EP4310248A1 - Screen support rod for use in the pulling of a tibial in a paper machine - Google Patents

Abstract

Screen support rod (10) for use when pulling the screen into a paper machine, comprising a support tube (1), which is made of CFRP, and a telescopic rod (3), as well as a bearing with which the telescopic rod (3) is inside the support tube ( 1) is mounted axially displaceably, with at least one shrink tube (2) being applied to the support tube (1) in such a way that the shrink tube (2) forms the surface on which the corresponding sieve is supported when used for pulling in the sieve.

Description

The invention relates to a screen support rod for use when pulling the screen into a paper machine, comprising a support tube made of CFRP and a telescopic rod, as well as a bearing with which the telescopic rod is mounted in an axially displaceable manner inside the support tube. The invention further relates to a support tube for such a sieve support rod.

Screen support rods have long been known as an aid to pulling endless screens into a paper machine. Here, sieves also include felts and other coverings for a paper machine. And a paper machine is considered to be all machines for the production of paper or paper-like fibrous webs, such as cardboard, tissue or pulp machines.

When pulling in, the endless screen is first draped, without tension, into the required shape of the screen run using several screen support rods on the side next to the corresponding section of the paper machine, with one side of the screen support rods being connected to the paper machine frame for support. The respective telescopic rod is pulled out of the support tube so that the telescopic rod can be attached or supported on the chair of the paper machine. The other side of the screen support rods is supported in a frame or on the building or held with an indoor crane. The support tubes of the screen support rods are then moved towards the paper machine, with the telescopic rods pushing back into the support tubes until the support pipes with the draped screen are positioned laterally close to the rollers that are supposed to carry the screen in the paper machine. The screen is then pulled laterally onto the rollers over the screen support rods or via their support tubes until the screen is in the desired position in the paper machine. The sieve slides over the surface of the sieve support rods or their support tubes.

The telescopic rod is mounted in the support tube in such a way that it allows it to be moved relative to one another and also when extended forms a sufficiently stable connection between the telescopic rod and the support tube for carrying the sieve.

In the prior art, screen support rods for pulling endless screens into a paper machine, for example in GB 503118 A described. As described there, some sieve support rods are also required to transport the endless sieves.

In the DE 1945230 A Please note that the sensitive surface of the sieves can be damaged if they are pulled over the sieve support rods when being pulled in. As a solution to avoid this, it is proposed to design the entire frame in which the screen support rods are held so that it can be moved into the paper machine and remain there. This means that no sieves are pulled laterally over the sieve support bars. However, this solution involves considerable design effort and is not possible in every paper machine due to space constraints.

The object of the invention is to provide a better, more flexible and cost-effective option for pulling in screens in the paper machine, which ensures that the surface of the screens is not damaged in the process.

The object is achieved according to the invention for the sieve support rod by an embodiment according to independent claim 1. Further advantageous embodiments of the present invention can be found in the corresponding subclaims. The advantageous embodiment is characterized in that at least one shrink tube is applied to the support tube in such a way that the shrink tube forms the surface on which the corresponding sieve is supported when used for pulling in the sieve. The shrink tubing makes the surface on the support tube so smooth that the screen is not damaged even when pulled over it. In addition, shrink tubing is inexpensive and can be easily applied. The surface of the CFRP support tube without any further reference is too rough and would damage the sieve when pulled over it. On the other hand, CFRP is for that Support tube is a preferred material that makes the sieve support rod lighter and thus simplifies handling the sieve support rod and its transport.

The invention can therefore provide a light, easy-to-handle and cost-effective screen support rod. This is still light even with large screen widths and can be flexibly manufactured for different screen widths. And what is particularly important, there is no risk that the sensitive surface of the sieves will be damaged when pulling in the sieves.

Another advantage is that the shrink tubing can be easily replaced and renewed if it is damaged. This means the sieve support rod can be easily repaired. It is also possible to remove only part of the shrink tubing and replace this section with a new shrink tubing. Since a new shrink tube is simply installed by heating it, repairs can be carried out on site without much effort.

A shrink tube is a thermoplastic tube that contracts radially when exposed to heat, for example from a hot air gun. This means the shrink tubing can easily be attached to the support tube. Shrink tubing is manufactured by radially stretching the extruded tubing while it is warm and then cooling it down in the stretched state. This means that the expansion remains fixed in the shrink tube for the time being. When heated again, the shrink tube contracts again. A shrink tube made of hard PVC is particularly preferably used for the invention in order to form an abrasion-resistant surface. Since the shrink tubing in this case is applied to a tube with a constant diameter, a low shrink ratio is sufficient. The outer diameter of the support tube is preferably between 80 mm and 250 mm. This depends, among other things, on the width of the sieve and how stiff the support tube should be. The length of the support tube is at least as large as the width of the sieve to be pulled in. Usual lengths of the support tube are between 3 m and 14 m, preferably between 8 m and 13 m.

The telescopic rod is usually designed as a tube and is between 2 m and 5 m, preferably between 3 m and 4 m long. This means that the screen can be draped next to the paper machine at a sufficient distance before it is moved close to the rollers in the paper machine by moving it on the telescopic rod.

CFRP is the name for carbon fiber reinforced plastic. The support tube is particularly preferably made from CFRP with continuous fibers. A thermoset is preferably used as the matrix material, for example epoxy resin.

Furthermore, there is an advantage if the shrink tube is applied next to one another in the form of several shrink tube sections. This makes it easier to install the shrink tubing. This is particularly advantageous for particularly long support tubes. In addition, if the surface is damaged, it is easier to remove a single section of shrink tubing and replace it with a new one. This makes repairs quicker and cheaper.

In particular, the support tube is designed as a wound CFRP tube. By manufacturing using the winding process, the support tube can be designed with a small wall thickness and yet with high rigidity against deflection. This offers advantages due to the low weight.

In a preferred embodiment, the telescopic rod is made as a metal tube, in particular made of aluminum or an aluminum alloy. This still enables a good compromise between rigidity and weight despite a small diameter.

Alternatively, the telescopic rod can be made as a tube made of CFRP, in particular as a wound CFRP tube. This is particularly advantageous if, for example, a slightly larger diameter but still low weight is desired.

Furthermore, the storage of the telescopic rod is carried out with at least one sliding bush made of plastic, in particular made of POM, and preferably with two Slide bushings made of plastic, especially POM. POM is the name for polyoxymethylene, also called polyacetals. This is a thermoplastic material that has high rigidity and good dimensional stability and at the same time has low coefficients of friction. This makes it particularly suitable for the sockets for storing the telescopic rod in the support tube. Compared to known rolling bearings, storage with these bushings requires less installation space and is lighter. The sliding bushings can easily be manufactured using injection molding.

In particular, one or two sliding bushes are attached to the telescopic rod via a press fit. This is particularly possible if the telescopic rod is made of metal and the sliding bushing is made of POM.

In a further advantageous embodiment, the support tube is provided at both ends with a metallic head piece, the head pieces preferably being fastened in the support tube by a press fit. This protects the edges of the CFRP support tube from damage. And the support tube can be attached more easily to a holder in a frame, to the building or to the hall crane using the head pieces.

In addition, one of the head pieces can be designed in such a way that it is designed to guide and/or support the telescopic rod when it is moved in the support tube.

The invention further relates to a support tube which is intended for a sieve support rod. For the support tube, the object is achieved according to the invention by an embodiment according to independent claim 10. The support tube is intended for use in a sieve support rod, in particular for a sieve support rod which is designed according to one of the preceding claims. Further advantageous embodiments of the support tube according to the invention can be found in the corresponding subclaims. The embodiment according to the invention is characterized in that: At least one shrink tube is applied to the support tube in such a way that the shrink tube forms the surface on which a sieve is supported when used for pulling in the sieve.

As described above, it is advantageous if the shrink tube is applied next to one another in the form of several shrink tube sections. And the same applies if the support tube is designed as a wound CFRP tube. Or if it is provided with a metal head piece at both ends, the head pieces being secured in the support tube by a press fit.

Fig.1

Schematische Darstellung einer erfindungsgemäßen Siebtragstange mit einem erfindungsgemäßen Tragrohr

Fig.2

Schematische Darstellung zum Aufbringen des Schrumpfschlauchs

Fig.3

Schematische Darstellung zum Aufschrumpfen der Gleitbuchsen

Fig.4

Schematische Darstellung zum Einschrumpfen der Kopfstücke

Further advantageous features of the invention are explained using exemplary embodiments with reference to the drawings. Similar parts are marked with the same reference numbers.

Fig.1

Schematic representation of a screen support rod according to the invention with a support tube according to the invention

Fig.2

Schematic representation of how to apply the shrink tubing

Fig.3

Schematic representation of how to shrink-fit the sliding bushings

Fig.4

Schematic representation of shrinking the head pieces

The Fig. 1 shows the screen support rod 10 according to the invention. It includes the support tube 1 according to the invention, which is provided with the shrink tube 2 on the outside. The shrink tube 2 is applied so that it forms the surface with which the screen is in contact when it is pulled in. The support tube 10 is made of CFRP, preferably it is manufactured as a CFRP tube using the winding process. This means it can be carried out particularly easily with good rigidity against deflection. Furthermore, the telescopic rod 3 is present, which is mounted in the support tube 1 in an axially displaceable manner via a bearing. The telescopic rod 3 is preferably designed as a metal tube, in particular made of aluminum or an aluminum alloy.

To pull in an endless sieve in a paper machine, the sieve is first placed next to the paper machine in the form of with the help of several sieve support rods 10 desired sieve loop. For this purpose, the telescopic rod 3 is extended and its free end is attached or placed at a corresponding position on the chair of the paper machine. The opposite end of the support tube 1 is held on a frame, on the building or with the help of an indoor crane. If the endless sieve is draped in the desired shape of the sieve loop, the support tube 1 with the sieve on it is pushed towards the paper machine, so that the telescopic rod 3 is pushed into the support tube 1. The sieve is therefore laterally close to the rollers of the paper machine, which are supposed to carry the sieve. The screen is then pulled sideways onto the rollers in the paper machine. It slides over the surface of the sieve support rod 10. Since this surface is formed by the smooth shrink tube 2, the sensitive sieve is protected from damage.

Optionally, the support tube 1, as shown here, is provided at its ends with the metallic head piece 5, which are preferably fastened in the support tube 1 via a press fit. The head pieces 5 can protect and reinforce the edge of the support tube 1. They are also suitable so that the screen support rod 10 can be held in a holder or attached to the hall crane. In addition, one of the head pieces 5 can be designed so that the telescopic rod 3 can be guided and/or supported thereby when it is pushed out of the support tube 1.

Furthermore, the embodiment shown includes two sliding bushings 4, which are preferably made of POM and are designed here as rings. The sliding bushings 4 serve to support the telescopic rod 3 in the support tube 1 and enable the telescopic rod 3 to be displaced in the axial direction. POM is a suitable material for this because it has high rigidity and dimensional stability and a low coefficient of friction. The sliding bushings 4 are preferably pressed onto the telescopic rod 3.

The shrink tube 2 is preferably made of hard PVC, as this forms a smooth and abrasion-resistant surface. The shrinking temperature is usually in the range of 50-100°C. In particular, the shrink tube 2 can consist of several annular ones Sections can be constructed, which are applied next to each other on the support tube 1.

In Fig.2 is shown how the shrink tube 2 is applied to the support tube 1 for the embodiment according to the invention. First, the stretched shrink tube is pulled over the support tube 1 at room temperature. Then the shrink tube 2 is heated, for example with a hot air blower, so that it contracts and is firmly attached to the support tube 1. The shrink tube forms the surface that comes into contact with the screen when it is pulled in and over which the screen is pulled.

Fig.3 shows schematically how the sliding bushes 4 can be attached to the telescopic rod 3. First, the sliding bushings 4 are heated above room temperature RT so that they expand slightly and can be pushed onto the telescopic rod 3 into the desired position. When cooling, the sliding bushings 4 contract so that they sit firmly on the telescopic rod 3 via a press fit. This enables safe and reliable storage for the displacement of the telescopic rod 3 in the support tube 1, which requires little installation space and brings little additional weight.

The Fig. 4 describes the assembly of the head pieces 5 in the support tube 1. The metal head pieces are cooled down to such an extent that they can be inserted into the support tube 1. When they warm up again to room temperature RT, they expand and sit firmly via a press fit in the support tube 1. The head pieces 5 reinforce and protect the edges of the support tube 1 from damage. In addition, they offer the possibility of guiding the telescopic rod 3 when moving it or, on the other hand, the possibility of attaching it to or holding it on a frame, on a building or on an indoor crane.

Reference symbol list

1

Support tube

2

Heat shrink tubing

3

Telescopic rod

4

sliding bushing

5

Headpiece

10

Sieve support rod

RT

Room temperature

Claims (13)

Screen support rod (10) for use when pulling the screen into a paper machine, comprising a support tube (1), which is made of CFRP, and a telescopic rod (3), as well as a bearing with which the telescopic rod (3) is inside the support tube ( 1) is mounted so that it can move axially,
characterized,
that at least one shrink tube (2) is applied to the support tube (1) in such a way that the shrink tube (2) forms the surface on which the corresponding sieve is supported when used for pulling in the sieve. Sieve support rod (10) according to claim 1
characterized,
that the shrink tube (2) is applied next to each other in the form of several shrink tube sections. Sieve support rod (10) according to claim 1 or 2
characterized,
that the support tube (1) is designed as a wound CFRP tube. Sieve support rod (10) according to one of the preceding claims
characterized,
that the telescopic rod (3) is made as a metal tube, in particular made of aluminum or an aluminum alloy. Sieve support rod (10) according to one of claims 1 to 4
characterized,
that the telescopic rod (3) is made as a tube made of CFRP, in particular as a wound CFRP tube. Sieve support rod (10) according to one of the preceding claims
characterized,
that the storage of the telescopic rod (3) comprises at least one sliding bushing (4) made of plastic, in particular made of POM, preferably two sliding bushings (4) made of plastic, in particular made of POM. Sieve support rod (10) according to claim 6
characterized,
that one or two sliding bushes (4) are attached to the telescopic rod (3) via a press fit. Sieve support rod (10) according to one of the preceding claims
characterized,
that the support tube (1) is provided at both ends with a metal head piece (5), the head pieces (5) preferably being fastened in the support tube (1) by a press fit. Sieve support rod (10) according to claim 8
characterized,
that one of the head pieces (5) is designed to guide and/or support the telescopic rod (3) when moving in the support tube (1). Support tube (1) for a sieve support rod (10), in particular according to one of the preceding claims, wherein the support tube (1) is designed as a CFRP tube,
characterized,
in that at least one shrink tube (2) is applied to the support tube (1) in such a way that the shrink tube (2) forms the surface on which a sieve is supported when used for pulling in the sieve. Support tube (1) according to claim 10,
characterized,
that the shrink tube (2) is applied next to each other in the form of several shrink tube sections. Support tube (1) according to claim 10 or 11
characterized,
that the support tube (1) is designed as a wound CFRP tube. Support tube (1) according to one of claims 10 to 12
characterized,
that it is provided at both ends with a metal head piece (5), the head pieces (5) being fastened in the support tube (1) by a press fit.

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