The present invention relates to a reel shaft for reeling a paper web in a reel-up in a paper machine, which reel-up includes at least one unit that is mobile in the longitudinal direction of the paper machine and supports a pair of opposite engagement members each of which includes an engagement part, which engagement parts are arranged for rotatably carrying and detachably engaging the reel shaft during reeling.
The invention also relates to a reel-up in a paper machine, in which paper is continuously manufactured in a coherent web that is wound onto reel shafts in the reel-up to form paper rolls, in which the reel shafts constitute reeling cores, which reel-up comprises
During continuous reeling of paper in a reel-up in a modem paper machine, very stringent demands as regards strength are made on the reel spools on which the paper web is wound to form jumbo rolls. A modern paper machine produces paper with a web speed of several thousand meters per minute, and the width of the paper web in such machines is ordinarily in the range 2.5-8 meters. Accordingly, the reel spools must be sturdily dimensioned to withstand the weight of the paper roll and the rotational speed required by the web speed. The demands made on a reel spool in the reel-up of a paper machine are thus completely different from the demands made on reel spools occurring in machines for subsequent processing of the paper roll, for instance rewinders and slitter-winders.
To meet the requisite demands for strength, known types of reel spools comprise a hollow steel reel spool. At its ends, the steel reel spool usually has protruding shaft journals, intended to support the steel reel spool rotatably in the reel-up. In a common type of reel shaft, a paper core is detachably attached to the envelope surface of the steel reel spool by means of a locking device. Thus, the steel reel spool acts as a support shaft for the paper core and, once the paper web has been wound onto the reel spool, the locking device is disengaged from the paper core, whereupon the steel reel spool is extracted from the paper core with the aid of an extraction device. The exposed steel reel spool is thereupon provided with a new paper core and returned to a nearby stock of steel reel spools provided with paper cores to be used in a subsequent reeling sequence. Accordingly, the paper core forms the core of the wound paper roll and thus accompanies the wound paper to subsequent processing procedures. When the paper core in due course is disengaged from the paper during such a processing procedure, for instance during rewinding of the paper roll, an uncovered steel reel spool is inserted into the paper core and thereafter placed in the stock of steel reel spools provided with paper cores for the reel-up.
It is known to cover the steel reel spool with a composite core of fiber-reinforced plastic instead of a paper core. Whereas a paper core must usually be discarded after about three reeling cycles, that is after being mounted on and removed from steel reel spools three times, a plastic composite core has a virtually unlimited service life.
Another type of reel spool is described in U.S. Pat. No. 3,743,199, which, in common with the spindle described above, consists of a steel reel spool, having protruding shaft journals at its ends, intended to support the reel spool rotatably in the reel-up. Unlike the reel spool described above, however, the paper is in this case wound directly onto the envelope surface of the steel reel spool. In addition, at least one of the shaft journals exhibits a channel running axially through the same and communicating with the hollow interior of the steel reel spool, and the envelope surface of the steel reel spool exhibits a plurality of evenly distributed holes running through the same and likewise communicating with the hollow interior of the steel reel spool. When the paper web is to be wrapped around the empty steel reel spool in the initial phase of the reeling, a vacuum pump is connected to the shaft journal exhibiting the through-running channel, or to both shaft journals if both shaft journals exhibit through-running channels, to generate a negative pressure inside the steel reel spool. The negative pressure creates a flow of air in through the holes in the envelope surface of the steel reel spool, which flow of air unsettles the film of air surrounding the paper web so that the paper web can be adjoined to the steel reel spool more easily, thereby facilitating the wrapping of the paper web on the steel reel spool. In this case, however, the steel reel spool must accompany the wound paper to subsequent processing procedures, as the steel reel spool cannot normally be withdrawn from the paper roll without difficulties. When the paper in due course is unreeled from the steel reel spool, the same is returned to the stock of steel reel spools in the reel-up to be used in a subsequent reeling sequence.
Using a reel spool comprising a steel reel spool entails numerous problems, however. As previously mentioned, a reel spool must be dimensioned to satisfy predetermined strength criteria, and, because of the strength criteria, the steel reel spool must be fashioned with a large diameter and substantial material thickness. Consequently, a conventional reel spool has considerable mass and a great moment of inertia with respect to its rotational axis. This makes it very difficult to balance a conventional reel spool and it is almost inevitable that the reel spool must exceed at least one rotational speed that is critical as regards self-oscillation to achieve normal rotational speed for reeling. This subjects both the reel-up and the reel spool to very considerable mechanical stress. Moreover, irrespective of said self-oscillation, the great mass and moment of inertia of the conventional reel spool require the reel-up to have sturdy dimensions to support, control, accelerate, and decelerate the reel spool. The great mass of the conventional reel spool also makes it very difficult to regulate the linear load in the paper web, especially in the initial phase of the reeling, as the weight of the reel spool greatly outweighs the linear load. A further problem arises in such cases where the finished paper roll rests on a plane surface with the reel spool still in place at the center of the paper roll, as sometimes occurs. In such cases, the paper roll can be deformed under the weight of the reel spool. This is a problem particularly in the manufacture of soft crepe paper, where costly additional equipment is necessary to relieve the mass of the reel spool so that the paper roll is not damaged by compression. Besides, the target aimed at in the current trend, especially in the manufacture of soft crepe paper, is ever higher web speeds, which, to satisfy strength requirements, necessitates steel reel spools with ever greater diameters and that are ever more rigid and heavy, which accentuates the above-mentioned problems.
A further problem can arise when using a reel spool of the type described above, which is that a gap can arise between the steel reel spool and the paper or plastic composite core covering the steel reel spool during reeling. When such a gap arises, balancing faults occur, which make it difficult to regulate the linear load. This is a problem particularly when using paper cores, as paper cores can be difficult to manufacture within the margins of tolerance that ensure a good fit between the paper core and the steel reel spool. Further, paper cores are not particularly stable in shape, which means that they can lose their original shape during the course of processing.
Another problem additionally arises in the reel spool described in U.S. Pat. No. 3,743,199. The shaft journals and their fastenings in the steel reel spool must be sturdily dimensioned, because of the weight of the steel reel spool. In reel spools of this type, the cross-sectional area of the channel in the shaft journal through which air is extracted from the hollow interior of the steel reel spool is therefore small relative to the cross-sectional area of the channel forming the hollow interior of the steel reel spool. As the limited cross-sectional area of the channel in the shaft journal constitutes an obstacle to the flow of air, it can be difficult to achieve the desired negative pressure inside the steel reel spool during the initial wrapping.
A main object of the present invention is to provide a reel shaft for reeling a paper web that at least substantially alleviates the problems associated with the great mass and moment of inertia of conventional reel shafts.
A further object of the invention is to provide a reel shaft that completely eliminates the above-mentioned problems with a loose-fitting paper or plastic composite core.
Another object of the invention is to provide a reel shaft that at least substantially alleviates the problem that arises during initial wrapping aided by negative pressure due to the great mass and moment of inertia of conventional reel shafts.
The reel shaft and the reel-up in accordance with the invention are wherein the reel shaft is free of a support shaft and includes a self-supporting, tubular sleeve, substantially consisting of fiber-reinforced plastic, which sleeve has an envelope surface on which the initial wrapping of the paper web shall be performed, and also an internal surface, defining an axial channel in the sleeve, terminating in axial openings at the ends of the reel shaft.
Stating that the reel shaft lacks a support shaft here denotes that it does not have a shaft running through it axially to give the sleeve radial support. Accordingly, the sleeve is self-supporting, that is to say that the sleeve in itself possesses the requisite strength for reeling machine reels, which means that the sleeve has a strength that is on a par with the strength of steel reel spools in known reel shafts. However, by virtue of the reel shaft being manufactured of fiber material impregnated with a plastic material, the reel shaft is considerably lighter than conventional reel shafts. The previously described problems relating to the great weight and moment of inertia of conventional reel shafts are thereby significantly alleviated.
Moreover, the aforementioned problem with a gap between the tubular roll and the paper or plastic composite core is eliminated in that the reel shaft does not need an axial support shaft.
In accordance with one embodiment of the reel shaft, the sleeve exhibits a plurality of holes passing through its envelope surface. By fashioning at least one of said engagement members with an axial through-running channel that communicates with the channel of the sleeve and through which the reel shaft can be connected to a vacuum system for creating a negative pressure inside at least a part of the reel shaft, a reel shaft for initial wrapping aided by negative pressure is provided that is lightweight thanks to its plastic composite material. Consequently, the cross-sectional area of the channel in the engagement member can be made large without the strength of the engagement member being jeopardized.
Having thus described the invention in general terms, reference will now be made to the accompanying drawings, which are not necessarily drawn to scale, and wherein:
The present inventions now will be described more fully hereinafter with reference to the accompanying drawings, in which some, but not all embodiments of the invention are shown. Indeed, these inventions may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein; rather, these embodiments are provided so that this disclosure will satisfy applicable legal requirements. Like numbers refer to like elements throughout.
The sleeve 2 is self-supporting, that is to say that no spindle or axial support element is intended to be introduced into the sleeve 2 to support the same during reeling. Accordingly, the sleeve 2 itself must satisfy the strength requirements made on a reel shaft. In accordance with the invention, the sleeve 2 consists mainly of fiber-reinforced plastic, that is a fiber material impregnated with a suitable plastic material. Preferably, the fibers in the fiber-reinforced plastic consist of carbon, aramid, or glass fibers, wound onto an arbor, and the plastic consists of thermo-setting plastic, which is caused to impregnate the fibers wound onto the arbor during the manufacture of the sleeve 2 and thereafter to harden. During the sleeve's manufacture, the strength properties of the sleeve 2, for instance the modulus of elasticity of the sleeve 2, can be controlled in that two consecutive winding turns of fibers are wound at respectively disparate angles. The plastic composite configuration of the sleeve 2 ensures that the reel shaft 1 exhibits a strength that is on a par with a conventional reel shaft comprising a steel reel spool. The reel shaft 1 is much lighter, however. By way of illustration, it is noted that a 5.5 m long reel shaft in accordance with the invention, satisfying the requisite strength criteria, can weigh as little as 800 kg, whereas a corresponding conventional reel shaft comprising a steel reel spool weighs approximately 3100 kg. It should thus be understood that the problems relating to the great weight and moment of inertia of conventional reel shafts described previously can be significantly alleviated with a reel shaft 1 in accordance with the invention. The length of the reel shaft 1 corresponds suitably to the machine width of the paper machine in which the reel shaft 1 is intended to be used, which length is usually in the range 2-8 m. The diameter of the sleeve 2 is preferably in the range 310-800 mm and the material thickness of the sleeve 2 in the range 15-36 mm.
In the following, the previously described engagement members 32, 33, and the manner in which they cooperate with a reel shaft in accordance with the invention, will be described with reference to
A stock 46 of empty reel shafts 23 is located at the upstream end of the reel-up, above the reel drum 43. The stock 46 comprises a substantially horizontal shelf 47, on which the empty reel shafts 23 rest next to each other and parallel to the reel drum 43, waiting to be reeled in the reel-up. The reel-up comprises an advancement unit 48 in the form of a carriage, which is mounted on rails 49 to be linearly movable for collecting the empty reeling shafts 23 sequentially from the stock 46 and bringing them with the aid of lowering arms 50 to a reeling system for reeling. In
Said reeling system comprises a first movable unit 51 and a mirror-inverted second movable unit 52 in the form of carriages. Each carriage 51, 52 comprises two parallel carriage bodies 53, 54, each mounted on one of the stand parts 41, 42, respectively, to be linearly movable in the longitudinal direction of the paper machine. For this purpose, the reel-up comprises actuators (not shown), arranged to influence the movement back and forth of the carriages 51, 52 in the longitudinal direction of the paper machine and consisting of, for instance, hydraulic or pneumatic piston cylinders. Each carriage body 53, 54 comprises a sledge 55, cooperating with one of the stand parts 41, 42, respectively, and also a pivot unit 57, pivotably mounted about a rotary shaft 56 on the sledge 55. The rotary shafts 56 are parallel to the reel drum 43, and each pivot unit 57 can be raised and lowered in relation to its sledge 55 by a pivoting movement about its rotary shaft 56 with the aid of a hydraulic or pneumatic piston cylinder 58. In each carriage 51, 52, the two engagement members 32, 33 described in connection with
The reel-up comprises a vacuum system, which here denotes a system for creating a predetermined pressure below normal atmospheric pressure. The vacuum system encompasses a first vacuum unit 59, situated on the operator side of the paper machine in the vicinity of the reel drum 43, and a mirror-inverted second vacuum unit 60, situated on the drive side of the paper machine in the vicinity of the reel drum 43. Each vacuum unit 59, 60 comprises an air pipe 61, which at one of its ends (not shown) is connected to a vacuum pump or a partial-pressure tank (not shown). Each air pipe 61 is, at its other end, connected to a nozzle 62. Each nozzle 62 is movably mounted on a stand 67 so that the nozzle 62 can perform a linear movement in the transverse direction of the paper web 40 as well as a movement in the longitudinal direction of the paper machine and a movement in the vertical direction. Each engagement member 33 is arranged to receive one of the nozzles 62 at its recess 38 (see
To accelerate an empty reel shaft 23′ in connection with a reeling sequence and thereafter to control the rotational speed of the reel shaft 23″, each carriage body 53 comprises an auxiliary drive system, that is arranged to drive, i.e. to rotate, the engagement member 32 on the carriage body 53 during a reeling sequence. For this purpose, the auxiliary drive system comprises a drive device 63, which can consist of an electric motor rigidly mounted on the carriage body 53, and a drive belt transmitting the turning torque of the motor to the engagement member 32.
A reeling sequence encompasses the following. The starting position is as shown in
The invention has been described above with reference to several embodiments. However, it should be understood that the invention is not limited to these. For instance, a reel shaft of the type shown in
This application is a continuation of International Patent Application PCT/SE01/01469 filed Jun. 27, 2001, which designated inter alia the United States and was published under PCT Article 21(2) in English, and which claims the benefit of U.S. Provisional Patent Application No. 60/214,507 filed Jun. 28, 2000.
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Number | Date | Country | |
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20030141403 A1 | Jul 2003 | US |
Number | Date | Country | |
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60214507 | Jun 2000 | US |
Number | Date | Country | |
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Parent | PCT/SE01/01469 | Jun 2001 | US |
Child | 10331112 | US |