according to FIG. 2 with an additional coating on the side opposite the metal layer (rear side) with an electrically non-conductive material to form a carrier for a flexible abrasive body, FIG. 4 shows the carrier according to FIG. 3 also dressed

5 shows the carrier according to FIG. 4 with metal / abrasive grain coating completely deposited on the front side of the metal coating. Position of a flexible grinding wheel, FIG. 6 the carrier according to FIG. 5 with metal / abrasive grain coating galvanically deposited on the front metal coating for the production of a modified flexible grinding wheel, and FIG. 7 the carrier or the grinding medium according to FIG. 5 in by bending (Flexen) caused broken condition.

Identical components in the figures of the drawing are provided with the same reference symbols.

1 shows a substrate 2 for a carrier of a flexible abrasive body in the form of a single-chain, one-shot fabric 4, with 6 warp threads and 8 weft threads. Other fabric structures, as well as knitted fabrics, knitted fabrics, braids and nonwovens, which all have cross-hair points, can also be used for the substrate.

The crosshair points cause a certain ripple or unevenness in the substrate surface. The fabric 4 is used to form a carrier 9 for the grinding wheel on one side (hereinafter referred to as the front) with an oversize metal coating 10 (FIGS. 2, 3) and on the opposite side (hereinafter referred to as the rear) with an electrically non-conductive material, preferably a curable resin, such as phenolic resin, provided with existing coating 12 (FIGS. 3, 4), where appropriate adhesion promoters and fillers can also be used.

The metal for the metal coating 10 is preferably copper and can be applied by suitable metallization methods, such as metal spraying, vapor deposition, sputtering or electroless electrodeposition. Due to the thread elevations of the weft and KetJ; - - thread crossing points, there is a waviness of the surface of the metal coating 10, but also of the rear coating 12, cf. 2 and 3. To achieve a support of constant thickness and smooth surface, the coatings 10 and 12 are dressed, for example by grinding to size and optionally by rolling, cf. Fig. 4. At least the metal coating (copper) 10 on the front of the carrier is removed so far that the highest elevations of the fabric, braid, fleece etc. - in the area of the weft and warp thread crossing points 17 - still wafer-thin - of the order of 5 - 15 μm - are covered by metal, while the bulk of the metal is arranged between the crosshairs. Due to these regular tapering points 13 of the coatings 10 and 12, the support 9 obtains the necessary flexibility, on the other hand a high compression resistance perpendicular to the support, specifically because the metal or the non-conductive material alternates between the crosshairs 17 (Resin) are positively embedded and the elastic springback of the wearer is suppressed under compression. The flexibility of the continuously metal-coated fabric caused by the tapering points is also influenced by the fabric construction, ie by the type of weave and density and location of the fabric crossing points. The rear coating 12 can be produced to size with a smooth surface without finishing, by spreading the resin in the liquid A state and rolling it in the still moldable B state and then curing it. This support 9 of constant thickness and smooth metallic surface thus formed forms an ideal, homogeneous basis for a full-surface galvanic coating. supply with a metallic embedding material 14, preferably nickel, and with abrasive grain 16, cf. 5, whereby a flexible grinding body 21 can be produced, which is characterized by a uniform grain size and grain embedding. The trained one

Metal coating 10 is connected as a cathode. The stiffening which inevitably occurs in the case of full-surface galvanic coating by the metallic grain binder layer 14 is eliminated according to the invention in that at least the rigid metallic abrasive coating 14, 16 is "flexed", ie. H. Fractures 18 are generated at regular intervals by exceeding the maximum bending capacity, the tapering points 13 of the underlying metal layer 10 having an initiating effect, cf. Fig. 7. To increase flexibility, the metallic coating 10 is preferably also flexed or broken, cf. Fig. 7. Flexing or breaking can take place before, during or after the galvanic coating. When flexing or breaking, 12 buckling bends 20 occur on the rear coating, cf. Fig. 7.

Preferably, the galvanic metal layer 14 and preferably also the underlying metal layer 10, which is switched as the cathode during the galvanic coating, is produced so brittle-hard that there is a real brittle fracture without kinking of both metal layers. The flexibility or breakability of the two metal layers can be increased by the fact that they are subject to an internal tensile stress. Due to the brittleness and possibly additionally the tensile residual stress, the formation of cracks during flexing or refraction is facilitated. The danger is avoided that one or both metal layers merely buckle but not break. This can be achieved by producing or applying the metal layers in a porous or micro-cracked manner or by incorporating defined foreign atoms or defined amounts of foreign particles. The Galvanic metal layer (nickel layer) is first made easier to break by being continuously interrupted by abrasive grain. This metal layer also becomes brittle and micro-cracked with a particularly low elasticity through the choice of an appropriate electrolyte (e.g. bright nickel plating) and also through appropriately selected deposition parameters.

It has been found that metal spraying of copper, which is characterized by high application rates at relatively low substrate temperatures, is particularly suitable for the surface metallization of the substrate (fabric). With this thick-film technological metallization process, excessive layer thicknesses can be achieved on the substrate, so that in the subsequent post-processing, as much copper can be removed from the copper layer following the substrate ripple that the aforementioned smooth copper surface and the mentioned tapering points 13 at the crosshairs 17 of the underlying substrate (tissue) result. It is also a property of the various metal spraying processes that the metal spraying layers are porous and contain oxides; In addition, these metal spray layers are subject to residual tensile stresses, which also facilitates the desired brittle fracture when flexing or breaking.

Surprisingly, when a bending load is removed, the cleats 22 are fully electrically contacted again at the break points 18, since otherwise a uniform, galvanic coating of the cathodically connected carrier would not be possible.

Said flexible grinding body according to FIG. 5 or 7 has a number of further advantages. The fact that there is an area-wide galvanic abrasive grain covering, there is no weak point on the surface of the abrasive body, as the island gaps with the interrupted island-shaped coating according to the state of the Represent technology. In contrast to the island-like occupancy, the cutting forces are distributed over the entire area of the dimensionally stable, hard support and not selectively on a comparatively soft reinforcement, which can ultimately shear off the island grinding pads. With this area-wide galvanic coating, no tilting moment occurs, since the clods 22 or bending points encompass larger areas. The massive, form-fitting anchoring of the underlying metal (copper) 10 in the substrate (tissue) enables heavy cutting work without loss of abrasive coating. In contrast to island occupancy, the full-surface coverage leads to an uninterrupted cut and a more uniform grinding pattern because the grinding pressure is distributed over the entire meshing surface of the flexible grinding body. At the same time, the force / grain ratio is reduced with a comparable spreading density. The particularly pressure-stable design and uniformly raised galvanic grain embedding on the dressed carrier 9 allow grinding to be precise.

5 and 7 is characterized by a very high thermal conductivity, since a surface-covering, coherent metallic see grain binder layer is connected to a surface-covering coherent metallic base 10, which fills the fabric recesses and spaces between the crosshairs. The high percentage by weight of this metal (2/3 to 5/6 of the total weight) means that high amounts of heat from

Abrasive grains can be picked up and removed. In addition, the massive metal content means that, due to the low thermal expansion of the metal, only insignificant changes in thickness and length of the flexible grinding body 21 can be recorded in grinding operations, which is important for dimensionally accurate grinding operations. As an alternative to the said two-dimensional galvanic coating, it is of course also possible to produce island-shaped abrasive coatings if a mask 24 is printed on the smooth, metallized carrier 9 prior to the galvanic coating, said mask covering discrete openings for galvanic coating with a metallic embedding material 26, preferably Nikkei. and leaves with abrasive grain 28, cf. Fig. 6. In contrast to the known designs of island-shaped, galvanic grinding linings, however, these do not have a tilting moment in grinding operation because they are seated on the solid, coherent base metal layer 10 and cannot be pressed down and sheared off at certain points. The metal spraying for applying the metal coating 10 is not limited to high-temperature-resistant substrates by suitable guidance of the coating parameters. Thus, in addition to metal fabrics, inorganic fabrics, organic fabrics can also be considered as fabrics, such as, for example, B. aramid, polyamide, polyester or cotton and viscose or mixtures thereof, if sufficient cooling is taken care of and the application quantities of metal and thus the amounts of heat transferred are carried out in stages. Metal fiber components in the fabrics cause the initially purely mechanical interlocking of the metal spray layer in the filaments of the yarn to achieve higher adhesive values; they also improve electrical conductivity. The stiffness can be adjusted by impregnating the substrate and other back coatings. In addition, the impregnation takes on the task of improving the adhesion of the metal spray layer to the fibers, for which the basically rough metal spray layer represents good points of connection. A metal binder can be added, e.g. B. vulcanization systems, silane coupling agents, polyurethanes, epoxides. The back coatings themselves are one or multilayer layers of curable resins, especially _ phenolic resins, as has already been mentioned, which are calendered after application in the still moldable B state under high pressure and finally hardened. Post-processing of the back is then not necessary with regard to the thickness tolerances, since it is a coating process with optimal flow properties.

Claims

claims

1. Flexible abrasive body with a flexible carrier, which has a layer made of a flexible substrate, on one side of which a surface-covering first metal coating is arranged, on which a second metal coating is arranged, in which the Brazilian material is at least partially embedded, characterized that the carrier (9) of substrate (2) and the first metal coating (10) has a constant thickness, and that the first metal coating (10) has a flat, smooth surface and a minimized layer thickness.

2. Flexible grinding wheel according to claim 1, characterized in that the second metal coating (14) is provided with break points (18).

3. Flexible grinding wheel according to claim 1 or 2, characterized in that the first metal coating (10) is provided with break points (18).

4. Flexible grinding wheel according to claim 1 or 2, characterized in that the second, the abrasive material fixing metal coating (14) is surface-covering or at discrete locations on the first metal coating (10).

5. Flexible grinding wheel according to one of the preceding claims, characterized in that the second metal coating (14) is applied by electrodeposition on the first metal coating (10).

6. Flexible grinding wheel according to claim 1, characterized in that the substrate (2) on the side opposite the first metal coating (10) has a coating (12) made of non-conductive material with a flat, smooth surface and minimized layer thickness.

7. Flexible grinding wheel according to claim 6, characterized in that the material of the coating (12) is a resin.

8. Flexible grinding wheel according to claim 7, characterized in that reactive, crosslinkable precursors of thermosets are used as curable resins, which have a still formable, curable B-state.

9. Flexible grinding wheel according to claim 8, characterized in that the resin is phenolic resin.

10. Flexible grinding wheel according to one of claims 6 to 9, characterized in that the coating (12) is provided with buckling bends (20).

11. Flexible abrasive body according to one of claims 1 to 10, characterized in that the substrate is a textile structure.

12. Flexible abrasive body according to one of the preceding claims, characterized in that the substrate (2) is a woven fabric, a mesh, a knitted fabric or a nonwoven.

13. Flexible grinding wheel according to claim 12, characterized in that the substrate (2) consists of heat-resistant, organic, inorganic, metallized fibers or metallic fibers or mixtures thereof.

14. Flexible grinding wheel according to one of the preceding claims, characterized in that the first metal coating (10) consists of copper.

15. Flexible grinding wheel according to one of claims 6 to 14, characterized in that the coatings (10, 12) are positively connected to the threads of the substrate.

16. Flexible grinding wheel according to one of the preceding claims, characterized in that the second metal coating (14) consists of nickel.

17. Flexible grinding wheel according to claim 1, characterized in that the abrasive material is diamond or cubic boron nitride.

18. Flexible abrasive body according to one of the preceding claims, characterized in that the layer thickness of the first metal coating (10) and the non-conductive material coating (12) at the highest elevations of the substrate (2) (fabric, braid, knitted fabric, fleece) 3 - 25 μm.

19. Flexible grinding body according to claim 2, 3 or 10, characterized in that the breaking points (18) and / or the kinks (20) extend substantially transversely to the intended grinding direction.

20. Method for producing a flexible abrasive body, in which metal is embedded on a carrier. tetem abrasive material is applied, according to one of the preceding claims, characterized by the following process steps:

a) covering one side of a flexible substrate with an excess of a first metal (first metal coating),

b) removing and leveling the metal to a predetermined thickness of the support formed from the substrate and the first metal coating,

c) coating the first metal coating with a second metal (second metal coating) while simultaneously embedding the abrasive material.

21. The method according to claim 20, characterized in that the first metal coating is removed and leveled so far that the highest elevations of the substrate still remain covered with a thin metal layer.

22. The method according to claim 20, characterized in that the carrier is provided on the side opposite the first metal coating with a coating of a non-conductive material.

23. The method according to claim 20, characterized in that the carrier is provided on the side opposite the first metal coating with a smooth, flat coating made of a non-conductive material.

24. The method according to claim 22 or 23, characterized in that the coating of the non-conductive

Material is removed and leveled so far that the highest elevations of the substrate are still thin Material layer remain covered.

25. The method according to claim 21 or 24, characterized in that the thin metal layer and the thin layer of non-conductive material is 3 to 25 microns.

26. The method according to claim 22 or 23, characterized in that the non-conductive material is a curable resin, in particular phenolic resin.

27. The method according to claim 20, characterized in that the first metal coating and / or the second material coating comprising the abrasive material is broken.

28. The method according to claim 24, characterized in that the breaking of the metal coatings is carried out before, during or after the application of the second metal coating.

29. The method according to any one of claims 22 to 26, characterized in that the coating of non-conductive material is provided with kink lines.

30. The method according to claim 27, characterized in that both metal coatings are brittle hard.

31. The method according to claim 27, characterized in that foreign particles are embedded in the metal coatings.

32. The method according to any one of the preceding claims, characterized in that the second metal coating is electrodeposited on the first metal coating.

33. The method according to any one of the preceding claims, characterized in that the first metal coating is carried out by application processes from the solid, liquid, gaseous or dissolved state of matter.

34. The method according to claim 33, characterized in that an adhesion promoter is used to improve the adhesion between the first metal coating and the substrate.

35. The method according to claim 21 or 24, characterized in that the leveling is carried out by rolling, plating, pressing, forging or shot peening.

36. The method according to claim 20 or 23, characterized in that the removal of the metal of the first metal coating and the material of the non-conductive coating by sandblasting, milling, grinding, chemical or galvanic etching, spark erosion or by cutting the removal process (laser, electron beam, water jet ) he follows.