This nonprovisional application claims priority under 35 U.S.C. §119(a) to German Patent Application No. DE 202007 007 038.1, which was filed in Germany on May 14, 2007, and which is herein incorporated by reference.
1. Field of the Invention
The invention relates to a device for dewatering bulk or free-flowing input material by compression.
2. Description of the Background Art
Within system and process engineering, a starting material is generally processed during its successive treatment to the desired final product. As a general rule, this is done stepwise during its passage through different processing stations.
An example of such a type of processing is the workup of lignocellulose-containing material, such as wood, annual plants, straw, bagasse, and the like. In such processes, the processing stations of pre-grinding, washing, pre-steaming, dewatering, cooking, defibration, drying, and separation are passed through. The fibers obtained in this way can then be used to produce pulp in paper manufacturing or as wood fibers in the manufacturing of wood fiber production, for example of MDF products.
The invention is based on a device with which the input material is dewatered by compressing it. In the above-described process, such a device can, for example, be arranged as a plug screw in front of a cooker with the function of making possible the introduction of the free-flowing input material into a subsequently pressurized system with simultaneous dewatering of the input material.
The theoretical design of such a device provides a housing with a jacket pipe, in which a screw shaft with a circumferential helix rotates, which in cooperation with axially aligned feed strips transports the still loose input material to the opposite end of the jacket pipe. As a result of the jacket pipe tapering conically toward this end or the decreasing pitch of the screw helix, the input material is strongly compressed and the residual water present in the input material is squeezed out. The removal of the squeezed-out water takes place through openings in the jacket pipe, which are adapted in their size and shape to the type of input material.
In addition to the squeezing out of the residual water, the compression of the input material also serves to create a highly compressed material plug, which ensures sealing of the inlet opening against the pressurized cooker system.
One drawback of such devices results from the high compression of the input material, resulting in higher compression forces on the inside of the screw jacket. These cause high abrasion both on the screw helix and on the jacket pipe, so that known devices must be repaired or reinforced at regular intervals. The resulting shutdown times and work reduce the economical operation of such devices.
An additional drawback results from the fixed geometry of the elements involved in the dewatering, which makes adaptation of known devices to the uniqueness of varying input materials impossible.
It is therefore an object of the invention to further develop a device for dewatering bulk or free-flowing input material.
In an embodiment, an inner jacket surface of the device, at least in the areas subject to high stress, is designed to be simply and rapidly replaceable. This is accomplished by separating the functional components into those with static supporting function and those with dewatering function. The supporting function is performed by the solid housing or jacket pipe of the device, which is provided with relatively large passages in view of the nature of the input material. The dewatering function, in other words, the separation of the input material from the squeezed-out water, is the job of the relatively slender inner pipe, which is supported against the inner circumference of the jacket pipe in the area of the passages, has passage openings for the squeezed-out water adapted to the nature of the input material. This division of functions makes possible the tailor-made adaptation of a device in accordance with the invention, both to static and also to process-related requirements, with the goal of optimizing both the structure and the quality of the processing.
In contrast to the conventional art, where the passage openings have a dimensional character because of the thickness of the jacket pipe and very small particles in the input material entail the risk of clogging of the openings, the very slender design of the parts guaranteeing the dewatering function results in an essentially two-dimensional dewatering surface, with which clogging of the openings is not to be expected. This effect is further increased through the formation of the passage openings as stepped holes. As a result, it is possible to select the cross section of the passage openings to be smaller overall, and thus to reduce proportionately the fraction of solid particles passing through the passage openings.
Since the parts forming the inner jacket surface are very slim in design, they can be made of high-strength material without greatly increasing the manufacturing costs, and therefore combat an excessively rapid wear. The longer useful lives of the machinery and longer maintenance intervals result in an additional economic advantage for the operator of devices in accordance with the invention.
In the interplay of the aforementioned functional components, it has been proven advantageous if the areas of the passage openings in the inner pipe amount to about 20% to 40%, preferably 25% to 30% of the cross sectional area of the passage openings in the jacket pipe and the plug screw. This results in establishment of a balanced ratio between adequate strength and high dewatering performance.
In practice, passage openings with diameters of 2 mm to 10 mm, preferably 4 mm to 8 mm, have proven suitable. However, other diameter ranges are likewise within the scope of the invention.
It has proven advantageous to form the passage openings in such a way that these expand in the passage direction, which can be accomplished in a conical or stepwise fashion. In this way the flow-through resistance decreases in a radially outward direction, which promotes the removal of the squeezed-out water and prevents clogging of the passage openings.
To minimize wear, according to an example embodiment, it is sufficient to design the device in accordance with the invention only in the end area of the jacket pipe or in the area of the plug pipe, since these are the areas of greatest compaction and thus the greatest wear.
In embodiments of the invention with a bearing pin at the end of the drive shaft, the compaction in the area of the plug pipe can be systematically influenced by a corresponding pin shape. For example, the compaction is increased by a bearing pin that expands conically in the direction of movement. A diameter of the bearing pin that decreases gradually toward the end can allow for gradual reduction of pressure on the input material, whereas a cylindrical bearing pin has neutral behavior.
In addition, it is advantageous to design the end of the jacket pipe as an independent component in the form of a plug pipe, which facilitates maintenance and repair work.
In a simple embodiment of the invention, the inner pipe is screwed together with the jacket pipe or plug pipe to impede relative movements of the two parts with respect to one another. An advantageous alternative with respect to rapid installation or replacement of the inner pipe is provided by form-locking means that to be sure, permit axial sliding-in of the inner pipe, but block rotation relative to the jacket pipe. Movement of the inner pipe relative to the jacket pipe in the axial direction is prevented by stops.
Further scope of applicability of the present invention will become apparent from the detailed description given hereinafter. However, it should be understood that the detailed description and specific examples, while indicating preferred embodiments of the invention, are given by way of illustration only, since various changes and modifications within the spirit and scope of the invention will become apparent to those skilled in the art from this detailed description.
The present invention will become more fully understood from the detailed description given hereinbelow and the accompanying drawings which are given by way of illustration only, and thus, are not limitive of the present invention, and wherein:
A conically tapered jacket pipe 9, fastened coaxially at the cylindrical input area 4 via ring flanges, is fastened to the side of the cylindrical input area 4 opposite the housing closure 6. In this way a continuous feeding and compaction chamber 10 results in the axial direction along the axis of rotation 2. On the inner surfaces delimiting the feeding and compaction chamber 10 one can see approximately axially aligned conveying grooves 11, which are distributed uniformly over the inner circumference. In addition, radial dewatering openings 12 are introduced into the jacket pipe 11, over which the squeezed-out water is conducted from the input material.
The dewatering pipe 9 is surrounded on the circumferential side by a cylindrical metal sheet 13, which in this way forms a collecting channel for the squeezed-out water labeled as 38. At its base can be seen an outlet 14 for the squeezed-out water and at its apex an outlet 15 for exiting air and exiting steam.
In the feeding and compaction chamber 10 along the axis of rotation 2, the drive shaft 8 extends, and a coil 16 runs helically along its circumference. Corresponding to the course of the jacket pipe 9 in the feeding and compaction chamber 10, the external diameter of the coil 16 decreases and, to ensure the axial transport of the input material, acts together with the feed strips 11 on the inner circumference of the feeding and compaction chamber 10.
The end of the drive shaft 8 forms a bearing pin 17, which is surrounded by a so-called plug pipe 18. The plug pipe 18 represents the axial extension of the jacket pipe 9 and has the task of accomplishing a tight and pressure-resistant connection to the upstream areas of the process engineering, for example a cooker operated at elevated pressure. The connection is formed by highly compacted input material, forming a plug, which simultaneously forms the radial bearing for the bearing pin 17.
The more detailed design of the plug pipe 18 is also apparent from
The annular flanges 20 and 21 are surrounded on the peripheral side by two half-shell shaped trays 23 and 24, which can be put together to make a cylindrical structure. Each of the trays 23 and 24 comprises two supporting profiles 25, on the outer circumference of which a round metal sheet 26 is fastened. The trays can be assembled over opposing longitudinal flanges 27 to make a hollow cylinder, which in the finished state completely surrounds the plug pipe 18 and into which squeezed-out water 38 enters from the input material. In the base area of the lower tray 24 an outlet 28 for carrying off the collected squeezed-out water 38 is visible.
In the axial overlapping area with the bearing pin 17, the pipe section 19 of the plug pipe 18 has radial passages 29 of rectangular shape, resulting in a perforated grid structure in a small space. The passages 29 assigned to the end of the jacket pipe 9 can also taper toward the outside over the wall thickness of the pipe section 19.
In the area of the passages 29, the pipe section 19 is machined out on its inner circumference, so that a graded enlargement of the inner diameter results. This serves to accommodate an inner pipe 30, which in this way can be slid into the plug pipe 18 until it comes to rest with its front end on the annular shoulder 31 formed by the step. In this process, the inner pipe 30 at the other end fits flush with the front face of the plug pipe 18.
Advantageously, the inner pipe 30 can be made in a single piece for fast assembly and disassembly, or can be made up of two half-shells, and includes an abrasion-resistant material. Along its inner circumference in an extension of the feed strips 11, additional feed strips 32 are visible. The fastening and positional securing of the inner pipe 30 in the plug pipe 18 takes place via screws 33, which extend radially through the cylindrical pipe section 19 of the plug pipe 18 and mesh with their threads in threaded borings that extend into the cross sectional area of the feed ribs 32 in the inner pipe 30. In this way the tension from the screws 33 is distributed over a large area via the feed ribs 32 to the inner pipe 30.
The inner pipe 30 has a plurality of dewatering areas 34 which are distributed over the circumference congruently to the passages 29. Each dewatering area 34 has a plurality of passage openings 35 arranged with respect to one another in the manner of a sieve, through which the squeezed-out water 38 passes from the plug pipe 18. The passages 29 and the passage openings 35 thus work together in removing the squeezed-out water 38.
In the operation of the device in accordance with the invention, the input material, as indicated by the arrow 36, is loosely fed into the input hopper 5, in which it moves downward under the influence of gravity and enters the intake zone of the plug screw 1. There it is picked up by the coils 16 and transported in the direction of the arrow 37. Through the conveyance and compaction chamber 10, continuously becoming smaller in the direction of movement 37, the input material is continuously compacted until it has its greatest packing density at the end of the jacket pipe 9. The water 38 initially squeezed out as a result of the increasing compaction passes over the dewatering openings 12 into the collecting tray formed by the cylindrical metal sheet 13 and is disposed of via the outlet 14.
To be able to withdraw additional water from the compacted input material, the possibility also exists for free water in the area of the inner pipe 30 and thus in the area with the greatest pressure to escape from the device through the passage openings 35 and radial passages 29, to collect in the tray 24, and to be conducted away over the outlet 28.
An embodiment of the invention with an alternative design of the inner pipe 30′ is shown in
The inner pipe 30′ shown in
The fastening of the arc segments 40 takes place by way of feed strips 32′, likewise representing arc segments, which can be clamped radially outward by screws 33 against the inner jacket of the pipe segment 19. The foot area of the feed strips 32′ tapers in the direction of its footprint on the inner circumference of the plug pipe 18, so that the sides of the feed strips 32 form wedge-shaped surfaces that interact with the beveled longitudinal edges 41 of the arc segments 40. Upon tightening the screws 33, consequently a clamping effect of the arc segments 40 takes place, guaranteeing that these will be securely seated within the plug pipe 18. This type of fastening has the advantage that individual arc segments 40 may also be replaced.
The invention also covers embodiments that are not shown, in which the shaft has no bearing pins and no plug pipe, and therefore compaction and dewatering in accordance with the invention only takes place in the last section of the jacket pipe.
The invention being thus described, it will be obvious that the same may be varied in many ways. Such variations are not to be regarded as a departure from the spirit and scope of the invention, and all such modifications as would be obvious to one skilled in the art are to be included within the scope of the following claims.
Number | Date | Country | Kind |
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20 2007 007 038 U | May 2007 | DE | national |
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Number | Date | Country | |
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20080287277 A1 | Nov 2008 | US |