This application claims priority on Finnish App. No. FI20215500, filed Apr. 29, 2021, the disclosure of which is incorporated by reference herein.
Not applicable.
The invention relates to a comminution device to comminute fiber material. Especially the invention relates to a blade element for the comminution device to comminute fiber material.
Refiners for refining fiber material and dispersers for dispersing fiber material are comminution devices to comminute fiber material. The material is comminuted between two opposite comminution elements at least one of which is rotating. A blade element applicable with the said comminution devices comprises a refining i.e., a comminution surface to comminute the fiber material, wherein the comminution surface comprises at least one comminution section comprising comminution parts (blade bars) and free spaces (grooves) therebetween, and at least one feed section extending at least partly in a direction of a longitudinal axis of the blade element for feeding fiber material to the at least one comminution section.
A problem with that kind of a blade element is an increased wear rate of especially those comminution parts that lie next to the feed section and first meet the fiber material fed into the feed section. In a rotatable comminution element those comminution parts which wear more are on that side of the comminution section that face in the rotation direction of the rotatable comminution element, and in the stationary comminution element, consequently, wear on that side of the comminution section that faces in the opposite direction relative to the rotation direction of the rotatable comminution element. The increased wear rate of the said comminution parts is caused by a strong turbulent flow of the fiber containing material over the comminution parts lying close to the feed section. This increased wear is especially visible as wear of the comminution part top surfaces and as rounding of edges of the comminution part and decreases an operation efficiency of the blade element.
An object of the present invention is to provide a novel blade element for a comminution device to comminute fiber material, as well as a novel comminution device to comminute fiber material.
The novel blade element has a feed section or area which extends along a side of the blade element and the feed section is wide at the inner edge of the blade element and narrows toward the outer edge of the blade element. The comminution parts or blade bars are arranged at an acute angle to a radial line from the inner edge to the outer edge and the comminution parts or blade bars, are wider as blade bars are arranged closer to the outer edge and there may be free spaces or grooves between bars of a constant width.
The invention is based on the idea of increasing a strength and wear resistance of the blade element close to the feed section of the blade element.
An advantage of the solution is a prolonged operational life of the comminution parts of the blade element next or close to the feed section, whereby satisfactory operational characteristics of the comminution surface of the blade segment may be maintained longer.
In the following the invention will be described in greater detail by means of preferred embodiments with reference to the accompanying drawings.
For the sake of clarity, the figures show some embodiments of the invention in a simplified manner. Like reference numerals identify like elements in the figures.
The comminution device 1 of
The stator 3 comprises one or more stator blade elements 4 comprising comminution parts and free spaces or interstices therebetween. The comminution parts are protrusions that protrude from a substrate of the respective blade element and are arranged to subject a comminution effect to the fiber material to be processed, i.e., to the fiber material to be comminuted. The free spaces adjacent to or between the comminution parts provide flow channels for the flow of the fiber material along the blade element 4. The comminution parts and the free spaces in each one or more stator blade elements 4 form a comminution surface 5 of the respective blade element 4. A complete comminution surface of the stator 3 is formed either of the comminution surface 5 of a single stator blade element 4 extending over the whole circumference of the stator 3 or, more commonly, of the comminution surfaces 5 of two or more blade elements 4 having a form of a blade segment and fastened next to each other in the stator 3 so that the complete comminution surface 5 extending over the whole circumference of the stator 3 is provided. In the latter case the comminution surface 5 of each stator blade segment 4 provides only a part of the complete comminution surface of the stator 3. For the sake of clarity, both the comminution surface of each one or more stator blade elements 4 as well as the complete comminution surface of the stator 3 are herein denoted with the same reference sign 5. Additionally, the same reference sign 4 may be used to denote a segment-like blade element for the stator 3 as well as a single blade element extending over the whole circumference of the stator 3.
The comminution device 1 further comprises a rotatable comminution element 6, i.e., a rotor 6 of the comminution device 1. The rotor 6 comprises a hub 7. The rotor 6 further comprises one or more rotor blade elements 8 supported to the hub 7, each one or more rotor blade elements 8 comprising comminution parts and free spaces or interstices therebetween. The comminution parts and free spaces in each one or more rotor blade elements 8 form a comminution surface 9 of the respective blade element 8. A complete comminution surface of the rotor 6 is formed either of the comminution surface 9 of a single rotor blade element 8 extending over the whole circumference of the rotor 6 or, more commonly, of the comminution surfaces 9 of two or more blade elements 8 having a form of a blade segment and fastened next to each other in the rotor 6 so that the complete comminution surface 9 extending over the whole circumference of the rotor 6 is provided. In the latter case the comminution surface 9 of each rotor blade segment 8 provides only a part of the comminution surface of the rotor 6. For the sake of clarity, both the comminution surface of each one or more rotor blade elements 8 as well as the complete comminution surface of the rotor 6 are herein denoted with the same reference sign 9. Additionally, the same reference sign 8 may be used below to denote a segment-like blade element for the rotor 6 as well as a single blade element extending over the whole circumference of the rotor 6.
The hub 7 of the rotor 6 is connected to a driving motor 10 by a shaft 11 so that the rotor 6 can be rotated relative to the stator 3 in a direction of arrow RD, for instance, the arrow RD thus indicating an intended rotation direction RD of the rotor 6.
The comminution device 1 may also comprise a loading device which, for the sake of clarity, is not shown in
The fiber material to be processed is fed into the comminution device 1 in a form of a fiber pulp being a mixture comprising water and fiber material, typically having a consistency of 3-40% via a feed channel 13 in a manner shown by arrow F. The fiber material fed into the comminution device 1 passes into the comminution gap 12 through a first end 12′ or a feed end 12′ of the comminution gap 12 having the smaller diameter. In the comminution gap 12 the fiber material is processed while the water contained in the material may vaporize. The already processed, i.e., comminuted, fiber material flows away from the comminution gap 12 through a second end 12″ or a discharge end 12″ of the comminution gap 12 having a larger diameter into a discharge chamber 14. From the discharge chamber 14 the processed material is removed via a discharge channel 15 from the comminution device 1, as schematically shown by arrow D.
It is emphasized that in addition to the conical comminution devices the blade element of the solution described herein is applicable to disc-type and cylindrical-type comminution devices and to comminution devices comprising both a conical portion and a disc portion, as well.
According to an embodiment the comminution device 1 is a refiner for refining fiber material, whereby the fiber material may be a virgin fiber material or recycled fiber material. In refining a refining effect is subjected to the fiber material to be processed for affecting on fiber properties of the fiber material. When the comminution device 1 is a refiner, the comminution elements 3, 6, i.e., the stator 3 and the rotor 6, are implemented as refining elements of the refiner, and the comminution surfaces 5, 9 of the comminution elements 3, 6 are implemented as refining surfaces of the refining elements and the refining surfaces of the blade elements in the refining elements. The refining surfaces of the refining elements/blade elements comprise blade bars and blade grooves therebetween. The blade bars form in the refining surface the comminution parts arranged to subject a refining effect to the fiber material to be processed. The blade bars are typically longitudinal ridges with straight, curved or in otherwise shaped substantially continuous structure in their longitudinal direction, and the length of each blade bar is typically substantially greater than its width. The blade grooves are free spaces or interstices remaining between the blade bars for providing between the blade bars flow channels for the flow of the fiber material along the refining surfaces. The shape of the blade groove in its longitudinal direction follows the longitudinal structure or shape of the adjacent blade bars. The length of each blade groove is therefore also typically substantially greater than its width.
The blade segment 4, 8 further comprises an outer end edge 17 or a second end edge 17 or a discharge end edge 17 to be directed toward the second end 12″ of the refiner, i.e., toward the end of the stator 3 or rotor 6 having the larger diameter. The refined fiber material is discharged from the refining surface 5, 9 over the second end edge 17.
A longitudinal direction of the blade segment 4, 8 or a longitudinal axis of the blade segment 4, 8 extends between the inner end edge 16 and the outer end edge 17 of the blade segment 4, 8. The longitudinal direction or the longitudinal axis of the blade segment 4, 8 is denoted schematically in
The blade segment 4, 8 further comprises a first side edge 18 or a leading side edge 18 extending from the inner end edge 16 of the blade segment 4, 8 up to the outer end edge 17 of the blade segment 4, 8. The first side edge 18 is the edge of the blade segment 4, 8 that first meets the edge of a counter blade segment in an oppositely positioned refining element (stator/rotor) during the rotation of the rotor 6. So, in the rotor 6 it provides the side edge of the blade segment 8 to be directed to the intended rotation direction RD of the rotor 6 and in the stator 3 it provides the side edge of the blade segment 4 to be directed to the opposite direction relative to the intended rotation direction RD of the rotor 6.
The blade segment 4, 8 further comprises a second side edge 19 or a trailing side edge 19 opposite to the first side edge 18 in the circumferential direction C of the blade segment 4, 8, the second side edge 19 extending from the inner end edge 16 of the blade segment 4, 8 up to the outer end edge 17 of the blade segment 4, 8. The second side edge 19 is thus, in turn, the edge of the blade segment 4, 8 that last meets the edge of a counter blade segment in an oppositely positioned refining element (stator/rotor) during the rotation of the rotor 6. So, in the rotor 6 it provides the side edge of the blade segment 8 to be directed to the opposite direction relative to the intended rotation direction RD of the rotor 6 and in the stator 3 it provides the side edge to be directed to the same direction with the intended rotation direction RD of the rotor 6. In the embodiment of
The leading edge and the trailing edge are easily recognized by a person skilled in the art from the bar/groove pattern and especially bar inclination. The blade bars 20 are always so inclined that they rise from the inner end edge and the leading side edge toward the outer end edge and the trailing side edge to ensure proper flow of the fiber material from the feed edge to the discharge edge.
The blade segment 4, 8 comprises the refining surface 5, 9 comprising blade bars 20 and blade grooves 21, the blade bars 20 and the blade grooves 21 having a first dimension in the circumferential direction C of the blade segment 4, 8 and a second dimension in the longitudinal direction X, or the axial or radial direction X, of the blade segment 4, 8. The first dimension of the blade bars 20 is thus a circumferential dimension of the blade bars 20 along the transverse axis C of the blade segment 4, 8, and the second dimension of the blade bars 20 is thus an axial or radial dimension of the blade bars 20 along the longitudinal axis X of the blade segment 4, 8. A section of the refining surface 5, 9 of the blade segment 4, 8 comprising the blade bars 20 and the blade grooves 21 forms a refining section 22, i.e., a comminution section 22, of the blade segment 4, 8. The section of the refining surface 5, 9 of the blade segment 4, 8 being substantially free from the blade bars 20 forms a feed section 23 of the blade segment 4, 8. The feed section 23 extends from the inner end edge 16 of the blade segment 4, 8 toward an outer end edge 17 of the blade segment 4, 8, and may extend up to the outer end edge 17 as schematically shown in
For resisting excessive wear of the blade bars 20 especially at a position next or close to the feed section 23 so as to prolong an operating life of the blade segment 4, 8 with a satisfactory operational efficiency.
For the sake of clarity, the mutual dimensioning of the blade bars 20, 20a, 20b, 20c, or the change in the first dimension of the blade bars 20, 20a, 20b, 20c from one blade to another blade bar is highly exaggerated in
The embodiment of
The first dimension d20a, d20b, d20c of the respective blade bar 20a, 20b, 20c shown in
The effect of the blade bar configuration disclosed in
In the embodiment of
According to an embodiment of the blade segment 4, 8, the first dimension of the blade bars 20 in the circumferential direction of the blade segment 4, 8 is arranged to increase in the circumferential direction C of the blade segment 4, 8 stepwise toward the feed section 23. At the same longitudinal position in the blade segment 4, 8 the first dimension of the blade bars 20 in a group of neighboring blade bars 20 is larger in the group of neighboring blade bars 20 closer to the feed section 23 in the circumferential direction of the blade segment 4, 8. Herein the term group of neighboring blade bars 20 refers to two or more immediately adjacent blade bars 20 in the circumferential direction C of the blade segments 4, 8.
According to an embodiment, at the same longitudinal or axial or radial X position in the blade segment 4, 8, in the circumferential direction C of the blade segment 4, 8, an increase in the first dimension of the blade bars 20 between the blade bar 20 located to be the closest to the feed section 23 and the blade bar 20 located to be the farthest away from the feed section 23 is 10-80%, preferably 10-50% or 10-30%.
According to an embodiment, at the same longitudinal or axial or radial X position in the blade segment 4, 8, in the circumferential direction C of the blade segment 4, 8, the width of the blade bar 20 located to be the closest to the feed section 23 is 1-10 mm depending on the fiber type, for short fiber pulp typically from 1-5 mm and 3-7 mm for long fiber pulp. As an example, in low consistency 3-6% refining of short fiber pulp, like eucalyptus-containing pulp, in a refiner with steep 10-30-degree blade bar angle AG the actual width of the blade bar 20 closest to the inner end edge and the leading side edge could be like 1.3 mm while the actual width of the blade bar 20 closest to the inner end edge and the trailing edge would be 1.1 mm, the increase of the actual width being around 20%. The respective widths for long-fiber softwood pulp could be from 6 mm closest to the feed section down to 4 mm closest to the opposite edge, the increase being around 50%.
In
Again herein, for the sake of clarity, the mutual dimensioning of the blade bars 20, 20a, 20b, 20c, or the change in the second dimension of the blade bars 20, 20a, 20b, 20c from one blade bar to another blade bar shown is highly exaggerated in
The embodiment of
The second dimension e20a, e20b, e20c of the respective blade bar 20a, 20b, 20c shown in
The effect of the blade bar configuration disclosed in
In the embodiment of
According to an embodiment of the blade segment 4, 8, the second dimension of the blade bars 20 in the longitudinal or axial direction X of the blade segment 4, 8 is arranged to increase in the longitudinal direction X of the blade segment 4, 8 stepwise toward the outer end edge 17 in such a way that at the same circumferential C position in the blade segment 4, 8 the second dimension of the blade bars 20 in a group of neighboring blade bars 20 is larger in the group of neighboring blade bars 20 closer to the outer end edge 17 in the longitudinal direction X of the blade segment 4, 8. Herein the term group of neighboring blade bars 20 refers to two or more immediately adjacent blade bars 20 in the longitudinal direction X of the blade segments 4, 8.
According to an embodiment, at the same circumferential C position in the blade segment 4, 8 in the longitudinal or axial direction X of the blade segment 4, 8, there is an increase in the second dimension of the blade bars 20 located farthest away from the inner end edge 16 is 10-100%, preferably 10-50% compared to the blade bar 20 located closest to the inner end edge 16.
In the embodiment of
According to an embodiment the comminution device 1 is a disperser for dispersing fiber material, whereby the fiber material may be recycled fiber material. In dispersing a dispersing effect is applied to the fiber material to be processed for disintegrating contaminants in the fiber material to diminish negative effects of the contaminants in the further use of the dispersed fiber material or to facilitate a removal of the contaminants. When the comminution device 1 is a disperser, the comminution elements 3, 6, i.e., the stator 3 and the rotor 6, are implemented as dispersing elements of the disperser, and the comminution surfaces 5, 9 of the comminution elements 3, 6 are implemented as dispersing surfaces of the dispersing elements. The dispersing surfaces of the dispersing elements comprise projecting parts or bars, and clearances or grooves therebetween. The projecting parts form in the dispersing surface the comminution parts arranged to apply a dispersing effect to the fiber material to be processed. The projecting part has typically a structure with substantially small length and width, the length of the projecting part typically not being substantially greater than the width of the projecting part. The shape of the projecting part may, however, vary in many ways, including for example various kind of polygons or pyramids etc. The clearances are free spaces or interstices remaining between the projecting parts for providing flow channels for the flow of the fiber material to be processed along the dispersing surfaces. In a dispersing surface of a disperser a distance between adjacent projecting parts is typically much greater than a distance between adjacent blade grooves, i.e., a width of the blade grooves in a refining surface of a refiner.
The blade segment 4, 8 comprises the dispersing surface 5, 9 comprising projecting parts 24, 25, 26 or teeth 24, 25, 26 and clearances 27 between the projecting parts 24, 25, 26. The projecting parts 24, 25, 26 are arranged at circumferentially extending rows positioned at different positions in the longitudinal direction X of the blade segment 4, 8 from the inner end edge 16 of the blade segment 4, 8, each row having a suitable number of the respective projecting parts 24, 25, 26. The projecting parts 24, 25, 26 and the clearances 27 have a first dimension in the circumferential direction C of the blade segment 4, 8 and a second dimension in the longitudinal direction X of the blade segment 4, 8. The first dimension of the projecting parts 24, 25, 26 is thus a circumferential dimension of the projecting parts 24, 25, 26 and the second dimension of the projecting parts 24, 25, 26 is thus the dimension of the projecting parts 24, 25, 26 along the longitudinal axis X of the blade segment. A section of the dispersing surface 5, 9 of the blade segment 4, 8 comprising the projecting parts 24, 25, 26 and the clearances 27 forms a dispersing section 22, i.e., a comminution section 22, of the blade segment 4, 8. The section of the dispersing surface 5, 9 of the blade segment 4, 8 being substantially free from the projecting parts 24, 25, 26 forms a feed section 23 of the blade segment 4, 8. The feed section 23 extends from the inner end edge 16 of the blade segment 4, 8 toward an outer end edge 17 of the blade segment 4, 8, and may extend up to the outer end edge 17 as schematically shown in
For resisting excessive wear of the projecting parts 24, 25, 26 especially at a position next or close to the feed section 23 so as to prolong an operating life of the blade segment 4, 8 with a satisfactory operational efficiency, it is shown in
For resisting excessive wear of the projecting parts 24, 25, 26 especially at a position next or close to the outer end edge 17 of the blade segment 4, 8 to further prolong an operating life of the blade segment 4, 8, it is also shown in
The discussion relating to the dimensioning of the blade bars 20 in connection with the embodiment of
It will be obvious to a person skilled in the art that, as the technology advances, the inventive concept can be implemented in various ways. The invention and its embodiments are not limited to the examples described above but may vary within the scope of the claims.
Number | Date | Country | Kind |
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20215500 | Apr 2021 | FI | national |
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10464068 | Sjöström et al. | Nov 2019 | B2 |
11142869 | Sjöström et al. | Oct 2021 | B2 |
20140091163 | Ek | Apr 2014 | A1 |
20210017706 | Lindblom | Jan 2021 | A1 |
Number | Date | Country | |
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20220349309 A1 | Nov 2022 | US |