This application is a 371(c) national state application based on PCT/FI2020/050101 filed on Feb. 18, 2020, and claims priority on Finnish Application No. FI20195130 filed on Feb. 20, 2019, the disclosures of which applications are incorporated by reference herein.
Not applicable.
The invention relates to a device for mechanically processing lignocellulose-containing fibrous material, such as to a disperser for dispersing pulp made of recycled lignocellulose-containing fibrous material, or to a high or medium consistency refiner for defibration of lignocellulose-containing fibrous material to produce refined pulp. More particularly the invention relates to a processing plate for mechanically processing lignocellulose-containing fibrous material, such as to a disperser plate for the disperser for dispersing pulp made of recycled lignocellulose-containing fibrous material or to a refiner plate for defibrating of lignocellulose-containing fibrous material to produce refined pulp.
Recycling of waste paper and packaging material as a source of raw material to new fiber-based products has long traditions, however its importance has increased in these days in terms of environment, energy and sustainability. Several processes are used to remove ink, tone, plastics, and stickies etc. which are present in the recovered paper.
When paper or paperboard is manufactured from pulp, and especially from pulp containing recycled fibers originating for example from wastepaper, chipboard, or waste pulp, it is an intention to process different contaminants in the pulp before a formation of a paper web or a board web so that negative effects of the contaminants to the pulp as well as to a web forming in a paper or board machine are reduced. Said contaminants include for example printing inks and surface coating agents, such as different stickies, waxes, adhesives, and pastes, remaining in the wastepaper, chipboard, or waste pulp.
Dispersing of the pulp does not actually remove the contaminants from the pulp but in the dispersing the pulp is slushed or treated in order to diminish negative effects of the contaminants to a quality and a runnability of the pulp or to facilitate a removal of the contaminants in process stages following the dispersing. In the dispersing, among other things, contaminants such as printing ink particles attached to the fibers are detached from the fibers and made smaller so that they can be easily removed from the pulp in a flotation stage following the dispersing or, alternatively, to prevent them being visible in a finished paper or paperboard at least by visual examination. In the dispersing also sticky particles remaining in the pulp are broken up in order to prevent a formation of different contaminant aggregates which may have negative effects on the runnability of the pulp during the formation of the paper or board web and on the runnability of the formed paper or board web in an actual paper or board machine. Dispersing does not actually cut or break the fibers but helps to release fibers from the contaminants and to reduce particulate size of stickies.
A typical disperser comprises coaxial oppositely positioned disperser discs having either disc-like or conical forms and providing a stator and a rotor of the disperser, the rotor being arranged to be rotated relative to the fixed stator. On the stator and the rotor there are disperser plates arranged in a removable way, the disperser plates providing dispersing surfaces of the stator and the rotor, whereby the dispersing surfaces of the stator and the rotor may consist of a single disperser plate extending over the whole perimeter of the stator/rotor but typically they consist of several pie-shaped disperser plates, i.e., segments, arranged adjacent to one another to form the complete dispersing surface. The dispersing surface comprises projecting parts, teeth or the like, and cavities which may be grooves but most often being planar areas between the projecting parts. The projecting parts and the cavities therebetween provide processing surfaces, i.e., dispersing surfaces, of the disperser plates. The dispersing surfaces of one or more disperser plates attached to the disc-like or conical stator/rotor thus provide the dispersing surface of the disc-like or conical stator/rotor.
The projecting parts in a typical disperser plate are pyramidal shaped discrete parts comprising a radially inner part having an inclined ascending wall towards the outer periphery of the disperser plate and a radially outer part having an inclined descending wall towards the outer periphery of the disperser plate, the radially inner and outer parts being connected at a ridge therebetween. The projecting parts are arranged in a number of concentric annular rows at different radial distances in the disperser plate, the projecting parts being at a distance from each other in that annular row. The cavities comprise thereby concentric annular open areas between the concentric annular rows of the projecting parts as well as radial groove-like open areas between the individual projecting parts in the annular rows of the projecting parts. In the disperser the projecting parts and the cavities in the oppositely positioned stator/rotor are then arranged to intermesh with each other such that the projecting parts in the annular rows in the stator plate extend into the annular open areas in the opposite rotor plate and vice versa as male-female elements. Dispersers of this kind are shown for example in WO-publication 2017/001359 A1 and EP1806451 B1.
When the disperser discs of the disperser are rotated relative to each other, the pyramidal shaped discrete projecting parts in the stator and rotor cause impacts to the pulp to be dispersed, whereby effects of these impacts together with effects of internal friction in the pulp detach the contaminant particles from the pulp and break them up into smaller pieces.
Similarly, a refiner is used to mechanically process lignocellulose-containing fibrous material between a pair of plates at least one of which is rotating to produce refined pulp for making paper or board products of different grades or for making fiber board.
An object of the present invention is to provide a novel device for mechanically processing lignocellulose-containing fibrous material, such as a novel disperser and a novel disperser plate for a disperser as well as a novel refiner and a novel refiner plate for the refiner.
The processing plate according to the invention has a projecting part with inclined walls which are mutually connected only partly so that they have in common only a crest section.
The device for mechanically processing lignocellulose-containing fibrous material according to the invention is a device comprising at least two oppositely positioned processing discs, at least one of the processing discs being arranged to be rotated relative to the at least one other processing disc, each processing disc comprising at least one processing plate attached to the processing discs with a processing surface provided with projecting parts having inclined walls which are mutually connected only partly so that they have in common only a crest section.
The invention is based on the idea of arranging a first part and a second part in a projecting part and the inclined walls thereof such that at least the inclined walls are dislocated relative to each other in the circumferential direction of the plate.
An advantage of the arrangement, in the disperser application, is that a number of course changing points for the flowing pulp is increased, thus increasing points or surfaces against which the flowing pulp may collide and cause the contaminant particles in the pulp to be broken into smaller pieces by the effects of these impacts and an internal friction in the pulp, or which points or surfaces may direct the pulp to be dispersed towards the dispersing chamber and the opposite disperser disc. Similar effects may also be achieved in defibration of wood chips in a refiner, especially in a medium or high consistency refiner, wherein the increased number of course changing points for the flowing fibrous material provides a more effective intermingle of the material and more cutting edges for the chips and fiber bundles to collide, thereby increasing an efficiency of the defibration of the lignocellulose-containing fibrous material.
In the following the invention will be described in greater detail by means of preferred embodiments with reference to the accompanying drawings, in which
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 disperser 1 shown in
The disperser plate 4 comprises a background surface 5a facing to the body 3 of the stationary disperser disc 2 and a front surface 5b facing away from the body 3 of the stationary disperser disc 2. The front surface 5b comprises a number of first projecting parts 6 and second projecting parts 7 extending upwards from a bottom of the front surface 5b of the disperser plate 4, as well as cavities 8 or open areas 8 between the projecting parts 6, 7 in a radial direction RD of the disperser plate 4 or of the stationary disperser disc 2. The front surface 5b of the disperser plate 4 together with the projecting parts 6, 7 and the cavities 8 or open areas 8 provide a processing surface 9, i.e., a dispersing surface 9 of the disperser plate 4. A complete processing surface, i.e., a dispersing surface of the stationary disperser disc 2 is formed by the dispersing surfaces 9 of a necessary number of the disperser plates 4 fastened next to each other in the stationary disperser disc 2 so that the complete dispersing surface extending over the whole circumference of the stationary disperser disc 2 is provided.
The disperser 1 shown in
The rotatable disperser disc 10 comprises a number of, i.e., one or more, disperser plates 12 of the rotatable disperser disc 10, the at least one disperser plate 12 being detachably fastened to the body 11 of the rotatable disperser disc 10, whereby a worn or broken disperser plate 12 may be replaced with a new one. The disperser plate 12 comprises a background surface 13a facing to the body 11 of the rotatable disperser disc 10 and a front surface 13b facing away from the body 11 of the rotatable disperser disc 10. The front surface 13b comprises a number of first projecting parts 14 and second projecting parts 15 extending upwards from the front surface 13b of the disperser plate 12, as well as cavities 16 or open areas 16 between the projecting parts 14, 15 in the radial direction RD of the disperser plate 12 or of the rotatable disperser disc 10. The front surface 13b of the disperser plate 12 together with the projecting parts 14, 15 and the cavities 16 or open areas 16 provide a processing surface 17, i.e., a dispersing surface 17 of the disperser plate 12. A complete processing surface, i.e., a dispersing surface of the rotatable disperser disc 10 is formed by the dispersing surfaces 17 of a necessary number of the disperser plates 12 fastened next to each other in the rotatable disperser disc 10 so that the complete dispersing surface extending over the whole circumference of the rotatable disperser disc 10 is provided.
The disperser 1 further comprises at the stationary disperser disc 2 at least one feed opening 21 through which the pulp to be dispersed is supplied into the dispersing chamber 20 along a feed or supply direction indicated schematically with an arrow F. Consistency of the pulp supplied into the disperser 1 may for example be 3-40%, preferably 10-30%. Together with the pulp also steam may be supplied into the dispersing chamber 20 so as to improve the travel of the pulp in the dispersing chamber 20 along the dispersing surfaces of the disperser discs 2, 10. The projecting parts 6, 7, 14, 15 provide the parts of the dispersing surfaces of the stationary 2 and rotatable 10 disperser discs that direct a dispersing effect to the pulp by the stationary 2 and the rotatable 10 disperser discs. The cavities or open areas 8, 16 provide free volumes intended to receive the projecting parts 14, 15 projecting from the opposed disperser disc 2, 10.
The disperser 1 shown in
The disperser plate 12 of
The disperser plate 12 of
The dispersing surface 17 of the disperser plate 12 further comprises second projecting parts 15 being situated at a portion of the disperser plate 12 which is located, relative to the feed zone 26, at a side of the outer periphery 23 of the disperser plate 12 and forming a dispersing zone 36 of the disperser plate 12. The second projecting parts 15 are arranged into groups of the second projecting parts 15, each group of the second projecting parts 15 comprising in the examples of
In the examples of
In the example of
Between the rows 27a, 27b, 27c there are concentric annular cavities 16 or open areas 16, i.e., areas not comprising any projecting parts. These cavities 16 or open areas 16 are thus free from any projecting parts and they provide at the dispersing surface 17 of the disperser plate element 12 a free volume into which the projecting parts in the opposite disperser plate may extend when the disperser plate 12 is installed to the disperser 1.
The disperser plate 12 is a disperser plate for the rotatable disperser disc 10. The disperser plate 4 for the stationary disperser disc is substantially similar reversed image, with the exception that the actual locations of the concentric annular rows of the second projecting parts 7 are different in the radial direction RD of the disperser plate 4 so that the concentric annular rows of the second projecting parts 7, 15 of the opposite plates may intermesh with each other in the radial direction RD of the disperser 1.
The second projecting parts 15 comprise a radially inner part 28 having an inclined ascending wall 29 of the projecting part 15 towards the outer periphery 23 of the disperser plate 12, or a front wall 29 if considered in the direction of flow of the pulp on the dispersing surface 17 from the inner periphery 22 towards the outer periphery 23 of the disperser plate 12. The inclined ascending wall 29 thus faces at least partly to the inner periphery 22 of the disperser plate 12 and ascends at least partly towards the outer periphery 23 of the disperser plate 12. The inclined ascending wall 29 of the outer part 28 of the projecting part 15 has an inner end 29a facing to the inner periphery 22 of the disperser plate 12 and an outer end 29b facing to the outer periphery 23 of the disperser plate 12. The direction of the inclined ascending wall 29 between the inner end 29a and the outer end 29b corresponds to the longitudinal direction of the inner part 28 and the dimension of the inclined ascending wall 29 between the inner end 29a and the outer end 29b is determined to be a length of the inclined ascending wall 29, a width of the inclined ascending wall 29 being the dimension of the inclined ascending wall 29 in a direction that is at least partly transversal to a direction of a longitudinal tangent of the inner part 28.
The second projecting parts 15 further comprise an outer part 30 on the side of the outer periphery 23 of the disperser plate 12 relative to the inner part 28. The outer part 30 of the projecting part 15 has an inclined descending wall 31 of the projecting part 15, or a back wall 31 if considered in the direction of flow of the pulp on the dispersing surface 17 from the inner periphery 22 towards the outer periphery 23. The inclined descending wall 31 faces at least partly to the outer periphery 23 of the disperser plate 12 and descends towards the outer periphery 23 of the disperser plate 12. The inclined descending wall 31 of the outer part 30 of the projecting part 15 has an inner end 31a facing to the inner periphery 22 of the disperser plate 12 and an outer end 31b facing to the outer periphery 23 of the disperser plate 12. The direction of the inclined descending wall 31 between the inner end 31a and the outer end 31b corresponds to the longitudinal direction of the outer part 30 and the dimension of the inclined descending wall 31 between the inner end 31a and the outer end 31b is determined to be a length of the inclined descending wall 31, a width of the inclined descending wall 31 being the dimension of the inclined descending wall 31 in a direction that is at least partly transversal to a direction of a longitudinal tangent of the outer part 30.
The inner part 28 and the outer part 30 of the projecting part 15 are radially coupled or interconnected to each other by a ridge 32 along a coupling line CL between the inner part 28 and the outer part 30, the coupling line CL running in a substantially transversal direction relative to the longitudinal directions of the inner part 28 and the outer part 30. The ridge 32 is formed by the outer end 29b of the wall 29 and the inner end 31a of the wall 31. The sloping walls 29 and 31 are mutually connected only partly so that the ridge 32 is not in common for them entirely, but only a crest section 40 of the ridge 32 is shared by both the inner part 28 and the outer part 30. The crest section 40 connects the two sloping walls 29 and the 31 of the inner and outer part 28 and 30, respectively. The crest section 40 has a length WCL along the coupling line CL.
In the embodiments of
In the embodiments of
In the embodiments of
The positioning of the first part 28 and the second part 30 of the projecting part 15 and the inclined walls 29, 31 thereof as disclosed above causes at least the inclined walls 29, 31 to be dislocated relative to each other in the circumferential direction of the disperser plate 12, what increases a number of course changing points for the pulp flow, thus increasing points or surfaces against which the flowing pulp may collide and cause the contaminant particles in the pulp to be broken into smaller pieces by the effects of these impacts and an internal friction in the pulp. In the disperser plate 12 for the rotatable disperser disc 10 the inclined wall 31 of the second part 30 is dislocated relative to the inclined wall of the first part 28 towards the intended rotation direction R of the rotatable disperser disc 10, as shown in
According to an embodiment of the second projecting part 15, a side of the inner part 28 facing at least partly towards the intended rotation direction R of the rotatable disperser disc 10 forms an inclined side wall 33 ascending at least partly in a direction of the periphery of the disperser plate 12, towards the direction that is opposite to the intended rotation direction R. In the embodiment shown in
In the embodiment of
Furthermore, in the embodiments of
Furthermore, in the embodiments of
Furthermore, in the embodiments of
According to an embodiment, as further shown in
According to an embodiment, as further shown in
According to an embodiment, a width of a groove 15″ portion remaining between the outer parts 30 of the adjacent second projecting parts 15 may be arranged to decrease towards the outer periphery 23 of the disperser plate 12. The effect of this is to equalize open surface area between the inner 22 and outer 23 peripheries of the disperser plate 12, which even out the flow of the pulp to be dispersed on the dispersing surface 17 of the disperser plate 12.
In the embodiment of
The disperser 1 disclosed above is an example of a device for mechanically processing lignocellulose-containing fibrous material, in this case pulp made of recycled waste paper and/or packaging material, and the disperser discs and the disperser plates thereof provide the respective processing or treatment discs and processing or treatment plates for mechanically processing or treating the pulp.
Another example of the device for mechanically processing or treating lignocellulose-containing fibrous material is a medium or high consistency refiner intended for defibration of the lignocellulose-containing fibrous material to produce refined pulp. The lignocellulose-containing fibrous material in this case is typically a mixture of water and wood chips having a consistency between about 10% and about 25% for medium consistency refiners and above 25% or above 30% in high consistency refiners, for example. The general construction and operation of the refiner is substantially similar to that of the disperser, thus, all the features disclosed above in connection with a disperser are applicable with a refiner, too.
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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20195130 | Feb 2019 | FI | national |
Filing Document | Filing Date | Country | Kind |
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PCT/FI2020/050101 | 2/18/2020 | WO |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2020/169884 | 8/27/2020 | WO | A |
Number | Name | Date | Kind |
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20100314476 | Vuorio | Dec 2010 | A1 |
Number | Date | Country |
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104492541 | Apr 2015 | CN |
1806450 | Jul 2007 | EP |
1806451 | Jul 2007 | EP |
2689853 | Jan 2014 | EP |
2016027019 | Feb 2016 | WO |
2017001359 | Jan 2017 | WO |
Entry |
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International Search Report for PCT/FI2020/050101, dated Apr. 23, 2020. |
Written Opinion of the International Searching Authority for PCT/FI2020/050101, dated Apr. 23, 2020. |
Number | Date | Country | |
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20220145537 A1 | May 2022 | US |