EP0052758A2 - Flexible abrasive article, for example in the shape of a bow, band, disc and the like - Google Patents

Abstract

A flexible abrasive article with a pliable backing on which a plurality of abrasive bodies are formed owing to the fact that abrasive bodies formed from a mass consisting of binding agent and abrasive grains are adhesively bonded to the backing before the binding agent hardens. <IMAGE>

Description

The invention relates to a flexible abrasive, which in the field in question is often referred to as "coated abrasive". Such a flexible abrasive can e.g. in the form of sheets, bands, disks or the like. It usually consists of a flexible base, for example made of paper or tissue, and a layer of binder is first applied to this base, on which the abrasive grain is then sprinkled. A cover layer is then usually applied, which in many cases consists of the same material as the binder layer. In many cases, this binder is a thermoset, and it can advantageously be a modifiable phenolic resin, epoxy resin or polyester resin or the like. Such binders are known.

In order to obtain an actually "flexible" abrasive in this manufacturing process, the abrasive produced so far is "flexed". This flexing means that the abrasive is usually flexed sequentially in two different directions, i.e. is practically broken by being guided over rollers with a small radius of curvature or over curved edges. An abrasive produced and flexed in this way can then be referred to as a flexible abrasive, the flexibility of the abrasive serving to enable the abrasive to adapt to different contours of the workpiece to be ground.

Abrasives produced and flexed in the manner described have generally proven themselves. However, a major disadvantage is that the life of the abrasive is comparatively short because there is only a single layer of abrasive grain. This layer wears out relatively quickly.

Various proposals have already been made in order to overcome the disadvantage of the comparatively short service life.

For example, attempts have been made to overcome the disadvantage of the comparatively short service life of flexible abrasives as described above in that several layers of abrasive grain have been applied one above the other. The procedure was such that in further passes through the production plant, a further abrasive grain layer was sprinkled onto the top layer explained above, to which a top layer of binder was in turn applied. In this way, two or more layers of abrasive grain could be formed. If several Abrasive grain layers are to be expected that the service life of the abrasive is longer. A major disadvantage of this known proposal is, however, that the structure, which consists of several layers of abrasive grains and thermosetting binder, is comparatively hard. Accordingly, this layered structure breaks open in the subsequent flexing in an unpredictable manner, so that there is an unpredictable grinding effect and essentially an uneven grinding effect. In addition, there is the disadvantage that abrasive grains can break out, especially if they are located at breaking points which are formed during flexing. Finally, an abrasive with multiple layers of abrasive grain is comparatively expensive to manufacture because multiple passes through the manufacturing facility are required.

It is also known not to sprinkle individual abrasive grains on the binder layer previously applied to the base, but rather so-called agglomerates, which for example have an essentially spherical shape. There are agglomerates made entirely of spheroidal corundum. There are also agglomerates with a base body, for example made of plastic, in which abrasive grains are partially embedded in such a way that they protrude outwards from the base body (DE-OS 26 08 273). It is also known to design the base body as a hollow body (DE-AS 23 48 338). A longer service life can possibly be expected when using these known designs, in particular because the abrasive grains are practically present in several layers one above the other. A disadvantage of these known designs, however, is that flexing is also required before use in order to obtain the required flexibility or flexibility. With this flex process However, the structure previously formed with the agglomeration _t s at least partially destroyed and not in a controllable manner again, so that the overall result is in use, the abrasive an unpredictable and often non-uniform sanding effect. In addition, the agglomerates can break out of the binder layer holding them. Finally, such known abrasives are comparatively expensive to manufacture.

It is also known (DE-GBM 19 82 299) to embed abrasive bodies prefabricated at a distance from one another in a flexible carrier, preferably made of plastic, the carrier being thickened in the region of each abrasive body. Even with such an abrasive, sufficient flexibility, as is required, for example, with abrasive belts, cannot be obtained. In addition, the production is comparatively expensive. Analogously, the same disadvantages exist with also known non-flexible abrasives (eg DE-OS 22 33 044, DE-OS 21 07 454, US Pat. No. 3,471,975), in which individual prefabricated abrasive bodies by means of special devices on a base body or on are attached to a pad. These known designs also do not have the required flexibility. The production is also comparatively expensive. Finally, it is also known (DE-PS 17 33 14) to sprinkle abrasive material on a flexible base provided with an adhesive layer only in certain areas such that the abrasive material is present at predetermined locations. The main disadvantage of this known embodiment is that the abrasive material can only be applied in a single layer, so that the service life of such an abrasive is comparatively short. There is therefore a great need for a flexible abrasive which has a comparatively long service life and is nevertheless simple and cheap to produce.

The present invention is based on a flexible abrasive with a flexible base on which a plurality of abrasive bodies are arranged in a predetermined pattern. According to the invention, such a flexible abrasive is characterized in that the abrasive bodies are formed from a mass consisting of a binder and abrasive grain and are glued to the base before the binder hardens.

The invention creates a flexible abrasive in which the individual abrasive bodies contain abrasive grains in several layers one above the other, so that a long service life of the abrasive is ensured. It has surprisingly been found that even if the abrasive bodies are arranged directly on the flexible base, sufficient adhesion of the individual abrasive bodies to the base could be achieved by the adhesive effect of the binder alone. In addition, the invention, the further important advantage is an abrasive according achieved that a flexing of the abrasive prior to Inbenutzung _D imitate is not required because the abrasive bodies are arranged directly on the base, which itself already has the required flexibility. By fixing the abrasive bodies in a certain arrangement on the base, free zones or areas are created which ensure that the natural flexibility of the base is retained even after the manufacturing process. The finished abrasive therefore has about the same flexibility as the starting product used.

The production of an abrasive according to the invention can preferably be carried out by preparing a flowable or spreadable mass of binder and abrasive grain and applying it to the flexible base in the form of individual abrasive bodies before the binder hardens.

In a preferred embodiment of the method, the mass prepared from binder and abrasive grain can be pressed into a grid or sieve placed on the base, for example in the form of a perforated plate or the like. The grid, sieve or the like is then removed from the base. Here, the height of the abrasive body can be determined by the thickness of the grid, screen or the like.

The grid, sieve or the like can be made of metal or plastic, for example.

It is particularly preferred if the flowable or spreadable mass of binder and abrasive grain, which has previously been prepared, has thixotropic properties such that the mass flows only when a mechanical force or mechanical pressure is applied to it. When using a mass of binder and abrasive grain with thixotropic properties, it is in particular easier to remove the grid, sieve or the like after pressing the mass mentioned into the openings of the paster, sieve or the like.

With certain materials for the flexible base, it may be advantageous to apply an adhesive layer beforehand.

• Fig. 1 ist eine Draufsicht eines Ausführungsbeispiels eine_b Schleifmittels gemäß der Erfindung.
• Fig. 2 ist eine Teilquerschnittsansicht des Schleifmittels gemäß Fig. 1.

The invention is explained below with reference to the drawing, for example.

• 1 is a top view of an embodiment of _ab abrasive according to the invention.
• FIG. 2 is a partial cross-sectional view of the abrasive of FIG. 1.

A flexible abrasive according to the invention can be in the form of sheets, tapes and discs or the like. As an example, an abrasive wheel is shown in FIGS. 1 and 2.

The flexible abrasive according to FIGS. 1 and 2 has. a flexible base 1 made of paper, tissue or the like. Such documents are known. A plurality of abrasive bodies 2 consisting of binder and abrasive grain are arranged on the base 1. The abrasive bodies 2 can be arranged in different patterns. For example, it has proven to be advantageous for an abrasive belt to arrange the abrasive bodies 2 in rows which are spaced apart from one another and are at an angle of 30 ° to the direction of movement of the abrasive belt.

Each abrasive body 2 consists of the mass formed from binder and abrasive grain and thus contains abrasive grain in a plurality of layers one above the other. As a result, the service life of a flexible abrasive according to the invention is comparatively long.

The shape of the abrasive body 2 can be different. For example, the abrasive bodies 2 can have a quadrangular shape, the shape of round, ie cylindrical knobs or the like. The height of the abrasive bodies as well as their cross-sectional dimensions and the distance between adjacent abrasive bodies 2 can change depending on the application conditions, the size of the abrasive grain, etc. When using round, ie cylindrical knobs, for example the diameter of the knobs in a range from 0.5 to 10 mm, the height of the knobs in a range from 0.1 to 5 mm, and the spacing of the knobs from one another are in the range of 0.5 to 5 mm.

It has surprisingly been found that the abrasive body 2 is adequately adhered to the base 1 if the mass of binder and abrasive grain forming the abrasive body 2 is applied directly to the base 1, ie without an adhesive layer being arranged in between. However, it may, for example, depending on the material used for di _l flexible backing material, also in certain cases be advantageous prior to applying the group consisting of binder and abrasive grain mass to the backing layer, a adhesive or applying an adhesion-promoting layer.

To produce a flexible abrasive according to the invention, a flowable or spreadable mixture of binder and abrasive grain of the desired grain size is first produced. This mixture is then pressed into the openings of a grid, sieve, perforated plate or the like, which was previously placed on the base. This grid, sieve, perforated plate or the like has openings in a pattern which corresponds to the pattern in which the abrasive bodies 2 are to be arranged on the base 1. Appropriate grids, sieves, perforated sheets or the like consist of metal, plastic or a similar material

When applying the mass consisting of binder and abrasive grain to the base 1 in the area of the openings of the grid, sieve, perforated plate or the like, the procedure is advantageously such that the height of the abrasive body 2 is determined by the thickness of the grid, sieve, perforated plate or the like . In this way, the process of applying the mass of binder and abrasive grain to the base 1 is simplified and at the same time it is ensured that the abrasive body 2 formed all the same ge desired height.

It is particularly expedient for the production of a flexible abrasive according to the invention if the mass of binder and abrasive grain is manufactured in such a way that it has thixotropic properties, whereby thixotropic properties mean the property that the mass of binder and abrasive grain is only is flowable when exposed to mechanical stress. If the mass of binder and abrasive grain has thixotropic properties as defined above, it no longer has the ability or the desire to flow after being applied to the base 1. This facilitates the formation of the abrasive bodies 1 with the desired shape and the desired dimensions and also the subsequent removal of the grid, sieve, perforated plate or the like.

Binders known in the field of abrasives, such as epoxy resin, polyurethane, urea resin, melamine resin, phenolic resin, polyester resin and inorganic binders such as water glass, phosphate binder, silicate binder, etc. can be used to form the mass from the binder and abrasive grain.

The abrasive grain is used in the required grain size. Appropriate mixing ratios of abrasive grain and binder are in the range between 0.5: 1 and 3.0: 1, the finer grain size of the abrasive grain being used with a larger mixing ratio such that the optimum grinding performance and service life are obtained with each grain size. The information on the mixing ratio relates to the binder and 100% solids content.

The thixotropic agents that can be used include alkali sulfates, alkali chlorides, alkali nitrates, bentonites, silicon dioxide, and talc.

Auxiliaries for adjusting the viscosity can also be added to the mixture of binder and abrasive grain. Suitable auxiliaries for adjusting the viscosity are e.g. Light spar, cryolite, potassium tetrafluoroborate, solvents such as esters, alcohols, water, ketones, halogenated hydrocarbons, etc. It should be understood here that, for example, the type of solvent used depends on the type of binder used. For a water-soluble binder, such as a phenolic resin, water is of course taken as the solvent.

Other additives can also be added to the mixture of binder and abrasive grain, for example to adjust the porosity or to improve the grinding performance by adding grinding-active fillers. The basic type of additive used in turn depends on the type of binder used. For example, if the binder is a phenolic resin, polyisocyanates or halogenated hydrocarbons can be used as additives to adjust the porosity. If an epoxy resin is used as the binder, the porosity adjuster can be azodicarbonamide or ethanol. On the other hand, if the binder is a polyurethane, water can be used as an additive for adjusting the porosity. The fillers customary in the abrasive industry can be used as grinding-active fillers, for example cryolite, potassium tetrafluoroborate, potassium sulfate, pyrite, halogenated organic compounds and sulfur-containing organic compounds. It is also possible to achieve a porosity using microencapsulated substances, for example microencapsulated oil, which has the abrasive properties or aggressiveness during the grinding process is very strongly influenced, and as a result an active grinding filler can be added at the same time.

In certain cases it may be advantageous to add a wetting agent to the mixture of binder and abrasive grain, i.e. a means which, when the mass of binder and abrasive grain is applied to the flexible base, ensures that the mass completely wets the material of the base. Suitable wetting agents are, for example

Polyethylene glycols, sulfurized castor oil, fatty alcohol sulfonates or silicone oils.

In some cases, it may also be expedient, particularly depending on the special material used for the flexible base, to add an adhesion promoter to the mass of binder and abrasive grain. Suitable adhesion promoters include polyamino amide and saturated and unsaturated polyesters.

In order to achieve further improvements in certain grinding processes which place a high mechanical load on the individual abrasive bodies, the entire abrasive body can be provided with a coating of a binder. The coating binder then covers both the individual abrasive bodies and the zones in between. So that the flexibility of the finished abrasive on the backing is not adversely affected, this coating should only be applied in an appropriate amount, or the coating binder itself could be elastic (e.g. polyurethane).

Regarding the flow behavior of the mass of binder and abrasive grain with additives, it should be noted that it is for the rheological behavior and the good processability It is important for the mass that the yield point, the thixotropy and the viscosity have certain values. These values are achieved by suitable selection of the type and grain size, ie the fineness of the fillers, thixotropic agents and solvents. Of course, the flow behavior of the mass also depends on the type of binder used, ie the resin used, and on the grain size of the abrasive grain.

The invention is described in more detail below with the aid of examples.

example 1

A mass of the following composition was formed:

The binder and the abrasive grain are first mixed in a mixer until a homogeneous mixture is obtained. The additives, namely the hardener, the thixotropic agent, the viscosity adjuster, which also serves as a solvent for the epoxy resin, and the colorant are then added and mixed in. The mixture is then immediately ready for use and can be used, for example, in the manner described above a grid, sieve or the like can be applied to a flexible base.

Example 2

Using the procedure according to Example 1, a mass of binder and abrasive grain was produced with the following composition:

Example 3

A mass was produced from the following composition using the procedure given in Example 1:

The parts specified are always parts by weight.

It should also be noted that the mixture or mass prepared may also be can remain for a few days until it is processed, at least if one-component binders are used.

With regard to the abrasive grain, it can be said that the range of applicable grain sizes or particle sizes is in the range from 10 to 2000 μm. The particular grain size that is used depends on the intended use.

With regard to the grid, sieve or the like, it should also be noted that such grids, sieves or the like can be used in a flat form.

Claims (27)

1. Flexible abrasive with a flexible base on which a plurality of abrasive bodies are arranged in a predetermined pattern, characterized in that the abrasive body (2) is formed from a mass consisting of a binder and abrasive grain and before the binder hardens to the base are glued. 2. Abrasive according to claim 1, characterized in that the mass forming the abrasive body contains a thixotropic agent. 3. Abrasive according to claim 2, characterized in that the thixotropic agent is an alkali sulfate, an alkali chloride, an alkali nitrate, a bentonite, silicon dioxide or talc. 4. Abrasive according to one of claims 1 to 3, characterized in that the binder is an organic binder. 5. Abrasive according to one of claims 1 to 3, characterized in that the binder is an inorganic binder. 6. Abrasive according to one of claims 1 to 5, characterized in that the mass forming the abrasive body is an auxiliary for adjusting the viscosity is added. 7. Abrasive according to claim 6,
characterized in that the adjuvants for adjusting the viscosity are light spar, cryolite, potassium tetrafluoroborate, potassium sulfate, pyrite, sulfur-containing organic compounds, microencapsulated substances and oils or solvents, for example esters, alcohols, water, ketones, halogenated hydrocarbons etc. 8. Abrasive according to claim 7, characterized in that the auxiliaries for adjusting the viscosity are simultaneously grinding-active fillers. ₉ . Abrasive according to one of claims 1 to 8,
characterized in that an additive for adjusting the porosity is added to the mass forming the abrasive body. 10. Abrasive according to claim 9,
characterized in that when using a modified phenolic resin for the binder, the additive for adjusting the porosity is a polyisocyanate or a halogenated hydrocarbon. 11. Abrasive according to claim 9,
characterized in that when using an epoxy resin as the binder, the additive for adjusting the porosity is an azodicarbonamide or ethanol. 12. Abrasive according to claim 9,
characterized in that when using polyurethane as the binder, the additive for adjusting the porosity is water. 13. Abrasive according to claim 9,
characterized in that the additive for adjusting the porosity is a microencapsulated substance or a microencapsulated oil. ₁ 4. Abrasive according to one of claims 1 to 13, characterized in that a wetting agent is added to the mass forming the abrasive body. 15. Abrasive according to claim 14,
characterized in that the wetting agent used is polyethylene glycol, sulfurized castor oil, a fatty alcohol sulfonate or a silicone oil. 16. Abrasive according to one of claims 1 to 15, characterized in that an adhesive is added to the mass forming the abrasive body. 17. An abrasive according to claim 16.
characterized in that the coupling agent is a polyamino amide, a saturated polyester or an unsaturated polyester. 18. Abrasive according to one of claims 1 to 17, characterized in that the flexible base (1) is provided with an adhesive layer or an adhesion-improving layer. 19. Abrasive according to one of claims 1 to 18, characterized in that it is additionally provided with a coating which does not impair flexibility. 20. Abrasive according to one of claims 1 to 19, characterized in that the binder and abrasive grain are present in a ratio in the range from 0.5: 1 to 3.0: 1. 2 ^1. Abrasive according to one of claims 1 to 20, characterized in that the abrasive body have a cylindrical or angular shape. 22. Abrasive according to claim 21,
characterized in that at the cylindrical abrasive bodies, these mm in diameter in the range of 0.5 to 10, a height in the range of 0, ¹ to 5 mm, and on the flexible backing (1) at a distance in the range of 0.5 to 5 mm are attached. 23. Abrasive according to one of claims 1 to 22, characterized in that the abrasive grain is present in a particle size in the range from 10 to 2000 µ. 24. Abrasive according to one of claims 1 to 23, characterized in that a dye is added to the mass forming the abrasive body. 25. Abrasive according to one of claims 1 to 24, characterized in that it has approximately the same flexibility as the original base. 26. A method for producing a flexible abrasive according to one or more of the preceding claims, characterized in that a flowable mass of binder and abrasive grain is prepared and applied to the flexible base in the form of individual abrasive bodies before the binder hardens. 2.7. The method of claim 26
characterized in that the flowable mass for application in the form of individual abrasive bodies is pressed onto the flexible base through the openings of a grid, sieve or the like which is placed on the base.

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