RU2679152C1 - Bucket tooth of mine crawler excavator - Google Patents

Abstract

FIELD: machine building.SUBSTANCE: invention relates to excavating equipment. Tooth bucket of a mine crawler excavator is made solid and contains a wedge-shaped working part, a massive transition part and a tail part with a socket open at the back and covering the landing part of the front wall of the bucket. Working part is formed by a convex upper and concave lower curvilinear faces formed by mating cylindrical surfaces, and flat side edges, provided with longitudinal ribs on the rear edge and has a rounded cutting edge, equipped with a drop-shaped protrusion and offset relative to the longitudinal axis of the tooth down, and the tail part is equipped with longitudinal ribs above and below. Width of the working and transitional parts of the tooth is 80–160 mm larger than the width of the tail, and the radii of the cylindrical surfaces forming the concave lower curvilinear face of the working part and the ribs on it are approximately equal to the length of the tooth. Working part is sharpened on the side edges approximately by 2/5 of its length, the tapering points are made at an angle α=10–12° to the side faces and provided with a cutting edge and drop-shaped protrusions similar to those made on the end cutting edge. On the back side of the working part 3–5 ribs are made.EFFECT: increased durability and service life.1 cl, 6 dwg

Description

FIELD OF THE INVENTION

The invention relates to earthmoving equipment, in particular to single-bucket open-pit mining excavators of cyclic action, and can be used in the mining industry for excavating rocks of any strength after preliminary loosening.

BACKGROUND OF THE INVENTION

In our country, on straight-shovel excavators for the development of rock formations in a fragmented state and for loading them into transport vehicles, the buckets are equipped with solid or stamped teeth. Cast teeth with complex curvilinear profiles of the front (upper) and rear (lower) faces of the working part made of steel 110G13L turned out to be the most effective and durable. They try to make the working part in the longitudinal section relatively thin, providing rigidity due to the ribs on the rear face, and sometimes on both the front and rear faces. The lateral faces of the working part are usually flat.

ширины зуба. Таким образом, зуб имеет в поперечном сечении крестообразную форму. Зуб снабжен средствами защиты края ковша в виде трапецеидальных выступов на боковых поверхностях, охватывающих край ковша и имеющих скобообразное сечение.A technical solution is known in the form of teeth intended for use on buckets of heavy mining excavators [1]. The working part of the tooth is wedge-shaped and has a complex curved profile of the upper and lower faces. It is assumed that during abrasion during operation, the tooth will maintain a sharp cutting edge. The tooth is made by stamping, it is equipped with wide central stiffening ribs located on the upper and lower surfaces of the tooth. The width of the ribs is approximately

tooth width. Thus, the tooth has a cross-shaped cross section. The tooth is equipped with means for protecting the edge of the bucket in the form of trapezoidal protrusions on the side surfaces covering the edge of the bucket and having a staple section.

However, the profiles of the change in the cutting edge depicted in the patent during wear are too idealized, the cutting edge will always be rounded, and as the abrasion occurs, the thickness of the tooth near the cutting edge increases, and the radius of curvature also increases. Moreover, the drawn profiles do not take into account wide edges. The teeth become dull, the forces during the introduction of the teeth into the rock and the raising of the bucket (while filling it with the rock) increase significantly.

The patent provides a diagram of the installation of teeth on the front wall of the bucket. The provided means of protecting the edges of the front wall of the bucket protect a very small part of the edge in the gap between the teeth. The possibilities for expanding these protrusions are limited, as this will lead to a decrease in the length of the working part of the tooth. The most intense wear of the front wall of the bucket will be at the edges where, when introduced into the rock and when scooped up, the front wall interacts directly with pieces of rock. The teeth are made narrow, the width of the working part of the teeth is 2.5-3.5 times less than its length. Intensive wear of the teeth occurs not only along the front and rear faces, but also along the side faces, and as the wear occurs, the cutting part becomes round, and the teeth not only scoop up the rock, but loosen it.

Closest to the invention in technical essence and the achieved result is a solid tooth of the bucket of the excavator, including a wedge-shaped working part, made with an acute angle of 10-15 ° between the convex upper and concave lower curved faces [2]. The rigidity of the working part of the tooth is provided by two peripheral ribs made on the rear face. The cutting part is offset downward relative to the longitudinal axis of the tooth, the cutting edge is rounded. Due to this form, the sharpening angle of the central part of the tooth during abrasion of the tooth does not change significantly until the end of operation, which ensures the conservation of the effective sharpening angle, and, therefore, a relatively high productivity. The use of teeth of this form has increased the wear resistance and service life and reduce the likelihood of sudden failure. The teeth were made in large quantities and are successfully used in open pit mines.

However, in the mass production and operation, the disadvantages of this tooth design were revealed. The tooth is made of the same width in all parts. The width of the working part seems insufficient, because intensive wear occurs not only along the front and rear faces of the working part, but also along the side faces. To protect the front wall of the bucket from wear, additional wide pads are required. The front curvilinear face of the working part of the tooth is abraded faster than expected due to the fact that its profile is excessively convex.

SUMMARY OF THE INVENTION

The aim of the invention is to increase the efficiency of the working bodies of mining excavators while reducing operating costs.

The technical results are an increase in wear resistance and service life, a decrease in the likelihood of sudden failure, an improvement in manufacturability during casting and heat treatment.

The specified goal and results are achieved by the bucket tooth, made in accordance with the claims, with a comprehensive solution of issues of service compliance and manufacturability.

Brief Description of the Drawings

Signs and advantages of the present invention will be more apparent from the following description of the technical nature of its implementation with reference to the accompanying drawings, in which:

- in FIG. 1 shows a proposed bucket tooth, side view,

- in FIG. 2 shows a bucket tooth, top view,

- in FIG. 3 shows a bucket tooth, rear view,

- in FIG. 4 shows a bucket tooth, a section along AA

- in FIG. 5 shows a bucket tooth, section BB

- in FIG. 6 shows a bucket tooth, section BB.

DETAILED DESCRIPTION OF THE INVENTION

The design of the proposed solid tooth of the bucket is presented in detail in FIG. 1-6. The tooth consists of a wedge-shaped working part, a short transition part and a tail part with a socket open at the back and covering the landing part of the front wall of the bucket. The width of the working and transitional parts of the tooth is 80-160 mm wider than the width of the caudal part. The drawings show the widest tooth. The wedge-shaped working part of the tooth is formed by a convex front face 1 and a concave rear face 2, smoothly mating at the end of the wedge along a cylindrical surface that is the cutting part (edge) 3. The cutting edge is shifted downward relative to the longitudinal axis of the tooth by about 100 mm and contains a droplet-shaped protrusion 4 of a smaller radius. The radii of the cylindrical surfaces forming the concave lower curved face 2 of the working part and the ribs 5 on it are taken to be approximately equal to the length of the tooth, R≅L. Five ribs 5 are made on the rear face of the working part, their width being different and decreasing for each next rib from the center to the periphery by ~ 10 mm, i.e. b ₁ ≅b ₂ + 10≅b ₃ +20 mm. For less wide teeth, the number of ribs may be less than 3 or 4.

The working part is pointed along the side faces 6 by approximately 2/5 of its length, the points 7 are made at an angle α = 10 ° -12 ° to the side faces and are provided with a cutting edge and drop-shaped protrusions similar to those made on the end cutting edge.

The transitional part of the tooth is used to interface the working part with the tail. A stepped inner cavity 8 is made in the transitional part, corresponding in shape to a longitudinal section of the tooth corresponding to the shape of the outer surface, communicating with the nest of the tail section and provided with cylindrical openings 9 facing the side surfaces of the tooth. The width b _{4 of the} middle part of the indicated step cavity corresponds to the width of the protrusion on the front wall of the bucket (the so-called "canine"). The transitional part of the tooth contains thrust surfaces 10, the radius of which is equal to the radius of the edge of the front wall of the bucket.

The caudal part of the tooth is equipped with two peripheral ribs 11 above and below. A rectangular window 12 is made in the upper and lower walls of the caudal part of the tooth between the ribs, the walls of which are perpendicular to the axis of the tooth. On the upper and lower walls of the caudal part of the tooth behind a rectangular window 12, inclined surfaces 13 are made with a rise to the back of the tooth.

The inventive wide tooth of the bucket of the excavator is made of cast from wear-resistant austenitic steel 110G13L. Its design takes into account the requirements of foundry technology: in places with a maximum wall thickness cavities and samples are made, longitudinal ribs are used to increase the rigidity of the working and caudal parts of the tooth, and fillets are used in the places of mating surfaces. The design of the tooth also takes into account the requirements of good calcined ™ during heat treatment.

The installation of wide teeth on the front wall of the bucket differs from the installation of narrow teeth. Firstly, the number of teeth decreases - on buckets with a capacity of 18 m ³ and 20 m ³ instead of 6 narrow teeth, 5 wide ones are installed. Secondly, while maintaining the width of the spaces between the teeth, the extreme teeth are mounted on the very edges of the front wall of the bucket. To lift the tooth, cash hoisting mechanisms are used, the cable is threaded through holes 9 located near the center of mass of the tooth. The assembly is carried out in the usual sequence: on the front wall of the bucket of the excavator the tooth is put on by the nest of the tail section until it stops along the surfaces 10. The protrusion on the front wall of the bucket (canine) enters the wide part of the stepped cavity 8. Then, the tooth has a rectangular window 12 and the same window a bracket is inserted in the front wall of the bucket and is worn by its working inclined surfaces onto the inclined surfaces 13 of the rear part of the tooth. A wedge is inserted into the gap between the back of the bracket and the front wall of the window 12 of the tooth. The wedge is hammered into the specified gap by hammer blows, while the clamp strongly compresses the upper and lower walls of the caudal part of the tooth and pushes the tooth back, creating an interference fit on the abutment surfaces 10.

The teeth work as follows. When lowering the bucket, the teeth are embedded in the rock mass or soil previously destroyed by the explosion. The force of penetration into the breed of a set of wide teeth increases slightly (by ~ 10-12%) in comparison with the use of narrow teeth. This is achieved by sharpening the working part of the teeth along the lateral faces, for example, the widest teeth with a width of 400 mm are sharpened to a width of 320 mm. Then 5 wide teeth are snapped into the rock at a length of 1600 mm, and 6 narrow teeth of a normal width of 240 mm - at a length of 1440 mm. The bucket is rotated, separating part of the rock from the massif, the rock moves along the upper (front) face of the teeth and the front wall of the bucket, gradually filling the bucket of the excavator. Then the bucket is transferred to the place of unloading and unloaded. When introduced into the rock and turning the bucket, the front (upper) 1 and lower (rear) faces 2, the cutting edge 3 and the side faces 6 are intensively abraded against the rock under the influence of abrasive and impacts. Due to the rational profiling of the working part in the proposed tooth design during blunting, the working part retains its shape with respect to a sharp wedge. Depreciation of wide teeth will occur at the same speed as narrow ones of the same material, but the durability of the tooth significantly (1.6-2.0 times) increases due to a significant increase in the width of the working part. Wear resistance is also ensured due to the high quality of the metal in all parts of the tooth after casting and heat treatment. The tooth retains a shovel-shaped section and scoops up clastic rock well up to the complete wear of the working part.

1. The cutting edge of the excavator bucket. Patent RF IPC E02F 9/28 No. 2116406.- Applic. 02/25/1997 - Publ. 07/27/1998 Authors: Sobolev V.F., Kudinov S.Ya.

2. Tooth bucket excavator. Patent RF IPC E02F 9/28 No. 2184814. - Declared. 02/13/2001 - Publ. 07/10/2002 Authors: Sokolov GA, Chernyshev SV, Rubina O.F.

Claims (1)

A tooth of a mining excavator bucket made of cast and containing a wedge-shaped working part, a massive transition part and a tail part with a socket open at the back and covering the landing part of the front wall of the bucket, the working part being formed by convex upper and concave lower curved faces formed by mating cylindrical surfaces, and flat side faces, provided with longitudinal ribs on the rear face and has a rounded cutting edge, provided with a drop-shaped protrusion and offset relative to along the longitudinal axis of the tooth down, and the caudal part is provided with longitudinal ribs above and below, characterized in that the width of the working and transition parts of the tooth is 80-160 mm wider than the width of the caudal part, and the radii of the cylindrical surfaces forming a concave lower curved face of the working part and ribs on it, are taken approximately equal to the length of the tooth, the working part is pointed along the side faces by about 2/5 of its length, the sharpenings are made at an angle α = 10-12 ° to the side faces and are equipped with a cutting edge and drop-shaped protrusions, anal tech formed on the end cutting edge and on the rear face of working part of the ribs 3-5 is satisfied, and their width varies and decreases for each successive edges from the center towards the periphery by about 10 mm.

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