RU2777584C2 - Supported gear plates in dispersant - Google Patents

Abstract

FIELD: separation.

SUBSTANCE: claimed group of inventions relates to segments of a plate for the separation of material and to a machine for the separation of material. Segments contain substrate with the front side and the rear side, wherein the rare side is configured so that it is attached to a support disc of a dispersant; rows of gears protruding from the front side of substrate, wherein each row is located along an arc extending from one side of a plate segment to the opposite side of the plate segment. Gears can be connected by a jumper covering a gap between neighboring gears, wherein the jumper is raised above the front side of substrate, so that the jumper is separated from the front surface by an open space in the gap. A gear in rows of gears can have the first face located remotely from the second face along a gear body with the first side of the gear and the second side of the gear, while there is a support extending from the first face of the gear to a support extending from the second face of the adjacent gear, wherein the support extending from the first face of the gear to the support extending from the second face of the adjacent gear meets it at a height above substrate, which is less than the full height of the gear. There is also can be a support extending from the first face of the gear to substrate only, adjacent to this first face of the gear, or, in the inclined direction, to the second face of the adjacent gear from the first face of the gear to substrate adjacent to this first face of the gear.

EFFECT: obtaining a machine for the separation of material.

39 cl, 37 dwg

Description

BACKGROUND OF THE INVENTION

1. CROSS-REFERENCE TO RELATED APPLICATIONS

[0001] This application claims priority for each of the following U.S. Provisional Applications, each of which is hereby incorporated by reference in its entirety: U.S. Provisional Application No. 62/752,077, dated October 29, 2018, and U.S. Provisional Application No. 66/844,570 dated May 7, 2019

2. FIELD OF TECHNOLOGY

[0002] This disclosure relates to dispersing machines for processing pulp fibers recovered from recycled paper and packaging material, and other machines for separating material with opposing discs and teeth engaged.

3. MATERIALS USED IN THE EXAMINATION OF THE APPLICATION

[0003] The disperser is a machine used to recycle paper and packaging material. Operators first pulp the recycled paper and packaging material to separate the fibers in the material. Operators then direct the pulped fibers through a dispersant, typically at a high consistency such as 20-40% dry matter content. Dispersants remove ink, toner and other "sticky substances" from the fibers in paper and packaging material. Dispersants also reduce the particle size of ink, toner, and stickies so that they are less clearly visible in the final pulp product.

[0004] Each disc typically includes an assembly of wafer segments in the form of ring sectors arranged in an annular matrix and secured to the platter. The assembly of plate segments is referred to here as a plate. The front surface of each insert segment that faces the front surface of the opposite insert segments typically includes teeth, also referred to as pyramids, arranged in rows through the insert segment. The rows of teeth usually form an arc through the insert segment. The arcuate rows of teeth on one plate engage with the rows of teeth on the opposite plate. That is, the arcuate rows of teeth on the segment of one insert rotate freely between the arcuate rows of teeth located on the segment of the opposite insert. Examples of dispersant discs are shown in US Patent Nos. 9,145,641; 7,766,269; 7,478,773; 7,472,855; 7,300,008 and 7,172,148; in US Patent Application Publication No. 2014/017.4688 and European Patent Application 2,683,870 B1.

[0005] Recycled paper and packaging materials typically include many contaminants, including abrasive particles such as coarse and hard particles. These abrasive particles wear the disperser teeth, which in turn limits the useful life of the plates.

[0006] It is known that to solve the problems associated with contaminants, the plates for the disks of the disperser are made of wear-resistant alloys that are resistant to wear caused by abrasive particles. However, wear resistant alloys are brittle. Due to brittleness, the teeth on the inserts can break when exposed to harder particles that contaminate the cellulosic material. Broken teeth limit insert life and can cause other damage further down the line.

[0007] To eliminate brittleness, wide and short teeth were used on insert segments made from wear-resistant alloys. In contrast, insert segments with high teeth are typically made from softer, fracture-resistant alloys that limit insert life. Wide and short teeth are more resistant to breakage, but they are not suitable for higher energy applications because wide and short teeth form fewer rows with fewer teeth than rows with narrow teeth and thus have fewer reentrants. into the meshing of the edge teeth on each row. Shorter teeth reduce the lengths of the intersecting edges of the opposing teeth, which also reduces the impact on the pulp fibers. In addition, short, wide teeth reduce the gap between opposing discs and thus reduce the throughput of material flowing through the disperser.

[0008] In addition, to support the teeth and to reduce damage to the teeth were used baffles and slopes on the substrate of the front surface of the discs and between adjacent teeth. Baffles and slopes to overcome the difficulties associated with brittle teeth formed from a wear-resistant alloy tend to be relatively large. Large baffles and slopes can adversely affect the uniformity of the fibrous material moving between opposing discs in an undesirable manner. Large slopes and especially large baffles will also reduce the throughput of the disperser plates.

SUMMARY OF THE INVENTION

[0009] There is a need for a new insert segment design that allows rows of tall, narrow teeth made from wear resistant alloys that are resistant to tooth fracture.

[0010] Disclosed here is an insert segment that has webs between adjacent teeth in a row. The webs support the teeth, allowing the teeth to be tall and narrow.

[0011] A new design of plates having teeth that are engaged has been developed. The teeth are reinforced so that they are connected to each other by webs at or near the top of the teeth and/or at an intermediate height between the top and bottom of the teeth.

[0012] It is believed that the bridges will not impose additional restrictions on the flow of cellulose fiber through the gap between the plates, at least compared to plates with large slopes and baffles. In addition, the bridges between the teeth contribute to the uniform distribution of the fibrous material moving between the plates. In addition, the location and shape of the joints can be optimized for carrying capacity and maximum tooth strength, thus providing tooth plates with good performance and low risk of tooth breakage.

[0013] The invention may be embodied as a plate segment for a dispersant or other material separation machine, comprising: a substrate having a front side and a back side, the back side being configured to be attached to a platter; rows of teeth protruding from the front side of the metal substrate, in which each of the rows is located along an arc extending from one side of the plate segment to the opposite side of the plate segment; in at least one of the rows of teeth, adjacent teeth are connected by a bridge spanning the gap between adjacent teeth in the row, in which the bridge is raised above the front side of the substrate so that the bridge is separated from the front side by an open space in the gap. The webs may span all adjacent teeth in the row, or the webs may span only selected pairs of teeth in the row.

[0014] The web may terminate on adjacent teeth spaced from the front side of the substrate. The bridge may connect the side walls of each of the adjacent teeth. The web may connect sidewalls of adjacent teeth at an elevation of the teeth above the front side, in the range of one third to two thirds of the height of adjacent teeth above the front side.

[0015] The webs can be positioned at various elevations above the substrate and along the height of the teeth so that there is a gap between the web and the substrate. For example, the webs may be at an elevation above the plate segment substrate that is three-quarters (¾) or more of the height of the teeth. In particular, the webs may be at or near the top of the teeth.

[0016] The webs may be circular in cross section at the midpoint of the web between adjacent teeth. Alternatively, the web may have other cross-sectional shapes such as a rectangular shape; tapered shape or teardrop shape, or any other shape that allows you to perform the function of the bridge.

[0017] The web may be between some or each of the adjacent teeth in one or more rows, and there may be no webs in other rows on the insert segment. The webs may be radially in the outermost row(s) and the radially inner rows may be devoid of webs.

[0018] The webs in a row may include a first web between a first pair of adjacent teeth in the row and a second web between a second pair of adjacent teeth in the row, wherein the first web is at or near the top of the first pair of adjacent teeth and the second web is at the bottom. elevation between the second pair of adjacent teeth, for example, in the range from one third to eighty percent (80%) of the height of the second pair of adjacent teeth. In a row of teeth, between each successive pair of teeth, the first and second webs may alternate.

[0019] Additionally, there may be two or more bridges between a pair of adjacent teeth on the insert segment. For example, one of the webs may be at or near the top of the teeth, and the second web may be at a height of one third to two thirds of the height of the teeth. A third or more of the lintels may be at the same height as the other lintels, or at a new height. The gaps are located both between the jumpers and the substrate of the plate segment, and between the jumpers.

[0020] The invention may be embodied as a dispersant comprising: a body including an inlet configured to receive a stream comprising cellulosic fibrous material; opposing disks fixed in the housing so that at least one of the disks rotates about an axis of rotation in the housing; each of the opposing discs has a front surface, and the front surfaces on the opposing discs face each other and are separated by a gap between the opposing discs; each of the opposite disks has rows of teeth on the front surface for the disks, and the teeth in each row of teeth are located on a common radius from the axis of rotation; the webs span gaps between adjacent teeth in at least one of the rows of teeth, the webs being separated from the front surface substrate by an open space in the gap; moreover, the rows of teeth on the front surface of the first of the opposite disks have radii different from the radii of the rows of teeth on the front surface of the second of the opposite disks; and wherein the rows of the first of the opposing discs engage with the rows of teeth on the second of the opposing discs.

[0021] In other exemplary embodiments, the plate segments may include struts extending from the face of the tooth to the substrate of the dispersant segment.

[0022] Without being bound by theory, it is contemplated that the exemplary props disclosed herein may allow fabricators to employ more and higher teeth on a dispersant plate segment, thereby improving the work that the dispersant plate segments can impart to recycled fiber on area unit.

BRIEF DESCRIPTION OF THE DRAWINGS

[0023] The foregoing will become clear from the following more specific description of exemplary embodiments of the disclosure as illustrated in the accompanying drawings. The drawings are not necessarily drawn to scale, with emphasis instead being placed on illustrating the disclosed embodiments.

[0024] FIG. 1A is a front view of a standard plate segment in a disc in a disperser.

[0025] FIG. 1B is a cross-sectional side view of the plate segment shown in FIG. 1A.

[0026] FIG. 1C is a side cross-sectional view of the part of the disperser in which the rotor disc and the stator disc are fixed.

[0027] FIG. 2(A) and 2(B) are side and front views of a portion of an insert segment showing teeth with standard high inclinations.

[0028] FIG. 3(A) and 4(B) are side and front views of a portion of an insert segment showing teeth with standard webs.

[0029] FIG. 4(A) and 4(B) are side and front views, respectively, of a portion of a plate segment having teeth with connecting webs.

[0030] FIG. 5(A) and 5(B) are side and front views, respectively, of a portion of another insert segment having teeth with connecting webs.

[0031] FIG. 6(A) and 6(B) are side and front views, respectively, of another toothed plate segment with connecting webs.

[0032] FIG. 7(A), 7(B), 7(C), and 7(D) are side views of teeth on blade segments showing webs having various cross-sectional shapes.

[0033] FIG. 8(A) and 8(B) are side and front views of teeth on insert segments showing web pairs between adjacent teeth.

[0034] FIG. 9 is a perspective view of two adjacent exemplary dispersant teeth having a strut extending from the first side of a tooth of each of the depicted dispersant teeth.

[0035] FIG. 10(A) and 10(B) show a perspective view of an exemplary disperser tooth showing pyramidal shaped struts.

[0036] FIG. 11(A), 11(B), 11(C), and 11(D) are perspective views of an exemplary dispersant tooth showing various forms of struts in which the adjacent area of the strut is smaller than the total area of the tooth facet to which the strut abuts. .

[0037] FIG. 12(A), 12(B), 12(C), 12(D), 12(E), 12(F), 12(G) are side views of exemplary disperser teeth showing exemplary props extending from one or over the edges of an exemplary dispersant tooth.

[0038] FIG. 13(A), 13(B), 13(C), and 13(D) are side views perpendicular to those of FIG. 12. These Figures show the adjacent area of the strut in relation to the total area of the first facet of the tooth.

DETAILED DESCRIPTION OF THE INVENTION

[0039] The following detailed description of preferred embodiments is provided for illustrative and descriptive purposes only and should not be construed as exhaustive or limiting the scope and spirit of the invention. Embodiments have been selected and described to better explain the principles of the invention and its practical application. One of ordinary skill in the art will appreciate that various variations may be made to the invention as disclosed herein without departing from the scope and spirit of the invention.

[0040] Like reference numerals refer to corresponding parts throughout several views, unless otherwise indicated. Although the drawings represent embodiments of various features and components of the present disclosure, the drawings are not necessarily drawn to scale and certain features may be exaggerated to better illustrate embodiments of the present disclosure, and such exemplification should not be construed as limiting the scope of the present disclosure.

[0041] Unless otherwise expressly stated herein, the following rules of interpretation apply to this description: (a) all words used herein are to be treated as words of the kind or number (singular or plural) as the circumstances warrant; (b) singular terms used in the description and in the appended claims include plural references unless the context clearly dictates otherwise; (c) the previous term "about", when applied to a specified range or value, means an approximation within a range deviation, or value, known or expected in the art from measurements; (d) the words "in this document" "thereby" "to this document" "hereinafter" and "hereinafter" and words of a similar meaning refer to this description in its entirety and not to any particular section , a claim or another subsection, unless otherwise indicated; (e) descriptive headings are for convenience only and should not control or influence the meaning or construction of any part of the description; and (f) the words "or" and "any" are non-exclusive, and "include" and "including" are non-limiting. In addition, the terms "comprising", "having", "including" and "containing" should be understood as non-limiting terms (ie, meaning "including, but not limited to").

[0042] References in the description to "one embodiment", "an embodiment", "an exemplary embodiment", etc., mean that the described embodiment may include a particular feature, structure, or characteristic, but each embodiment embodiments may not necessarily include a particular feature, structure, or characteristic. Moreover, such phrases do not necessarily refer to the same embodiment. In addition, when a particular feature, structure, or characteristic is described in relation to an embodiment, it is stated that one skilled in the art knows how such feature, structure, or characteristic can be influenced in relation to other embodiments, whether explicitly or implicitly. they are described.

[0043] To the extent necessary to provide descriptive support for the teeth, the subject matter and/or the text of the appended claims is incorporated herein by reference in its entirety.

[0044] The listing of ranges of values herein is only intended to serve as a shorthand way to refer individually to each individual value within a range within any subranges within it, unless otherwise explicitly stated herein. Each individual value within the specified range is included in the description or in the claims, as if each individual value would be listed in this document separately. It should be understood that where a specific range of values is presented, each intermediate value, to within one tenth or less of one, the lower limit between the upper and lower limit of that range and any other specified or intermediate value in that specified range or subrange thereof, is included. in this document, unless the context clearly dictates otherwise. All subranges are also included. The upper and lower limits of these smaller ranges are also included, subject to any specific and intentionally excluded limit in the specified range.

[0045] It should be noted that some of the terms used herein are relative terms. For example, the terms "top" and "bottom" are relative to each other in location, i.e., the top component is located at a higher elevation than the bottom component in a given orientation, but these terms may change if the device is turned upside down. The terms "input" and "output" are given in relation to the flow flowing through them in relation to a given structure, for example, to the flow inflowing through the entrance to the structure and flowing out through the exit of the structure. The terms "upstream" and "downstream" are relative to the direction in which the flow flows through the various components, i.e., in relation to the flow of fluids through the upstream component before the downstream component. along the stream.

[0046] The terms "horizontal" and "vertical" are used to refer to a direction relative to an absolute reference, i.e., ground level. However, these terms should not be construed as requiring that the structures be absolutely parallel or absolutely perpendicular to each other. For example, the first vertical structure and the second vertical structure are not necessarily parallel to each other. The terms "top" and "bottom" or "bottom" are used to refer to locations/surfaces where the top is always higher than the bottom/bottom relative to an absolute reference, ie, the surface of the Earth. The terms "up" and "down" are also used in relation to an absolute standard; the upward flow is always directed against gravity.

[0047] Dispersants typically come in one of three forms: disc, conical, and cylindrical. Although this Detailed Description mainly describes disc dispersers, conical and cylindrical dispersers generally function in a similar manner. Instead of opposing discs, they have nested truncated cones and nested cylinders, respectively. The exemplary plate segments described herein can be made to operate with conical or cylindrical dispersers, and such plate segments and types of dispersers are considered to be within the scope of this disclosure. FIG. 1A, 1B and 1C show the disperser 10 (FIG. 1C) which houses the rotor plate segments 12 attached in an annular matrix to the rotor support disc 14. The segments 12 of the rotor plate and the support disk 14 rotate around the central 16 axis of the disperser. The rotor plate segments 12 and disc 14 are rotated by a shaft 15 driven by a drive motor (not shown). The disperser also houses stator plate segments 18 attached in an annular matrix to a stator support disk 20 that is attached to the disperser housing.

[0048] The central 22 entrance to the stator 20 support disk receives the work material between the segments of the rotor plate and the stator. The material may be cellulose recovered from paper or packaging material. The material moves into the gap 24 between the front surfaces of the segments 12 of the rotor plate and the front surfaces of the segments 18 of the stator plate. Rotation of the rotor plate segments (and stator plate segments if configured to rotate) generates centrifugal forces that propel material through gap 24. As material moves through gap 24, material flows between and over teeth 26 arranged in rows on the front surfaces of each of segments 14 of the rotor plate and segments 18 of the stator plate.

[0049] The rows of teeth 26 on the segments 12 of the rotor plate engage with the rows of teeth on the segments 18 of the stator plate. To ensure mutual engagement, the rows of teeth on the segments 12 of the rotor plate are located at radii from the central axis 16, different from the radii of the rows of teeth on the segments 18 of the stator plate. Each row of teeth extends through a plane 28 extending through the central axis 16 and radially outward through gap 24.

[0050] As the material passes through the gap 30, the teeth on the segments 12, 18 of the rotor and stator plate act on the material and expel ink particles, toner, and adhesives from the cellulose fibers from the pulp fibers. Displacing these particles from the fibers is desirable. As the material exits the gap in the radial direction, the material enters the annular chamber 30 of the disperser body 10. The material moves through the chamber to the outlet. After release, the displaced particles are separated from the cellulose fibers in the material during further processing.

[0051] The plate segments 12, 18 may be, for example, individual annular components in the form of a component sector or an annular plate region. Plate segments, which are individual sector-shaped annular components, and are arranged in an annular matrix to form an entire plate. The plate segments/plate are fixed on the support disc 14, 20. An annular array of segments 14 of the rotor plate is attached to the support disk 12 of the rotor, and an annular array of segments 18 of the stator plate is attached to the support disk 13 of the stator. The plate segments may be attached to the disc in any convenient or standard manner, such as by bolts (not shown) passing through channels 17. The plate segments 12, 18 are placed side by side to form an annular matrix as they are attached to each disc support.

[0052] The rotor or stator plate may or may not be formed from the individual components of the plate segments. Rather, the plate segments may be connected as a single plate. While plate segments are disclosed here which are separate components, the invention may be embodied as an annular plate in which the plate segments are embedded in a single plate.

[0053] The plate segment 12, 18 has an inner edge 32 towards the central axis 18 of the disc support attached thereto and an outer edge 34 near the periphery of the disc support. Each segment 12, 18 of the plate has a front surface with a substrate 45 and protruding from the substrate 45, concentric rows 42 of teeth 26. a gap 24 between the discs in a radially outward direction from the inner 32 edges to the outer 34 edges of the plate segments. The cellulosic material advantageously moves between adjacent teeth 26 in each row on opposite discs. The cellulosic material flows radially outward from the gap 24 at the outer periphery of the discs and into the casing 30 of the refiner 10.

[0054] Each of the rows 26 of teeth on each disc is at a total radial distance of 44 from the center 16 of the disc. Rows 26 on the disc are concentric. Rows on opposite discs engage through gap 24 whereby teeth 26 intersect plane 28 in gap 24 between discs.

[0055] The fiber extending from the central stator disc inlet 22 through the gap 24 and out to the periphery of the discs is impacted when the rotor teeth 26 pass close to the stator teeth 28. The gap between the rotor teeth 26 and the stator teeth 28 may be in the range of 0.5-12 millimeters ("mm"). The gap can be chosen so that the fibers are strongly and alternately bent as they pass between the teeth in the rows of the rotor and stator disk. The curving fiber breaks the ink and toner particles on the fiber into smaller particles and destroys the adhesive particles on the fibers. The gap should not be so small as to damage or destroy the fibres.

[0056] The rotor or stator plate segments 12, 18 are shown in more detail in FIG. 1A and 1B than in FIG. 1C. The plate segment has an inner 32 edge and an outer 34 edge. These edges may be arcuate, with each arc centered on the central axis 16 when the plate segments are attached to the disc and fixed in the disperser 10. The back 26 side of the plate is configured to be attached to the front surface of the support disc 14, 20.

[0057] The front 38 side includes an outer 40 arcuate section on which rows 42 of teeth 28 are located. Each row 42 is arcuately spaced and has a constant radius 44 from the central 16 axis of the disperser. The teeth extend from the backing 45 of the plate segment. The inner 46 section of the front surface may be a flat substrate 45 of the front of the segment of the plate.

[0058] The side 48 edges of the plate segment 12, 18 may be straight edges aligned along a radius from the central 16 axis. The side edges 48 are configured to fit against the side edges of other plate segments attached to the rotor or stator support disk. By placing platter segments next to each other on the platter, the platter segments form an annular disk array on the platter. Each of the rows 42 of teeth 26 on the insert segment is aligned along a common radius with the row of teeth on the other insert segments attached to the platter. Thus, the teeth from all the insert segments attached to the platter are arranged in circular rows. These circular rows of teeth on the rotor plate segments attached to the rotor platter engage with the circular rows of teeth on the stator plate segments attached to the stator platter in the disperser.

[0059] FIG. 2(A), 2(B), 3(A) and 3(B) show slopes 50 and webs 51 between adjacent teeth 26 in a row of 42 teeth in standard insert segments. These standard baffles 50 and slopes 51 are large protrusions extending from the substrate 45 of the front surface of the plate segment. The slopes 50 may protrude from the substrate by 2-6 mm or more in height. The baffles 51 may extend over the substrate from a few millimeters to about three quarters (¾) of the height of the tooth. Slopes or partitions may alternate with webs between the teeth in the row. For example, there may be groups of two to six webs between adjacent teeth, followed by a slope or partition between the next one to six teeth. Tilts, baffles and webs can also be combined in any way between adjacent teeth, such as web and slant in the same area.

[0060] As is known in the art, slopes and baffles reinforce the teeth to which they are attached. The height of the ramp or baffle is chosen to provide the desired level of tooth support. Slopes or baffles that are relatively low compared to the height of the tooth provide less support than higher slopes or baffles. Slopes or baffles that are high in relation to the height of the tooth provide good support for the teeth, but adversely affect the flow of cellulosic material through the teeth and can significantly reduce the production capacity of the disperser. Another adverse effect caused by high slopes or baffles may be to reduce the uniformity of the cellulosic material due to the flow of material into concentrated areas between the disks.

[0061] FIG. 4(A) and 4(B) show teeth 26 on a plate segment 52 configured to be mounted on a rotor or stator platter. The teeth 26 are arranged in concentric rows 42. The teeth 26 in each row are connected by webs 56 which extend between and connect adjacent teeth. Webs 56 provide structural support for the teeth and help prevent damage to the teeth by large, hard particles in material moving between the teeth. The webs 56 may bridge the gap 57 between adjacent teeth in the row. Webs 56 may be present between all adjacent teeth 26 and span all slots 57 in the row, as shown in FIG. 2 and 3. The webs 56 may be integral with the teeth 26, whereby the teeth and webs are made from the same material and as a single cast component. These materials can be wear resistant alloys such as nickel and chromium alloys, as well as martensitic or austenitic stainless steels.

[0062] Webs 56 may be engaged in all rows 42 of teeth on the insert segment. Alternatively, jumpers 56 may be in selected rows and not be part of other rows. For example, the jumpers may be in the first few rows, such as the first row, the first two rows, or the first three rows. The first rows are radially inner rows. The first rows of teeth can be exposed to the largest particles in the material passing through the disperser. Also, webs may be applicable in the radially outer 42 rows, due to the effect of the aforementioned centrifugal forces on the radially outer rows as compared to the radially inner rows. Thus, a plate segment may have rows 42 with webs 56 on the radially outer row, or on several outer rows, such as an outer row of seven rows, rather than on the radially inner rows. In some applications, the radially inner rows tend to be wider and more spaced apart from the radially outer rows. Webs may not be needed to support wide teeth. In addition, webs may not be suitable for bridging wide tooth gaps such as those that may exist in most radially internal rows.

[0063] The bridges 56 are raised around the substrate 45 of the front surface of the segment 12, 18 of the plate. Because of the elevation, there is a gap 58 between the bottom of the web and the surface of the substrate 45. The width of the gap 58 may be half the height (H) of the teeth, one third of the height of the teeth, two thirds of the height of the teeth, eighty to ninety percent (80%-90% ) height, or almost the entire height of the teeth. The width of the gap 58 is determined during the design of the plate segment. The gap width can be determined to increase the resistance of the teeth to breakage and to increase the movement of the cellulosic material through the dispersant. Placing the webs in a staggered pattern at different spacings between the teeth can promote a more even flow of fiber through the rows of teeth. Also, staggering the ribs on opposite sides of the tooth can give the tooth increased strength.

[0064] The webs 56 may have a cross section that is circular as shown in FIG. 2 and 3. The cross-sectional area may be less than the cross-sectional area of the tooth 26. For example, the cross-sectional area of the web may be one-fifth, one-third, half, or two-thirds of the cross-sectional area of the tooth at the same elevation from the substrate 45 as jumper. Webs 56 can be offset from the leading 62 tooth faces and similarly offset from the rear 60 tooth faces, as shown in FIG. 4(A) and 4(B). Webs 56 may be centered on the sides of the teeth along the radial direction, or they may be offset to one of the edges.

[0065] The substrate may include a gentle slope or partition 50 between adjacent teeth in a row of teeth. The slope or baffle 50 may be short, such as less than a quarter of the height of the teeth, to reduce the effect of the slope or baffle on the uniformity of the cellulosic material. If there is a slope, a shoulder 54 may be formed on the trailing edge (radially outward) of the row of teeth. The slope or web 50 provides additional structural support to the teeth. The slope or baffle 50 may also assist in the processing of recycled material by guiding the material away from the backing and towards the top regions of the teeth.

[0066] FIG. 5(A) and 5(B) show an exemplary insert segment 64 in which webs 66 form the top of teeth 26. Each row of teeth 42 has a web 64 arranged in an arc fitted to the arc formed by the row. Web 66 forms the top of the teeth in the row. The front surface of the bridge 66 may be in the same plane as the leading 62 face of the teeth in the row and the back 60 face of the teeth. The top surface of the web may be flatter and generally parallel to portions of the substrate other than the slopes or baffles. In addition, the thickness of web 66 may be less than the width where the thickness is in a direction perpendicular to the radial line and the thickness is parallel to the radial line.

[0067] FIG. 6(A) and 6(B) show an insert segment 68 having rows of webd teeth 26, with web segments 70, 72 alternating with segments 70 at an average height between adjacent teeth and with segments 72 at the top of adjacent teeth. The height of the jumper segments is given relative to the substrate 45 of the plate segment. Due to the alternating heights, the gap 58 between the substrate and web segments also varies between adjacent pairs of teeth. The alternating segments continue for all teeth in each row 42. The alternating tooth height provides a structural support structure for each tooth, both on the top and middle of the tooth. Thus, alternating heights can be used to impart increased structural strength to the teeth for blade segments expected to process cellulosic material having large, hard particles or otherwise having particles that can destroy the teeth.

[0068] FIG. 7(A), 7(B), 7(C) and 7(D) show exemplary webs 74, 76, 56 and 78 between adjacent teeth 26 in various rows of insert segments. The lintels have various cross-sectional shapes. The web 74 has a triangular cross-section, with the apex of the triangle facing the flow of cellulosic material flowing between the rotor and stator disks. The orientation of the top towards the flow reduces the flow resistance caused by the bridge. Jumper 76 has a rectangular cross section. The rectangular cross-sectional shape can give a more uniform structural support structure across the width of the tooth, where the width extends from the leading face to the back face of the tooth. The circular cross-sectional shape for web 56 provides a good structural support structure for the teeth, relatively low flow resistance (compared to a rectangular web), and can be resistant to web damage (compared to webs having other cross-sectional shapes.). Web 78, which is teardrop shaped with the thickest portion of the web facing forward, provides good structural support for the front of the teeth (where damage is most likely to occur) and low resistance to material flow. It should be understood that the disclosed forms are exemplary forms of webs that fall within the scope of this disclosure, and nothing herein is intended to limit the webs to these specific forms.

[0069] FIG. 8(A) and 8(B) show front and side views of teeth 26 having a pair of webs 80, 82. The top web 80 may be eighty to ninety percent (80%-90%) of the height of the teeth 26. The lower web 82 may be at an elevation above the substrate 45, which is from one third to two thirds of the height of the teeth. Alternatively, a pair of webs 80, 82 may be at the same elevation above the substrate, where one web 80 is in front of the other web 82 along the direction of material flow through the teeth (this direction is parallel to the substrate 45).

[0070] Webs can be applied to different plate segments, whereby all rows in a plate segment have webs with the same cross-sectional shape. Alternatively, webs in one row of teeth on an insert segment may have different cross-sectional shapes from those of other rows.

[0071] The webs provide a structural support structure for the teeth on a segment of the plate or the entire plate for the dispersant. Due to the structural support structure provided by the webs, the teeth are more resistant to breakage caused by hard, large particles in the dispersant-treated recycled cellulose material. Due to the structural support structure provided by the webs, the teeth may be taller and/or narrower than would be possible without the webs. Narrower teeth mean more teeth per row.

[0072] The toothed bar segments can be formed by casting metal, such as high wear metal alloys. The mold for casting the plate segments can be formed from sand. The sand mold may be formed by investment casting, 3D printing, or other complementary manufacturing techniques. Sand cores may be needed to form parts of the plate segments. When forming a segment of the plate, the sand form is lost. Alternatively, the wafer segment may be formed directly by 3D printing or other advanced fabrication techniques. In addition, webs can be added to an existing plate segment, for example by welding webs between teeth or wedging wooden pegs, for example to create webs.

[0073] Barbed tooth segments in one or more rows of teeth may be applicable to machines other than dispersers. These machines include opposing discs with rows of intermeshing teeth and are used to separate particles from fibers being processed by the machine, to separate clumps from fibers, or to reduce the size and homogenize feed particles.

[0074] FIG. 9 is a perspective view of two adjacent exemplary disperser teeth 26 having a strut 73 extending from the first 69 tooth face of each of the depicted disperser teeth 26. The region 79 (FIG. 13(A)-(D)) of the strut 73 that is adjacent to the first tooth face 69 (i.e., the “adjacent region”) is smaller than the total area 55 (FIG. 13(A)- (D)) the first 69 facet of the tooth. In certain exemplary embodiments, the exposed area 59 (FIGS. 13(A)-(D)) is about 20%-80% of the total area 55 of the first facet of the tooth. It should be understood that the total area 55 of the first facet of the tooth is the sum of the area 79 of the buttress and the exposed area 59 of the first facet of the tooth.

[0075] The tooth 26 further comprises a second tooth face 53 (FIG. 12(B)) and a body 65 defined by a first tooth face 69, a second tooth face 53, a first tooth flank 67 and a second tooth flank 88 (FIG. 13( A)). Without being bound by theory, the Applicant contemplates that the exemplary supports 73 described herein provide additional support for the dispersant teeth 26 while also allowing a sufficient open area 47 (FIGS. 12(A)-(G)) between adjacent teeth 26 dispersant, allowing recycled material to flow through the open area 47 to maintain sufficient productivity.

[0076] Support 73 of FIG. 9 has the height (h) of the backup. In the depicted embodiment, the height (h) of the strut is less than the height (H) of the tooth, thus exposing the first 69 facet of the tooth. In this image, the first tooth face 69 starts as the back tooth face 26 as the disperser rotates. Without being bound by theory, it is believed that most of the dispersion results from the bending of the recycled fibers between the edges of the intermeshing teeth 26 on the opposing disperser plates. The exposure of the first facet 69 allows operators to reverse the rotation of the disperser plates when the leading facet is worn (see second facet 53). Thus, the disclosed embodiment may allow operators to extend the life of the disperser plate segment.

[0077] In certain exemplary embodiments, the strut 73 is located on the second 53 face of the tooth. In still other exemplary embodiments, the strut may be located on both the first 69 tooth face and the second 53 tooth face. Manufacturers can place and configure the props 73 according to the desired application of the dispersant.

[0078] While not wishing to be bound by theory, it is further contemplated that the use of struts 73, such as the exemplary struts 73 disclosed herein, allow manufacturers to deploy more taller teeth 26 on the backing 45 of the plate disperser segment, thereby enhancing performance. , which the segments of the disperser plate can impart to the recycled fiber per unit area. In certain exemplary embodiments, the dispersant teeth 26 have a flat top 75. In other exemplary embodiments, the top may be pointed.

[0079] The stay 73 further comprises a remote lower edge 85, an upper edge 83, and a hypotenuse (hyp) extending from the upper edge 83 to the remote lower edge 85. In certain exemplary embodiments, the maximum width (w2) of the base (B) of the stay 73 is greater than the width (w1) at the top 83 edge of the stay 73.

[0080] FIG. 10-13 illustrate that the strut 73 may have any number of shapes, provided that the adjacent area 79 of the strut 73 is less than the total area 55 of the facet of the tooth 69, 53 to which the strut 73 is adjacent. Such shapes include, by way of example only, for example, a shape selected from the group consisting of: tetrahedral prism, pyramid, trihedral prism, rectangular prism, and trapezoidal prism. Such shapes can be symmetrical or asymmetrical.

[0081] FIG. 12 is a section through the row along the length of the row of teeth. FIG. 12, each strut 73 is a distinct exemplary embodiment of an exemplary strut. FIG. 12(A) shows the bottom edge 85 removed not extending to the second tooth face 53 of adjacent tooth 26. FIG. 12(D) shows the removed lower edge 85 extending to the second tooth face 53 of adjacent tooth 26. FIG. 12(E) shows a first strut 73 extending from the first face of the first disperser tooth 26 and a second strut 73 extending from the second 53 face of the adjacent disperser tooth 26.

[0082] FIG. FIG. 13 better illustrates the adjacent 79 region relative to the exposed 59 region of the first 69 tooth facet. As shown in FIG. 13(A)-(D), the shape of the stay 73 can vary greatly, provided that the adjacent area 79 is smaller than the total area 55 of the tooth facet 69.52 to which the stay 73 adjoins.

[0083] An exemplary plate segment comprises: a substrate having a front side and a back side, with the back side configured to be attached to the dispersant support disk, rows of teeth protruding from the front side of the substrate, with each of the rows located along an arc extending from one side of the insert segment to the opposite side of the insert segment, in at least one of the rows of teeth, adjacent teeth are connected by a bridge that bridges the gap between adjacent teeth, and the bridge is raised above the front side of the substrate so that the bridge is separated from the front surface by an open space in the gap .

[0084] In an exemplary embodiment, the web is at or near the end of adjacent teeth away from the front side of the substrate.

[0085] In an exemplary embodiment, a bridge connects the sidewalls of each of adjacent teeth.

[0086] In an exemplary embodiment, the bridge connects the sidewalls of adjacent teeth at a tooth elevation above the front side ranging from one third to the full height of adjacent teeth, above the front side.

[0087] In an exemplary embodiment, the web has a shape selected from the group consisting of: circular or oval in cross section at the midpoint of the web between adjacent teeth, rectangular in cross section at the midpoint of the web between adjacent teeth; tapered shape in cross section at the midpoint of the web between adjacent teeth; and drop-shaped in cross section at the midpoint of the web between adjacent teeth.

[0088] In an exemplary embodiment, a web is provided between each of adjacent teeth in at least one of the rows.

[0089] In an exemplary embodiment, the web is a first web between adjacent teeth, and the insert segment includes a second web between adjacent teeth, the second web being at a different height than the first web.

[0090] In an exemplary embodiment, the web is radially in the outermost row, and there is no web in the radially inner row.

[0091] In an exemplary embodiment, the web is a first web between a first pair of adjacent teeth in a row, and the insert segment further comprises a second web between a second pair of adjacent teeth in a row, the first web being at a different height than the first web.

[0092] In an exemplary embodiment, the plate segment is configured to rotate about the axis of rotation, and the plate segment includes an arcuate radially inner edge and an arcuate radially outer edge, and the plate segment has side edges, each of which is aligned along a respective radial line.

[0093] An exemplary machine comprises: a housing including an inlet configured to receive a stream including cellulosic fibrous material, opposing disks secured in the housing so that at least one of the disks rotates about an axis of rotation in the housing, each of the opposing disks has a front surface, and the front surfaces on the opposing disks face each other and are separated by a gap between the opposing disks, each of the opposing disks has rows of teeth on the front surface for the disks, and the teeth in each row of teeth are located at a common radius from the axis rotation, the bridges cover the gaps between adjacent teeth in at least one of the rows of teeth, and the bridges are separated from the substrate of the front surface by an open space in the gap, and the rows of teeth on the front surface of the first of the opposite disks have radii that differ from the radii of the rows of teeth on front surface of the second of the opposite d claims, and at the same time the rows of the first of the opposite disks are engaged with the rows of teeth on the second of the opposite disks.

[0094] In an exemplary embodiment, each of the first and second of the opposing discs includes: a platter attached to either a shaft or directly to the housing, the platter including a mounting substrate, and plate segments attached to the mounting substrate in the form of an annular matrix, and the front surface for the disk is formed by the front surfaces of the segments of the plate.

[0095] An exemplary plate segment comprises: a substrate having a front side and a back side, with the back side configured to be attached to the dispersant support disk, rows of teeth protruding from the front side of the substrate, the rows being located along an arc extending from the first the side of the insert segment to the opposite side of the insert segment, wherein the tooth in the rows of teeth has a first face located remotely from the second face along the tooth body having the first tooth side and the second tooth side, and at the same time from the first tooth side to the substrate, adjacent to the first face of the tooth, the support extends.

[0096] The exemplary plate segment further comprises a strut extending from the second tooth face to a backing adjacent to the second tooth face.

[0097] In an exemplary embodiment, the strut has a height, wherein the height of the strut is less than the height of the tooth from which the strut extends.

[0098] In an exemplary embodiment, the post further comprises an adjacent area, wherein the first tooth facet further has a total area, and wherein the adjacent area of the post is less than the total area of the first tooth facet.

[0099] In an exemplary embodiment, the difference between the adjacent area and the total area defines the exposed area.

[00100] In an exemplary embodiment, the exposed area is in the range of 20%-80% of the total area of the first facet of the tooth.

[00101] In an exemplary embodiment, the strut has a shape selected from the group consisting of: tetrahedral prism, pyramid, trihedral prism, rectangular prism, and trapezoidal prism.

[00102] In an exemplary embodiment, the tooth further comprises a flat surface located on top of the tooth, in addition to the first tooth face, the second tooth face, the first tooth side, and the second tooth side.

[00103] In an exemplary embodiment, the post further comprises a base located on a substrate adjacent to the first face of the tooth, the base having a width, and where the width of the base is greater than the width at the top edge of the post.

[00104] In an exemplary embodiment, the strut further has a hypotenuse extending from the top edge of the strut to the distal bottom edge of the strut.

[00105] In an exemplary embodiment, the distal lower edge abuts a second tooth face belonging to an adjacent tooth.

[00106] While the invention has been described in relation to what is currently considered the most practical and preferred embodiment, it should be understood that the invention is not limited to the disclosed embodiment, but rather is intended to cover various modifications and equivalent arrangements included the essence and scope of the invention.

Claims (60)

1. A plate segment for a material separating machine, comprising: - a substrate having a front side and a back side, with the back side configured to be attached to the support disk of the disperser; - rows of teeth protruding from the front side of the substrate, with each of the rows located along an arc extending from one side of the plate segment to the opposite side of the plate segment; - and at least in one of the rows of teeth, adjacent teeth are connected by a bridge that bridges the gap between adjacent teeth, and the bridge is raised above the front side of the substrate so that the bridge is separated from the front surface by an open space in the gap. 2. The insert segment of claim 1, wherein the web is at the end of adjacent teeth away from the front side of the substrate. 3. The insert segment of claim 1, wherein the web connects the side walls of each of the adjacent teeth. 4. The insert segment of claim 1, wherein the web connects the sidewalls of adjacent teeth at an elevation of the teeth above the front side ranging from one third to the full height of the adjacent teeth above the front side. 5. The insert segment of claim 1, wherein the web has a shape selected from the group consisting of: circular or oval in cross section at the midpoint of the web between adjacent teeth, rectangular in cross section at the midpoint of the web between adjacent teeth; wedge-shaped in cross section at the midpoint of the bridge between adjacent teeth and drop-shaped in cross section at the midpoint of the bridge between adjacent teeth. 6. An insert segment according to claim 1, wherein the web is provided between each of adjacent teeth in at least one of the rows. 7. An insert segment as claimed in claim 1, wherein the web is a first web between adjacent teeth and the insert segment includes a second web between adjacent teeth, the second web being at a different height than the first web. 8. A plate segment according to claim 1, wherein the web is located radially in the outermost row and there is no web in the radially inner row. 9. An insert segment as claimed in claim 1, wherein the web is a first web between a first pair of adjacent teeth in the row, and the insert segment further comprises a second web between a second pair of adjacent teeth in the row, the first web being at a different height than the first. jumpers. 10. The plate segment of claim 1, wherein the plate segment is configured to rotate about an axis of rotation, and the plate segment includes an arcuate radially inner edge and an arcuate radially outer edge, and the plate segment has side edges that are each aligned along a respective radial lines. 11. A machine for separating material, comprising: - a housing including an inlet configured to receive a stream including cellulosic fibrous material; - opposite disks fixed in the housing so that at least one of the disks rotates around the axis of rotation in the housing; wherein each of the opposing discs has a front surface, and the front surfaces on the opposing discs face each other and are separated by a gap between the opposing discs; each of the opposite disks has rows of teeth on the front surface for the disks, and the teeth in each row of teeth are located at a common radial distance from the axis of rotation; the webs span gaps between adjacent teeth in at least one of the rows of teeth, the webs being separated from the front surface substrate by an open space in the gap; moreover, the rows of teeth on the front surface of the first of the opposite disks have radii different from the radii of the rows of teeth on the front surface of the second of the opposite disks; and wherein the rows of the first of the opposite disks are placed with the possibility of free rotation between the rows of teeth on the second of the opposite disks. 12. The machine of claim 11, wherein the first of the opposing discs is a rotor disc that rotates about an axis of rotation, and the second of the opposing discs is a stator disc that is permanently located in the housing. 13. The machine according to claim 11, in which each of the first and second of the opposite discs include: - a platter attached either to a shaft or directly to the housing, the platter including a mounting substrate; and - plate segments attached to the mounting substrate in the form of an annular matrix, and the front surface for the disk is formed by the front surfaces of the plate segments. 14. The machine of claim 11, wherein the web is located at the end of the teeth away from the front surface substrate. 15. Machine according to claim 11, in which each of the jumpers is connected to the side walls of adjacent teeth. 16. The machine of claim 11, wherein each of the webs is connected to the sidewalls of adjacent teeth at an elevation of the teeth above the front surface substrate in the range of thirty to ninety percent of the height of the adjacent teeth above the substrate. 17. The machine according to claim 11, in which the bridge has a shape selected from the group consisting of: circular or oval in cross section at the midpoint of the bridge between adjacent teeth, rectangular in cross section at the midpoint of the bridge between adjacent teeth; wedge-shaped in cross section at the midpoint of the bridge between adjacent teeth and drop-shaped in cross section at the midpoint of the bridge between adjacent teeth. 18. Machine according to claim 11, wherein the webs are between each pair of adjacent teeth in at least one of the rows. 19. The machine of claim 11, wherein the webs include at least two webs between a pair of adjacent teeth. 20. A machine as claimed in claim 11, wherein there are webs radially in the outermost row and no webs in the radially inner row. 21. The machine of claim 11, wherein the webs include a first web between a first pair of adjacent teeth in the row and a second web between a second pair of adjacent teeth in the row, the first web being at a different height than the first web. 22. A plate segment for a material separating machine, comprising: - a substrate having a front side and a back side, with the back side configured to be attached to the support disk of the disperser; and - rows of teeth protruding from the front side of the substrate, the rows being arranged along an arc extending from the first side of the insert segment to the opposite side of the insert segment, moreover, the tooth in the rows of teeth has a first face located remotely from the second face along the tooth body having the first side of the tooth and the second side of the tooth, and wherein a support is provided extending from the first tooth face only to the substrate adjacent to this first tooth face, or in an oblique direction to the second face of the adjacent tooth from the first tooth face to the substrate adjacent to this first tooth face. 23. The plate segment of claim 22, further comprising a strut extending towards the face of the second adjacent tooth from the second face of the tooth to a backing adjacent to the second face of the tooth. 24. A plate segment according to claim 22, wherein the stay has a height, and wherein the height of the stay is less than the height of the tooth from which the stay extends. 25. A plate segment as claimed in claim 22, wherein the post further comprises an adjacent area, wherein the first tooth face further has a total area, and wherein the adjacent area of the post is less than the total area of the first tooth face. 26. The plate segment of claim 25, wherein the difference between the adjacent area and the total area defines the exposed area. 27. A segment of the plate according to claim 26, in which the exposed area is in the range of 20-80% of the total area of the first facet of the tooth. 28. A plate segment according to claim 22, wherein the stay has a shape selected from the group consisting of: tetrahedral prism, pyramid, trihedral prism, rectangular prism, and trapezoidal prism. 29. The plate segment of claim 22, wherein the tooth further comprises a flat surface located on top of the tooth, in addition to the first tooth face, the second tooth face, the first tooth side, and the second tooth side. 30. The plate segment of claim 22, wherein the post further comprises a base located on a substrate adjacent to the first face of the tooth, the base having a width, and where the width of the base is greater than the width at the top edge of the post. 31. The plate segment of claim 22, wherein the strut further has a hypotenuse extending from the top edge of the strut to a distal bottom edge of the strut. 32. The insert segment of claim 31, wherein the distal bottom edge abuts a second tooth face belonging to an adjacent tooth. 33. The plate segment of claim 22, configured to rotate about an axis of rotation and includes an arcuate radially inner edge and an arcuate radially outer edge, and has side edges each aligned along a respective radial line. 34. A plate segment for a material separation machine, comprising: - a substrate having a front side and a back side, with the back side configured to be attached to the support disk of the disperser; and - rows of teeth protruding from the front side of the substrate, the rows being arranged along an arc extending from the first side of the insert segment to the opposite side of the insert segment, moreover, the tooth in the rows of teeth has a first face located remotely from the second face along the tooth body having the first side of the tooth and the second side of the tooth, and wherein a support is provided extending from the first face of the tooth to a support extending from the second face of the adjacent tooth, wherein the strut extending from the first face of the tooth to the strut extending from the second face of the adjacent tooth meets it at a height above the substrate that is less than the full height of the tooth. 35. The plate segment of claim 34, wherein the post further comprises an adjacent area, wherein the first tooth face further has a total area, and wherein the adjacent area of the post is less than the total area of the first tooth face. 36. The plate segment of claim 35, wherein the difference between the adjacent area and the total area defines the exposed area. 37. A segment of the plate according to claim 36, in which the exposed area is in the range of 20-80% of the total area of the first facet of the tooth. 38. The plate segment of claim 34, wherein the tooth further comprises a flat surface located on top of the tooth, in addition to the first tooth face, the second tooth face, the first tooth side, and the second tooth side. 39. The plate segment of claim 34, configured to rotate about an axis of rotation and includes an arcuate radially inner edge and an arcuate radially outer edge, and has side edges each aligned along a respective radial line.

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