RU2541580C1 - Bushing from composition polymeric material for rail transport - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: bushing is designed from composite polymeric material containing filamentary filler in the form of fibre glass and/or carbon fibre, and a binder in the form of polymethyleneoxide, with the following mass ratio of components, wt %: fibre glass and/or carbon fibre 25-35; the rest - polymethyleneoxide.

EFFECT: increase of service life of the bushing due to improvement of its performance, which is achieved by means of qualitative and quantitative ratio of components of the bushing material.

1 dwg

Description

The invention relates to the field of engineering, namely the production of bushings with a low coefficient of friction, not requiring lubrication, made of composite polymer material, for the lever brake system of rail transport, for example, passenger and freight, including subway cars.

Currently, in engineering for the manufacture of such bushings are widely used phenoplasts - a variety of plastics based on phenol-formaldehyde resins. These materials for the manufacture of technical parts are particularly durable and highly resistant to various influences. In mechanical engineering, wheels, gears, bushings and other parts of various impact-resistant mechanisms are made from them.

However, in the manufacture of such bushings from phenolic free phenol, formaldehyde and dust are released.

Phenol is a poison that causes acute and chronic poisoning, which can penetrate the human body through unprotected skin. Inhalation of phenol vapor causes irritation of the upper respiratory tract, and with prolonged exposure - general poisoning. The maximum permissible concentration of phenol vapor in the airspace of the working area of industrial premises is 0.1 mg / m ³ .

So, the bushings of the lever brake system of the rail transport, made of phenoplast grade U-301-07, are known (see phenoplast grades U-301-07 and U-2-301-07 according to TU 2253-001-2572341-99, Organization - supplier : LLC “Plastic” Tula region, 4, Uzlovaya), containing phenol-formaldehyde resin, cotton cellulose with additives (talc, magnesia, lime, FFA), in the following ratio of components, wt.%:

Phenol formaldehyde resin 46.5 Cotton pulp 43.8 Additives 9.7

However, these bushings have low strength characteristics. In addition, due to the presence of a large amount of formaldehyde resin in the sleeve material, phenol, formaldehyde and dust are released during the manufacture of such bushings, which requires increased safety measures.

Known sleeve lever brake system of the rail transport, made of a composite material containing a fibrous filler in the form of a mixture of polyoxadiazole and cotton fibers, a release agent in the form of zinc stearate and / or calcium stearate, a binder in the form of phenol-formaldehyde or cresol-formaldehyde resin.

In addition, the material of the known sleeve includes an adhesive - polyvinyl acetate and / or polyvinyl butyral and a powder filler - silicon oxide (See RF patent No. 2298707 according to CL F16C 33/04, B61H 13/34, claimed. 04.10.2005, published on May 10, 2007. “Bush of the lever brake system of rail vehicles”).

The known sleeve is made of two layers and consists of an inner working layer of the slide and the outer damping layer.

The known sleeve is technologically difficult to manufacture, during operation, delamination of its parts is possible. In addition, in the manufacture of such bushings, as the initial composite material contains a large amount of formaldehyde, free phenol, formaldehyde and dust are released.

The closest in technical essence and the achieved effect and selected as the closest analogue (prototype) is a sleeve for rail vehicles made of composite polymer material (KPM) containing a fibrous filler in the form of fiberglass and / or carbon fiber, a release agent in the form of molybdenum disulfide and a binder in the form of polyamide.

(See RF patent No. 2441787 for class B61H 13/34, F16C 33/04, filed 09.09.2010, publ. 02/10/2012 "Bush of the lever brake system of the rail transport.")

However, the known sleeve is more susceptible to water absorption and has a greater coefficient of friction.

The objective of the invention is to increase the service life of the sleeve for rail vehicles.

The technical result that allows us to solve this problem is to increase the service life of the sleeve by increasing its technical characteristics, which is achieved by the qualitative and quantitative ratio of the components of the sleeve material.

The task is achieved in that the KPM sleeve for rail transport is made of a composite polymer material containing a fibrous filler and a binder. According to the invention, the sleeve is made of a composite polymer material containing fiber and / or carbon fiber as a fibrous filler, polyoxymethylene as a binder, in the following ratio, wt.%:

Fiberglass and / or carbon fiber 25-35 Polyoxymethylene Rest

Studies on patent and scientific and technical sources of information indicate that the proposed sleeve for rail transport is unknown and does not follow explicitly from the studied prior art, i.e. meets the criteria of "novelty" and "inventive step".

The proposed sleeve for rail vehicles can be manufactured using equipment and materials of both domestic and foreign industry, therefore, meets the criterion of "industrial applicability".

The proposed set of essential features informs the claimed sleeve for rail vehicles of new properties that can solve the problem, namely increasing the life of the sleeve for rail vehicles.

The implementation of the sleeve for rail vehicles from a composite polymer material containing fiberglass and / or carbon fiber as a filler allows to increase the wear resistance of the sleeve, which, in turn, increases the life of the sleeve.

The implementation of the sleeve for rail transport from a composite polymer material containing polyoxymethylene as a binder, improves strength and antifriction properties; because polyoxymethylene is characterized by: increased impact resistance, especially at low temperatures, better elastic properties, resistance to cracking, low moisture absorption, while polyoxymethylene has exceptional fatigue resistance (1.5 times higher than polyamide) and is the optimal component of the material for products, subject to repeated mechanical stress, shock loads and vibration, which further increases the life of the sleeve.

The ratio of the components of the composite polymer material of the sleeve, wt.%:

Fiberglass and / or carbon fiber 25-35 Polyoxymethylene Rest,

established experimentally and allows you to achieve the required performance anti-wear and anti-friction properties of the rubbing parts at any time of the year under a wide variety of temperature conditions.

Thus, the set of essential features allows you to achieve a technical result, namely an increase in the service life of the sleeve by increasing its technical characteristics, which is achieved by the qualitative and quantitative ratio of the components included in the material of the sleeve and, therefore, to solve the task, namely increasing the service life bushings for rail vehicles.

The invention is illustrated in the drawing.

Figure 1 shows a General view of the sleeve in section.

The inventive sleeve KPM for rail transport is made by injection molding in an injection molding machine from injection material, which is conditionally called PTs-10-2.

It was experimentally established that the technical characteristics of the proposed KPM bushings for rail vehicles significantly exceed the same characteristics of the bushings obtained from known materials.

Thus, compared with the known bushings of the inventive sleeve KPM for rail vehicles has an increased service life.

An additional effect in the manufacture of the proposed sleeve is a sharp increase in labor productivity, since the manufacturing process is reduced to injection molding in a molding machine of composite material PC-10-2, which is prepared by introducing filler into the binder using one of the many extrusion methods, as a result of which a compound is obtained in the form of granules.

Example 1:

Take fiberglass, mixed with polyoxymethylene in the following ratio of components, wt.%:

Fiberglass 25% Polyoxymethylene Rest

Then the obtained granules are poured into the receiving hopper of the injection machine. From there, the material is poured directly into the auger of the machine, where it is melted and, under the action of a piston, is fed with high pressure into the mold. The melt passes through the sprue channels and fills the mold cavity with great speed, after which the mold is cooled and the material solidifies, forming a casting. The mold is opened, the part drops out, and the cycle is repeated again. The mold provides receiving sleeves in the form that is shown in figure 1.

Example 2:

Take fiberglass, carbon fiber, mixed with polyoxymethylene in the following ratio of components, wt.%:

Fiberglass 30,0 Carbon fiber 5,0 Polyoxymethylene Rest,

Then the obtained granules are poured into the receiving hopper of the injection machine. From there, the material is poured directly into the auger of the machine, where it is melted and, under the action of a piston, is fed with high pressure into the mold. The melt passes through the sprue channels and fills the mold cavity with great speed, after which the mold is cooled and the material solidifies, forming a casting. The mold is opened, the part drops out, and the cycle is repeated again. The mold provides receiving sleeves in the form that is shown in figure 1.

Example 3:

Take the carbon fiber, mixed with polyoxymethylene in the following ratio of components, wt.%:

Carbon fiber 33% Polyoxymethylene Rest

Then the obtained granules are poured into the receiving hopper of the injection machine. From there, the material is poured directly into the auger of the machine, where it is melted and, under the action of a piston, is fed with high pressure into the mold. The melt passes through the gate channels and fills the mold cavity with great speed, after which the mold is cooled and the material solidifies, forming a casting. The mold is opened, the part drops out, and the cycle is repeated again. The mold provides receiving sleeves in the form that is shown in figure 1.

Claims (1)

KPM bush for rail transport made of composite polymer material containing a fibrous filler and a binder, characterized in that the bush is made of composite polymer material containing glass fiber and / or carbon fiber as a filler, polyoxymethylene as a binder, in the following ratio components, wt.%:
Fiberglass and / or carbon fiber 25-35 Polyoxymethylene Rest