EP1702103A1 - Method for refining paper or cellulose fibres in an aqueous suspension - Google Patents

Abstract

The invention relates to a method for refining paper or cellulose fibres in an aqueous suspension. According to the invention, a refining region is formed between the inner wall of a rotating refining drum, e.g. a refining cylinder (1), and at least one rotating refining roller (2, 2') with a fixed rotational axis. As a result of the rotation of the refining cylinder (1), a liquid layer (8) forms on the inner wall thereof and thus penetrates between the refining roller (2, 2') and the refining cylinder (1) that are pressed against each other. A constant liquid flow containing the paper or cellulose fibres in an aqueous suspension is guided into and out of the liquid layer (8). In particular forms of embodiment, the axial transport over the entire length of the refining drum is assisted by fixed transport devices, e.g. transversal bars (14) comprising guide vanes.

Description

Process for the grinding of aqueous paper or cellulose fibers

The invention relates to a method according to the preamble of claim 1.

It has long been known that pulp fibers have to be ground so that the paper subsequently produced from them has the desired properties, in particular strength, formation and surface. By far the most frequently used grinding processes use grinding surfaces which are provided with strips known as knives. The corresponding machines are mostly called knife refiners. For special cases, grinding processes are also used in which at least one of the grinding surfaces is knife-free, so that the grinding work is transmitted by friction or shear forces.

The effect of the method can be controlled over a wide range by changing the grinding parameters, and in addition to the amount of grinding, a distinction is made in particular as to whether a more cutting or more fibrillating grinding is desired. If cellulose fibers are processed by the known grinding processes, their resistance to dewatering increases with increasing grinding. A common measure of drainage resistance is the Schopper-Riegler degree of grinding.

The increase in the degree of grinding has an unfavorable effect on sheet formation on the paper machine, but is accepted because the quality characteristics of the pulp mentioned above play an outstanding role in its usability. In many cases, the grinding parameters are chosen so that the increase in the degree of grinding to achieve the required fiber quality is as small as possible. However, this influence is very limited. In addition, this can make the grinding less economical.

DE 894 499 shows a grinding device which has a rotating grinding cylinder, on the inner wall of which a plurality of grinding rollers are pressed in order to grind fibrous material. The grinding rollers are provided with special circumferential grooves in order to achieve a certain desired grinding effect can. The grinder is not designed for continuous driving.

The invention is therefore based on the object of creating a continuously operating method by means of which it is possible to mill cellulose or paper fibers in such a way that the strength values of the paper produced therefrom are increased. The increase in dewatering resistance that occurs should be at least less than in known grinding processes. The device required should be suitable for use on an industrial scale in the production of paper.

This object is achieved by the features mentioned in claim 1.

Most known grinding drums are not suitable for this purpose, since their effect is based on the breaking of coarse parts. For example, US 2,719,463 a grinding cylinder, which is to be used in the paper-making industry, but for the processing of the relatively coarse reject material. Such a device aims at comminuting impurities and should leave the fibers contained in the reject unchanged.

The new grinding process works in such a way that the fiber properties are optimized, the desired strengths being developed without the grinding degree increasing as in the conventional process.

Comparative tests with long fiber pulp have shown that to achieve a tear length of 8 km with a knife grinding a 45 ° SR freeness was achieved and with the new process only 18 ° SR. The specific grinding work required was up to 50% lower.

It can be assumed that the new grinding process changes the structure of the fiber wall and the surface of the fibers in such a way that they receive improved flexibility and binding ability without the need to remove fibrils from the outer surface of the fibers. The production of fine material, i.e. fiber fragments, is also very low.

If the process is applied to recycled fibers, the advantages mentioned under 1. and 2. can play a special role. Recycled fibers already have at least one, often even several grinding processes behind, so that any further comminution is avoided.

The invention and its advantages are explained with reference to drawings. Show:

1 shows an example for carrying out the method according to the invention with the aid of a grinding cylinder;

FIG. 2 shows a detail with a grinding roller according to FIG. 1;

3 shows a milling device suitable for the method in side view, milling rollers removed;

4 shows an installation part for the axial transport of the fibrous material;

5 shows a further exemplary embodiment with a modified flow guide;

FIG. 6 detail of a grinding roller according to FIG. 5;

Fig. 7 shows another embodiment with shorter grinding rollers;

8 shows an example with a conical grinding drum.

The grinding device shown in FIG. 1 has a lying grinding cylinder 1 in which there are a plurality of grinding rollers 2 arranged uniformly over the circumference. Five grinding rollers 2 are shown in this illustration. Their total number is 8. The grinding rollers are each provided with a larger number of grinding strips 3, which can also be referred to as knives. The grinding strips 3 and the wetted surfaces of the grinding cylinder 1 can be made of the material common in such applications (e.g. hardened cast chrome steel) or of porous material, e.g. sintered chrome steel. When the method is carried out, a grinding zone is formed between the grinding roller 2 and the grinding cylinder 1, specifically at the point at which the inner wall of the grinding cylinder 1 and the grinding strips 3 are closest. In order to generate the necessary grinding force, the grinding rollers 2 are pressed radially against the inner wall of the grinding cylinder 1. A spring 6 is shown as an example. Of course, other pressure generating systems, e.g. a pneumatic or hydraulic pressure cylinder can be used. The grinding rollers 2 are rotatably mounted with fixed axes of rotation. You can e.g. be fixed via two stands 7 extending axially into the grinding cylinder. The grinding cylinder 1 is set in rotation by a drive roller 4. But there are also other drive options. The grinding rollers 2 do not need their own drive, since they are set in rotation on the inner wall of the grinding cylinder 1. This means a significant simplification of the grinding device.

The aqueous paper fibers are suspended with the help of one or more pipelines 9 brought near the inner wall. Such a pipe 9 is shown here schematically at a point where the grinding rollers are not shown for better clarity. As a result of the rotation of the grinding cylinder 1, the aqueous suspended paper fibers lay down as a fibrous layer 8 on its inner wall. Since both the pipeline 9 and the stand 7 are arranged fixed in space, it is easily possible to supply the pipes 9 with suspension S centrally from the stand 7. The pulp suspension S emerging from the pipeline 9 is accelerated in the circumferential direction and is distributed over the inner wall of the grinding cylinder 1. It then arrives in a grinding zone, formed between a grinding roller 2 provided with grinding strips 3 and the inner wall of the grinding cylinder 1. It is usually desirable to: that the fiber suspension is passed several times through grinding zones. As a result of the centrifugal forces within the grinding cylinder 1, a relatively uniform thickness of the fibrous layer 8 is achieved. As shown in FIG. 2, the ground pulp suspension S ^' can exit through an outlet opening 10 on the circumference of the grinding cylinder 1. It will be discharged through a sealing element 11 into a fixed ring channel 12. Sealing element 11 or ring channel 12 can be designed such that there is a connection to the ring channel 12 only in a limited part of the circumference. In order to ensure a defined thickness of the fibrous layer 8 in the grinding cylinder 1, a counter pressure can be built up in the ring channel 12. In the upper part of the grinding cylinder 1, a crossbar 14 is shown as an example, on which a number of guide vanes 15 are attached. These dip into the fiber layer 8 and lead to a defined axial transport. The axial transport will be discussed in more detail later.

The grinding strips 3 will be arranged axially parallel in the general case. However, it is also possible for them to be at an acute angle α to the center line of the grinding roller 2, in order thereby to e.g. to favor the axial transport of the fiber suspension. These two possibilities are indicated on a single grinding roller 2 in FIG. 2.

3 shows a side view of a grinding device suitable for carrying out the method. It consists of a horizontal grinding cylinder 1. You can also see some carriers δ. The grinding rollers, however, are not shown. In order to obtain the most uniform possible mass transfer, the fibrous material is guided axially from an end face 13 of the grinding cylinder 1 to the opposite side. The supply through the pipeline 9 is shown here on the right and the discharge through an annular channel 12 on the left. In the vicinity of the inner wall of the milling cylinder 1 there are one or more fixed crossbeams 14 with guide vanes 15. As shown in FIG. 4, the guide vanes are 15 inclined relative to the circumferential direction 16, which leads to an axial offset 17 of the fiber suspension S. One or more scraper bars 14 ^' can also be used, which lift the fibrous layer 8 from the inner wall of the grinding cylinder 1, loosen it up and move it axially via guide vanes 15' mounted on the opposite side.

The grinding device shown in FIG. 5 also has a lying grinding cylinder 1, in which there are a plurality of grinding rollers 2 ′ arranged uniformly over the circumference. This illustration shows three of a total of ten grinding rollers 2 ', the length of which is slightly less than half the length of the axial length of the grinding cylinder 1 (see FIG. 7). The means for driving the grinding cylinder 1 and for generating the grinding force are similar or the same as already described in FIG. 1. The grinding rollers 2 ^' rotate about fixed axes of rotation. They can, for example, be overhung in a carrier 5 which is fastened to a yoke 19 extending axially through the grinding cylinder.

As already described in connection with FIG. 1, the aqueous suspended paper fibers are fed into the grinding device, distributed therein and treated. In order to generate a continuous, uniform suspension flow, it is advantageous to provide overflow openings 20 in one, or preferably in both, end faces 23 of the grinding cylinder 1. The overflow openings 20 can be evenly distributed over the circumference. As with a weir, its radial distance from the inner wall of the grinding cylinder 1 essentially determines the height at which the liquid layer 8 can form. As shown in FIG. 6, the ground fiber suspension S ^' can be discharged through a sealing element 21 into a fixed ring channel 22. The sealing element 21 can be designed such that there is a connection to the annular channel 22 only in a limited part of the circumference, for example immediately in front of the point at which the pipeline 9 opens. In order to reduce the cost of the relatively large sealing element 21, a co-rotating line (not shown here) can of course also guide the ground fiber material to a location that is easier to seal.

The grinding strips 3 will be arranged axially parallel in the general case. However, it is also possible for them to be at an acute angle to the center line of the grinding roller 2 ', in order thereby to promote, for example, the axial transport of the fiber suspension. These two possibilities are indicated on a single grinding roller 2 'in FIG. 6. In Fig. 7 the grinder of Fig. 5 is shown in side view. It consists of a horizontally lying grinding cylinder 1. It can be seen here that two grinding rollers 2 'are each floatingly supported in a carrier 5. This results in a simple construction with little disruption to the suspension flow. In addition, the axial extent of the grinding rollers 2 'can be kept relatively short, which contributes to a uniform grinding of the fibers. The fiber suspension S is added here through two axially spaced pipes 9.

Unlike previously shown, the axial transport in the grinding drum can also be improved in special embodiments in that a conical grinding drum 18, as shown schematically in FIG. 8, is used. Its inner wall has an oblique angle β relative to the axial direction, which is preferably less than 5 °. As a result of the centrifugal forces when the grinding drum rotates, a correspondingly usable axial force component is created. These measures can, under certain circumstances, dispense with the fixed transport devices, such as crossbar 14 or scraper bar 14 ^' of FIGS. 1, 3 or 4.

Claims

claims:

1. A process for the grinding of aqueous suspended paper fibers or cellulose fibers, in which the aqueous suspended paper fibers are passed through at least one grinding zone which lies between the inner wall of a rotating grinding drum and at least one grinding roller (2, 2 ^' ) which rotates thereon, in the grinding roller (2, 2 ^' ) and grinding drum are pressed against each other and in the mechanical grinding work is transferred to the fibers in such a way that the strength of the paper produced therefrom changes, characterized in that on the inner wall of the rotating grinding drum a fibrous layer consists of the aqueous suspended paper fibers (8) is formed so that the fibrous layer (8) is applied to the inner wall by rotation and that a constant liquid flow with the aqueous suspended paper fibers is fed into and out of the fibrous layer (8).

2. The method according to claim 1, characterized in that the grinding roller (2, 2 ') is provided with strips (3) whose axial extension to the axial direction of the grinding roller (2, 2') at an angle (α) between 0 and 45 ° stands.

3. The method according to claim 2, characterized in that a grinding drum is used, the inner wall of which has no grinding strips engaging between the grinding strips (3) of the grinding roller (2, 2 ^' ).

4. The method according to claim 1, 2 or 3, characterized in that the relative speed between the inner wall of the grinding drum and the grinding rollers (2, 2 ^' ), seen in the circumferential direction of the grinding drum, at the point where two grinding rollers (2, 2 ^' ) in the grinding zone are closest to a maximum of 10% of the peripheral speed of the inner wall of the grinding cylinder (1).

5. The method according to claim 1, 2, 3 or 4, characterized in that the grinding roller (2, 2 ') and grinding drum are pressed against each other with such a force that in the grinding zone linear forces between 5 and 30 N / mm, preferably at least 15 N / mm.

6. The method according to any one of the preceding claims, characterized in that the grinding drum is rotated at a peripheral speed on the inner wall of 20-40 m / s, preferably approximately 30 m / s.

7. The method according to any one of the preceding claims, characterized in that the center line of the grinding drum is set at an angle of 0-5 ° with respect to the horizontal.

8. The method according to claim 7, characterized in that the grinding drum is arranged horizontally.

9. The method according to any one of the preceding claims, characterized in that the paper fibers in the fibrous layer (8) are continuously guided axially from one end of the grinding drum to the other end.

10. The method according to claim 9, characterized in that the aqueous suspended paper fibers in a fiber suspension (S) through at least one inside the grinding drum at one end (13) opening pipe (9) fed, milled and then through at least one outlet opening (10) at the other end of the grinding drum.

11. The method according to any one of claims 1 to 8, characterized in that the paper fiber suspension (S) to be ground is fed to the liquid layer (8) at at least two axially spaced locations which lie within the grinding drum.

12. The method according to claim 11, characterized in that the supply takes place through pipes (9) which open near the liquid layer (8).

13. The method according to claim 11 or 12, characterized in that the locations are evenly distributed over the axial extent of the grinding drum.

14. The method according to any one of the preceding claims, characterized in that the ground paper fiber suspension (S ^' ) is discharged from the grinding drum through one or more overflow openings (20) which are located on the end faces (23) of the grinding drum.

15. The method according to claim 14, characterized in that the overflow openings (20) define the thickness of the liquid layer (8).

16. The method according to any one of the preceding claims, characterized in that an average consistency of 2 to 6% is set in the grinding zone.

17. The method according to any one of the preceding claims, characterized in that a grinding cylinder (1) is used as the grinding drum.

18. The method according to claim 17, characterized in that the axial transport of the fibrous layer (8) by at least one within the grinding cylinder (1) over the length of the grinding cylinder (1) extending transport device.

19. The method according to claim 18, characterized in that a spatially fixed transverse bar (14) with guide vanes (15) immersed in the fibrous layer (8) is used as the transport device.

20. The method according to claim 18, characterized in that a spatially fixed scraper bar (14 ') with guide vanes (15') immersed in the fibrous layer (8) is used as the transport device.

21. The method according to any one of claims 1 to 16, characterized in that the inner wall of the grinding drum is conical.

22. The method according to claim 21, characterized in that the conical grinding drum (18) has an oblique angle (β) between 1 ° to 5 °.