SK500282013U1 - Brake shoes - Google Patents

Abstract

The brake pad (2) mainly for brake systems of rail vehicles, removably fastened to the brake stopper (1) and consisting of mutually connected anchoring frame (23) and the friction element (24) made of ceramic-metallic material. Anchoring frame (23) comprises an anchoring plate (231) to which the part of the surface of the anchor (21) attached to the side-lock washer (233) and the central anchoring tab (232) having a central hole. Anchor plate (231) of the anchoring of the frame (23) is provided with a coating consisting of copper, and the friction element (24) is connected to diffusion to form a single compact unit.

Description

Brake shoe

Technical field

The technical solution falls within the field of construction of the brake system of rail vehicles, where the braking effect is generated by pressing the brake shoe against the surface of the moving part and relates to an embodiment of a brake shoe adapted to be attached to a brake stop provided with a friction element.

BACKGROUND OF THE INVENTION

In the case of rolling stock, the deceleration device is most often made up of a brake caliper system in the form of a brake caliper. The shoe brake consists of a brake stopper in which a removable brake shoe or retainer with a width of 50 to 60 mm is removable. The brake shoe, the working surface of which corresponds in shape to the braked counterpart, is pressed against the periphery of the wheel rim by means of a lever mechanism as the rolling stock slows. A friction force is created on the surface of the wheel tread, which inhibits the rotation of the wheel or the wheelset, and the frictional forces that are produced also have a cleaning and polishing effect. The magnitude of the brake force of the shoe brake is dependent on the contact force applied through the brake shoe and the magnitude of the coefficient of friction between the wheel tread and the friction element of the brake shoe.

Various designs of brake shoes are known which differ in particular in terms of material, technology and construction. For example, CZ253310B1, CZ272668B1 discloses brake shoes with a metal anchor plate, which are made by casting from cast iron to molds and have a central anchoring ear with an opening for receiving a fastening wedge on the upper non-working surface. The fastening wedge serves for coupling the brake shoe and the brake stop, the anchor plate being provided with two lateral locking washers which serve as a guide for the fastening wedge and also as a fixation of the brake shoe in the longitudinal strip of the brake stop. As is evident from the file

-2US2748902A, the cast iron brake shoes may also be manufactured such that a steel shell is embedded within the segment body, the fastening portion of which is led outside the shoe body. The disadvantage of cast iron shoes is the low coefficient of friction, which is compensated by the high specific pressures between the shoes and the wheel tread, which significantly reduces the service life of the brake shoes.

Currently, brake shoes made of composite materials are used in addition to cast iron brake shoes, which, unlike cast iron brake shoes, have a more stable coefficient of friction between the shoes and the wheel. In such an embodiment of the brake shoe, lower thrust forces are required, which results in less wear and also ensures a smooth braking of the vehicle. For example, in US6328143, US5704454A, as well as in the literature, BA Shirjaev Manufacture of brake shoes of composite materials for railway wagons, Moscow, Chemistry, 1982, pp. 9-14, 70, 71, describes various composite brake segments comprising a friction composite element mounted on an anchor plate. This anchoring plate is generally formed by a steel strip and in the central part is provided with an anchoring lug with holes for inserting a locking wedge. On the outside of the anchoring plate are also provided two locking washers, which serve to guide the wedge and fix the shoe in the groove of the brake stop. It is also known to provide an anchoring plate in the form of a bent carrier plate with an outwardly directed U-shaped central projection, and on the inside the anchoring plate is provided with a reinforcing plate, thereby forming a very rigid anchoring skeleton. In particular, the reinforcing plate is used to provide a higher reliability of attachment of the composite jaw element by cutting from a steel strip an elongated octagonal base, the edges of the base bending longitudinally and transversely to the side of the jaw work surface to form lateral fastening ribs. The reinforcing plate is also provided with four holes that serve to couple the reinforcing plate and the anchor plate and to leak the friction composite composition during molding in order to increase the coherence of the friction material with the anchor frame. A disadvantage of composite brake shoes is the possible occurrence of various defects and failures, such as e.g. thermal cracks on the rolling surface, wear on the rolling surface, reducing the braking efficiency of the jaws in the friction zone or in the presence of coal or peat dust and fallen leaves on the rail surface. In addition, at speeds of more than 160 km / h, high temperatures are generated on the surface of the composite brake shoes, causing the composite material to lose its working ability.

-3In order to continuously increase the speed of the rolling stock, it is necessary to ensure the required level of reliability in the brake shoes over a given period of time. In particular, the metal-ceramic brake shoes meet the required operating functions at speeds above 160 km / h. Of the friction metal-ceramic materials, iron-based materials are used. The disadvantage of such friction elements is excessive wear or damage to the wheel tread after replacing a worn brake shoe with a new one. Copper-based friction metal-ceramic materials are also known which have a lower strength as well as wear and tear and have no aggressive effect on the surface of the wheel rolling as compared to iron-ceramic jaws. Copper-based friction materials are produced by sintering base powder mixtures in refractory molds as individual semi-finished products, made by cold pressing or by sintering together with copper-coated steel sheet or skeleton. For example, CZ1996-510A3 discloses an embodiment of a brake shoe consisting of an anchor plate, a support plate, a metal interlayer which is diffused to a metal-ceramic friction lining containing 50 to 75% copper, 4 to 7% tin, 8 to 11% iron , 5 to 9% mullite and 8 to 14% artificial hexagonal carbon. RU2310779 discloses an embodiment of a brake shoe comprising an anchoring plate shaped in the central part into an inverted U-shaped anchoring ear, the anchoring carrier plate being provided on the outside with two locking washers and a friction-plated reinforcing plate mounted on the inside. length and width correspond to the dimensions of the friction metal-ceramic element. The reinforcing plate is first connected to the friction element by means of a sintering technology at high temperature and pressure in the furnace and is then welded in several points to an anchoring support plate which is provided with welding holes for this purpose. A disadvantage of such an embodiment of the brake shoe is that the design only addresses the rigidity and reliability of the anchorage of the brake shoe, but does not solve the noise generated during braking. With this design of the brake assembly, harmful high-frequency noise is generated both on the contact surface of the anchor plate of the brake shoe and the brake stop, and between the anchor plate and the reinforcement plate. The anchoring plate and the reinforcing plate are welded only at eight points, whereby a very thin gap is formed at the points where they adhere freely to each other. In this slot, the vibrations of the anchor plate and the reinforcing plate cause undesirable squeaking noise, which in many cases exceeds the permissible limit of the hygienic standard many times.

When contacting the wheel with the brake shoe friction element, excessive wear occurs on the contact surface of the wheel when the friction element has very low wear and a long service life over the entire contact surface. When replacing a worn shoe, the new brake shoe never reaches the wheel over the entire contact surface, but only rests at a few small points. When braking, this causes vibrations that produce harmful noise and local damage to the wheel material and brake shoe under high pressure. For example, US5341904A discloses an embodiment of a composite brake shoe which is provided in a portion of the contact surface along the side walls with a lateral, rapidly worn, running-in layer made of a material with a low coefficient of friction. However, such a design is not applicable to brake shoes whose friction elements are made of metal-ceramic materials.

SUMMARY OF THE INVENTION The object of the present invention is to provide a completely new embodiment of a brake shoe whose friction element made of metal-ceramic material has a high coefficient of friction, long service life and does not lose its working ability under high temperatures, in particular when braking rolling stock exceeding 160 km / h. conditions. The friction element is provided on the contact friction surface with a rapidly worn run-in layer to prevent excessive wear or damage to the wheel tread, especially after replacing a worn brake shoe with a new one. The overall design of the brake shoe makes it possible to eliminate the harmful high-frequency noise generated in the vicinity of the anchoring area, whilst the entire anchoring frame must meet the strength and reliability requirements.

The essence of the technical solution

The object is largely achieved by a technical solution which is a brake shoe, in particular for a rolling stock brake system, removably mountable in a brake stop and consisting of an interconnected anchoring skeleton and a friction element made of a metal-ceramic material when the anchoring skeleton comprises an anchoring plate to which side anchors and central anchoring ear with central hole are attached from the side of the anchoring surface, where the anchoring plate of the anchoring skeleton is

-Fitted with a copper-based coating and a friction element, it is diffused to form a compact unit.

In a preferred embodiment, the friction element at the work surface is provided with a running layer made of 1 to 5 mm metal-ceramic material, wherein the friction coefficient of the running layer material corresponds to the friction coefficient of the friction element and has a hardness of 20 to 80%.

In an optimum embodiment, the anchoring skeleton in the region of the anchoring surface is provided with an anti-vibration assembly formed of at least four anti-vibration segments in the form of longitudinal strips that are situated at the contact points or a portion of the anchoring plate contact with the brake pad contact surface.

The present technical solution achieves a higher effect in that, by means of a new brake shoe design, the harmful noise produced by the braking of the rail vehicles is eliminated, while ensuring high strength and reliability of the anchorage of the brake shoe. The metal-ceramic running-in layer, which has the same coefficient of friction as the metal-ceramic friction element, but has a very high abrasion, allows a rapid run-in of the contact surface between the brake shoes and the wheel running surface.

The running layer adapts to the shape of the wheel tread over several brakes, and the brake shoe rests with its entire working surface on the braked wheel, thus eliminating not only the noise caused by the imperfect bearing of the brake shoe on the wheel tread, but also excessive wear and wheel wear high specific pressure.

BRIEF DESCRIPTION OF THE DRAWINGS

A particular embodiment of the invention is schematically shown in the accompanying drawings, in which Fig. 1 is a side exploded view of a brake holding system; Fig. 2 is a top view of a brake shoe;

Fig. 3 is a longitudinal section of the brake shoe; and Fig. 4 is a cross-section of the brake shoe.

The drawings which illustrate the technical solution and the following examples of a particular embodiment thereof do not in any way limit the scope of protection claimed in the claims, but merely clarify the nature of the technical solution.

EXAMPLES

The rail holding system shown in FIG. 1 consists of a brake stopper 1 where a removable brake shoe 2 is removable, the anchoring surface 21 of which corresponds to the contact surface 11 of the brake stopper 7 and the working surface 22 abuts the chassis surface 51 of the brake wheel 5.

The brake shoe 2 in the basic embodiment of FIG. 1, FIG. 2, FIG. 3 and FIG. 4 consists of an anchoring skeleton 23 and a metal-ceramic friction element 24, wherein the anchoring skeleton 23 is formed by an anchoring plate 231 realized in the form of a flat longitudinal direction of an arcuate sheet which is provided with an unlabeled copper-based coating, e.g. This anchoring plate 231 of the anchoring skeleton 23 is diffusively connected to the friction element 24 so as to form a single unit, the friction element 24 being provided with a running layer 241 made of a metal-ceramic material at the work surface 22 of the brake shoe 2. On the side of the anchoring surface 21 of the brake shoe 2, a centrally anchoring ear 232 with a central hole 2321 is fastened, preferably welded, to the anchoring plate 231 with a central hole 2321 for receiving a fastening wedge 4. guiding the fixing wedge 4 i to fix the position of the brake shoe 2 in the not-shown longitudinal groove of the brake stopper T The brake shoe 2 is further provided with an anti-vibration assembly 3 from the anchoring surface 21 at the presumed contact points or part of the presumed contact wherein the vibration segments 31 are disposed along the edge of the anchor plate 231 in the form of four longitudinal strips.

The production of the brake shoe 2 according to the invention is carried out by producing an anchor plate 231 of anchoring skeleton 23 of the desired size and shape having a copper-based coating formed on the surface of the steel strip, for example by plating. A metal-ceramic mixture containing copper, iron, tin, graphite, mullite and other substances is prepared and cold fraction produced from this mixture by friction element 24 having a running layer 241 having a thickness of 1 to 5 mm having the same friction coefficient as friction element 2, however, it has a 20 to 80% lower hardness, which, after commissioning, allows the working surface 22 of the brake shoe 2 to run quickly with the running surface 51 of the wheel 5. When assembling the brake shoe 2, a coppered anchoring plate 231 is applied. Sintering is performed under pressure in the furnace to form a single compact unit, which is then calibrated to the desired dimensions by compression. By compactly connecting the friction element 24 and the anchoring plate 231 of the anchoring skeleton 23, internal vibrations of the brake shoe 2, which cause unwanted noise when braking the wheel 5, are prevented. This compact assembly is fitted with auxiliary anchoring members such that two lateral locking washers 233 and anchoring ear 232 are welded to the outside of the anchoring plate 231 by welding and subsequently the steel parts are coated. In the final phase, the anchoring skeleton 23 is provided in the region of the anchoring surface 21 of the brake shoe 2 with an anti-vibration assembly 3, the anti-vibration segments 31 of which are situated at the contact points or part of the anchoring plate 231 with the contact surface 11. The anti-vibration assembly 3 permits the delimitation of minor irregularities between the brake shoes 2 and the brake stopper 7, thereby eliminating the possibility of noise in this part of the brake device, the anti-vibration segments 31 being resistant to climatic conditions, temperatures and braking pressures.

The described embodiment is not the only possible construction of the brake shoe 2 according to the invention, since the anchoring skeleton 23 does not have to be equipped with an anti-vibration assembly 3 at the anchoring surface 21 of the brake shoe 2. Further, the friction element 24 need not necessarily be provided with run-in layer 241. equipped with reinforcing plate to increase stiffness.

-8 Industrial Applicability

The brake shoe can be used as part of the braking system of rolling stock where high performance requirements are imposed not to exceed the limit of the noise produced by braking, for example for vehicles intended to operate in closed spaces such as metro or vehicles exceeding 160 km / h above train sets.

Claims (4)

PROTECTION REQUIREMENTS 1. Brake shoe, intended in particular for the braking system of rail vehicles, removably attachable in a brake stop and consisting of an interconnected anchoring frame and a friction element made of a metal-ceramic material, the anchoring frame comprising an anchoring plate to which a lateral detent is attached from the anchoring surface washers and a central anchoring ear with a central opening, characterized in that the anchoring plate (231) of the anchoring skeleton (23) is provided with a copper-based coating and is diffusedly connected to the friction element (24) to form a compact unit. A brake shoe according to claim 1, characterized in that the friction element (24) is provided at the work surface (22) with a running layer (241) made of 1 to 5 mm metal-ceramic material, wherein the friction coefficient of the running layer material (24). 241) corresponds to the friction coefficient of the friction element (24) and has a hardness of 20 to 80% of the hardness of the friction element (24). Brake shoe according to either of Claims 1 and 2, characterized in that the anchoring frame (23) is provided with an anti-vibration assembly (3) in the region of the anchoring surface (21). Brake shoe according to claim 3, characterized in that the anti-vibration assembly (3) is formed by at least four anti-vibration segments (31) in the form of longitudinal straps which are situated at the contact points or in the contact area of the anchoring plate (231) with the contact surface. (11) brake stop (1).