FI83241C - Foerfarande vid urvattning av en cellulosafibersuspension - Google Patents

Description

1 83241

Method for dewatering cellulose fiber suspension -Förfarande vid urvattning av en cellulosaflbersuspension

The present invention relates to a process for dewatering an aqueous suspension containing cellulose fibers, the suspension being passed to a hydrocyclone and then dewatered for further processing. The invention also relates to an apparatus for carrying out this method.

When cleaning cult suspensions in sieves and hydraulic cylinders, relatively dilute fiber suspensions are used in order to achieve the best possible cleaning and good separation of impurity particles, e.g. sticks, sand, shell and plastic chips. For this reason, the fiber suspension must first be diluted to a low fiber content and then dewatered again. The fiber suspension introduced into the hydrocyclone or hydrocyclone plant usually has a fiber content of less than 1%. The purified or receiving fraction from the hydrocyclone may have a fiber content of 0.4% or less, depending on the type of pulp and the starting material or the desired purification. For washing or grinding or other treatment of the pulp, e.g. for dispersing the wax, when treating the recycled pulp in the pulp, it is necessary that the pulp is considerably thicker, whereby its content is e.g. at least 30%. The thickening, e.g. from 0.5% to 30-40%, must be carried out in several stages, usually in two. The first most often uses a filter that gives a consistency with a factor of 10-15, e.g. from 0.5 to 5-7%. The thickened pulp is then fed to a pulp press, e.g. a screw press, to the desired fiber content for final thickening. The minimum fiber content of the suspension for feed to the pulp press is about 3%.

The cleaning of the fiber suspensions with hydrocyclones is used, for example, before the pulp collector. The fiber suspension must be diluted to a suitable consistency for purification in a hydrocyclone, after which it is again given a higher fiber content suitable for 2 83241 collectors, e.g. 2-3%.

It is an object of the present invention to direct the incoming fiber suspension to a pressurized dewatering device so that it operates under optimal conditions.

Another purpose is to maintain a constant pressure in the fiber suspension introduced into the dewatering device.

Yet another object is to control and keep constant the fiber content in the high fiber fraction obtained in the dewatering device.

The object is achieved by a combination in which the fibrous stream purified by the hydrocyclone is passed to a pressurized dewatering device and divided into a high fiber fraction which is passed on for further processing, and a substantially non-fibrous fraction the outlet of the dewatering device is adjusted according to one or more physical parameters of the high fiber fraction. The physical parameter is usually selected to be fiber content, pressure or flow, with flow measurement and control being particularly advantageous.

According to one embodiment, the pressure of the fiber suspension entering the dewatering device is also adjusted, which is preferably kept constant. This is done by measuring the inlet line pressure, comparing the measured pressure to the setpoint, and varying the flow through the second outlet of the substantially fiber-free fraction toward the setpoint, depending on the difference between the measured value and the setpoint.

According to another embodiment, this pressure control is provided by a valve fitted to the side line, through the side line of which the fiber suspension is passed past the dewatering device to the high fiber fraction outlet, correspondingly measuring the inlet line pressure, comparing the measured pressure value to the setpoint. that the pressure in the supply line moves towards the setpoint.

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According to another embodiment, the high fiber fraction from the dewatering device and the bypassed suspension, which are connected so that the side line falls into the discharge line, are fed to a fiber treatment device, the suspension pressure or level being controlled by a valve in the dewatering device. In this specification and claims, level and pressure are equivalent terms to the suspension in the fiber treatment device.

The method according to the invention will be described in more detail below with reference to the drawing, in which Fig. 1 schematically shows parts of a fiber suspension treatment line including a dewatering device, Fig. 2 schematically shows the same parts of a fiber treatment line, but the thickener is changed another embodiment.

The method according to the invention will be explained by means of a drawing, and first a description of the processing line of Fig. 1 will be shown. The fiber suspension to be purified in the hydrocyclone, followed by dewatering and other treatment, e.g. dispersion in a pulp press, comes from a fiber source not shown via line 21, is diluted to a suitable fiber concentration and pumped to a screen 17 before the hydrocyclone. The protective screen 1 is a pressure screen in which impurities, if they got into the hydrocyclone, could damage this. Preferably, the material discarded in the screen 1 is periodically removed and discarded. The feed from the screen 1, which is essentially the entire fiber suspension fed, continues to the hydrocyclone 2.

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Hydrocyclone 2 is preferably a hydrocyclone plant with several hydrocyclones connected in parallel in at least two stages. The figures in the drawing show three stages 2, 3 and 4. The stages of the hydrocyclone are often cascaded. The effluent from the first or primary hydrocyclone stage 2 goes to the second or secondary hydrocyclone stage 3, which is returned to the primary hydrocyclone stage 2, in this case via the pump 17 and the screen 1. The slurry from the primary hydrocyclone stage 2 is fed to a pressurized dewatering device 5 via a line 22.

In the dewatering device 5, the incoming fiber suspension is divided into a high-fiber fraction and a mainly non-fibrous fraction. The suspension formed by the high-fiber fraction is fed to a fiber processing device, in this case a thickening device 6, via a line 23. The substantially non-fibrous fraction from the dewatering device, the thin fraction, is fed to line 21 prior to pumping via lines 24 and 26, where the substantially non-fibrous fraction is used to dilute the suspension from the fiber source to a suitable mouthpiece.

In the thickener 6, the thickened fraction goes to the next processing step, which will not be described in more detail here. The thin fraction, i.e. the non-fibrous fraction, coming from the thickening device 6 is collected in an overflow flat vessel 8.

The level vessel 8 is connected by lines 26, 27 and 28, respectively, to the suction side of all pumps 17, 18 and 19 before or upstream of dewatering device 5. If the amount of substantially non-fibrous fraction from dewatering device 5 is not sufficient to dilute the suspension from fiber source, non-fibrous fraction from fiber processing device is used. for dilution via line 26. The method of control and adjustment of the dilution is known to a person skilled in the art and will not be explained in more detail.

From the line 22 between the inlet of the hydrocyclone 2 and the dewatering device 5, a branch line 25 exits, which after the dewatering device 5 descends to a line 23, where the high-fiber fraction from the dewatering device 5 is led to a thickening device 6. The branch line 25 has a control valve 11.

The thickening device 6 is provided with a trough 7 from which the fiber suspension fed to the device 6 enters the thickening part of the device 6.

According to the invention, the properties of the high-fiber fraction obtained from the dewatering device 5, such as pressure, fiber content and in particular flow, are kept at a predetermined, preferably constant value by measuring the parameter value of the fraction with sensor 32, passing a proportional signal to the control and effecting element 15, comparing the parameter value with that parameter. the difference occurs by affecting the setting of the valve 12, which is preferably located downstream of the sensor 32, so that the measured property of the high fiber fraction approaches the set value. It is preferred that the flow of the high fiber fraction through the high fiber fraction outlet of the dewatering device be controlled and that the sensor 32 be a magnetic flow meter.

In order for the dewatering device 5 to operate as optimally as possible, the pressure of the incoming suspension is also adjusted. The pressure in the line 22 is measured by a sensor 31. The measured pressure is compared with the setpoint and, if there is a difference, the setting of the valve 11 in the side line 25 is changed by the control and actuating member 14 towards the pressure setpoint. A constant pressure in the line 22 is not only advantageous for the uniformity of dewatering but also necessary if the line 22 is preceded by a hydrocyclone 2 having a suspension in the dewatering device 5, since the back pressure must be constant in order to obtain a uniform and acceptable separation in the hydrocyclone 2. Preferably, the pressure setpoint in line 22 is determined by the hydrocyclone supply pressure.

According to another embodiment, the flow through the outlet of the substantially non-fibrous fraction 6 83241 of the dewatering device 5 is also regulated. This flow is adjusted so that a constant level in the trough 7 is maintained in the treatment device, which is the thickener 6 in Fig. 1. The liquid level or equivalent hydrostatic pressure in the trough 7 is thus measured, compared to the setpoint and, if there is a difference, the settings of the valve 13 are changed. the trough level approaches the level setpoint.

Fig. 2 shows a fiber processing device, which in Fig. 1 is a thickening device 6, a pulp collection machine. This includes a headbox 46 and a wire 47 for removing water from the fiber suspension. The other parts of the fiber processing line are identical to the parts of Figure 1.

The high-fiber fraction from the dewatering device 5 goes to the tail box 46 and from there to the wire 47 for dewatering. The substantially fibrous circulating water separated by the wire 47 is collected in an overflow tank 8. In the same way as in Fig. 1, this substantially fibrous circulating water is used as a pressure reference for all pumps 17, 18 and 19 located before the dewatering device 5. The headbox 46 maintains a constant overpressure corresponding to a certain level of fluid so that the fiber suspension exiting the lip of the headbox 46 is given a desired speed adapted to the speed of the wire. If the pressure in the headbox 46 deviates from a predetermined value, the setting of the valve 13 is influenced by the control and actuating member 16 so that the pressure in the headbox approaches the set value.

In Fig. 3, the fiber processing device is, as in Fig. 2, an assembly machine. According to this embodiment, the side line 25 provided with the valve 11 is missing or also the valve 11 is completely closed, so that the suspension does not pass the dewatering device 5 at all. The thickener 5 thus removes water from the incoming fiber suspension to the desired fiber content. The pressure or level of the headbox 46 is adjusted by a valve 12 in the discharge line 23 of the dewatering device 5.

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Unlike the embodiment of Figure 2, the pressure in the inlet line of the dewatering device 5 is controlled by valve 13. The pressure in line 22 is thus measured by sensor 31 and the pressure deviation in line 22 is adjusted to the setpoint by means of control and actuator 14 by valve 13. Drainage of line 24 also affects dewatering. and the flow of suspension in line 23. Valve 12 adjusts the properties of the high fiber fraction so that the desired amount of fibers, i.e., the desired fiber content and flow, enters the headbox 46.

The substantially non-fibrous circulating water separated by the wire 47 is collected in an overflow tank 8. As in Figures 1 and 2, this substantially non-fibrous circulating water is used as a pressure reference for all pumps 17, 18 and 19 upstream of the dewatering device 5.

Claims (11)

A method for dewatering an aqueous suspension containing cellulose fibers, comprising suspending the suspension in a hydrocyclone and then dewatering it for further treatment, characterized by a combination of the hydrocyclone-purified fiber stream to a pressurized dewatering device (5) and to a fraction which is introduced upstream of the pressurized dewatering device to the fiber suspension to dilute it, and that the flow of the high fiber fraction at the outlet of the pressurized dewatering device is adjusted according to one or more physical parameters of the high fiber fraction. Method according to Claim 1, characterized in that the fiber concentration, pressure and / or flow of the high-fiber fraction are measured as a physical parameter. Method according to Claim 1 or 2, characterized in that the pressure of the suspension before the inlet of the dewatering device (5) operating under pressure is kept constant by adjusting the flow mainly through the outlet of the low-fiber fraction. Method according to Claim 3, characterized in that the pressure before the inlet of the pressurized dewatering device (5) is determined by the inlet pressure of the hydrocyclone arranged before the inlet. Method according to Claim 1 or 2, characterized in that the fiber suspension to be dewatered is passed partly past the pressurized dewatering device (5) to the high-fiber fraction drain line (23) and partly through the pressurized dewatering device (5). 9 83241 Method according to Claim 4, characterized in that the pressure of the suspension before the inlet of the pressurized dewatering device (5) is kept constant by adjusting the flow through the side line (25) through which the fiber suspension is passed past the pressurized dewatering device (5). Method according to Claim 6, characterized in that the pressure of the suspension before the inlet of the pressurized dewatering device (5) is determined by the inlet pressure of the hydrocyclone arranged from the inlet line (22) before the branch line (25) branches. Method according to one of Claims 5 to 7, wherein the fiber suspension in the high-fiber fraction discharge line (23) is fed to a fiber treatment device (6; 46), characterized in that the level or pressure of the fiber suspension in the fiber treatment device (6; 46) is controlled by a pressurized dewatering device (5). with a valve (13) in the low fiber fraction outlet line (24). Method according to Claim 8, characterized in that the fiber processing device (6; 46) is a pulp collecting machine provided with a headbox (46) and that the pressure in the headbox (46) is adjusted. Method according to Claim 8, characterized in that the fiber processing device (6; 46) is a thickening device (6) and that the level is the level prevailing in the trough (7) belonging to the thickening device (6). Apparatus for carrying out a method according to any one of claims 1 to 10 in a fiber processing device, such as a pulp collector or a fiber suspension thickener, characterized in that it comprises in combination: a) a pump (17) for feeding the fiber suspension b) to a hydrocyclone (2, 3, 4), is a valid pulp outlet connected to 10 83241 c) a pressure dewatering device (5) with an inlet and respective outlets for high-fiber and low-fiber fractions, the outlet for high-fiber fractions being connected to a pulp collection machine or pulp collection machine or 6) and the outlet for the low fiber fraction is connected to a supply pipe (26, 27, 28) for diluting the fiber suspension fed upstream of the pressurized dewatering device; and (d) means for controlling the flow through the outlet for the high fiber portion of the pressurized dewatering device.