WO2010054912A1

WO2010054912A1 - Hydrocyclone

Info

Publication number: WO2010054912A1
Application number: PCT/EP2009/063540
Authority: WO
Inventors: Wolfgang Mannes
Original assignee: Voith Patent Gmbh
Priority date: 2008-11-14
Filing date: 2009-10-16
Publication date: 2010-05-20
Also published as: EP2358478A1; DE102008057339A1; CN102215979A

Abstract

The invention relates to a hydrocyclone for cleaning a fibre suspension (1) with a chamber (11) of circular cross section, into which an inlet (4) and an outlet (5) for lightweight fractions open at one end, and a separator (6) for heavyweight fractions at the opposite end. Short-circuit flows between the inlet (4) and the outlet (5) for lightweight fractions should be prevented by virtue of the diameter of the chamber (11) being greater in a guide section (8) between the inlet (4) and the separator (6) than at the inlet (4).

Description

hydrocyclone

The invention relates to a hydrocyclone for the purification of a pulp suspension with a chamber of circular cross-section, in which at one end an inlet and a light part outlet and at the opposite end a heavy-part separator opens.

Hydrocyclones are well suited for centrifugal forces to concentrate heavy particles and light parts in pulp suspensions and to discharge them via the outlet or the separator.

As a rule, they are used for the removal of small metal parts, glass splinters and sand or styrofoam and other light plastic parts.

However, short-circuit currents occur between the pulp suspension introduced via the inlet and the light-part outlet. This significantly reduces the efficiency of cleaning, especially at high fabric densities.

The object of the invention is therefore to hinder the short-circuit currents.

According to the invention, this object is achieved in that in a lying between the inlet and the separator guide section, the diameter of the chamber is larger than at the inlet.

The pulp suspension is placed on a circular path by tangential blowing through the inlet in the chamber, the pulp suspension being forced against the wall of the chamber by centrifugal force. The pulp suspension moves in a spiral from the inlet towards the heavy particle separator.

Since the diameter of the chamber in the guide section is greater than at the inlet, the pulp suspension applied to the wall of the chamber develops a suction effect from the inlet section to the guide section. As a result, the amount of short-circuit currents from the inlet section to the light part outlet decreases considerably.

It has proved to be advantageous if the maximum diameter of the chamber in the guide section at least 5 mm, preferably at least 10 mm and / or at least 4%, preferably at least 8% greater than at the inlet.

In order not to swirl the inflowing pulp suspension too much, the distance between the inlet and guide section should be greater than 30 mm, preferably greater than 60 mm.

In the interest of a simple construction, the inlet end of the chamber should be flat.

However, in order for the pulp suspension which has flowed into the chamber after one revolution not to hinder the inflow over the inlet too much, it may be advantageous if the inlet-side end of the chamber is formed spirally at least over a radial circumferential area.

It may also be advantageous if the spiral

Peripheral region extends over the entire inlet end of the chamber or only over the radially outer part of the inlet end of the chamber.

In particularly preferred embodiments, the spiral-shaped circumferential region in the direction of flow of the pulp suspension coming from the inlet should adjoin the boundary of the inlet facing the inlet-side end of the chamber and the spiral-shaped peripheral region terminate at the boundary of the inlet pointing away from the inlet end of the chamber.

Depending on the task and type of hydrocyclone and the composition of the pulp suspension, it may be advantageous if the chamber in an im Mouth region of the inlet lying inlet section is cylindrical or conical.

The preferred design of the transition between the inlet and the guide section depends i.a. from the distance to the outlet

In the interest of a low turbulence of the pulp suspension, it is when the diameter of the inlet section to the guide section changes gradually. However, a strong suction effect can be achieved when the diameter of the inlet section to the guide section changes stepwise.

A reinforcement of the suction effect emanating from the guide section can still be achieved in that the guide section is conical, with the diameter increasing in the direction of the separator. If, on the other hand, the diameter decreases in the direction of the separator, the separation of the heavy parts in the guide section could already be initiated. In particular, short guide sections should be cylindrical.

The guide section should follow a preferably cone-shaped separating section, in which the diameter of the chamber for

Separator reduced. The reduction of the diameter leads to an increase in the rotational speed and thus to an increase in the centrifugal and centrifugal forces. As a result, the heavy parts are pressed against the wall of the chamber and concentrated there. At the end of the separation section, the heavy parts can then be removed from the chamber.

Since focus on the light parts in the center axis of the chamber, a preferably tubular, running along the center axis light part spout should project into the center of the chamber at the inlet end of the chamber. About this outlet so the light parts of the suspension can be pumped.

Because of the suction effect of the guide area, the light part outlet should extend into the guide area of the chamber, but not beyond it as far as possible. - A -

In this case, the short-circuit flow can be hindered if the outer circumference of the light-part outlet increases in at least one section, preferably on the chamber-side end. It is advantageous if the outer circumference of the light part spout preferably increases continuously towards its chamber-side end.

In order to be able to also clean pulp suspensions of high consistency, it is advantageous if, for example, as described in EP 1 069 234, at least one feed line for dilution liquid opens into the chamber.

Particular advantages arise when the hydrocyclone is used to clean the pulp suspension of heavy parts while the purified pulp suspension is discharged through the light part outlet.

However, it is also possible to remove light parts through the outlet from the pulp suspension and remove the purified pulp suspension through the separator.

Due to the achieved containment of short-circuit currents of the hydrocyclone can be used with advantage for the purification of pulp suspensions, which serve to produce a paper, board, tissue or another fibrous web and preferably a stock density between 1, 5 and 4%, in particular between 2 , 5 and 3.5% have. This applies in particular when dilution liquid is supplied via a supply line.

The invention will be explained in more detail below with reference to several exemplary embodiments. In the attached drawing: FIG. 1 shows a schematic cross section through a hydrocyclone; FIGS. 2a-c: various design forms with a cylindrical inlet section 7 and FIGS. 3a-c: various design forms with a conical inlet section 7. The hydrocyclones described here are used to clean a pulp suspension 1 with a consistency between 2.5 and 3.5% of heavy parts. The fixed housing of the hydrocyclone encloses according to Figure 1, an elongated chamber 11 with a circular cross-section. At one end of the chamber 11 is an inlet 4, via which the pulp suspension 1 to be cleaned is injected tangentially into a cylindrical inlet section 7 of the chamber 11. As a result, the pulp suspension 1 is brought to a circular path, wherein the pulp suspension 1 is pressed against the wall of the chamber 11.

By acting centrifugal and centrifugal forces accumulate the heavy parts 3 on the wall of the chamber 11 and the light parts 2 in the middle of the chamber 11 at. In this way, reach the heavy parts 3 on the wall of the chamber 11 spirally to the opposite end of the chamber 11 with the Schwerteil- separator 6, through which the heavy parts 3 get out of the hydrocyclone.

In order not to guide the pulp suspension 1 flowing in via the inlet 4 into the inflow region of the inlet 4 after one revolution on the wall of the chamber 11, the radial outer peripheral region of the inlet-side end of the chamber 11 is formed spirally in FIG. In this case, the spiral-shaped peripheral region 15 adjoins in the flow direction of the coming out of the inlet 4 pulp suspension 1 to the inlet end of the chamber 11 facing boundary of the inlet 4 and terminates at the inlet end of the chamber pioneering boundary of the inlet. 4

To counteract blockages of the heavy-part separator 6, dilution liquid 13 is conducted into the chamber 11 in the region of the heavy-part separator 6 via a feed line 10.

This allows the trouble-free use of the hydrocyclone even at high material densities, as sought here. The existing in the middle of the chamber 11, purified from the heavy parts 3 pulp suspension 1 is pumped out here as light-component 2 via the Leichtteil- outflow 5. For this purpose, a tubular lightweight drain 5 at the inlet end along the center axis 12 in the middle of the chamber 11th

The light-part outlet 5 has at its chamber-side end a thickening 14 of the outer circumference, in which the outer diameter increases continuously towards the end of the outlet 5. This will cause the downward flowing

Pulp suspension 1 pushed away from this outlet 5, which hinders short-circuit currents to this outlet 5.

At the inlet section 7 closes in the direction of separator 6, a guide section 8, in which the diameter of the chamber 11 is greater than at the inlet 4.

In this way, a suction flow from the inlet 7 to the guide section 8 is generated, which counteracts a short-circuit flow from the inlet 4 to the light-part outlet 5. As a result, the efficiency improves significantly.

At the guide section 8 is then followed in the direction of separator 6 still a conical separating section 9, in which the diameter of the chamber 11 to the separator 6 decreases continuously.

As a result of this taper, the rotational speed of the suspension increases in such a way that the heavy parts 3 concentrate on the wall of the chamber 11. The light-part outlet 5 extends into the guide section 8.

In order not to impair the flow of the pulp suspension 1 in the inlet, the guide section 8 has a minimum distance of at least 30 mm from the inlet 4. For sufficient reinforcement of the flow from the inlet section 7 into the guide section 8, the maximum diameter of the chamber 11 in the guide section 8 is at least 10 mm larger than at the inlet 4.

According to Figures 2 and 3, the chambers 11 can be designed differently for this purpose. However, here is the design-simplification, the inlet-side end of the chamber 11 made flat.

In the case of the hydrocyclones shown in FIG. 2, the inlet section 7 is cylindrical.

However, the transition from the inlet section 7 to the cylindrical guide section 8 takes place in a stepped manner in FIG. 2a, whereas in FIG. 2b this takes place gradually. In contrast, the guide portion 8 is conically formed in Figure 2c, wherein the diameter of the chamber 11 increases towards the separator 6, so that the chamber 11 at the transition between the guide 8 and Abscheideabschnitt 9 has its maximum diameter.

The hydrocyclones shown in FIG. 3 have a conical inlet section 7, in which the diameter of the chamber 11 in the direction of the guide section 8 increases continuously, which assists the flow to the guide section 8. In FIG. 3 a, the guide section 8 is cylindrical and conical in FIGS. 3 b and 3 c. In FIGS. 3b and c, too, the diameter of the chamber 11 increases in the direction of the separating section 9. However, in FIG. 3b, the inclination of the wall in the guiding section 8 coincides with the inclination of the wall in the inlet section 7, while in FIG. 3c the wall in the guiding section 8 is more inclined to the center axis 12 than the wall in the inlet section. 7

If lightweight parts 2 are to be removed from the pulp suspension 1, the pulp suspension 1 purified therefrom is conveyed as heavy component 3 via the heavy-part separator 6 from the hydrocyclone, while the light parts 2 are removed via the light-part outflow 5.

Claims

claims

1. hydrocyclone for purifying a pulp suspension (1) having a chamber (11) of circular cross-section into which at one end an inlet (4) and a light part outlet (5) and at the opposite end a heavy-part separator (6) opens, characterized in that in a between the inlet (4) and the separator (6) lying guide section (8), the diameter of the chamber (11) is greater than at the inlet (4).

2. A hydrocyclone according to claim 1, characterized in that the maximum diameter of the chamber (11) in the guide section (8) at least 5 mm, preferably at least 10 mm larger than at the inlet (4).

3. Hydrocyclone according to claim 1 or 2, characterized in that the maximum diameter of the chamber (11) in the guide section (8) at least 4%, preferably at least 8% greater than at the inlet (4).

4. Hydrocyclone according to one of the preceding claims, characterized in that the distance between the inlet (4) and guide section (8) is greater than 30 mm, preferably greater than 60 mm.

5. Hydrocyclone according to one of the preceding claims, characterized in that the chamber (11) in a in the mouth region of the inlet (4) lying inlet portion (7) is cylindrical.

6. Hydrocyclone according to one of claims 1 to 4, characterized in that the chamber (11) in a, in the mouth region of the inlet (4) lying inlet portion (7) is conical.

7. Hydrocyclone according to one of the preceding claims, characterized in that the diameter of the inlet section (7) to the guide section (8) gradually changes.

8. Hydrocyclone according to one of claims 1 to 6, characterized in that the diameter of the inlet section (7) to the guide section (8) changes stepwise.

9. Hydrocyclone according to one of the preceding claims, characterized in that the guide section (8) is cylindrical.

10. Hydrocyclone according to one of claims 1 to 8, characterized in that the guide section (8) is conical.

11.Hydrocyclone according to one of the preceding claims, characterized in that the guide section (8) is followed by a preferably cone-shaped separating section (9), in which the diameter of the chamber (11) decreases towards the separator (6).

12. Hydrocyclone according to one of the preceding claims, characterized in that the inlet (4) leads tangentially into the chamber (11).

13. A hydrocyclone according to any one of the preceding claims, characterized in that at the inlet end of the chamber (11) a preferably tubular light-part outlet (5) in the center of the chamber (11) protrudes.

14. Hydrocyclone according to one of the preceding claims, characterized in that the outer circumference of the light part spout (5) in at least one, preferably located on the chamber side end section increases.

15. Hydrocyclone according to claim 14, characterized in that the outer circumference of the light part outlet (5) preferably increases continuously towards its chamber-side end.

16.Hydrocyclone according to one of the preceding claims, characterized in that the inlet end of the chamber (11) is flat.

17.Hydrocyclone according to one of claims 1 to 15, characterized in that the inlet-side end of the chamber (11) is formed spirally at least over a peripheral region (15).

18.Hydrocyclone according to claim 17, characterized in that the spiral-shaped peripheral region (15) extends over the entire inlet-side end of the chamber (11).

19.Hydrozyklon according to claim 17 or 18, characterized in that the spiral peripheral region (15) in the flow direction of the inlet from the inlet (4) pulp suspension (1) to the inlet end of the chamber (11) facing the boundary of the inlet (4 ).

20.Hydrocyclone according to one of claims 17 to 19, characterized in that the spiral-shaped peripheral region (15) ends at the inlet end of the chamber 11 facing away from the boundary of the inlet (4).

21.Hydrocyclone according to one of the preceding claims, characterized in that the light-part outlet (5) runs along the center axis (12) of the chamber (11).

22. Hydrocyclone according to one of the preceding claims, characterized in that the light part outlet (5) extends into the guide region (8) of the chamber (11).

23. Hydrocyclone according to one of the preceding claims, characterized in that in the chamber (11) at least one supply line (10) for dilution liquid (13) opens.

24.Hydrocyclone according to one of the preceding claims, characterized in that the purified pulp suspension (1) via the Leichtteil- outlet (5) is discharged.

25.Hydrocyclone according to one of the preceding claims, characterized in that serving to produce a paper, board, tissue or another fibrous web pulp suspension (1) preferably has a consistency of 1, 5 and 4%, in particular between 2.5 and 3.5%.