Wear part, processing apparatus and processing plant for mineral material

Abstract

A wear part for a mineral material processing apparatus includes an outer wear surface which includes an initial phase wear surface to be put in crushing contact with an opposite wear surface, and an end phase wear surface to be taken vertically into use in the crushing process from under the initial wear surface when the wear is progressing. The wear part includes an end phase wear surface with a protrusion to be put in use when the wear of the outer wear surface is progressing. As a result of the wear part including the protrusion working life of the wear part can be prolonged. A mineral material processing apparatus and a mineral material processing plant.

Claims

1. An inner wear part having a conical shape and centered along a vertical rotation axis and configured for use with a mineral material processing apparatus to create a crushing chamber with an opposite outer wear part, the inner wear part, comprising: an outer wear surface which comprises an initial phase wear surface and an end phase wear surface located below the initial phase wear surface, wherein the initial phase wear surface is configured to be in crushing contact with the outer wear part during initial use and the end phase wear surface is configured to be in crushing contact with the outer wear part when wear of the inner wear part is progressing; the end phase wear surface comprising an upper region joined to the initial phase wear surface; the end phase wear surface comprising a lower region that comprises a protrusion that has a horizontal upper end surface, wherein the outer wear surface is formed to have surface portions next to the upper end portion both upwards and downwards from the upper end portion which the surface portions are most close to vertical relative to the conical shape; and the protrusion extends to a lower end of the wear part.

2. The wear part according to claim 1, wherein the protrusion is configured to limit flow-through of material between the outer wear surface of the wear part and the outer wear part when wear is progressing.

3. The wear part according to claim 1, wherein the upper end of the protrusion is directed along a horizontal plane.

4. The wear part according to claim 1, wherein the upper end of the protrusion is inclined in relation to a horizontal plane.

5. The wear part according to claim 1, wherein the wear part comprises two or more successive protrusions.

6. The wear part according to claim 5, wherein the upper end of the protrusion is directed along a horizontal plane.

7. The wear part according to claim 5, wherein the upper end of the protrusion is inclined in relation to a horizontal plane.

8. The wear part according to claim 5, wherein the wear part comprises two or more successive protrusions.

9. The wear part according to claim 5, wherein the end phase wear surface with the protrusion is formed of a material which is more wear resistant than a base material of the wear part.

10. The wear part according to claim 5, wherein the wear part comprises a separate skirt part vertically under the initial phase wear surface, which skirt part comprises the end phase wear surface with the protrusion.

11. The wear part according to claim 5, wherein the radius of the crushing surface from the rotation axis of the wear part is continuously increasing when measuring from the top edge part to the bottom edge part.

12. The wear part according to claim 1, wherein the end phase wear surface with the protrusion is formed of a material which is more wear resistant than a base material of the wear part.

13. The wear part according to claim 12, wherein the end phase wear surface with the protrusion is formed of a material which is more wear resistant than a base material of the wear part.

14. The wear part according to claim 12, wherein the wear part comprises a separate skirt part vertically under the initial phase wear surface, which skirt part comprises the end phase wear surface with the protrusion.

15. The wear part according to claim 1, wherein the wear part comprises a separate skirt part vertically under the initial phase wear surface, which skirt part comprises the end phase wear surface with the protrusion.

16. The wear part according to claim 1, wherein a radius of the crushing surface from the vertical rotation axis of the inner wear part is continuously increasing when measured from a top edge part to a bottom edge part.

17. The wear part according to claim 1, wherein the wear part is configured to be supported by a support cone and the protrusion resides entirely at a radius that exceeds greatest radius of the support cone.

18. The wear part according to claim 1, wherein the outer wear surface is formed to have a substantially vertical part next to said upper end upwards from the upper end.

19. The wear part according to claim 1, wherein the outer wear surface is formed to have a substantially vertical part next to said upper end downwards from the upper end.

20. The wear part according to claim 1, wherein the protrusion has a height that is seven times the length of the wear part.

Description

DESCRIPTION OF THE DRAWINGS

(1) The invention will be described in more detail with reference to the accompanying principled figures, in which:

(2) FIG. 1a shows a profile view of a crusher chamber at the beginning of the working life of the wear part,

(3) FIG. 1b shows the profile view according to FIG. 1a at the end of the working life,

(4) FIG. 2a shows a profile view of a wear part according to the invention at the beginning of the working life,

(5) FIG. 2b shows the profile view of the wear part according to FIG. 2a during the working life,

(6) FIG. 2c shows the profile view of the wear part according to FIG. 2a at the end of the working life,

(7) FIG. 3a shows measuring data of the operation of the crushing chamber according to FIGS. 1a-1b,

(8) FIG. 3b shows measuring data of the operation of the crushing chamber according to FIGS. 2a-2c,

(9) FIG. 4a shows a cone crusher according to the invention,

(10) FIG. 4b shows a gyratory crusher according to the invention,

(11) FIG. 5 shows a crushing plant according to the invention.

(12) For the sake of clarity only such details are shown in the figures which are necessary for understanding the invention. Structures and details which are not necessary for understanding the invention but are self-evident for a skilled person are ignored in the figure in order to highlight the characteristics of the invention.

DETAILED DESCRIPTION OF PREFERABLE EMBODIMENTS

(13) In the following description, like numbers denote like elements. It should be appreciated that the illustrated drawings are not entirely in scale, and that the drawings mainly serve the purpose of illustrating embodiments of the invention.

(14) A crusher in this description means a processing unit of cone and gyratory type which is suitable for material processing.

(15) FIG. 1a shows a profile view of a crusher chamber profile according to prior art unworn before crushing. A crushing surface 107 of an outer crushing blade 102 and a crushing surface 106 of an inner crushing blade 101 are forming a crushing chamber where crushing of material is taking place when the inner crushing blade is put in an eccentric movement in relation to the outer crushing blade.

(16) The crushing surfaces of the inner 101 and outer 102 crushing blades are forming a nip angle/a jaw angle due to which crushing efficiency of the crusher is maintained on an acceptable level until an end of working life of the wear part. The angle is illustrated with contact points between circles 103 and 104 and crushing surfaces 106 and 107. As can be seen in the figures, in an initial situation the jaw angle increases substantially when moving from a bottom part to an upper part of the crushing chamber.

(17) FIG. 1b shows a profile view of FIG. 1a in worn state. As can be seen in the figure, the jaw angle between the crushing blades 101 and 102 is decreased which is illustrated by the contact points between the circles 103 and 104 and the crushing surfaces. Tangents formed in said contact points are substantially more parallel than in the situation of FIG. 1a.

(18) FIG. 2a shows a crusher chamber profile according to an embodiment of the invention unworn before initiating the crushing process. An inner crushing blade 201 and an outer crushing blade 202 are shown in the figure. The inner crushing blade 201 comprises a step-like protrusion 250 according to the invention in a bottom part of the crushing surface which is arranged to limit flow of material in the crushing chamber. According to FIG. 2a, the protrusion 250 comprises a step-like surface 251 directed along the horizontal plane, which step-like surface is forming an angle with a crushing surface which is located above. The protrusion may also be inclined in relation to the horizontal plane, in one or another direction. Amount of the angle and depth of the protrusion and distance from a bottom edge of the crushing blade can be chosen according to each embodiment.

(19) A protrusion 250 according to the invention does not affect the efficiency of the crusher at this stage. An efficient region of the crushing chamber profile is limited at its lower part to a minimum gap which is a minimum distance between the inner and outer crushing blades or a setting of the crusher. The crushing chamber profile is, due to the protrusion, designed so that the efficiency of the crusher is maximized for the whole working life of the wear part. The efficiency means capacity of the crusher [ton/h], grain distribution of crushed material and quality of grains. In the embodiment shown in FIG. 2a, one or more additional protrusions 252 and 254 can be included on the crushing surface 106.

(20) FIG. 2b shows the profile of the crushing chamber according to FIG. 2a during the working life. During the crushing process the wear surface of the inner crushing blade is put in crushing contact with the wear surface of the opposite crushing surface. When the crushing process is further proceeding the inner crushing blade is moved in vertical direction in relation to the outer crushing blade, preferably vertically upwards (and/or the upper crushing blade is moved downwards), for compensating the wear. Thus, an end phase wear surface is taken vertically into use from under an initial phase wear surface, when the crushing process is proceeding. The form of the crushing chamber is changing at its upper and bottom portions more parallel, the jaw angle decreases until the end phase wear surface with is put in use when the wear is progressing. In other words, the protrusion 250 according to the invention moves to a crushing surface 106 of the inner crushing blade 201 during the wear of the blades 201 and 202. The jaw angle of the lower part of the crushing chamber starts again to increase, which is illustrated by the increase of the angle between the tangents of contact surfaces between the crushing surfaces 106, 107 and the circle 104 when compared to a corresponding location in FIG. 2a. When the jaw angle increases the lower part of the chamber limits the flow of the material to be crushed out of the chamber. The limitation of the flow causes in the chamber an increase in the density of the material to be crushed wherein a larger portion of a movement, or length of a stroke of the crushing, of a movable crushing blade presses the material. When the material is pressed more, more crushing work is taking place and power intake of the crusher and crushing force are increasing, as can be found in FIG. 3b and its description below.

(21) FIG. 2c shows the crushing chamber profile according to FIG. 2a at the end of the working life. The jaw angle has further been preserved in the bottom portion of the chamber as is shown by the angle between tangents of contact surfaces between the circle 104 and the crushing surfaces 106, 107, which angle so is larger than in the situation of FIG. 1a, Likewise, the efficient crushing work has been preserved as can be seen in FIG. 3b and its description below. The crushing blades are to be changed when an adjustment reserve ends or when the thickness of the blades becomes less than a set minimum limit for them. The efficiency of the crusher has remained on a good level to the end.

(22) FIG. 3a shows measuring data of the operation of the crushing chamber shown in FIGS. 1a-1b. In the figure, as the measuring data have been shown crushing capacity 301, working hours 302, movement 303 of the inner crushing blade for compensating the wear and power 304 intake of the crusher during a period of nine days (T=0, T=T+9),

(23) Initially, at the time point T=0 the crushing blades have a wear shape of FIG. 1a where the crushing surfaces of the inner and outer crushing blade form a jaw angle relative each other which enables maintaining the crushing efficiency. Close 309, 309 to the end of the crushing process, a reduction in the crushing process takes place and also power intake of the crusher has decreased.

(24) FIG. 3b shows measuring data of the operation of the crushing chamber shown in FIGS. 2a-2c. Crushing capacity 301, working hours 302, movement 303 of the inner crushing blade for compensating the wear and the power intake 304 of the crusher have been shown, according to FIG. 3a, as the measuring data (T=0, T=T+30).

(25) In FIG. 3b, a point of time 310, 310 is shown when the protrusion of the inner crushing blade according to the invention moves to the region of the crushing chamber to limit the flow of the material in the crushing chamber. The incident is illustrated by an increase of the power intake 304 of the crusher and by staying of the crushing capacity 301 substantially on the same level the whole final working time 302.

(26) FIG. 4a shows a cone crusher 410 according to the invention comprising an outer crushing blade 202, an inner crushing blade 201, a protrusion 250 in the inner crushing blade, a support cone 411, an eccentric sleeve 412 and a main shaft 413. The crusher comprises additionally a transmission such as a gear 414 and 415, a transmission shaft 416 and a pulley 417.

(27) FIG. 4b shows a gyratory crusher 420 according to the invention comprising an outer crushing blade 202, an inner crushing blade 201, a protrusion 250 in the inner crushing blade, a support cone 421, a main shaft 422, an eccentric sleeve 423, an upper support 424 of the main shaft, a bearing arrangement 425 of the main shaft. The crusher comprises additionally a transmission such as a gear 426 and 427, a transmission shaft 428 and a pulley 429.

(28) FIG. 5 shows a crushing plant 500 according to the invention comprising a frame 501, a track base 502 for enabling an independent movement, a feeder 503 for feeding material to be crushed, a crusher 504 for crushing the material to be fed, a power source 505, 506 and at least one material conveyor 507 for delivering crushed material, for example, to a pile at the second end of the processing plant. The crusher 504 may be, for example, the crusher shown in FIGS. 4a and 4b.

(29) The crushing plant can be implemented also as a so called stationary plant, additionally to what is said above. The track base may be replaced alternatively by legs, runners or wheels.

(30) The wear part according to the invention may be produced preferably directly to its form by casting to a mould wherein the production is simple and cost-effective. The surfaces need not necessarily to be machined at all. Alternatively or additionally, the protrusion may be made to the surface of the crushing blade by removing material, for example, by machining the wear surface such that a portion having a form of the protrusion 250 is forming in the surface of the wear surface. Alternatively or additionally, material may be added to the wear surface, for example, by welding so that the protrusion 250 is forming in the wear surface. The material to be added may be a more wear resistant material than the base material of the wear part. Alternatively or additionally, the protrusion 250 may be made as a separate skirt part under the conical wear part. Then, the skirt forming the protrusion is forming a portion of the end phase wear surface to be put in crushing contact with the opposite crushing blade when the wear is progressing. Alternatively or additionally, the protrusion 250 and, if desired, the wear part under it may be made of a more wear resistant material than the base material of the wear part, for example, by casting the wear part of two different materials. The separate skirt part may be made of a more wear resistant material than the base material of the wear part. When the wear is progressing, the base material wears faster than the material at the location of the protrusion wherein the protrusion according to the invention is formed in the end phase wear surface. The material forming the protrusion 250 which is more wear resistant than the base material is preferably embedded at least partly inside the wear part. The material which is more wear resistant than the base material may be embedded totally inside the wear part under the end phase wear surface.

(31) The foregoing description provides non-limiting examples of some embodiments of the invention. It is clear to a person skilled in the art that the invention is not restricted to details presented, but that the invention can be implemented in other equivalent means.

(32) Some of the features of the above-disclosed embodiments may be used to advantage without the use of other features. As such, the foregoing description shall be considered as merely illustrative of the principles of the invention, and not in limitation thereof. Hence, the scope of the invention is only restricted by the appended patent claims.