EP1561545A1 - Abrasive belt - Google Patents

Abstract

Abrasive belt comprises a polymer film or a mixed fiber fabric as a support. The film units (1a, 1b) of the support are interconnected via a zero connection. An independent claim is also included for the production of the above abrasive belt. Preferred Features: Two film units are designed so that at least one section of the surface of a film unit that adjoins the other film unit is angled away from the other film unit and a fiber material (2) is introduced into the gap.

Description

The present invention relates to an abrasive belt which is particularly suitable for grinding of ceramic parts is suitable.

Ceramic parts are used for various applications. For example be reminded of cladding of building facades or on flow. ceramic parts usually need to be polished to mirror gloss for such uses to be acceptable. This makes high demands on the accuracy of the used Sanding belts. Meet conventional abrasive belts for other applications these high requirements are not. In particular, the documents and their Tape joints on conventional abrasive belts too uneven.

This is particularly problematic because bumps or over thicknesses the abrasive belt to irreparable damage to the surface of the ceramic parts lead, which usually make the ceramic workpiece void. A post-processing is not feasible with sintered ceramics for dimensional reasons. Sintered ceramics often have a gradient of porosity (more porous above than below in the sintering direction), so that the part to the respective correct step is no longer identical is.

It was the object of the present invention to provide an abrasive belt which suitable for grinding ceramic parts.

This object is achieved by a grinding belt according to the independent claims.

In particular, the present invention relates to an abrasive belt comprising a polymeric film or a mixed fiber fabric as a base, characterized in that the Units of the pad are connected to each other via a zero connection.

According to the present invention, a compound becomes a zero compound of two band units which are almost none, i. not more than maximum 5 μm thick due to a protruding band.

It has been found that a pad which comprises a polymer film and whose Tape units are connected to each other via a zero connection, which is used for grinding Have required accuracy of ceramic parts with very good traction. By Using a polymeric film, a backing can be provided which does not have the bumps adversely affecting unevenness. It has become though also shown that a mixed fiber fabric can be used as a base, when connecting the pad units to each other via a null connection.

As a material for the polymer films according to the invention preferably polyester, polyethylene or polypropylene used. According to a preferred embodiment the backing of the abrasive belt can also be made of a laminate of such a Polymer film and a waterproof, finished fabric backing.

According to the present invention, the backing of the abrasive belt preferably a thickness of 250 to 350 μm, in the embodiment of a laminate of polymer film and tissue to a thickness of 300 to 600 microns.

On the pad the abrasive is applied. The abrasive must be for the Having grinding of ceramic parts required hardness. According to the invention Abrasive used in the usual grain sizes for grinding applications. According to In the present invention, the abrasive is preferably a superabrasive such as diamond (e.g., monocrystalline resin-bond, monocrystalline metal-bond, polycrystalline, coated) or cubic boron nitride (cBN).

The abrasive is bonded to the backing by means of a binder. As a binder Common materials used in this field can be used. According to the invention, the binder is preferably a phenolic resin in a proportion of 0-20% by weight of phenoxy resin. It is according to the present invention but also possible to use a binder by inserting very solid Fibers is reinforced. Preferably, small additions of cut fibers become (chopped fibers) incorporated during the preparation of the binder matrix in the same. Fibers of m- and / or p-aramid (aromatic Polyamide), ultra-high-density polyethylene, highly oriented polyester, polyester, Polyamide, carbon fibers or glass fibers and stranded wires. According to the invention especially preferred is the use of m-aramid fibers available from the company Du Pont under the Nomex® brand and Teijin under the Teijinconex® brand be sold, and / or p-aramid, which by Du Pont under the Brand Kevlar®, by Twaron under the brand Twaron® and by the company Teijin sold under the brand Technora®, and / or of ultra-high-strength fibers Polyethylene marketed by Toyobo under the Dyneema® brand become. Particularly preferred according to the invention is the use of fibers from p-polyphenylene-2,6-benzobisoxazole marketed by Toyobo under the trade name Zylon® be distributed. According to the invention, however, combinations of all above-mentioned materials as a fiber material for reinforcing the Bi ndemittelmatrix be used.

The abrasive is applied to at least one surface of the pad. ever However, after the type of zero connection, the abrasive can also be applied to both surfaces the pad are applied. Especially if the pad is made of a laminate a polymer film and a waterproof fabric, is the application of the Abrasive preferably on both surfaces of the pad thus formed. In embodiments, where the abrasive is applied to both surfaces of the pad can, for the different surfaces each have a different abrasive or the same abrasive with different granularity (on one surface coarse abrasive, on the other surface fine-grained abrasive used) become. In this way, an abrasive belt is provided, both of which Surfaces have different grinding properties. According to the invention this can be realized in particular in the embodiment in which a laminate of Polymer film and waterproof fabric is used as a backing.

In the context of the present invention, the backing of the abrasive belt, whether polymer film, Mixed fiber fabric or laminate, also with a backside coating be provided. The tape units of the pad together with the backside coating are connected to a null connection. The backside coating is preferably made of a synthetic resin and preferably has a thickness of 100 up to 200 μm.

Particularly advantageously, the backside coating is provided with additives. This can be organic or inorganic particles, e.g. Minerals, plastic granules or cork. As a result, for example, achieved a damping during processing become. With such a sanding belt less oversized scratches, as a result Grain or the entire grinding belt can recede at oversizes in the belt.

The abrasive belt of the present invention is made by first passing the Substrate prepares and then the abrasive by means of a binder with the pad connects. The pad is made by joining several padding units provided via a null connection. The generation of these zero connections is explained below with reference to preferred embodiments.

According to the present invention, there are five different types of null connections prefers. Preferred embodiments of the inventive abrasive belts with These null connections are shown in the non-limiting figures.

Fig. 1

ein Schleifband mit einer Nullverbindung gemäss einer ersten bevorzugten Ausführungsform

Fig. 2

ein Schleifband mit einer Nullverbindung gemäss einer zweiten bevorzugten Ausführungsform

Fig. 3

ein Schleifband mit einer Nullverbindung gemäss einer dritten bevorzugten Ausführungsform

Fig. 3A

ein weiteres Schleifband mit einer Nullverbindung gemäss einer dritten bevorzugten Ausführungsform

Fig. 4

ein Schleifband mit einer Nullverbindung gemäss einer vierten bevorzugten Ausführungsform

Fig. 5

ein Schleifband mit einer Nullverbindung gemäss einer fünften bevorzugten Ausführungsform.

Show it:

Fig. 1

a grinding belt with a zero connection according to a first preferred embodiment

Fig. 2

a grinding belt with a zero connection according to a second preferred embodiment

Fig. 3

a grinding belt with a zero connection according to a third preferred embodiment

Fig. 3A

another abrasive belt with a zero connection according to a third preferred embodiment

Fig. 4

a grinding belt with a zero connection according to a fourth preferred embodiment

Fig. 5

an abrasive tape with a zero connection according to a fifth preferred embodiment.

A zero connection according to a first preferred embodiment according to the The present invention is realized by forming two film units in such a way are that at least a portion of the surface of the film units, which in each case other film unit is adjacent, beveled away from the other film unit and a fiber material is introduced into the space formed thereby.

The fiber material may be any fiber material conventionally used for fiber-reinforced films be used. According to the invention, it is preferable an aramid fiber (Keflar®).

The zero connection of the first preferred embodiment of the present invention is generated by first at least a portion of the surface the film units which adjoins the respective other film unit, from the other Beveled foil unit away. This may be conventional, known in the art Art done, for example by grinding the slides. According to the invention preferred In this case, each film unit is in this case over a distance of 5-15 microns, preferably 5 to 10 bevelled. The bevel can be over the entire width or just over one Part of the width of each film unit be present. In this way, a wedge-shaped Space created between the two film units.

In this wedge-shaped space, a fiber material is introduced. According to the invention Preferably, this fiber material has a thickness of 50 to 100 microns. The length of the fiber material is to be chosen so that between the two film units in the connected Condition on the side where the film units come closest maximum space of 1 mm is present. The fiber material is in the wedge-shaped Pressed space, so that part of this space and this as possible the entire projecting gap through the fiber material substantially completely is filled. The fiber material is glued to the two film units. in this connection The bonding is to be carried out so that there is no excess thickness. For this can Any adhesive used for bonding polymer parts to fiber parts conventionally used. According to the invention, preference is given to a polyurethane-based adhesive.

The zero connection formed in this way can be loaded up to a tensile force of about 200 N / cm.

A preferred example of this first embodiment of the inventive Abrasive belt is shown in FIG. Two film units 1a and 1b were ground off, that they are bevelled over a distance a. The bevel is in this example not formed over the entire width of the film units. In the so formed wedge-shaped cavity, a part of fiber material 2 was introduced. The fiber material 2 was pressed into the space between the film units 1a, 1b so that the space between the straight sections of the adjoining surfaces of the Foil units 1a, 1b as completely as possible filled by the fiber material 2 and thus ensuring the most accurate possible connection between the film units 1a, 1b is. The fiber material 2 was bonded to the film units 1a and 1b, so that a firm connection was formed. Here was the emergence of a Over-thickness avoided.

On the surface of the base formed from the units 1a, 1b, the possible has no gap, was then the abrasive 4 by means of a Binder 3 bound. In the present example, the abrasive was 4 to Superabrasiv and the binder 3 to a phenolic resin with a proportion from 0-20% by weight of phenoxy resin.

A zero connection according to a second preferred embodiment according to the present invention is realized in that the adjoining surfaces the film units are chamfered to each other precisely fit and glued. This can be done in a conventional manner known in the art, for example by grinding the slides. According to the invention, each film unit is preferably transferred over here a distance of 10-30 microns, preferably 10 to 20 microns bevelled. For gluing The film units can be any adhesive that is used for bonding Polymer parts is used conventionally. Here, the bonding is carried out so that there is no excess thickness. According to the invention, an adhesive is preferred polyurethane-based.

An example of this type of null connection is shown in FIG. The two foil units 1a, 1b were bevelled so that the adjoining surfaces 5a, 5b these units fit together exactly. The surfaces 5a and 5b became one with each other glued so that there is no over-thickness at any point.

On a surface of the substrate formed from the units 1a, 1b was then the abrasive 4 bound by means of a binder 3. In the present For example, the abrasive 4 was superabrasive and the binder 3 to a phenolic resin in a proportion of 0-20 wt .-% phenoxy resin. In the case of In the present second embodiment, it is also possible to apply the abrasive to both Apply surfaces of the substrate.

In an inventive abrasive belt according to a third preferred embodiment the pad additionally comprises a layer of a waterproof cloth backing, which is connected to the polymer film. The pad is thus in this Case a laminate of two layers. A zero connection according to a third preferred Embodiment according to the present invention is realized thereby, that staggered butt joints of 2 film units and two tissue units present and glued. In other words, in the laminate, the layers are made of film and fabric offset from each other, so that, for example, the Ends of the film units do not lie directly over the ends of the tissue units. On these are the ends of the respective units by a unit of the other material bridged. As a result, a stable zero connection of each Foil units and the tissue units realized.

The compound of the laminate layers can by methods known to those skilled in the art be achieved. According to the invention, preference is given to hot-melt laminating.

In the case of the present third embodiment, it is possible to apply the abrasive Apply both surfaces of the pad, so both on the free surface of the Foil units as well as on the free surface of the tissue units. The abrasive is bound by means of a binder to the surfaces. The surfaces In this case, preferably different abrasives or a Schleifmitttel having different graininess so that the abrasive belt surfaces with having different grinding properties.

In Fig. 3 and 3A is an example of an abrasive belt according to the third embodiment shown. The film units 1a, 1b and the fabric units 6a, 6b were arranged offset from each other and form a laminate underlay. The units 1a, 1b and 6a, 6b were joined together by hot-melt laminating so that the Units 1a and 1b and 6a and 6b each form a zero connection with each other.

On one of the two surfaces of the laminate base was then in dependence From the grain size used, the abrasive 4 by means of a binder 3 bound. For coarse grain (P80-P600 or 180 microns - 25 microns) is preferably the Tissue side with grain occupied, for finer grain (P800-P3000 or 20 microns - 3 microns) is preferred the foil side. In the present example, the abrasive was 4 to Superabrasiv and the binder 3 to a phenolic resin in a proportion of 0-20 wt .-% phenoxy resin.

In an inventive abrasive belt according to a fourth preferred embodiment the pad comprises a layer of a waterproof cloth backing, which is connected to a layer of mixed fiber fabric. The underlay is thus in this case a laminate of two layers. The waterproof fabric underlay has an increased thickness of about 50-80 microns. This is required to make a null connection to realize the mixed fiber fabric units. Otherwise it would scraping the fabric underlay to irreparably damage the mixed fiber fabric come. A zero connection according to a fourth preferred embodiment According to the present invention is realized that the waterproof Fabric backing at the position below the junction of the mixed fiber fabric units 8a, 8b is scraped off. This can be done with conventional, the expert done with known methods. In this scraped area is a fiber reinforced Connecting film, which the connecting film according to the first embodiment corresponds, inserted and glued. For gluing the foil units Any adhesive that is used to bond polymer parts to fabric parts can be used conventionally used. According to the invention, an adhesive is preferred polyurethane-based.

The compound of the laminate layers can by methods known to those skilled in the art be achieved. According to the invention, preference is given to hot-melt laminating.

FIG. 4 shows an example of a grinding belt according to the fourth embodiment. The mixed fiber cloth units 8a, 8b and the thick cloth units 7a, 7b were arranged offset to each other and form a laminate underlay. The units 8a, 8b and 7a, 7b were joined together by hot-melt laminating. Subsequently the fabric backing became underneath the compound of polymer film units Scraped off 8a, 8b. In the resulting space was the fiber reinforced Inserted film 9 and glued so that the units 8a, 8b a zero connection trained.

On the formed by the mixed fiber fabric surface of the laminate pad was then the abrasive 4 bound by means of a binder 3. In the present For example, the abrasive 4 was superabrasive and the Binder 3 to a phenolic resin in a proportion of 0-20 wt .-% phenoxy resin.

FIG. 5 shows a grinding belt according to a further embodiment. The Polymer film units 1a, 1b were provided with a backside coating 10a, 10b. In the region of the connection of the film units 1a, 1b, the backside coating became except. In the resulting gap was a fiber-reinforced Inserted film 9, so that the polymer film units 1a, 1b via a zero compound were connected. The depth of the recess corresponds to the thickness the fiber-reinforced film 9.

The abrasive belt according to the invention is particularly suitable for grinding ceramic parts such as cladding of building facades or tiles. With The abrasive tape according to the invention can be used to polish ceramic parts to mirror finish What is not possible with conventional abrasive belts due to their unevenness is.

Claims (18)

Abrasive belt, comprising a polymer film or a mixed fiber fabric as a base, characterized in that the base units (1a, 1b, 8a, 8b) are interconnected via a zero connection. Sanding belt according to claim 1, characterized in that a zero connection is realized in that in each case two film units (1a, 1b) of the base are shaped such that at least a portion of the surface of the film units (1a, 1b), which to the respective other film unit adjacent, is bevelled away from the other film unit and in the space formed thereby a fiber material (2) is introduced. Sanding belt according to claim 1, characterized in that a zero connection is realized in that the respectively adjacent surfaces (5a, 5b) of the film units (1a, 1b) are chamfered and glued to each other precisely fitting. Sanding belt according to claim 1, characterized in that the zero connection is realized in that mutually offset butt joints of in each case 2 film units (1a, 1b) and two waterproof fabric underlays (6a, 6b), which are connected to the film units (1a, 1b), present and glued. Sanding belt according to claim 1, characterized in that the base comprises a layer of mixed fiber fabric (8a, 8b) and in addition a thick layer of a waterproof fabric backing (6a, 6b, 7a, 7b), which with the layer of mixed fiber fabric (8a, 8b ) connected is. Sanding belt according to claim 5, characterized in that the zero connection is realized in that the fabric support (7a, 7b) below the compound of the film units (8a, 8b) removed and in this space a fiber-reinforced film (9) is introduced. Sanding belt according to claim 1, characterized in that the film units (1a, 1b) are provided with a backside coating (10a, 10b). Sanding belt according to claim 7, characterized in that the zero connection is realized in that the backside coating (10a, 10b) below the compound of the film units (1a, 1b) removed and in this space a fiber-reinforced film (9) is introduced. An abrasive belt according to any one of claims 1 to 8, comprising an abrasive (4) on one or both surfaces of the pad. An abrasive belt according to claim 9, characterized in that one of the two surfaces of the abrasive belt is coated with the abrasive depending on the grain size. Sanding belt according to claim 9 or 10, characterized in that the abrasive (4) is selected from the group of Superabrasive such as diamond (eg monocrystalline resin-bond, monocrystalline metal-bond, polycrystalline, coated) or cubic boron nitride (cBN). Sanding belt according to one of claims 1 to 11, characterized in that the abrasive (4) with a binder (3) consisting of a phenolic resin and 0-20 wt .-% phenoxy resin, attached to the pad. Sanding belt according to one of claims 1 to 12, characterized in that the binder is fiber-reinforced. Abrasive belt according to claim 13, characterized in that the fiber material for reinforcing the binder is selected from the group consisting of m- and / or p-aramid, ultra high-strength polyethylene, highly oriented polyester, polyester, polyamide, p-polyphenylene-2,6-benzobisoxazole , Carbon fibers, glass fibers and stranded wires. Sanding belt according to one of claims 1 to 14, characterized in that the base has a thickness of 250 to 350 microns or in the case of a laminate of polymer film and fabric has a thickness of 300 to 600 microns. Sanding belt according to one of claims 1 to 15, characterized in that the polymer film (1a, 1b) consists of a material selected from the group consisting of polyester, polyethylene and polypropylene. Method for producing an abrasive belt according to one of claims 1 to 16, comprising the steps: a) providing a substrate comprising a polymer film (1a, 1b) or a mixed fiber fabric (8a, 8b), b) applying an abrasive (4) by means of a binder (3), wherein in step a) the pad is provided of a plurality of pad units by either at least a portion of the surface of the film units (1a, 1b) adjacent to a respective film unit being slanted away from the other film unit and into the space formed thereby Fiber material (2) is introduced, or by adjoining surfaces (5a, 5b) of film units (1a, 1b) are bevelled and glued to each other precisely fit, or by staggered joint joints of a laminate of 2 film units (1a, 1b) and two water-resistant In a laminate of mixed fiber fabric (8a, 8b) and waterproof fabric backing (7a, 7b), the fabric backing (7a, 7b) is removed below the junction of the blended fiber fabric units (8a, 8b) and in this space, a fiber-reinforced film (9) is introduced, or by the film units (1a, 1b) with a Rückbesbes coating (10a, 10b) are provided and the backside coating (10a, 10b) is removed below the junction of the film units (1a, 1b) and a fiber-reinforced film (9) is introduced into this space. Use of an abrasive belt according to any one of claims 1 to 16 for Grinding ceramic parts.

Images