CS245694B1 - Friction material with high coefficient of friction - Google Patents

Abstract

The invention relates to a friction material, in particular for dry work, consisting of synthetic resins, refractory araaid resins fibers and silicon carbide microfibre.

Description

The object of the invention is a friction material with a high and stable friction coefficient, particularly suitable for dry working.

Friction materials are made from a mixture of asbestos fibers, inorganic fillers such as powders of limestone, kaolin, barite, silicon carbide or produced magnesium, calcium, organic fillers such as friction powders, metal fillers such as powders, fine granules, machining chips (iron, copper, brass, aluminum), phenol-formaldehyde resin or synthetic or natural rubber or mixtures thereof are commonly used as binders.

A disadvantage of current asbestos friction materials is the discovery that sprayed asbestos particles from worn linings are carcinogenic and thus pollute the environment. Another negative fact is the decreasing reserves of natural asbestos in the world. While maintaining the current volume of mining, the remaining resources are estimated to be only a few decades.

A number of solutions have already been proposed to overcome these asbestos fiber deficiencies. For example, asbestos-free friction materials and the use of fibers of so-called aromatic polyamide polymers are known. These so-called aramid fibers are characterized by high heat resistance with unchanged basic physical properties. This solution, although relatively one of the most widely used, has the drawback that the carbon fibers used have a lower coefficient of friction at higher temperatures.

Embodiments replacing asbestos fibers with other plastic, steel fibers, combinations thereof or alumina fibers are also known.

The advantage of all these solutions is to provide a friction-bearing support frame of asbestos-free friction material, however, as asbestos threads as we also know have frictional properties, the disadvantage is that they do not fully achieve the asbestos properties due to friction coefficient and temperature stability.

Such friction materials perform their function in conjunction with a metal mating material, usually of gray cast iron. During friction of opposing pieces due to the pressure and mutual displacement, heat is generated on the 3-stroke surface by thwarting kinetic energy, which accelerates the wear of the opposite friction materials. To achieve the desired service life, particles or fibers of metals or their alloys such as zinc, aluminum, copper, brass and others are used in friction materials.

Metal fillers are used for rapid heat dissipation in order to avoid an enormous temperature rise on the contact surface due to the high insulating properties of the refractory fibers, whereby the temperature gradient to the subsurface layer would be undesirable, leading to disruption of the lining surface yield strength of organic binder. A significant disadvantage of the current friction materials of the asbestos or asbestos-free type, particularly suitable for motor vehicle brake lining, is the presence of these metal particles which are released from the lining during braking. they cause the formation of local galvanic cells. These in turn significantly accelerate the depth corrosion of the brake discs, especially in winter, when air humidity and deteriorated operating conditions due to chemical scattering agents cause inorganic electrolyte aerosol to enter the brakes, causing internal electrolysis of the material on said local galvanic cells. It is an object of the invention to provide a friction material with a high and stable friction coefficient.

SUMMARY OF THE INVENTION The present invention provides a synthetic resin-based friction material with a carbon refractory fiber backing which comprises 15 to 50% by weight of polymer fibers in combination with 20 to 40% by weight of a 10µm silicon carbide micro-powder.

The advantage of combining polymer fibers with a silicon carbide micropowder is to substantially improve the coefficient of friction at high temperatures. The filler according to the firing ensures a high and stable friction coefficient value and good thermal conductivity, which ensures desirable heat dissipation from the contact friction zone.

This additive replaces metal fillers, increases thermal conductivity, stabilizes the coefficient of friction to an acceptable high value in the absence of asbestos fibers, and worn particles are completely inert to the formation and course of corrosion.

Further advantages of this friction material are good abrasion resistance and low abrasiveness with sufficient service life. Said properties are ensured by the content of micro-silicon carbide, which has a positive effect on the friction process during the generation and removal of heat from the contact friction surface. The particle size of the micropowder with particles up to 10 µm ensures greater homogeneity of the material and resistance to the release of filler and material.

An exemplary selection of a base fiber skeleton and other ingredients includes the following composition by weight:

15 to 50 20 to 40 % % Polymer fibers micro powder. of size 10/7 / µm silicon carbide (SiC) 0 to 20% inorganic filler (powdered limestone, • barite, kaolin) 30 to 40 % binders - powdered phenol-formaldehyde rubber- kyřice 1 to 3% plasticizer

The friction material according to the example is described in connection with use as a brake lining of the friction pads of disc brakes. Obviously, the same effect by using a silicon carbide micropowder can be achieved in brake linings intended for drum brakes or other types of friction materials, e.g. in clutch linings.

Claims (1)

High friction friction material, in particular for dry working, based on synthetic resins with a carbon refractory fiber backing and with a filler, characterized in that it contains 15 to 50% by weight of polymer fibers and 20 to 40% by weight of silicon carbide micro-powder particles £ 10 µm.