SE462567B - DEVICE FOR CONTINUOUS TREATMENT OF CELLULOSAMASSA WITH AN ACTIVATING CHEMICAL - Google Patents

Description

462 567 In the following, the invention will be described in more detail with reference to the figure which shows a preferred embodiment of the invention. W The device shown comprises a pressure-tight container 1. This container is provided at the top with a feeding device 2 for gas-tight feeding of pulp. The device 2 suitably consists of a screw 3 through which the mass is fed in the form of a gas-tight plug. For tearing and atomizing the pulp plug at the entrance to the container 1, a special device 4 is arranged. At the bottom of the container 1 there is a discharge device 5 for gas-tight discharge of the mass. This device suitably comprises a vessel 6 directly connected to the container 1, in which vessel a dilution zone is maintained with outlet 7 below the liquid level.

Furthermore, the container 1 is divided into an upper part 8 and a lower part 9. These two parts may have the same diameter or the diameter of the lower part may be larger. Suitably the diameter of the lower part is 10-40% and preferably 20-30% larger than the diameter of the upper part.

The upper part 8 comprises a mixing zone 10 and a reaction zone 11. The mass level in the reaction zone is indicated by a level sensor 12. To the mixing zone 10 in the top of the container 1 a line 13 for supplying nitrogen dioxide is connected.

A line 14 for returning gas is connected between the discharge device S and the container 1 in the transition between the upper part B and the lower part 9. Gas supply preferably takes place symmetrically around the periphery of the container. In the line 14 a fan 15 is placed to ensure the gas flow.

A line 16 for supplying oxygen is connected to this return line 14. The oxygen gas can be supplied as pure oxygen or as a gas containing oxygen.

The container 1 extends down into the vessel 6 of the dispensing device 5 so that a space 17 is formed above the dilution zone between the outside of the container wall and the vessel wall. To this space 17 the line 14 for returning gas is connected. 462 567 'At the bottom of the container 1 a circumferential opening 18 is placed, through which the treated mass is intended to be discharged by means of a rotatable scraper device 19 to the surrounding vessel 6. Alternatively, the entire bottom can be designed as a rotatable conical disc on which the whole pulp bed rests. The output then takes place at the periphery of the disc. Other types of outputs are of course also conceivable, eg screw output. The vessel 6 arranged to receive the mass from the container 1 is provided with diluent nozzles 20 which are tangentially arranged to set the mass in rotation at the same time as the dilution. Furthermore, the vessel can be formed with a helical channel leading down to the outlet 7.

Optionally, a separate post-reaction vessel 21 can be placed after the container 1, a pump 22 being arranged to pump the mass directly from the container to this vessel 21.

The pulp treated in the device according to the invention must be produced by chemical means, preferably sulphate pulp, but other chemical pulps can also be used.

Pulp with a concentration of 20-35% is supplied to the container 1 through the feeding device 2 in such a way that gas is prevented from leaking. At the same time, air is prevented from accompanying the mass into the container. Upon entering the container, the mass is atomized by the device 4 and is allowed to fall down through the mixing zone 10 in the upper part 8 of the container.

There is a mixture of nitrogen dioxide which is supplied through the line 13 in an amount of 10-20 kg / ton of pulp. With the aid of the level sensor 12, the level of the pulp bed in the container is determined. In the reaction zone 11, the reaction starts between the nitrogen dioxide and the pulp. In this zone, the mass and the gas are continuously moved downwards at substantially the same speed, ie the nitrogen dioxide enclosed in the mass does not move in relation to the mass.

After the reaction zone 11 in the upper part 8 of the container, the mass enters the lower part 9 of the container. Where 462 567 gas is supplied through line 14. This gas consists of recycled residual gas, which is separated from the pulp in the discharge device 5, mixed with oxygen which is supplied through line 16 in an amount of 5-10 kg O 2 per tonne of pulp. . The gas supply through the line 14 and the distribution of the gas flow in the entire pulp bed is facilitated if the diameter of the container increases in the transition between the upper part 8 and the lower part 9.

Through the gas return in the line 14, the gas flow through the lower part 9 of the container can be regulated. The fan 15 must thus ensure a gradient in downward flow rate between gas and pulp, the gas velocity having to exceed the velocity of the pulp through this part 9 of the container.

The velocity gradient must be large enough to cause such a pressure drop across the pulp bed in the lower container part 9 that a good distribution of the gas flow in the entire pulp bed is obtained.

From the bottom of the container 1, the mass of the rotatable scraper device 19 is discharged to the surrounding vessel 6.

There, the mass is diluted to a low concentration, suitably 3-5%, by means of the diluting nozzles 20 which simultaneously set the mass in rotation along the helical channel towards the outlet 7. The flow through the outlet is regulated so that a liquid level is maintained in the vessel 6. to ensure a gas-tight discharge.

The majority of the gas that has not reacted with the pulp is discharged into the vessel 6. This gas is diverted through the line 14 via the space 17 which is dimensioned so that the pulp and liquid are not entrained by the gas flow.

The treated pulp is then pumped for further treatment in subsequent process steps. Optionally, however, a post-reaction may be required, which takes place in the separate vessel 21, through which the mass with the remaining gas content is allowed to pass continuously with the residence time required for the reaction to end. The invention is of course not limited to the embodiment shown but can be varied within the scope of the inventive idea.

Claims (5)

s' 462 567 Patent claim Device comprising a pressure-tight container (1) for continuous treatment of cellulose pulp with a gas phase activating chemical, preferably nitrogen dioxide, and oxygen, characterized in that it in combination comprises a) a feeding device (2) in the top of the container (1) for gas-tight feeding of the cellulosic pulp and a discharge device (5) at the bottom for gas-tight feeding of the treated pulp; b) a pulverizing device (4) for the mass at the feed; c) a line (13) for supplying nitrogen dioxide to the top of the container; d) an upper container part (8) with a mixing zone (10) and a reaction zone (11) for the pulp and the nitrogen dioxide; 1 e) a lower container part (9) whose diameter is equal to or larger than the diameter of the upper part (B), preferably 10-40%, preferably 20-30% larger; f) a conduit (14) with a fan (15) for returning gas from the discharge device (5) to the transition between the upper and lower container part (B and 9, respectively), the fan (15) being arranged to create a gradient in downward flow rate between gas and mass; g) a line (16) for supplying oxygen to the lower container part (9), this line (16) being connected to the line (14) for returning gas from the discharge device (5). Device according to claim 1, characterized in that the dispensing device (S) comprises a vessel (6) directly connected to the lower part (9) of the container with a dilution zone with outlet (7) below the liquid level. Device according to claim 2, characterized in that the vessel (6) comprises a space (17) above the dilution zone, which space is substantially free of mass, wherein the line (14) for returning gas is connected to this space (17). 462 567 Device according to claim 2 or 3, characterized in that a scraper device (19) is arranged in the bottom of the container (1) for radial transfer of the mass to said vessel (6). Device according to one of Claims 2 and 3, characterized in that a separate post-reaction vessel (21) is arranged after the container (1), a pump (22) being arranged to pump the mass directly from the container (1) thereto. vessels (21).