DE2811966B2 - Covering material, in particular as a floor - Google Patents

Description

Thermosetting plastics and other plastics that are used at normal room temperatures have a high hardness, have a relatively small impact and impact in the non-reinforced (unfilled) state Impact resistance. These pure, unfilled plastics tear and break even with small impact or Impact loads. Reinforcement of these plastics by filling them with fibers, for example Fiberglass mats, only slightly improves the shock and impact resistance of the plastics. Although it is through such a filling of the plastic in question or the covering material produced from this even with relative Hold large joints together, but small joints still cause damaging cracks in the material.

The covering material in the form of slabs or tiles or a covering made on site, especially the floor, should have the greatest possible impact resistance so that no damage occurs, when heavy objects fall on it. Conventional covering material is made of fillers made of reinforced plastics and thus has a high resistance to wear and tear on, it's also relatively economical and cheap to manufacture. This covering material is often used for Floors used in workshops, storage rooms and other manufacturing areas where there is hard impact is exposed to falling objects, running wheels and other means of manufacture. However, this conventional covering material was not completely satisfactory because there were still cracks in the material develop. Even a small crack is harmful because this is due to the permanent mechanical The stress on the material and the penetration of oil and dirt into this crack grows rapidly. One has therefore for a long time looking for a way to increase the shock and impact resistance of the above To increase the covering material without affecting the other good properties of the material, namely the high one Stiffness and good wear resistance.

Incidentally, it is known to use plastics with powdered materials, namely lime, wood chips, sawdust or various oxides to fill and strengthen. However, none of these fillers brought any improvement

ι 5 with regard to the susceptibility to cracks of the manufactured from them Covering material.

In a known covering material, a glass fiber fabric is enclosed on all sides by a plastic, whereby the glass fiber fabric prevents the undesired formation of bubbles in the covering material (DE-GM 17 25 823). Although this known covering material has a high level of abrasion and wear resistance, it does also inadequate resistance to the formation of cracks in the event of knocks or blows.

Another covering material is known, which consists of a plastic-coated fabric made of jute consists, the plastic for discharging electrostatic charges to a maximum of 5 percent with particles made of metal! and the fabric at a distance of 6 to 10 cm with woven-in electrically conductive metal threads is provided (DE-AS 11 26 352). This other well-known The main reason why facing material has insufficient resistance to cracking is that the Fabric by weaving in metal thread locally

J) has places of different strength, which at Impact loading, damaging stress concentrations and corresponding cracks in the covering material cause.

By the way, it is a covering material made of plastic

ίο known which to achieve an electric Conductivity is filled with particles of metal (US-PS 27 61 854). This known covering material has a Much too little resistance to the formation of cracks in the event of knocking or hitting.

The invention specified in claim 1 has the object of providing a covering material in the form of Slabs or tiles or a covering made on site, in particular a floor, from one Hard plastic at normal room temperatures, which is reinforced by a filling with glass fiber fabric is to create, which with good rigidity and high wear resistance an improved resistance compared to the formation of cracks when knocked or hit, and which is also economical can be produced.

With the facing material of the invention specified in claim 1 it is achieved that the energy of Impact stress in the laid or potted flooring material is largely due to the individual, themselves

Wi touching or mechanically coupled with one another Particles of plastically deformable metal due to plastic deformation work of these particles is absorbed and is destroyed. The filling of the plastic with the glass fiber fabric also causes large

· ■ Shock loads are absorbed by the covering material without cracks or • breaks. the Production of the covering material by conventional pressing of plates (tiles) or by applying and

Curing the plastic in place is easy and economical.

If particles of a non-metallic material with insufficient plastic deformability, for Example silica particles, used to fill the plastic, results in a remarkable one small shock and impact resistance; because these brittle particles become in the material when subjected to impact crushed without significantly absorbing or destroying the energy of the shock. So that means, that then the impact energy must be destroyed solely by the work of deformation of the plastic, so that often cracks appear in the plastic.

In contrast, the particles can be made of a plastically deformable metal, to a high degree are deformed, so that a large part of the deformation work done by the individual particles and the Impact energy in the covering material is accordingly absorbed without cracking.

Advantageous further developments of the invention are described in the subclaims . Particularly advantageous metals for the particles are given in claims 2 and 3 and the embodiment according to claim 4 ensures that an optimal mechanical coupling of the individual particles made of plastically deformable metal is ensured by a correspondingly large content of particles in the plastic. so that these particles absorb a significant part of the impact energy.

Claim 5 contains a particularly advantageous shape ω of the particles of plastically deformable metal, the particles being easily and economically manufactured and in the covering material can be incorporated.

Claim 6 finally refers to particles that are economically r> as a by-product of rolling bearing production can be procured.

Below are some test results that are available in the Drawing are shown graphically, are described, the advantages of the invention Explain the covering material. -to

Drop tests were carried out on test plates with a 0.5 kg ball. The test panels had a Size of 150 150 χ 5 mm and were made of a polyester plastic. They were with the Drop tests on a relatively stiff foundation. The »5 Ball was dropped onto the test panels from different heights. It was found at the height of the fall, cracks appear in the test panels.

In a first test, test plates made of pure (unfilled) polyester plastic were examined. Test plaques made of polyester plastic, which were reinforced with a glass fiber mat (300 g / m ² ), were then tested. In addition, test panels made of polyester plastic filled with steel particles were subjected to the drop test. Finally, test plates made of polyester plastic were tested, which were reinforced with the glass fiber mat specified above and filled with additives of 10, 20, 30, 40, 50 and 80% by weight of particles made of roller bearing steel. The particles bo were designed as abrasive particles in the form of chips and had a thickness of 2 to 20 μm and a length which was about 10 to 20 times as large as their thickness.

The results of this drop test are shown graphically in the drawing. The height of fall is n of the sphere, where the first cracks appear, on the ordinate (vertical axis) and the corresponding Content of roller bearing steel particles in percent by weight plotted on the outline (horizontal axis).

The horizontal line A in the drawing shows the height of fall for test plates made of pure ( unfilled) polyester plastic and the horizontal line B for test plates made of polyester plastic reinforced with glass fiber mats. Accordingly, the reinforcement (filling) of the plastic with glass fiber mats causes a slight increase in the crack resistance, that is the resistance of the material of the test plate to the development of cracks.

In the drawing, test results marked with a cross in a circle are entered, which were obtained with test plates made of polyester plastic without glass fiber mat reinforcement, but with different contents of steel particles. Curve C of the drawing is adapted to these individual test results, indicating the crack resistance of the polyester plastic as a function of the steel particle content in the plastic. The representation in the drawing shows that the crack resistance of the plastic can be somewhat improved by filling the (pure) plastic with steel particles.

A substantial increase in the crack resistance is achieved with the covering material according to the invention, because the test plates made of polyester plastic reinforced with glass fiber fabric and filled with steel particles have significantly greater drop heights at which the first cracks appear in the test plates. This can be seen from the test results in this regard, entered with a cross in the drawing. Curve D of the drawing, which is adapted to these test results, shows the crack resistance of the test panels filled with glass fiber fabric and steel particles as a function of the steel particle content in the polyester plastic.

It can be clearly seen from the drawing that the crack resistance of the test panels filled with fiberglass fabric and steel particles is much greater than expected, because the sum of the strength of the test panel reinforced with fiberglass fabric alone with the strength that is reinforced with one reinforced with steel particles Test panel is found provides a composite strength given by the curve indicated by E in the drawing. This curve E is at least in the range of 20 to 80% by weight of steel particles in the plastic, substantially below curve D. which actually applies to test panels filled with glass fiber mat and steel particles. A content of steel particles greater than 80% by weight in the plastic also has the effect that the plastic in the test plate is no longer cohesive and thus there is no longer a dimensionally stable test plate.

The steel particles in the test panels made of facing material were economical as abrasive chips, which is an inexpensive one Represent waste product in steel processing, manufactured.

The invention can be modified within the scope of the inventive concept. So needs the covering material not necessarily in the form of prefabricated tiles or slabs that are laid on floors, be carried out. Rather, this material can also be put in place together with a fiberglass mat and poured and filled with particles of a highly plastically deformable metal to be cured.

The covering material according to the invention in the form of slabs or tiles or one in place manufactured covering, in particular floor, has the

great advantage that this significantly improved one with good rigidity and high wear resistance Has resistance to the formation of cracks in the event of shock or impact loads and can be produced economically.

1 sheet of drawings

Claims (6)

Patent claims: 1. Covering material in the form of slabs or tiles or a covering made on site, in particular flooring made of plastic that is hard at normal room temperatures, which is reinforced by a filling with glass fiber fabric, characterized by that the plastic contributes to achieving an increased resistance to the formation of cracks Bumping or hitting additionally with particles of plastically deformable metal in amounts up to 80% by weight, based on plastic, is filled. 2. Covering material according to claim 1, characterized in that the plastically deformable metal Stahi is. 3. Covering material according to claim 1, characterized in that that the plastically deformable metal is lead. 4. Covering material according to claim 1, 2 or 3, characterized in that the content of particles of plastically deformable metal is between 20 and 80% by weight. 5. Covering material according to claim 2, characterized in that the particles chip-shaped with a Thickness from 2 to 20 μm and a length that is about 10 to 20 times as large as their thickness are formed. 6. Covering material according to claim 1, 2, 4 or 5, characterized in that the particles from are plastically deformable metal abrasive particles made of roller bearing steel.