SU1724767A1 - Tower for bleaching cellulose - Google Patents

Abstract

The invention relates to the pulp and paper industry, in particular to towers for the finishing of pulp, and allows to simplify the design and increase reliability. As the cellulose advances upward in the tower body, it enters the zone affected by the circular jet of a circular nozzle, under the influence of which the thick cellulose is height-stratified, evenly cross-sectioned and transported in the direction from the center of the tower where the nozzle is located periphery. 1 hp ff, 3 ill.

Description

cl

WITH

The invention relates to the pulp and paper industry, in particular to towers for pulp bleaching.

The purpose of the invention is to simplify the design and increase reliability.

Figure 1 shows the bleaching tower, section; 2 shows a device for uniformly discharging cellulose into a receiving pocket; Z-trzhe, in the receiving pocket with a variable width of the slotted channel of the circular nozzle.

The bleaching tower (FIG. 1) includes a housing 1 with upper 2 and lower 3 bottoms, a nipple 4 for feeding pulp into a tower located in the lower part of the housing 1, a receiving pocket 5 of annular shape in the upper part of the housing 1, a nipple 6 for feeding liquid to cellulose dilution; and nozzle 7 for discharging liquid pulp. The tower also includes a device 8 for uniformly discharging pulp into

receiving pocket, made in the form of a circular nozzle, the walls of which form a slotted channel 9, tapering from the center to the periphery (Fig. 2), with one of the walls belonging to the ring 10, and the other - to the plate 11 located below it. Ring 10 and the plate 11 mounted on the bottom of the nozzle 6 for feeding the liquid to the dilution of the pulp. The ring 10 can be connected to the pipe 6 through the adapter sleeve 12 with the flange 13 by means of bolts 14, and the plate 11 can be mounted on a rack 15 connected to the flange 13 having openings 16 for the passage of fluid from the pipe 6 to the annular slotted channel 9. The lower part of the nozzle 6 is located coaxially with the tower body 1. The plate 11 may be equipped with a fairing 17, for example, in the form of a cone. The plate 11 can be installed with the possibility of vertical movement.

vi vi VI o VI

For example, by means of a screw mechanism, including a threaded rod 18 connected to the plate 11 and a nut 19 connected to the socket 6. The rod 18 can be rotated by means of the lever 20 and fixed in the desired position with the help of a lock nut 21 with the handle 22. The rod 18 can be equipped with a gland seal 23 at the passage through the wall of the nozzle 6.

The tower works as follows.

Entering the tower through the nozzle 4, a cellulose mass with a concentration of more than 4% (for example, at 10-12%) moves up the hull 1 from bottom to top. This mass reaches the upper cut of the housing 1 and continues to rise in the area of the receiving pocket 5 in the form of a pole. At the same time, fluid is supplied through the nozzle 6 to dilute the cellulose. This fluid from the nozzle 6 enters the annular tapered slot 9 from the center to the periphery through the holes 16 of the flange 13 and flows out in the form of a flat annular jet part of the pipe 6 and the tower body), which is directed in the cross section of the tower from its center. As the height of the cellulose column advancing from the bottom upwards and the value of, for example, 100 mm above the upper cut of the shell of the tower body 1, increases, the upper end of the cellulose column enters the zone of the annular stream of liquid. Under the influence of the kinetic energy of this jet, the cellulose mass is layer-by-layer in height, uniformly cut across the cross section and transported from the center of the tower, where the nozzle 8 is located, to the periphery. At the same time, the thick pulp is simultaneously diluted with a liquid to a concentration of, for example, 1-2% and by gravity enters the receiving pocket 5, from where it is removed through the nozzle 7. By means of a screw mechanism (positions 18-21)

set the slit width of the circular nozzle 8, and accordingly, the flow rate of the liquid jet and its kinetic energy necessary for efficient operation of the device for uniform pulp unloading into the receiving pocket, and thus ensure the minimum required flow rate and pressure for the cellulose to be diluted depending on

the initial concentration of thick pulp and the productivity (at the entrance to the tower) of cellulose, which may vary depending on the technology adopted and on the needs of a pulp mill.

Claims (2)

Claim 1. Cellulose bleaching tower comprising a vertical body with a port for its lower part cellulose feed and in the upper part of the receiving pocket formed by the shell shell and the outer shell of a larger diameter, the pipe for supplying the dilution liquid, located above the upper section of the housing, and a pipe for discharging the liquid pulp, as well as a means of uniformly unloading the pulp into the receiving pocket, characterized in that, in order to simplify the design and increase the reliability of operation, the means of evenly unloading the pulp are mounted on the bottom of the diluted and made in the form of a circular slit nozzle, tapering from center to the periphery, while the axis of symmetry in cross section at the periphery of the nozzle is parallel to the plane of the upper section of the body. 2. The tower according to claim 1, characterized in that one of the walls of the circular slit nozzle is formed by a ring, and the other is located coaxially below the plate mounted with the possibility of vertical movement. WITH s  7 2