RU2599137C1 - Insert of hard-alloy material for a tool of a sleeper tamping machine - Google Patents

Abstract

FIELD: railway equipment.

SUBSTANCE: invention can be used for consolidation of a railway tracks ballast. Insert of hard-alloy material for a tool of a sleeper tamping machine is made in the form of a mushroom-shaped element containing a head and leg (1). Upper part of the head is ripper (2), and the lower part is fender (3). External dimensions of ripper (2) in cross section does not project beyond the minimum external dimensions of leg (1) in cross section. In the place of ripper (2) and fender (3) conjugation the head body is made so that side surfaces of fender (3) and ripper (2) make an obtuse angle on at least a part of the perimeter of their conjugation. When making fender (3) and/or ripper (2) with flat side surfaces, the obtuse angle is formed by these surfaces. When making fender (3) and/or ripper (2) with curvilinear side surfaces, the obtuse angle is formed by tangents to these surfaces in the place of ripper (2) and fender (3) conjugation. When making fender (3) and/or ripper (2) with conical side surfaces, the obtuse angle is formed by generating lines of said surfaces.

EFFECT: reduced resistance of the tool deepening is achieved.

10 cl, 6 dwg

Description

The invention relates to railway equipment, and in particular to tools of tamper machines that compact ballast ballast of a railway track.

The blades of the tamping machine tools, working in an abrasive environment under high vibration loads, wear out quickly. To increase the service life of the blades, they are strengthened by fixing carbide elements of various shapes on the blade.

Known hardening of the tool blade of the tamping machine by fixing carbide inserts made in the form of bars, rollers, pins on the blade (see p. RF No. 2238363 according to CL E01B 27/12, E01B 27/16, published on 10.28.2002, publ. 04/27/2004 "Tool tamper machine").

When the tool is used, ballast particles penetrate between the carbide inserts and come in contact with the metal of the blade, causing abrasive wear of the tool material. This leads to the breakdown of some of the inserts together with the destroyed material of the scapula. Due to the complexity of replacing tools and their high cost, ballasting is continued with partially worn tools whose blade geometry is changed. This reduces the quality of the ballast seal.

The closest in technical essence, the achieved result and selected as a prototype is an insert made of carbide material for a trowel tool in the form of a mushroom-shaped element containing a head and a leg. The head of the tooth can be made in the form of a cylinder, cone, pyramid, in the form of a chisel (see paragraphs of the Russian Federation No. 2293155 according to class E01B 27/12, E01B 27/16, declared July 25, 2005, published February 10, 2007 tapping machine ”).

The implementation of carbide inserts in the form of a mushroom element allows you to more reliably protect the tool material from the abrasive effects of ballast particles. However, the use of a tool with inserts having an acute wedge-shaped top of the head leads to excessive loosening of the ballast in the inter-sleeper space, as when immersed in ballast, the tool has a small upsetting effect on ballast particles in the inter-sleeper space. Using a tool with inserts having a cylindrical head shape, i.e. with a tip without sharpening, or with inserts having a blunter shape of the tip of the head, leads to an increase in the time of deepening of the tool into the ballast and excessive energy consumption for its deepening, i.e. the performance of the tamping machine on which the tamping tools are installed is reduced.

The objective of the present invention is to increase the performance of the tamping machine while providing high efficiency ballast compaction and increasing the life of the tool.

The technical result obtained by the implementation of this invention is to reduce the resistance to deepening of the tool.

The problem is solved due to the fact that in the known insert made of carbide material for the tool of the tamping machine, made in the form of a mushroom-shaped element containing a head and a leg, according to the invention, the upper part of the head is a cultivator and the lower part is a guarding shield, and the outer dimensions of the cultivator are the cross section does not protrude beyond the minimum external dimensions of the legs in the cross section, while the body of the head at the junction of the cultivator and the shield is made so that at least an hour The perimeter of this joint, the lateral surfaces of the flap and ripper make an obtuse angle, which, when the flap and / or ripper with flat side surfaces are formed, is formed by these surfaces, when the flap and / or ripper with curved side surfaces are formed, it is formed tangent to these surfaces at the junction of the flap and the ripper, when performing the shield and / or ripper with conical surfaces formed by forming these surfaces.

The head cultivator can be made in the form of a part of an ellipsoid, or a ball, or a chisel head, or in the form of a part of a cylindrical body bounded by a cylindrical surface and secant planes located at an angle to it.

The guard can be made in the form of either a prism or a truncated pyramid or cone located relative to the cultivator, with its top up or down, or as a combination of these geometric bodies.

The insertion body in the plane of articulation of the foot and the guard flap can be made so that on the part of the perimeter of this joint the guard flap does not have a mushroom-shaped protrusion above the leg.

The height of the shield can be at least 10% of the height of the head. In cross section, the enclosure plate, at least in its lower part, may be a figure whose longitudinal dimension is larger than its transverse dimension.

The guard at the junction of the guard and legs can be made with visors protruding beyond the outer contour of the cross section of the guard by a value of at least 0.4 mm.

The cultivator can be performed with a flat on top.

The leg can be made with a cross section in the form of a circle, or an oval, or a rectangle.

The leg can be made either with a continuous increase in the cross section along the entire height of the leg from its base to the place of its conjugation with the guard, or with an increase in the cross section to part of the height of the legs, or without increasing the cross section.

Studies conducted on the sources of patent and scientific and technical information have shown that the inventive carbide insert is unknown and does not follow explicitly from the studied prior art, i.e. meets the criteria of novelty and inventive step.

The insert can be made at any enterprise specializing in this industry, as this requires well-known materials and standard equipment, and is widely used in compaction of ballast of a railway track, i.e. is industrially applicable.

Typically, voids under the sleepers are filled with ballast from the inter-sleeper space, which, under the influence of the train load, causes the ballast to move from under the sleepers into the loosened inter-sleeper space and causes a violation of the geometry of the straightened path. When using the inventive insert in the layer of the processed ballast, the head cultivator is first immersed. The dimensions and shape of the ripper are selected so that its cross section satisfies both the conditions of the strength of the insert and the conditions of minimal resistance to the introduction of the head of the insert into the ballast. A cultivator immersed in the ballast has a primary effect on it, sufficient to move the ballast particles from place, softening the caked layer of ballast. This facilitates the introduction of a wider part of the insert into the ballast - the guard, and then the blade plate itself. At the same time, the dimensions and shape of the enclosing flap are also selected taking into account the working conditions of the tool. As a result, the tool, plunging into the ballast, exerts on the ballast particles both a static pressing effect, upsetting the particles down, and a dynamic effect, leading to the direction of the ballast particles bouncing off the surfaces of the cultivator and the enclosing guard of the insert, both in the basement and inter-sleepers . It should be noted that the use of an insert with a large mushroom head size, providing high quality ballast compaction, increases the time of the tool to be buried in the ballast, i.e. reduces the performance of the tamping machine. The use of the insert with a cultivator by facilitating the introduction of the tool into the ballast and, consequently, reducing the time for deepening, allows both to preserve the performance of the tamping machine and to ensure high quality ballast compaction. In addition, the implementation of the insert with a cultivator, removing excessive load from the mushroom head of the insert and from the side surfaces of the tool blade, helps to increase its durability.

The execution of the enclosing flap so that its lower part is an element whose length exceeds its width, facilitates the selection of the required number of inserts to equip the tool. This allows, due to the orientation of the insert with the long or short side along the edge of the tool blade, or at a certain angle to this edge, the inserts are most optimally positioned in accordance with the dimensions of the blade and the required degree of protection.

The implementation of the ripper with a flat on the top reduces the likelihood of destruction of the carbide insert when it accidentally hits the metal of the rail track.

All this reduces the likelihood of the formation of mechanical defects (chips, chipping, etc.), positively affects the increase in the resource of the blade and the hammering as a whole.

Thus, the inventive insert, reducing the resistance to penetration of the tool into the ballast, provides the ability to effectively seal the ballast in the inter-sleeper and under-sleeper spaces while ensuring high performance tamping machines and has an increased resistance to fracture, which increases the life of the tool.

The claimed technical solution is illustrated by drawings, which depict:

FIG. 1 - carbide insert (an embodiment of an insert with a cylindrical leg, a shield in the form of a combination of a prism and a pyramid and a cultivator in the form of an ellipsoid);

FIG. 2 is a side view of FIG. one;

FIG. 3 is a plan view of FIG. one;

FIG. 4 - carbide insert (an embodiment of an insert with a leg made in the form of a combination of a top downward relative to the flap of a truncated pyramid and a prism, a flap in the form of a combination of a pyramid and a prism and a cultivator in the form of a cylindrical surface bounded by cutting planes);

FIG. 5 is a side view of FIG. four;

FIG. 6 is a plan view of FIG. four.

The insert made of carbide material for the tool of the tapping machine, made in the form of a mushroom-shaped element, contains a head and leg 1. The foot 1 of the insert is designed for immersion in the body of the blade and / or in the body of the shaft of the tool and is fixed to the tool by interference fit or soldering. The insert head is designed to protect the tool body from abrasion and, as a rule, protrudes above the surface of the tool. Sometimes the insertion head is slightly sunk in the body of the scapula to improve abrasion protection. The upper part of the head is a ripper 2, and the lower part is a guarding shield 3. The body of the head at the junction of the ripper 2 and the shield 3 is made so that at least part of the perimeter of this joint, the ripper and the shield form an obtuse angle α. When performing a cultivator and a flap with a flat side surface, this angle α is formed by the flat side surfaces of the flap 3 and a cultivator 2. When performing a cultivator with a complex curved surface, for example spherical or ellipsoidal, this angle α is formed by a flat side surface of the flap 3 and tangent to the curved side surface of the cultivator 2. When performing the cultivator with a conical surface, this angle α is formed by the flat lateral surface of the flap and forming the conical surface of the cultivator 2. External dimensions (in the drawing e marked L ₂ ) of the cultivator 2 in cross section do not protrude beyond the minimum outer dimensions (indicated in the drawing by L ₁ ) legs 1 in cross section.

The ripper 2 of the insertion head can be made in the form of a part of an ellipsoid, for example, an ellipsoid segment, or a part of a ball, for example a segment of a ball, or a chisel head, or in the form of a part of a cylindrical body bounded by a cylindrical surface and secant planes that are angled to it, and also parallel to the cylinder generatrix. In this case, the pairing of the ripper 2 and the shield 3 is a smooth conversion of one form to another. It is also desirable to carry out the same smooth conversion of one form into another when pairing the leg 1 with the shield 3. This allows one to reduce internal stresses in the body of the carbide insert. The insertion body in the plane of articulation of the leg 1 and the guard 3 can be made so that on the part of the perimeter of this articulation the guard 3 does not have a mushroom-shaped protrusion above the leg 1 (see Fig. 4). This allows, for example, to install the insert more compactly, having joined the leg of one insert to the leg of the other insert.

The guard 3 can be made in the form of either a prism, or a truncated pyramid or cone, located relative to the cultivator with the top up or down, or in the form of a combination of these geometric bodies. The height of the flap 3 (marked B in the drawing) is at least 10% of the height of the head, i.e. from the total height of the shield and the cultivator (in the drawing, the height of the cultivator is marked A, the height of the legs is C) of the insert. In cross section, the guard can be a figure whose longitudinal size is larger than its transverse size (rectangle, oval, etc.). This can be, for example, a rectangle, the length of the short side of which (in the drawing L ₃ ) and the long side (in the drawing L ₄ ) is selected so that by turning the insert to gain a certain length corresponding to the length of the edge of the blade tamping tool.

The execution of the enclosing flap 3 with additional visors 4, protruding beyond the outer contour of the cross section of the flap by at least 0.4 mm, increases the reliability of protecting the material of the blade from abrasive wear where this material holds the leg 1 of the insert.

The implementation of the ripper 2 with a flat 5 on top, the implementation of the legs1 of the insert with a cross section in the form of a circle, or an oval, or a rectangle, the execution of the legs 1 or with a continuous increase in the cross section along the entire height of the legs from its base to the place of its conjugation with the enclosing shield, or with an increase in the cross section to part of the height of the legs, or without an increase in the cross section, all these modifications of the insert allow you to choose the most reliable option depending on the specific operating conditions of the tool.

Thus, the inventive insert, reducing the resistance to penetration of the tool into the ballast, provides the ability to effectively seal the ballast in the inter-sleeper and under-sleeper spaces while ensuring high performance tamping machines and has an increased resistance to fracture, which increases the life of the tool.

Claims (10)

1. An insert made of carbide material for the tool of the tapping machine in the form of a mushroom-shaped element containing a head and a leg, characterized in that the upper part of the head is a cultivator and the lower part is a guarding shield, and the outer dimensions of the ripper in cross section do not protrude beyond the minimum outer dimensions legs in cross section, while the body of the head at the junction of the ripper and the shield is made so that at least on the part of the perimeter of this joint the side surfaces of the shield and ripper with they leave an obtuse angle, which is formed by these surfaces when flap and / or cultivator with flat side surfaces is formed, when flap and / or cultivator with curved side surfaces are formed, it is formed tangent to these surfaces at the junction of flap and ripper, when flap and / or cultivator with conical surfaces formed by the generators of these surfaces. 2. The insert according to claim 1, characterized in that the head cultivator is made in the form of a part of an ellipsoid, or a ball, or a chisel head, or in the form of a part of a cylindrical body bounded by a cylindrical surface and secant planes located at an angle to it. 3. The insert according to claim 1, characterized in that the enclosing flap is made in the form of either a prism or a truncated pyramid or cone located relative to the cultivator with the top up or down, or in the form of a combination of these geometric bodies. 4. The insert according to claim 1, characterized in that the insert body in the plane of articulation of the leg and the guard flap is made so that on the part of the perimeter of this joint the guard flap does not have a mushroom protrusion above the leg. 5. The insert according to claim 1, characterized in that the height of the shield is at least 10% of the height of the head. 6. The insert according to claim 1, characterized in that in cross section the enclosing flap, at least in its lower part, is a figure whose longitudinal dimension is larger than its transverse dimension. 7. The insert according to claim 1, characterized in that the enclosing flap at the junction of the flap and legs is made with visors protruding beyond the outer contour of the cross section of the flap by at least 0.4 mm. 8. The insert according to claim 1, characterized in that the cultivator is made with a flat on the top. 9. The insert according to claim 1, characterized in that the leg is made with a cross section in the form of a circle, or an oval, or a rectangle. 10. The insert according to claim 1, characterized in that the leg is made either with a continuous increase in the cross section along the entire height of the legs from its base to the place of its conjugation with the guard, or with an increase in the cross section to part of the height of the legs, or without increasing the cross section .

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