RU120375U1 - Drum Mill Lining - Google Patents

Abstract

1. The lining of a drum mill, which includes plates of elastic material installed on the inner surface of the drum with longitudinal side recesses, in which lifters are installed in the form of bars made of elastic material connected to the armor, characterized in that the lifter's armor is made of wear-resistant material and installed along the elevator height from the side of the influence of the load on the elevator, while the elevator is connected to the inner surface of the mill drum by means of fastening means made directly in the armor. ! 2. The lining of a drum mill according to claim 1, characterized in that the surface of the armor, which is connected to the surface of the elastic material bar, contains from two to eight protrusions. ! 3. The lining of a drum mill according to claim 1, characterized in that the surface of the armor, which is connected to the surface of the elastic material bar, contains projections that have a trapezoidal cross-section. ! 4. Lining of a drum mill according to claim 1, characterized in that the elevator armor has a wedge-shaped profile in cross-section. ! 5. Lining of a drum mill according to claim 1, characterized in that the lifter is connected to the inner surface of the mill drum by means of fasteners that are inserted into the holes of the tapered profile. ! 6. The lining of a drum mill according to claims 1 and 5, characterized in that the holes for the fasteners are made directly in the lifter armor to its entire height. ! 7. Lining of a drum mill according to claims 1 and 5, characterized in that the holes for the fasteners are made at a distance from the edge of the lifter armor, which is equal to the distance

Description

The utility model relates to wear-resistant elements that are used for lining the inner surfaces of ball mills, which work in the first grinding stage with balls of 80-120 mm and self-grinding mills, and can be used in mining, processing, energy, chemical and other industries for processing and preparation of raw materials.

In mills of the first grinding stage, the use of a lining made entirely of rubber is impractical. Through high shock loads, intensive wear of rubber occurs in the attack zone of the lining. Therefore, a combined lining design is used in a rubber-metal combination. This combination allows you to maximize the benefits of each of the materials - elasticity and abrasion resistance of rubber and impact resistance of steel in the attack zone of the lining.

In technical essence, the closest analogue to the claimed utility model is a mill lining with a wear-resistant lifter for facing the inner surface of drum mills (USSR patent No. 1829962, V02C 17/22, publ. 07/23/93, prototype), which includes plates installed on the inner surface of the drum from an elastic material, mainly rubber, which have longitudinal side recesses, in which lifters are installed in the form of beams of elastic material and a vulcanized metal bar and a mounting plate, whereby lifters attached to the drum body by fasteners.

However, the lining of this design has several disadvantages:

- a solid wear-resistant plate is attached to the rubber base of the elevator chemically or mechanically. During operation, due to shock loads acting on both the plate and the rubber, intensive wear of rubber occurs around the metal plate, which leads to the formation of recesses at the joints of the metal and rubber, which subsequently lead to the separation of the metal plate and, as a result to premature wear of the lining;

- metal plates have certain dimensions in height and thickness, and as the elevator wears out, these dimensions decrease, which in the future, during operation also leads to the separation of the plate. The rubber base, having lost its protective wear-resistant layer, wears out prematurely.

The utility model is based on the task of optimizing the design of lining plates and improving the design of the elevator in the combination of rubber - wear-resistant material to increase the reliability and efficiency of the lining in drum mills of the first stage, avoid the above disadvantages, increase the service life of the lining of the mill, increase productivity and reduce downtime mills during repair work.

The problem is solved in that the lining of the drum mill, including installed on the inner surface of the drum plates of elastic material, mainly rubber, with longitudinal side recesses, in which lifters are installed in the form of beams of elastic material connected to the armor, according to a utility model, the elevator armor made of wear-resistant material and installed along the elevator height from the side of the load influence on the elevator, while the elevator is connected to the inner surface of the mill drum with with the help of fasteners made directly in the armor.

The wear-resistant part of the elevator (armor) performs two functions:

- protection of the elevator from shock loads, both from the mass which is crushed, and from ball loading;

- reliable and permanent fastening of the elevator for the entire period of operation of the mill.

The surface of the armor, which is connected to the surface of the beam of elastic material, may contain from two to eight protrusions, which are in cross section, trapezoidal or other shape.

The presence of protrusions makes it possible to redistribute the load when the surface of the elevator armor, which accepts the shock load, contacts the surface of the elevator beam, which dampens the armor, which increases the bond strength of these surfaces and the lining service life. This will protect the non-working surface of the elevator, made of rubber, from shock loads and increase its service life. The number and size of the protrusions is determined technologically, based on the operating conditions of the mill, the diameter of the balls and the dimensions of the elevator.

The shape of the protrusions on the non-working surface of the armor allows you to optimize the distribution of the shear load during the operation of the elevator.

The cross-section of the elevator armor may have a wedge-shaped profile.

An armor profile of this form will extend its service life with gradual wear of the armor material caused by shock loads on the elevator.

The lifter can be connected to the inner surface of the mill drum using fasteners that are inserted into the holes of the conical profile.

Such a connection of the elevator with the drum increases the reliability of fixing all the elements of the lining on the surface of the drum, and also ensures the stability of the fastening connection with the gradual wear of the armor material and is technological in the manufacture and assembly of the lining of the mill drum.

Holes for fasteners can be made directly in the armor of the elevator to its entire height.

Therefore, the placement of the fastener at the level of the upper surface of the elevator will protect this surface in the area of the holes from premature wear.

The holes for the fasteners can be made at a distance from the edge of the elevator armor, which is equal to the distance of the protrusion on the non-working surface of the elevator.

This allows you to increase the strength of fasteners that work on a break under the influence of shock on the armor of the elevator.

The lifter can be connected to the inner surface of the mill drum using fasteners that are inserted into the T-groove.

Such a connection of the elevator with the drum increases the reliability of fixing all the elements of the lining on the surface of the drum, and also ensures the stability of the fastening connection with the gradual wear of the armor material and is technological when assembling the lining of the mill drum.

A T-slot for fasteners can be made directly at the base of the armor.

This makes it possible to simplify the connection of the elevator with the inner surface of the drum of the mill with the help of fasteners that are inserted into the T-groove.

The elevator armor can be made of wear-resistant high-manganese steel.

This allows you to increase the perception of shock loads on the armor, which lengthens its life and lining as a whole.

The elevator armor can be connected to the elevator beams by vulcanization.

The connection of the elevator armor with the elevator beams by vulcanization increases the manufacturability and installation of the lining, and will also increase the strength of the connection of the working and non-working parts of the elevator to increase its life.

The width of the elevator And can be performed according to the ratio A = K ₁ · D, where: D - the inner diameter of the mill drum; K ₁ - coefficient, which is 0.03 ... 0.1.

The inventors, through numerous studies of drum mill samples, it was found that the coefficient K ₁ depends on the inner diameter of the mill drum, the number of rows of mounting holes, the lateral clearance allowed between the plates on the drum, the width of the drum plate, and is selected from the interval of 0.03 ... 0 ,one.

The height of the elevator C can be performed according to the ratio C = K ₂ · D, where D is the inner diameter of the mill drum, K ₂ is a coefficient that is 0.03 ... 0.1.

The inventors have also scientifically established that the coefficient K ₂ depends on the technological parameters of the mill, on the inner diameter of the drum, the diameter of the grinding media, the rotation speed of the mill, the level of loading of the material that is crushed.

It was found that the bevel angle α ₅ from the working side of the elevator can be selected from the range α ₅ = 25 ° ... 45 °, and the bevel angle α ₄ from the non-working side of the elevator can be selected from the range α ₄ = 0 ° ... 15 °.

In cross section, the armor has a height F ₂ , which can be selected from the ratio F ₂ = K ₃ · C, where H is the height of the elevator; K ₃ - coefficient, which is equal to 0.65 ... 1.0.

It was found that the coefficient K ₃ depends on the diameter of the grinding media and the level of loading of the material that is crushed.

The width of the base of the metal armor E ₁ can be determined by the ratio E ₁ = K ₄ · A, where A is the width of the elevator, K ₄ is a coefficient that is 0.6 ... 0.8.

It was found that the coefficient K ₄ depends on the technological parameters of the mill, the diameter of the grinding media, the level of loading of the material that is crushed.

Moreover, the angle β of the inclination of the surface of the metal armor from the non-working side of the elevator can be selected from the interval 0 ° ... 15 °.

The surface of the armor, which is connected with the elastic material of the beam, can be made in a wave-like profile. It was established that the number and size of wave crests is determined technologically, based on the operating conditions of the mill, the diameter of the balls and the dimensions of the elevator and can be in the range from 2 to 8.

When installing the fastener, the upper surface of its thickening can be located at the level of the upper surface of the elevator, and the lower surface, which has a cone-shaped profile, keeps the elevator from the effects of different loads, as close as possible to the lower level of the armor. The fastener itself may have, as an option, a thickened part with a rubber coating that fills the hole in the armor to the upper surface of the elevator.

The bevel height from the working side of the elevator F ₁ can be determined by the ratio F ₁ = K ₆ · C, where N is the elevator height; K ₆ is a coefficient that can be selected from the range of 0.25 ... 0.4.

In this case, the height of the bevel from the non-working side of the elevator F is determined by the ratio F = K ₅ · C, where N is the elevator height; K ₅ - coefficient, which is selected from the range 0 ... 0.25.

It was found that the coefficients K ₅ and K ₆ depend on the technological parameters of the mill.

Lining plates of elastic material can be made according to the ratios:

- the thickness of the lining plate H from the ratio H = K ₇ · D, where: D is the inner diameter of the mill drum; To ₇ is a coefficient that can be determined from the range of 0.02 ... 0.07.

It was found that the coefficient K ₇ may depend on the technological parameters of the mill and on the inner diameter of the mill drum.

- the thickness of the plate in the middle H ₁ part from the ratio H ₁ = K ₈ · H, where N is the thickness of the plate of the lining of the drum, K ₈ is a coefficient that can be selected from the range of 0.65 ... 1.0.

It was found that the coefficient K ₇ may depend on the difference in the heights of the plate, the level of loading of the material that is crushed,

In this case, the angle of inclination of the working surface of the slab az can be selected from the interval 0 ° ... 25 °.

The upper surface of the plates can be made flat or concave, and the concavity is formed by straight planes at an angle of inclination α ₃ , or a surface with a radius R, which is determined from the range 160 ... 1500 mm

The longitudinal lateral recesses in the plate for installing the elevator are made with the thickness of the foot h, which can be selected from the ratio h = K ₉ · N, where N is the thickness of the lining plate of the mill drum; K ₉ is a coefficient that can be selected from the range of 0.1 ... 0.3,

It was found that the coefficient K ₉ depends on the inner diameter of the mill drum, the number of rows of mounting holes, side clearance, which is allowed between the plates along the drum,

Moreover, the angle α of inclination of the inner surface of the foot of the plate can be determined from the range of 5 ° ... 10 °, angle α _{1 of the} inclination of the side surface of the recess of the plate can be determined from the range of 5 ° ... 10 °, and the angle α _{2 of the} inclination of the outer (lower) surface of the foot plates are determined from the range 0 ° ... 7 °.

The elevator installation height above the stove G can be determined from the relation G = K ₁₀ · D, where D is the inner diameter of the mill drum; To ₁₀ is a coefficient that can be determined from the range of 0.007 ... 0.02.

It was found that the coefficient K ₁₀ depends on the technological parameters of the mill, on the inner diameter of the drum, the diameter of the grinding media, the rotation speed of the mill, the level of loading of the material that is crushed.

The design of the plate according to the stated ratios: the thickness of the plate H = K ₇ · D, as well as the thickness of the plate in its middle part H ₁ = K ₈ · H and the angle of inclination of the working surface of the plate from the interval 0 ° ... 25 °, will ensure its optimal configuration and will allow to bring the mill productivity to the calculated parameters in the shortest possible time, while ensuring reliability of the lining. The working surface of the plate, in accordance with the indicated parameters, can be made of a different profile, as indicated in Fig. 5, straight, or, as indicated in Fig. 6, concave, or, as indicated in Fig. 7, curved. In this case, concavity is formed by straight planes at an angle of inclination α ₃ . Curvature can be formed by a surface with a radius R equal to R = 160 ... 1500 mm.

The angle γ of the slope of the elevator working surface relative to the plane of the plate can be determined from the interval γ = 90 ° ... 130 °, which provides the most favorable conditions for the operation of the lining while increasing the productivity of the mill.

The implementation of the elevator in the form of a beam with a width A, which can be determined by the ratio A = K ₁ · D and height C, which can be determined by the ratio C = K ₂ · D, made of an elastic material, with armor F ₂ installed in it, which can be determined by the ratio of F ₂ = K ₃ · C and the width of the base E ₁ which can be determined by the ratio of E ₁ = K ₄ · A made of a wear-resistant material, for example, wear-resistant high manganese steel, while the armor has holes for cone-shaped fasteners profile which are made directly in the thickening of the metal armor to its entire height and installed along the elevator height, from the side of the load on the elevator, will maximize the advantages of each of the materials: rubber elasticity and wear resistance of steel. The armor takes shock loads, and the rubber acts as a damping element that absorbs shock loads. Given the elevator’s armor height and its cross-sectional width, during operation of the mill uniform wear of the elevator occurs, while maintaining its operability until it is completely abraded by height and, as a consequence, an increase in the life of the lining.

The execution of longitudinal lateral recesses in plates with the declared parameters of the side surface and the foot, and the implementation of the elevator base of the corresponding configuration, that is, in the center of the base an even cut, and the edges are beveled, will form a tight connection between the plates and the elevator, and firmly press the plates to the body mill drum, eliminating the ingress of pulp under the slab to the mill body.

The lining of the drum mill is shown in the drawings.

Figure 1 is a General view of a drum mill.

Figure 2 - section aa in figure 1, shows a fragment of the lining of the mill with conical fasteners and plates, the working surface of which is made flat;

Figure 3 - section aa in figure 1, shows a fragment of the lining of the mill with plates, the working surface of which is made concave in radius;

Figure 4 - section aa in figure 1, shows a fragment of the lining of the mill with T-shaped fasteners;

Figure 5 is a cross section of a plate with a rectilinear working surface;

Figure 6 is a cross-sectional view of a plate with one of the profile variants of the working surface (curved-concave formed using straight planes at an angle of inclination α ₃ );

7 is a cross section of a plate with one of the profile options of the working surface (curved-concave formed using a surface with a radius R;

On Fig - elevator, shown an option that contains the tabs and conical fasteners, top view;

In Fig.9 - section bB in Fig.8, the cross section of the elevator;

Figure 10 - elevator, shows a variant that contains T-shaped fasteners, top view;

Figure 11 is a section bb in figure 10, the cross section of the elevator.

The lining of the drum mill consists of plates 1 made of an elastic material, such as rubber, mounted on the inner surface of the drum of the mill 2 and fixed to the body using lifters 3 made of elastic material 4 with armor 5. The lifters 3 are attached to the drum of the mill 2 with fasteners 6, which are installed in the holes 7 of the metal armor 5. The metal armor 5, on the side of the non-working surface of the elevator, has projections 8. Alternatively, the elevators 3 can be attached to the drum of the mill 2 means of fixing members 9, which are mounted in T-slots 10 5 metal armor (4, 10, 11).

When rotating the drum of the mill 2, the inner surface of which is lined with plates 1, attached to the casing with the help of elevators 3, the ball load and the material that is crushed are lifted by the elevator working surface to a height due to the height G of the elevator 3 installed above the plate 1 and the slope angle of the working surface α ₅ . Tearing away from the side wall of the drum, the material that is crushed, and the ball load fall on the working surface of the plates 1 and lifters 3. The shock load is perceived by the metal armor of 5 lifters, which protects the rubber part of 4 lifters and plate 1 from premature wear. The metal armor 5 of the elevator 3 has a profile that expands in cross section, therefore, as the elevator wears out in height, the width of the armor increases, while ensuring that it performs technological functions. Fasteners 6 are installed directly in the metal armor and, as the elevator wears out in height, provide a constant force of pressing the plates by lifters.

With further movement of the material that is crushed in a circular path, it slides along the working surface of plate 1. Due to the fact that the plates are made of rubber, which works better on abrasion than metal, and shock loads are excluded by lifters 3, which have armor 5 , then the plates are less exposed to wear.

The parameters of the proposed design of plates and lifters allow to give a wave-like profile to the inner surface of the drum, which positively affects the operational parameters of the mill.

If the design of the lining complies with all the declared parameters of the plates and elevators, the use of the proposed lining will reliably protect the working surface of ore-grinding ball mills, increase the reliability and durability of the lining, and increase the productivity of the mill.

Claims (32)

1. The lining of the drum mill, which includes plates on the inner surface of the drum of elastic material with longitudinal side recesses, in which lifters are installed in the form of beams of elastic material connected to the armor, characterized in that the armor of the elevator is made of wear-resistant material and installed on the height of the elevator from the side of the influence of the load on the elevator, while the elevator is connected to the inner surface of the mill drum by means of fasteners made directly in the br no. 2. The lining of the drum mill according to claim 1, characterized in that the surface of the armor, which is connected to the surface of the beam of elastic material, contains from two to eight protrusions. 3. The lining of the drum mill according to claim 1, characterized in that the surface of the armor, which is connected to the surface of the beam of elastic material, contains protrusions that have a trapezoidal shape in cross section. 4. The lining of the drum mill according to claim 1, characterized in that the elevator armor in cross section has a wedge-shaped profile. 5. The lining of the drum mill according to claim 1, characterized in that the elevator is connected to the inner surface of the drum of the mill using fasteners that are inserted into the holes of the conical profile. 6. Lining of the drum mill according to claims 1 and 5, characterized in that the holes for the fasteners are made directly in the armor of the elevator to its entire height. 7. The lining of the drum mill according to claims 1 and 5, characterized in that the holes for the fasteners are made at a distance from the edge of the elevator armor, which is equal to the distance of the protrusions. 8. The lining of the drum mill according to claim 1, characterized in that the elevator is connected to the inner surface of the drum of the mill using fasteners that are inserted into a T-groove. 9. The lining of the drum mill according to claims 1 and 8, characterized in that the T-shaped groove for fasteners is made directly at the base of the armor. 10. The lining of the drum mill according to claim 1, characterized in that the armor of the elevator is made of wear-resistant high manganese steel. 11. The lining of the drum mill according to claim 1, characterized in that the elevator armor is connected to the elevator beams by a vulcanization method. 12. The lining of the drum mill according to claim 1, characterized in that the width of the elevator A is made according to the ratio A = K ₁ · D, where D is the inner diameter of the mill drum; K ₁ - coefficient, which is 0.03 ... 0.1. 13. The lining of the drum mill according to claim 1, characterized in that the height of the elevator C is made according to the ratio C = K ₂ · D, where D is the inner diameter of the mill drum; K ₂ - coefficient, which is 0.03 ... 0.1. 14. The lining of the drum mill according to claims 1 and 13, characterized in that the bevel angle α ₅ from the working side of the elevator is chosen equal to 25 ° ... 45 °. 15. The lining of the drum mill according to claims 1 and 13, characterized in that the bevel angle α ₄ from the non-working side of the elevator is α ₄ = 0 ° ... 15 °. 16. The lining of the drum mill according to claims 1 and 13, characterized in that the height F _{2 of the} armor is made according to the ratio F ₂ = K ₃ · C, where C is the height of the elevator; K ₃ - coefficient, which is equal to 0.65 ... 1.0. 17. The lining of the drum mill according to claims 1 and 12, characterized in that the width of the base of the armor E ₁ is equal to E ₁ = K ₄ · A, where A is the width of the elevator; K ₄ - coefficient, which is 0.6 ... 0.8. 18. The lining of the drum mill according to claims 1 and 17, characterized in that the angle β of the inclination of the surface of the armor from the non-working side of the elevator is 0 ° ... 15 °. 19. The lining of the drum mill according to claim 1, characterized in that the thickness of the lining plate of the drum N is made according to the ratio H = K ₇ · D, where D is the inner diameter of the mill drum; K ₇ - coefficient, which is 0.02 ... 0.07. 20. The lining of the drum mill according to claims 1 and 19, characterized in that the thickness of the plate in the middle part of H _{1 is} made according to the ratio H ₁ = K ₈ · H, where H is the thickness of the plate of the lining of the drum; K ₈ - coefficient, which is equal to 0.65 ... 1.0. 21. The lining of the drum mill according to claim 1, characterized in that the upper surface of the plates is made flat. 22. The lining of the drum mill according to claim 1, characterized in that the upper surface of the plates is made concave. 23. The lining of the drum mill according to claims 1 and 22, characterized in that the concavity of the upper surface of the plates is formed by straight planes at an angle of inclination α _{3 of the} working surface of the plate equal to 0 ° ... 25 °. 24. The lining of the drum mill according to claims 1 and 22, characterized in that the concavity of the upper surface of the plates is formed by a surface with a radius R equal to 160 ... 1500 mm. 25. The lining of the drum mill according to claims 1 and 19, characterized in that the longitudinal side recesses in the plate for installing the elevator are made with the thickness of the foot h, which is made according to the ratio h = K ₉ · H, where H is the thickness of the lining plate of the mill drum; K ₉ - coefficient, which is equal to 0.1 ... 0.3. 26. Lining of a drum mill according to claims 1 and 25, characterized in that the angle of inclination α of the inner surface of the foot of the plate is α = 5 ° ... 10 °. 27. The lining of the drum mill according to claims 1 and 25, characterized in that the inclination angle α _{1 of the} side surface of the recess of the plate is α = 5 ° ... 10 °. 28. The lining of the drum mill according to claims 1 and 25, characterized in that the angle of inclination α _{2 of the} outer lower surface of the foot of the plate is α ₂ = 0 ° ... 7 °. 29. The lining of the drum mill according to claims 1 and 13, characterized in that the bevel height from the working side of the elevator F _{1 is} made according to the ratio F ₁ = K ₆ · C, where C is the height of the elevator; K ₆ - coefficient, which is equal to 0.25 ... 0.4. 30. The lining of the drum mill according to claims 1 and 13, characterized in that the bevel height from the non-working side of the elevator F is made according to the ratio F = K ₅ · C, where C is the height of the elevator; K ₅ - coefficient, which is 0 ... 0.25. 31. The lining of the drum mill according to claim 1, characterized in that the installation height of the elevator above the plate G must satisfy the ratio G = K ₁₀ · D, where D is the inner diameter of the mill drum; K ₁₀ - coefficient, which is equal to 0.007 ... 0.02. 32. The lining of the drum mill according to claims 1 and 31, characterized in that the angle of inclination of the working surface of the elevator relative to the plane of the plate γ is 90 ° ... 130 °.