The present invention relates to a wear tip holder for holding a wear tip adjacent to an outflow opening of a vertical rotor wall of a rotor of a VSI crusher. The invention also relates to a method of reducing the wear rate of such a rotor.
Vertical shaft impact crushers (VSI crushers) are used in many applications for crushing hard material, such as rocks, ore etc. A VSI crusher comprises a housing and a horizontal rotor located inside the housing. WO 2008133568 (A1) discloses an example of a rotor of a VSI crusher. Material that is to be crushed is vertically fed into the rotor, and with the aid of centrifugal force the rotating rotor ejects the material against the inner wall of the housing. On impact with the wall of the housing the material is crushed to a desired size. The housing wall could be provided with anvils or have a bed of retained material against which the accelerated material is crushed.
The rotor of a VSI crusher usually has a horizontal upper disc and a horizontal lower disc. The upper disc has an aperture for feeding material to be crushed into the rotor, such that the material lands on the lower disc. The upper and lower discs are interconnected by a vertical rotor wall, which guides the material to material outflow openings about the circumference of the rotor. The vertical rotor wall of WO 2008133568 is provided with a number of wear tips adjacent to the outflow openings in the rotor wall, to protect the rotor wall from wear caused by the material leaving the rotor at a high speed. The wear tips are provided with air flow directing ridges for reducing the wear of the wear tips and the rotor wall.
When the wear tips have become worn out they must be replaced. Replacement of the wear parts requires the VSI crusher to be shut down for a considerable time for maintenance.
It is an object of the present invention to solve, or at least mitigate, parts or all of the above mentioned problems. To this end, there is provided a wear tip holder for holding a wear tip adjacent to an outflow opening of a vertical rotor wall of a rotor of a VSI crusher, said wear tip holder comprising a mounting plate for mounting the wear tip holder to said rotor wall; and a wear body, connected to said mounting plate, the wear body being provided with an elongate wear tip recess for holding the wear tip, and the mounting plate having a mounting face for facing the rotor wall to which it is to be mounted; and, opposite the mounting face, a wear face for facing the interior of the rotor, wherein the wear tip holder comprises at least one material retention groove extending along the wear tip recess at a position upstream, as seen in a direction of an intended flow of material to be crushed, of the wear tip recess, the material retention groove having an upstream groove wall and a downstream groove wall, said downstream groove wall forming an acute angle with the wear face for retaining material to be crushed. When such a wear tip holder is used in a VSI crusher, material to be crushed may become trapped in the material retention groove. The trapped material will assist in forming and maintaining a bed of material on the rotor wall and on the wear tip holder, such that the wear of the rotor wall, wear tip holder, and wear tip will be reduced. Thanks to the acute angle, material to be crushed is wedged in the retention groove by the downstream groove wall. Thereby, the acute angle reduces the risk that the bed of material slides off the rotor wall and exposes the rotor wall/wear tip holder/wear tip to wear. As a consequence, an increase of the service interval of the crusher may be allowed.
According to an embodiment, said acute angle is sharper than 70°. Such a design increases the material trapping and retention efficiency of the material retention groove.
According to an embodiment, said at least one material retention groove comprises a material retention groove formed in the wear body between the mounting plate and the wear tip recess. Due to the adjacency of the material retention groove to the wear tip recess, the bed of material may more efficiently protect the wear tip from wear.
According to an embodiment, the material retention groove is located at a shortest distance from the wear tip recess of less than 50 mm.
According to an embodiment, said at least one material retention groove comprises a material retention groove formed in the wear face of the mounting plate. The material retention groove formed in the wear face of the mounting plate may also be combined with a material retention groove formed in the wear body between the mounting plate and the wear tip recess.
According to an embodiment, the material retention groove extends along at least ⅓ of the length of the wear tip recess. Such a design increases the material trapping and retention efficiency of the material retention groove.
According to an embodiment, the upstream groove wall slopes towards a plane defined by the mounting face. Thereby, the material retention groove will be at least partly countersunk into the wear tip holder, such that the material retention groove is protected from excessive wear.
According to an embodiment, the upstream groove wall slopes from a surface essentially flush with the wear face. Such a design increases the material trapping efficiency of the material retention groove.
According to an embodiment, the upstream groove wall forms an angle with the wear face of less than 45°. Such a design increases the material trapping efficiency of the material retention groove.
According to an embodiment, a surface portion of the wear body located between the material retention groove and the wear tip recess is essentially flush with the wear face. Such a design concentrates the wear to the wear-resistant wear tip, thereby increasing the life expectancy of the wear tip holder.
According to an embodiment, the downstream groove wall has a width of less than 70% of the width of the upstream groove wall. Such a design provides the wear tip holder with an appropriate balance between durability and material trapping/retention ability.
According to another aspect of the invention, parts or all of the above mentioned problems are solved, or at least mitigated, by a method of decreasing the wear rate of a rotor of a VSI crusher, the rotor comprising a wear tip holder holding a wear tip onto a rotor wall, the wear tip holder comprising a mounting plate having a mounting face facing the rotor wall to which it is mounted; and, opposite the mounting face, a wear face facing the interior of the rotor, the method comprising trapping material to be crushed in a material retention groove extending along the wear tip at a position upstream, as seen in a direction of an intended flow of material to be crushed, of the wear tip, the material retention groove having an upstream groove wall and a downstream groove wall, said downstream groove wall forming an acute angle with the wear face of the mounting plate. Using such a method, material to be crushed is wedged upstream of the wear tip. Thereby, the risk is reduced that the bed of material slides off the rotor wall and exposes the rotor wall/wear tip holder/wear tip to wear. As a consequence, an increase of the service interval of the crusher may be allowed.
The above, as well as additional objects, features and advantages of the present invention, will be better understood through the following illustrative and non-limiting detailed description of preferred embodiments of the present invention, with reference to the appended drawings, where the same reference numerals will be used for similar elements, wherein:
a is a three-dimensional view of a wear tip holder according to a first embodiment;
b is a further three-dimensional view of the wear tip holder of
a is a diagrammatic view in section, as seen from above, of a detail of the wear tip holder of
b is a diagrammatic view corresponding to the view of
is a three-dimensional view of a wear tip holder according to a second embodiment.
As is shown in
The upper and lower discs 12, 14 are separated by and held together by a vertical rotor wall 24, which is separated into three separate wall segments 26. Gaps between the wall segments 26 define outflow openings 28, through which material may be ejected against a housing wall (not shown). At each outflow opening 28 the respective wall segment 26 is protected from wear by a wear tip 30 located at the leading edge of the respective wall segment 26. Each wear tip 30 is mounted to the respective wall segment 26 by means of a wear tip holder 32, which will be described further below. Each wall segment 26 is also provided with a respective pair 34 of cavity wear plates, which protect the rotor 10 and in particular the wear tips 30 from material rebounding from the housing wall and from ejected material and airborne fine dust spinning around the rotor 10.
a and 4b illustrate a first embodiment of a wear tip holder 32. The wear tip holder 32 has a wear body 40 with an elongate wear tip recess 42, in which the wear tip 30 (
The wear tip recess 42 and wear tip 30 (
A mounting plate 44, which is a flat, rectangular plate for mounting the wear tip holder 32 to a vertical wall segment 26 of the rotor 10, is attached to the wear body 40. Two threaded bars 46, 48 (
When the wear tip holder 32 is in use, material to be crushed flows along the path illustrated by the arrow A of
A material retention groove 58 runs along the wear body 40, i.e., when the wear tip holder 32 is mounted in a VSI crusher, in an essentially vertical direction. It runs along the entire length of the wear body 40, such that the length of the material retention groove 58 corresponds to the length L of the wear tip recess 42. The material retention groove 58 is located between the wear tip recess 42 and the wear face 54 of the mounting plate 44, i.e., referring to the flow direction A, upstream of the wear tip recess 42. The material retention groove 58 serves for retaining material to be crushed, such that a bed 36 of material may easier be built up on the wear tip holder 32 and the rotor wall 24. In the embodiment illustrated in
The top view of
The magnified cross-section of
The downstream groove wall 62 forms an angle α with the wear face 54 of the mounting plate 44, said angle α being acute, i.e. sharper than 90°, such that the downstream groove wall 62 will guide parts of the material to be crushed, flowing across the wear face 54, into the material retention groove 58. Thereby, as material flows along the path A (
In the illustrated embodiment, the upstream groove wall 60 has a width W1 which is larger than the width W2 of the downstream groove wall. The upstream and downstream groove walls 60, 62 meet at a groove bottom 63, such that the upstream and downstream groove walls 60, 62 together form a material retention groove 58 which is essentially V-shaped.
A surface portion 64 of the wear body 40, located between the material retention groove 58 and the wear tip recess 42, is essentially flush with the wear face 54, so as to minimize the wear of the wear body 40 upstream of the wear tip recess 42; instead, wear is concentrated to the wear tip 30 (
b illustrates the function of the material retention groove 58 when the crusher is operated with material to be crushed is present in the rotor 10. The figure illustrates how pieces 70 of material to be crushed, e.g. pieces of rock, have, by operating the crusher, been trapped in the material retention groove 58, and thanks to the centrifugal force acting on the pieces 70 of material, the pieces 70 may be stuck firmly to the material retention groove 58 for as long as the crusher is operated. The pieces 70 of material form a rough, structured surface 72 facing the interior of the rotor 10, thereby assisting in preventing the bed 36 of material from sliding across the wear tip 30 and leaving the rotor 10.
Furthermore, the adjacency of the material retention groove 58 to the wear tip recess 42 assists in extending the bed 36 of material very close to the wear tip 30, thereby efficiently protecting also the wear tip 30 (
The upstream groove walls of the material retention groove segments 159a-b also form a respective angle β (again, c.f.
The invention has mainly been described above with reference to a few embodiments. However, as is readily appreciated by a person skilled in the art, other embodiments than the ones disclosed above are equally possible within the scope of the invention, as defined by the appended patent claims.
For example, also a downstream groove wall which has, as seen in a cross-section corresponding to the view of e.g.
Moreover, the invention is not limited to any particular number of material retention grooves in a single wear tip holder, or to any particular size or shape of the material retention groove(s) other than those limitations imposed by the features of the appended claims. Many different groove sizes and groove shapes are suitable for retaining, when the wear tip holder is in use, material to be crushed. All such embodiments fall within the scope of the appended claims.
Number | Date | Country | Kind |
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11182565.9 | Sep 2011 | EP | regional |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2012/066745 | 8/29/2012 | WO | 00 | 3/21/2014 |