NL9400066A - Method for combining glass particles into a bound compound and material obtained thereby - Google Patents

Abstract

The invention relates to a method for combining glass particles to a bound, load-bearing glass compound, wherein the glass particles, without further admixture of substances and without the shape or size of the separate particles being subject to any further requirements, are fused together without liquefaction of the cores of the separate particles. The invention also relates to the material thus obtained.

Description

Method for combining glass particles into a bound mass and material obtained thereby.

The invention relates to a method for combining glass particles from, for example, return glass, into a bonded mass, as well as to materials and products manufactured according to that method.

The amount of glass, as a result of the large-scale collection of glass, greatly exceeds the possibilities for reuse.

Known forms of reuse are described in US patent no. 3 900 303. In all cases it concerns a reuse, which consists in adding glass particles to another mixture.

In addition, manufacturing techniques for bonding glass particles are known from various patents and patent applications

Patent No. 1813901 describes a method for fusing glass particles on a glass plate for decorative purposes. These particles can be fused together by heating. The invention, however, relates to the gluing and fusing of one layer on a flat bottom layer and requirements are imposed for that purpose on the shape of the glass particles.

U.S. Patent No. 3,900,303 describes a method in which the glass particles are joined together to form a mass by adding a binder and a foaming agent. Except that a maximum of 0.2 mm is imposed on the grain size, as a result of which higher demands are made on the processing of the glass particles and the mutual adhesion of the particles is achieved by means of an addition other than glass, the material obtained loses also the appearance of glass.

The object of the invention is to combine the glass particles in a simpler manner in a constructionally usable loadable and aesthetically attractive material without further additives to the composition, while retaining the characteristics of the individual glass particles.

This object is achieved by coating glass particles, which can vary in size and thus can be obtained from different glass grinding and processing systems, in a mold or on a surface and heat them slowly to the point that the periphery of the individual particles fuses together, without the cores of the individual particles reaching the melting point. This creates a fused mass, in which the shape, colors of particles and the patterns in which they are deposited remain largely recognizable and are decisive factors in the appearance of the mass, which, by varying therein, can be largely influenced. Because the particles are not completely melted and converted into a homogeneous mass, fewer requirements are imposed on the homogeneity of the raw materials used and energy is saved compared to processes in which this is the case. Because no additives other than the glass particles are added, the material can be reused per se without harmful side effects, also by the same procedure. These factors represent a significant environmental gain. The material obtained by this process is characterized by a structure in which the visually observable characteristics of the individual particles, such as that e.g. Meur, translucency, size, can be preserved and largely determine the appearance in mutual connection, whereby the appearance of the material can be determined within rough limits by the choice of the added glass particles and the manner and order in which and in which particles are combined. By shaping the mold in which the particles are brought together, the final material can be given a three-dimensional random shape.

The glass mass can be compacted during the process by rolling or other pressure.

Between the different layers of glass particles, a reinforcement of e.g. glass fibers.

Gas can be injected into the glass mass, which is thereby trapped between the fusing particles, thereby reducing the volume weight of the material.

Glass fibers which have a higher melting point than the surrounding glass particles can also be placed between the glass particles for reinforcement, whereby the glass particles fuse with the fibers, without the reinforcement structure being lost. In order to improve the fusion of the glass particles with the fibers, the periphery of the fibers can be softened by briefly increasing the temperature.

Claims (3)

Claim 1: A method for joining glass particles into a bonded, constructively loadable glass mass, characterized in that the glass particles are coated on a surface without further necessary addition of other substances and are heated to the melting point and kept at that temperature until the temperature is substantially the same throughout the layer, after which the temperature is brought to above the melting point and kept as long as necessary to bring the periphery of the particles into a liquid state and to allow them to flow together, without the cores of the individual particles get into a molten state and a homogeneous mass is created. conclusion A method according to claim 1, characterized in that the glass mass consists of glass particles originating from unsorted waste glass. Conclusion Method according to claim 1, characterized in that the glass mass consists of glass particles from sorted waste glass. claim 4: method according to claims 1,2 and 3, characterized in that an armament of glass fibers is applied between a bottom layer and a top layer, or between several layers of glass particles, the glass fibers having a slightly higher melting point than the surrounding glass particles, as a result of which the fusing process of the particles can take place without the fibers melting. Claim 5: Method according to Claims 1,2,3 and 4, characterized in that during the fusing process the glass mass is compacted by the application of pressure. claim 6: method according to claims 1,2,3 and 4, characterized in that a gas is injected between the glass particles during the fusion. Claim 7: Method according to Claims 1,2,3,4,5 and 6, characterized in that the mass of fused glass particles on the surface is partially or completely fused and covered with homogeneous glass. claim 8: Glass mass obtained according to the method of claim 1,2,3,4,5,7