UA134100U - LINING PLATE OF THE DRUM MILL - Google Patents

Abstract

The lining plate of the drum mill comprises a base in the form of a bar made of an elastomeric material with a work surface equipped with vulcanized inserts having a wear resistance higher than the elastomeric material of the base, and the opposite surface equipped with means of communication with the surface of the mill. The inserts are made in the form of a beam, the longitudinal axis of which coincides with the direction of the longitudinal axis of the base, and the work surface contains at least one projection and an inclined surface. The projection is formed by the longitudinal rib of one of the inserts, and the slope of the inclined surface is made in the direction opposite to the movement of the mill drum. Another insert is vulcanized into an inclined surface so that it protrudes from this surface. The insert forming the protrusion and the insert protruding from the sloping surface are inclined with respect to the vertical axis of the cross-section of the base and directed in opposite directions relative to the vertical axis of the cross-section of the base.

Description

A useful model belongs to the mining industry or the building materials industry and can be used to line the inner surface of drum mills for grinding materials with grinding bodies such as ball loading or the like.

Similar lining plates are known, among which the following are the closest.

The lining plate of the drum mill is known, which contains a base made of elastomeric material in the form of a bar with a cross-section in the form of a multifaceted prism. The upper surface of the prism is the working surface and consists of a horizontal part and two inclined parts on both sides of the horizontal part to form a wavy surface of the mill drum lining.

The horizontal part and one inclined part of the base are equipped with metal inserts in the form of spikes. Metal inserts are made in the form of rectangular parallelepipeds with a flat or beveled upper face protruding above the surfaces of the base faces. Metal inserts are oriented at an angle relative to the longitudinal axis of the base and are located at the same step along its length. On the surface of the base, opposite to the working surface, a longitudinal groove is made for connection with the surface of the drum of the mill (ША 81709, published on January 25, 2008).

The disadvantage of the described lining plate is the intensive destruction of the metal inserts during the operation of the mills at the first stage of grinding, which is due to the location of the metal inserts separately from each other and leads to their intensive wear under the influence of high shock loads from grinding bodies, such as balls with a diameter of 80. .120 mm.

The gradual destruction of the metal inserts leads to premature wear of the elastomeric material of the base of the lining plate and a reduction in the service life of the lining of the mill drum.

Also known is the lining plate of the drum mill, which contains a base in the form of a bar made of elastomeric material, into which a metal insert in the form of a protrusion of a trapezoidal cross-section is vulcanized, which forms a lifter for lifting the grinding bodies and the grinding material during the rotation of the mill drum. The insert is made for the entire length of the base beam. The base also includes a flat working surface coupled to the lifter surface via a projection with through holes for attachment to the drum surface (005 6,036,127, published 03/14/2000).

The disadvantage of such a lining plate is a decrease in the reliability of the base attachment due to the impact of shock loads from the grinding bodies and material on the upper part of the attachment, as well as the lack of support for the protrusion that serves as a lifter, an elastomeric material from the back of the working surface of the base, which leads to a sufficiently fast wear of the reinforcing insert and exposure of areas of the working surface made of elastomeric material.

Also known is the lining plate of the drum mill, which contains a base in the form of a bar made of elastomeric material, in the upper working surface of which metal inserts in the form of protrusions are vulcanized, which act as lifters for lifting the grinding bodies and the grinding material. The inserts are located equally along the length of the section at different heights relative to each other to form a stepped surface for better gripping of the grinding bodies and the material being ground. Between the inserts there is an inclined surface perpendicular to the side surface of the inserts. Also, the lining plate is equipped with means of connection with the surface of the drum of the mill, located on the surface of the base, opposite to the working surface, and made as an armature with a continuous groove along its length for the installation of fastening elements (OA 96945, published on February 25, 2015).

The disadvantage of such a solution is the lack of protection for the inclined surface, which reduces the reliability of the lining and its service life, or the use of grinding bodies of only a certain size, which exceeds the dimensions of the depression formed by the side surface of the protrusion and the inclined surface located below this protrusion. Also, the relief of the lining formed by such plates does not allow to increase the number of grinding bodies and grinding material, which are captured once when the drum rotates, and to increase the height of their rise for further falling on the material below and its grinding.

The closest analogue is the lining plate of a drum mill, which contains a base in the form of a bar made of elastomeric material with a working surface equipped with vulcanized inserts that have a higher wear resistance than the elastomeric material of the base, and a surface opposite to it, equipped with means of connection with the surface of the mill drum. The working surface includes a protrusion of elastic material in the rear part of the base, reinforced by one of the inserts, installed at an angle relative to the vertical axis of the base section. This insert is located on the side of the back of the base, which is opposite the inclined surface on which the other insert is vulcanized. The specified inserts have the form of a parallelogram of a certain thickness and are located with a tight step along the length of the base beam (ЕР 1 279 438 A1, published on January 29, 2003).

The disadvantage of the closest analogue is that the protrusion, which acts as a lifter, is made of elastic material and reinforced with an insert only on the back side, which leads to premature wear of the front part of the protrusion. Also, most of the working surface is not equipped with inserts to strengthen it, which leads to its premature wear during the operation of the mill under the influence of shock loads from the grinding bodies and the grinding material.

The useful model is based on the task of increasing the reliability and efficiency of the lining plate in drum mills of the first stage of grinding, in particular with grinding bodies such as balls with a diameter of 80-120 mm, by changing the shape of the working surface and the geometry of vulcanized inserts, which have higher wear resistance than elastomeric material the base, as well as the location of the inserts relative to the relief of the working surface, to exclude premature wear of the elastomeric material of the base.

The problem is solved by the fact that in the lining plate of the drum mill, which contains a base in the form of a bar made of elastomeric material with a working surface equipped with vulcanized inserts that have a higher wear resistance than the elastomeric material of the base, and the surface opposite to it, equipped with means of connection with the surface of the mill drum, according to a useful model, the inserts are made in the form of a bar, the longitudinal axis of which coincides with the direction of the longitudinal axis of the base, and the working surface contains at least one protrusion and an inclined surface, and the protrusion is formed by the longitudinal edge of one of the inserts, and the slope of the inclined surface is made in the opposite direction movement of the drum of the mill, while the other insert is vulcanized into the inclined surface so that it protrudes from this surface, and the insert forming the protrusion and the insert protruding from the inclined surface are located with an inclination relative to the vertical axis of the cross section of the base and are directed in opposite directions relative to vertical axis of the cross-section of the base.

The technical result achieved by the useful model consists in increasing the protection of the parts of the working surface that work under the influence of high shock loads from the grinding bodies, along the entire length of the support bar, with the simultaneous formation by the lining plates of the relief of the lining of the inner surface of the drum to ensure lifting

From the grinding bodies and the material to be ground to the required height (along the circumference of the drum) with the subsequent fall of the grinding bodies from above onto the layer of the material to be ground, located on the lower lining plates to increase the grinding efficiency while maintaining the integrity of the material of the plate base. At the same time, such relief excludes the throwing of grinding bodies on the back of the working surface of the lining plates, which prevents their premature wear and extends the service life.

The protrusion formed by the longitudinal edge of one of the inserts acts as a lifter during operation on mills and gradually wears down the height of the insert, which is vulcanized in the middle part of the working surface of the base plate. According to one embodiment of the protrusion-forming insert, it has an outer face whose width B is determined by the ratio specified below. The location of the insert, which forms a protrusion, with an inclination relative to the vertical axis of the cross-section of the base, makes it possible to achieve the fact that with the gradual wear of this insert under the action of grinding bodies and material, the outer face of the insert increases, which perceives the main impact load, which helps to increase the duration of the function performed by the insert lifter and its working condition. At the same time, the grinding material and grinding bodies, rolling over the working surface of the lining plate, fall on the inserts vulcanized into an inclined surface with an inclination relative to the vertical axis of the base section in the opposite direction from the inclination of the insert, which forms a protrusion. As a result, in the process of grinding, they achieve preservation of the working condition of the elastomeric material of the base and increase the efficiency of using the entire working surface of the lining board.

According to one preferred embodiment of the lining plate, according to a useful model, the vertical axis of the section of the insert forming the protrusion can be located at an angle "is within 20...35"7" relative to the vertical axis of the section of the base. Thus, the displacement of the insert from the vertical axis of the cross-section of the base towards the back of the base is achieved, which allows to reduce the area of the surface of the elastomeric material located between the insert and the rear edge of the base, and thus to reduce the rate of destruction of the indicated surface of the elastomeric material and increase the reliability of the lining slabs

According to one more of the preferred options for the lining plate, according to a useful model, the inclined surface can be located at an angle of VD to the horizontal axis of the base section within 8...307, which allows creating a concavity along the entire length of the plate along with 60 with a surface of of elastomeric material located between the insert and the rear edge of the base, the adjacent lining plate and thereby increase the maximum possible height of the grinding bodies and grinding material on the inner surface of the drum of the mill and improve the grinding efficiency.

According to another preferred option for the lining plate, according to a useful model, additional inserts can be vulcanized into the inclined surface, which have a higher wear resistance than the elastomeric material of the base and protrude from the inclined surface, which increases the protection of the front part of the lining plate when crushing objects fall on it bodies and grinding material from the height of their rise and protects against premature wear.

In this case, inserts vulcanized into an inclined surface can be arranged with a step T, which is T-BxK, where B is the width of the outer face of the insert, K is a coefficient that is within 1...2, which allows you to reduce the total volume the material of the inserts and the weight of the plate while maintaining the effectiveness of protecting the surface where the inserts are installed, as well as placing the inserts with the maximum effectiveness of protecting the inclined surface depending on the size of the grinding bodies, etc.

At the same time, the distance A at which the inserts protrude from the inclined surface can be determined by the ratio A-рхКи, where B is the width of the outer face of the insert, Ki is a coefficient in the range of 0.01...0.5, which allows you to choose optimal parameters for the use of inserts that strengthen the inclined surface, depending on the technological parameters of the mill operation, on the internal diameter of the mill drum and on the size of the grinding bodies, for example, the diameter of the ball loading used in the operation of the mill.

According to another of the preferred options for the lining plate, according to a useful model, the insert that forms the protrusion may contain an external face, the width of which is determined by the ratio B-OxK», where O is the diameter of the mill drum, and K» is the coefficient, which is in the range of 0.01...0.03, which allows you to provide the necessary area for the lifter to perform its functions and at the same time to maximally extend the protection of this part of the working surface when the protrusion is worn and the height of the insert is reduced.

According to another preferred embodiment of the lining board, according to a useful model, the height of the insert that forms the protrusion can be determined by the ratio

Ni-KzhO, where O is the diameter of the mill drum, Kz is a coefficient in the range of 0.025...0.05,

Which, compatible with the previous feature, provides the functions of a lifter for the protrusion and extends its service life with gradual wear.

According to one more of the preferred options for performing the lining plate, according to a useful model, the height E of the location of the longitudinal edge of the insert, which forms a protrusion, relative to the working surface of the base can be determined by the ratio E-OxKay, where O is the diameter of the mill drum, K--0.008. ..0.02, which allows you to further improve the lifting of the grinding material and the grinding bodies to the required height to improve the grinding of the material.

According to another preferred embodiment of the lining plate, according to a useful model, the insert, which forms a protrusion, can be located with an offset relative to the vertical axis of the cross-section of the base by a distance C, which is determined by the ratio

СхК5, where I is the width of the base, K» is a coefficient in the range of 0.05...0.1, which allows you to reduce the surface area of the part of the plate made of elastomer material located behind the protrusion and thereby extend the service life slabs

According to another preferred option for the lining plate, according to a useful model, all vulcanized inserts can have a rectangular cross-section and a length equal to the length of the plate, which simplifies the manufacture of elements of protection of the working surface and increases the reliability of protection along the entire length of the bar of the inserts.

According to another of the preferred options for the lining plate, according to a useful model, as a means of connecting the plate with the surface of the drum of the mill, an armature with grooves for installing fasteners, vulcanized into the surface opposite to the working surface, can be used as a means of connecting the plate to the surface of the mill drum, which makes it possible to increase the reliability of fastening the lining to surfaces of the drum of the mill.

In this case, the total height H of the plate from the extreme point of the reinforcement to the longitudinal edge of the insert, which forms a protrusion, can be determined by the ratio H-KeхО, where О is the diameter of the mill drum, Ке is a coefficient within 0.03...0 ,08, which allows the use of the declared lining plates in drum mills of the first stage of grinding of various standard sizes.

The useful model is illustrated by the following example of the lining plate of the drum mill and the method of its use, as well as by the drawings on which it is indicated: - in Fig. 1 - a top view of the lining plate; because - in fig. 2 - cross section A-A in fig. 1;

- in fig. C - cross-section of the drum of the mill with lining plates in working condition, - in fig. 4 - axonometric view of the lining plate.

The following designations are used in the figures indicated above: 1 - base, 2 - working surface of the base,

C, 4 - inserts, 5 - lower surface of the base, b - armature, 7 - grooves of the armature, 8 - inclined surface, 9 - drum of the mill, 10 - protrusion, 11 - longitudinal edge of the insert (4), 12 - outer face of the insert ( 4), 13 - grinding bodies.

The provided examples of the execution of the lining plate and its use and drawings do not limit other possible execution options, according to the useful model, but only explain its essence.

The lining plate of the drum mill contains a base (1) in the form of a beam made of an elastomeric material, for example, rubber. The base (1) has a working surface (2), equipped with vulcanized inserts (3) and (4), and the opposite lower surface (5), equipped with means of connection with the surface of the drum of the mill. Inserts (3) and (4) are made in the form of a beam, the longitudinal axis of which coincides with the direction of the longitudinal axis of the base (1). The vulcanized inserts (3) and (4) are made of a material with higher wear resistance than the elastomeric material of the base (1), for example, metal.

As a means of connecting the plate with the surface of the mill, fittings (b) with grooves (7) were used for installing fasteners. The armature (6) is vulcanized into the surface (5), opposite to the working surface (2).

Z The working surface (2) contains an inclined surface (8). The slope of the inclined surface (8) is made in the direction opposite to the movement of the mill drum (9). The angle of inclination B of the inclined surface to the horizontal axis of the cross-section of the base is within 8...307, for example 257. Inserts (3) protruding from this surface (8) are vulcanized into the inclined surface (8). The inserts (3), vulcanized into the inclined surface (8), are located with a step T - the distance between the same points of the adjacent inserts (Fig. 2). Step T is determined by the T-OxK ratio, where B is the width of the outer face of the insert, and K is a coefficient within 1...2. For example, the step T is 40 mm with the width of the outer face of the insert 5-40 mm and K-1 or the step T is 80 mm with the width of the outer face of the insert 0-40 mm and K-2. The distance A, at which the inserts (3) protrude from the inclined surface, is determined by the ratio A-rhKi, where B is the width of the outer face of the insert, and Ki is a coefficient in the range of 0.01...0.5. For example, the distance A is 10 mm when the width of the outer face of the insert is 6-40 mm and K-0.25.

The working surface (2) also contains a protrusion (10) formed by the longitudinal edge (11) of the insert (4). The vertical axis of the cross-section of the insert (4) is located at an angle "within 20...35" relative to the vertical axis of the cross-section of the base 0-0, for example 30". Thus, the insert (4) forming a protrusion (10) and the insert (3) protruding from the inclined surface (8) are located with an inclination relative to the vertical axis of the cross-section of the base O-O and are directed in opposite directions relative to the vertical axis of the cross-section bases 0-0.

The insert (4) contains the outer face (12). The width В of the outer face (12) is determined by the ratio В-ОхК», where О is the diameter of the drum of the mill (9), and К»о is a coefficient in the range of 0.01...0.03. For example, the width B of the outer face (12) is 80 mm for a drum diameter of 0-6 100 mm and Ko-0.013. Height H;: inserts (4) is determined by the ratio N'i-

KzhO, where 0 is the diameter of the mill drum, and Kz is a coefficient in the range of 0.025...0.05.

For example, the height of No: inserts (4) is 152.5 mm with a drum diameter of 0-6 100 mm and

Ka-0.025. The height E of the location of the longitudinal rib (11) of the insert (4), which forms a protrusion (10), relative to the working surface (2) of the base (1) is determined by the ratio E-:OxKa, where O is the diameter of the mill drum, and K--0.008. ..0.02. For example, the height of E is 49 mm with a drum diameter of 0-6 100 mm and KA-0.008. The insert (4) is located with an offset relative to the vertical axis of the cross-section of the base by a distance C, which is determined by the ratio C-хК5, where Y is the width of the base, and K5 is a coefficient that is within 0.05...0.1. For example, the distance C is 60 23 mm when the base width I is 460 mm and K5 is 0.05.

All vulcanized inserts (3) and (4) have a rectangular cross-section and a length Ii equal to the length of the plate 12. The total height H of the plate from the extreme point of the reinforcement (6) to the longitudinal rib (11) of the insert (4), which forms a protrusion (10) ), is determined by the H-KeхO ratio, where O is the diameter of the mill drum, and Kee is a coefficient in the range of 0.03...0.08. Example,

B total height H is 183 mm with a drum diameter of 0-6 100 mm and K.-0.03.

The K.:-Kie coefficients specified above, as well as the ratio and angles of the structural elements, were determined during the tests of the declared lining plate and depend on the technological parameters of the mill, on the internal diameter О of the mill drum (9) and on the sizes of the grinding bodies used, such as the diameter of the ball bearing.

As shown in fig. 3, the lining plates assembled on the inner surface of the mill drum (9) form a drum lining with a continuous undulating working surface formed with protrusions (10) alternating with depressions created by inclined surfaces (8).

Such drum lining is used as follows.

When the mill drum (9) rotates, the grinding material, for example, ore, and grinding bodies (13), for example, ball loading with a diameter of 80...120 mm, interact with the wavy working surface (2) of the lining plates. At the same time, the grinding material and grinding bodies (13) are caught by the insert (4), which is vulcanized in the middle part of the working surface (2) of the lining plate and acts as a lifter, and are lifted by the insert (4) to the required height for further falling onto the layer of the material being crushed is located on the lower lining plates, where the material is crushed. The location of the insert (4) at an angle a from the vertical axis of the plate and its displacement from the vertical axis О-О of the section of the base (1) towards the rear part of the plate allows to reduce the area of the part of the base (1) made of elastomer material located behind the insert, and thereby extend its service life. The above-mentioned intervals of the values of the angle a and the distance E are determined as optimal in order to ensure the lifting of the grinding material and the grinding bodies (13) to the required height. During the operation of the lining, the part of the insert (4), which protrudes from the working surface (2) and forms a protrusion (10), wears out under the impact of the shock load from the material being crushed and the crushing bodies (13). When the protrusion (10) wears, the area of its outer surface increases due to the inclination of the insert (4) at an angle a and its displacement by

From the distance C towards the back of the base (1), which extends the protection period of this part of the work surface (2), the working condition of the lining plate and the effective use of the maximum part of the work surface (2).

During grinding, the front inclined part of the working surface (2) is also subjected to intensive wear. Thanks to the vulcanized inserts (3) made of wear-resistant metal, this part of the base (1) is protected from premature wear.

Thus, the useful model makes it possible to achieve an increase in the reliability and efficiency of the lining plate in drum mills of the first stage of grinding, in particular with such grinding bodies as balls with a diameter of 80-120 mm.

Claims (14)

40 USEFUL MODEL FORMULA 1. Lining plate of a drum mill, containing a base in the form of a bar made of elastomeric material with a working surface equipped with vulcanized inserts that have wear resistance higher than the elastomeric material of the base, and a surface opposite to it, 45 equipped with means of connection with the surface of the drum of the mill, which differs in that that the inserts are made in the form of a bar, the longitudinal axis of which coincides with the direction of the longitudinal axis of the base, and the working surface contains at least one protrusion and an inclined surface, and the protrusion is formed by the longitudinal edge of one of the inserts, and the slope of the inclined surface is made in the direction opposite to the movement of the mill drum, while the other insert is vulcanized into the 50 inclined surface so that it protrudes from this surface, and the insert forming the protrusion and the insert protruding from the inclined surface are located with an inclination relative to the vertical axis of the cross-section of the base and are directed in opposite directions relative to the vertical axis of the section foundations. 2. Lining plate according to claim 1, which is characterized by the fact that the vertical axis of the cross-section of the insert, which forms a protrusion, is located at an angle of 207...357 relative to the vertical axis 55 of the cross-section of the base. 3. Lining plate according to claim 1, which is characterized by the fact that the inclined surface is located at an angle B to the horizontal axis of the cross-section of the base within 87...30"7. 4. Lining plate according to claim 1, which differs in that additional inserts are vulcanized into the inclined surface, which have a higher wear resistance than the elastomeric material of the base and because they protrude from the inclined surface. 5. Lining plate according to claim 4, which differs in that the inserts vulcanized into an inclined surface are located with a step T, which is T-OxK, where p is the width of the outer edge of the insert, K is a coefficient within 1. .2. 6. Lining plate according to claim 4, which is characterized by the fact that the inserts, vulcanized into an inclined surface, are located in a row and connected to each other along adjacent faces to form a continuous protruding surface. 7. Lining plate according to claim 4, which differs in that the distance A, at which the inserts protrude from the inclined surface, is determined by the ratio A-OxKi, where p is the width of the outer face of the insert, and K; - coefficient in the range of 0.01...0.5. 8. Lining plate according to claim 1, which is characterized by the fact that the insert, which forms a protrusion, contains an outer face, the width of which is determined by the ratio B-OxK", where O is the diameter of the drum of the mill, K" is a coefficient that is within 0 .01...0.03. 9. Lining plate according to claim 1, which differs in that the height of the insert, which forms a protrusion, is determined by the ratio Ni-KzhO, where O is the diameter of the drum of the mill, Kz is a coefficient in the range of 0.025...0.05. 10. Lining plate according to claim 1, which differs in that the height E of the location of the longitudinal edge of the insert, which forms a protrusion, relative to the working surface of the base is determined by the ratio E-OxKuy, where O is the diameter of the mill drum, K.--0.008...0 ,02. 11. Lining plate according to claim 1, which is characterized by the fact that the insert, which forms a protrusion, is located with an offset relative to the vertical axis of the cross section of the base by a distance C, which is determined by the ratio C-th xK»5, where Y is the width of the base, K5 is the coefficient , which is within 0.05...0.1. 12. Lining plate according to claim 1, which is characterized by the fact that all vulcanized inserts have a rectangular cross-section and a length equal to the length of the plate. 13. Lining plate according to claim 1, which differs in that as a means of connecting the plate with the surface of the drum of the mill, an armature with grooves for installation of fastening elements, vulcanized into the surface opposite to the working surface, is used. 14. Lining plate according to claim 12, which differs in that the total height H of the plate from the extreme point of the reinforcement to the longitudinal edge of the insert, which forms a protrusion, is determined by the Ko) ratio Ne-KekhO, where O is the diameter of the mill drum, Kee is a coefficient that is within 0.03...0.08. and TKA KOVOK KYA KV I am not yet 3 Fig. 1 and more Mn med ki Z sushi a I s shi Esh SHO i ke her GI u GKNN: I ŽI i M o wn what SI Y I V i Ka M z ped, vana Kont kash i i i h i v i In her and 7th: aa; o i Y ka in ; How is it? and still a od KE NYA sh A, Ha feyi gene I OK Ky eh koor ssh Ж ov still once again roya y che Koh y KK zh MO uh Z ; Her a a sa i z Zno sovy wa v i V Y V i SOS AS Ok B t da I Kasha KO zhiyhy som nn i tu B that or ZATE KK MK nn NIC. si y Oka MY Se from K r; ko : V OK ozh sche iya Z Her and Her N me E ia noya Fig. 2 Shu por in V a yah Kg M She root schu Y sov and DS" zno ee in Y and MK I Mi ! 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