DE20016895U1 - Cover for abrasive surfaces - Google Patents

Description

Coating for abrasive surfaces

The invention relates to a coating for surfaces subject to abrasion.

Areas of application for abrasion protection include, for example, blasting systems, pneumatic or mechanical conveyor systems, components and assemblies subject to stress due to friction or impact and shock, such as the loading areas of vehicles.

The surfaces of objects are blasted using blasting systems. Old paint or corrosion layers and other contaminants are removed from the surfaces to be treated using a carrier medium such as compressed air or water and particles distributed in it, the blasting agent.

The pressure parameter with which the jet leaves the nozzle has a major influence. The size and mass flow of the blasting or grinding particles distributed in the compressed air and their speed when they hit the surface to be blasted as well as the angle of impact are also important.

For sandblasting large objects, such as rail vehicles, the blasting takes place in large blasting rooms or blasting chambers, e.g. with a volume of 1000 m ³ . The actual functional blasting technology is mostly set up outside the blasting rooms. For smaller blasting systems, sandblasting is carried out in blasting cabins.

During sandblasting, the abrasive particles hit the surface of the object to be treated and tear away corrosion or paint particles from the surface. The kinetic energy of the blasting or grinding particles is

used to remove unwanted corrosion or paint particles from the surface.

Depending on the pressure, speed and angle of impact of the blasting or grinding particles on the surface as well as their rheological properties, the grinding particles are partially reflected on the surface. These blasting or grinding particles reflected on the surface to be blasted then hit the surfaces of the blasting rooms or the building structure or the wall of a blasting cabin in an uncontrolled manner in smaller blasting systems.

This results in uncontrolled surface damage caused by reflection and deflection of grinding particles.

In the current state of the art, this problem is solved by protecting the blasting cabins and blasting chambers in larger systems with blasting protection walls or mats. These blasting house linings require a considerable amount of extra effort in the design and manufacture of blasting systems, and the replacement of these protective devices depending on usage leads to additional maintenance costs for the operation of blasting houses.

Equipment parts are also elaborately provided with covers and casings, which must be replaced as they wear out in order to ensure trouble-free operation of the systems.

The object of the invention is to protect abrasive surfaces against wear efficiently and cost-effectively.

This object is achieved according to the invention by the features of the main claim, the subclaims show further advantageous embodiments of the invention.

The concept of the invention consists in providing the surfaces in question, which are to be protected against uncontrolled abrasion, with a coating which absorbs the kinetic energy of the blasting particles.

The coating is designed in such a way that the particles transfer their kinetic energy to the coating without the coating being destroyed by the particles, whereby this coating consists of a rubber-like, elastic or plastoelastic material.

This material consists, for example, of 0.1 to 0.8 parts of rubber granulate of different grain sizes up to a maximum of 2 mm in diameter, whereby the rubber granulate is bound with 0.9 to 0.2 parts of water-soluble acrylate dispersion including additives.

One advantage of the invention is that the coating directly on the surfaces to be protected means that costs for separate protective structures and the like can be saved. In addition, the service life of systems modified according to the invention is extended.

Maintenance and repair intervals can be significantly extended, leading to further cost savings.

Repairing worn areas is made much easier by spraying on new material. Dismantling work is often not necessary in this case.

In addition, the surface coating according to the invention also provides additional noise and droning protection, since sound waves are also partially absorbed by the coating.

For further explanation of the invention, reference is made to the claims. Details, features and advantages of the invention also emerge from the following description of embodiments.

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Particularly suitable embodiments of the invention are the coating of surfaces subject to strong abrasive stress.

This includes the surfaces of blasting systems in particular. Both the blasting system and the surfaces surrounding it, such as blasting floors, the blasting system enclosures, the blasting cabin or the blasting house with its walls, ceilings and floors, are subject to severe abrasive stress due to the reflection of blasting or grinding particles on the surfaces to be blasted, which, as already described, leads to high maintenance and repair costs.

The coating according to the invention on these stressed surfaces absorbs the kinetic energy of the blasting or grinding particles and thus prevents the removal of material from the affected surfaces.

Further areas of application of the invention are that this coating is also applied to the stressed surfaces of intake labyrinths. In intake labyrinths, for example, large quantities of air are sucked in and, due to frequent changes in the direction of flow, particles entrained in the air impact on the surfaces due to their inertia and thus lose their kinetic energy, causing them to sink downwards via gravity and be separated.

However, the impact of the particles on the surfaces of the intake labyrinth naturally leads to some material being removed from these surfaces. As a result, the labyrinths have to be replaced and the affected surfaces have to be reworked.

The coating according to the invention specifically prevents material removal on these surfaces.

Another advantageous application is the coating of a cyclone for particle separation. This works on a similar principle to the suction labyrinth, whereby the centrifugal forces in the cyclone during the circular movement of the particles lead to a reduction in the kinetic energy of the particles.

Undesirable abrasion effects caused by particles also occur in filter and ventilation systems. According to the invention, the coating on the stressed surfaces reduces or even eliminates abrasion, which leads to an extension of the service life of such components and systems. The problems of noise pollution that often occur in such systems are also reduced by the coating.

Another advantageous use of the cover is the lining of loading areas and loading spaces of trucks. In addition to its mechanical strength, the cover is also non-slip, which prevents the load from accidentally slipping during transport.

Claims (9)

1. Coating for surfaces subject to abrasion, which absorbs the kinetic energy of bodies coming into contact with the surface and thereby protects the surface from abrasion or destruction, whereby this coating consists of a rubber-like, elastic or plastoelastic material. 2. Coating according to claim 1, characterized in that it consists of 0.1 to 0.8 parts of rubber granulate of different grain sizes up to a maximum of 2 mm in diameter, the rubber granulate being bound with 0.9 to 0.2 parts of water-soluble acrylate dispersion including additives. 3. Blasting system, characterized in that it is provided with a coating according to one of claims 1 to 2 and the coating absorbs the kinetic energy of the blasting or grinding particles which impinge on the surface of the blasting system as a result of reflection from the surfaces to be blasted. 4. Blasting system according to claim 3, characterized in that the enclosures, the blasting cabin, the blasting house and its walls, ceilings and floors are provided with the coating. 5. Suction labyrinth, characterized in that the surfaces of the components coming into contact with the suction flow are provided with an abrasion-inhibiting coating according to one of claims 1 to 2. 6. Cyclone, characterized in that the surfaces of the components coming into contact with the loaded fluid stream are provided with an abrasion-inhibiting coating according to one of claims 1 to 2. 7. Filter system, characterized in that surfaces subject to abrasion are provided with an abrasion-inhibiting coating according to one of claims 1 to 2. 8. Ventilation system, characterized in that surfaces subject to abrasion are provided with an abrasion-inhibiting coating according to one of claims 1 to 2. 9. A truck, characterized in that the surfaces coming into contact with the goods to be transported are provided with an abrasion-inhibiting coating according to one of claims 1 to 2.