SE434125B - DEVICE FOR SUPPLYING A SLIDE OR PARTICULAR LIQUID FLUID TO A ROTABLE LIQUID DRUM - Google Patents

Description

8200233-8 to different rotational positions.

In the drawings, a liquid separation device is drum, which is applied to the invention, with the number 1. Drum 1 has flow openings 2, in the form of, for example, holes, gaps or net-like openings, such as in the case of cloths, which extend through the mantle wall of the drum 3. The drum 1 is at its one end partially closed by means of a preferably detachable end wall 4, and at the other end of the drum connect the jacket wall 3 to an end wall having the shape of a truncated cone Said end wall 5 delimiting: an outlet opening 6 in the narrower cone party. Connected to the end wall 4 is one in the feed direction rear-facing pipe socket 7, which is arranged coaxially with the silo drummans mantel 3.

In through the pipe socket 7 into the drum 1 extends a tubular supply device 8, which in the present embodiment example, is such a device as shown in FIG. 1-5.

The liquid separation drum 1 is supported by a numbers, preferably paired support rollers 9 resp. 10, which is arranged to run along their respective running tracks 1A resp. IB at each end of the drum 1. Suitably the rollers 9, 10 may be adjustable in height to enable adjustment of the drum 1 to desired slope.

Inside the drum 1 a feeding device is arranged 11, which is intended for feeding the slurry 12, etc. as is supplied to the drum 1, along the drum 1 in its longitudinal direction. Food- the mounting device 11 preferably has the shape of a screw flange 11, which extends radially from the inside 3A of the jacket 3 towards the center of the drum 13.

As can be seen from, for example, Figures 2 and 3, the screw 11 shows the rising flange height, calculated in the feed direction, along a substantial portion A of the drum 1, i.e. that the distance a, b, c and so on. for flanges lla, llb, llc, etc. in the direction from the drum jacket 3 towards the center 13 of the drum 1 increases. Conveniently can the increase is chosen so that it becomes substantially constant from the beginning to the end of said section A, but there is also the possibility that make sure that the flange height decreases step by step. Suitably said distance A approx. 2/3 of the effective length of the drum. The rise of the screw 11 can also be varied in the direction from the inlet 7 of the drum 8200233-8 to its outlet 6 in the desired manner.

The screw ll is terminated after said portion A with the flange height, with a portion B with preferably constant flange height. Suitably said constant flange height is equal to maximum flange height for lot A. The pitch for lot B. is suitably selected less than for the portion A, as shown in fig. 1 and 3, to thereby act as an extended dewatering step for goods fed by means of the helical feed device ningen 11.

The function of the one described above and in the drawings shown drum 1 with associated flange mounting 11 is according to the following: The slurry 12, which is fed to the drum 1 into its interior by means of the supply device 8, is effectively separated from liquid 14 on contact with the inner jacket wall of the drum 3. Liquid 14 then passes through the perforations 2 in the jacket wall 3 and collected in a container 15, which is located under the drum 1, from which the liquid 14 is discharged via an outlet pipe 16. The drum 1 is arranged to be rotated by means of, for example, a drive motor 17, which co-operates via a gear 18 by means of a drive gear 20A a drive gear ring 20B, which is arranged along the circumference of the drum at one end wall 4 of the drum, and drives the drum 1 in the same direction as the pitch of the helical flange device 11 extends itself, and as indicated by the arrow 19 in Figs. 4 and 5. Collected slurry 12 is transported in the spaces between each other nearby flanges, thanks to the pitch of the flange device 11, in the direction of the discharge opening 6 of the drum when rotating the drum 1, as stated above, and the slurry 12 is thereby released efficiently from liquid 14. Due to the increasing height of the flange the element 11 in the direction of the discharge opening 6 is made possible to receive a larger amount of slurry 12 etc. between two each other nearby flange turns, the further from the feed opening 7 counted.

The liquid separating portion B of the flange element 11 drains the essentially completely dewatered goods, which are fed by means of the helical flange element 11, further before the dewatered cleaner 12A is discharged through the opening 6 for collection in a container, cleaning press or not shown in the drawings similar.

In the flow openings 2 possibly accumulated sslzuozzs-š material is removed by means of one against the drum jacket 3, on previously known method, pressed brush 20, which is relatively rigid brush, and a flushing pipe directed towards the outer mantle surface of the drum supply of liquid. The brush 20 is stored at the storage device. ningen 21 resp. 22 rotatably at its respective free ends and is suitably supported by a casing 23, a so-called splash hood, to the drum 1. The brush 20 is driven either by means of a separate drive device or by the brush abutting against the drum jacket 3 and rotated with the drum 1. The cleaning takes place through that bristles penetrate into the perforations 2 of the drum jacket, which for example, can be circular or slit-shaped, and effective clean these from unwanted accumulations of e.g. pollutants.

Would the perforations of the drum jacket 2 still be and the amount of liquid in the interior of the drum will thereby increase the excess liquid to flow out in the direction of the arrow 24 in fig. 2 over the overflow drain formed by the pipe nozzle 7, which is located f at a lower level than the lower edge of the drum outlet opening 6 in it opposite end. The excess liquid flows downstream in a collection container 25 and passed therefrom via an outlet line 26.

This liquid can be returned, for example, by means of a pump device 27. to the drainage device via the inlet line 8. A number of suitable sensors can then be arranged in connection to the overflow drain 7 to regulate the amount of slurry 12 f supplied to the device. 2 During normal operation of the device, a good separating liquid 14 from the slurry 12 etc. provided the device and the dewatered cleaner 12A discharged through, the opening 6 thereby becomes very dry.

The supply device 8 shown in Figs. 1-5 opens into an upwardly open tubular gutter-like inlet device 28, which preferably shows increasing in the feed direction volume, and extending into and along the drum 1 about 2/3 of the length of the drum, i.e. substantially along the entire screw flange portion A. The end of said inlet device 28 is preferably formed by one in the direction from the bottom portion of the groove 28 towards the drum discharge opening 6 inclined end wall 29, which suitably has greater elevation than the side edges of the gutter. Along said side- edges extend one in each direction from the groove 28 out- ........._._. ..._ _ .___ ._ 8200233-8 sliding flange 30 resp. 31. Said flanges 30, 31, which are free in upward direction as shown in the drawings, are located in close proximity connection to the inner casing wall 3 of the drum and extends along the flange element 11. Due to said flange element 11 exhibits rising flange height, calculated in the discharge direction, the two flanges 30, 31 preferably have a larger width. laterally at the end of the chute 28 facing away from the feed direction, and suitably the flanges 30, 31 are formed with gradually decreasing width seen in the feed direction, and as clearly shown in Figs. 2 and 3. As shown in Figs. 4 and 5, the inlet device 28 is mounted rotatably about the shaft 32, as in the example shown coincides with the center axis 13 of the drum.

Slurry supplied through the pipe 8 to the gutter 28 12 etc. passes along said flow flanges 30, 31 in direction of with 33 designated arrows, i.e. in the direction of the drum mantle wall 3 laterally on the upper side of said flanges 30, 31. Drainage the slurry 12 is effectively effected by the bulk of the slurry is applied to the side shell surface 3 of the drum. man 1 where there are no fluid accumulations. About 1/3 of the liquid from the supplied slurry each flows through at the respective tive with the number 34 denoted arrow-marked flow point, in the setting of the supply device 28 shown in Fig. 4 with i substantially uniform flow flanges 30, 31.

When turning the feeder 28 to the position shown in Fig. 5, in the direction of the arrows 35, the slurry 12 is essentially to be applied to only one side wall of the mantle surface 3 in the direction of the arrow 36. By applying the slurry 12 in substantially the same direction as the drum is rotated, such as shown in Fig. 5, a more efficient degree of purification is obtained for it through the perforations 2 flowing liquid 14 than what is the case when applying the slurry 12 substantially to the drum direction of rotation. In the case of reverse feed, however, is obtained faster dewatering, which may sometimes be desirable, e.g. show if there are several purification steps. Undesirable particles, such as however, fibers etc. can then flow out together with the liquid 14 through the perforations 2.

The supply device used in the execution it works in case of the slurry 12 or the supplied one the liquid with the unwanted particles desired is separated from the liquid. 8200233 '-8 6 The invention is not limited to those described above and on. the drawings show exemplary embodiments, but can be varied within the scope of the appended claims.

Claims (9)

7 8200233-8 P a t e n t k r a v Inlet device for supplying a slurry (12) or a particle-laden liquid to a rotatable drum (1), the jacket (3) of which has flow openings (2) for separating liquid (14) from the slurry (12), which drum preferably has a helical flange element (11) projecting in the rotational movement of the drum, projecting from the drum jacket, in order to advance the slurry along the drum, the inlet device (28) comprising a number of outlet openings (30, 31) extending along the longitudinal direction of the drum the interior of the drum, characterized in that the inlet device (28) is formed by a tube (28) with a number of side flow flanges (30, 31) projecting in the longitudinal direction of the tube extending towards the drum shell (30, 31), which are arranged to guide the slurry on its upper side, and that the tube (28) is located at such a distance from the inner circumferential surface of the drum with the side flow flanges (30, 31) extending at an angle to and b located at such a distance from the drum jacket (3) that the free-flowing slurry (12) coming from the tube (28) is enabled to pass freely along said side flow flange (30, 31) and is supplied at an angle to the jacket surface (3) of the drum (1) at a distance from the bottom of the drum. Device according to claim 1, characterized in that the tube (28) is open in the upward direction and has two substantially diametrically arranged relative flanges (30, 31). Device according to claim 2, characterized in that the tube (28) has an increasing height in the direction from one end (4) of the drum. Device according to one of the preceding claims 1-3, characterized in that the tube (28) has a length inside the drum (1) which amounts to about 2/3 of the length of the drum. Device according to one of Claims 1 to 4, characterized in that the tube (28) is mounted rotatably about an axis (13) running in the longitudinal direction of the drum. azoózzs-3 Device according to one of Claims 1 to 5, characterized in that the tube (28) is mounted so that it can be adjusted to an angle relative to the drum (1) across its longitudinal direction. Device according to any one of claims 1-6, characterized in that the flanges (30, 31) extend at least up to said helical flange elements (11) which are arranged along the inner screen surface surface (3) of the drum. Device according to one of Claims 1 to 7, characterized in that the tube (28) has an end wall (29) at its end extending into the drum. Device according to claim 8, characterized in that said end wall (29) slopes in the direction from the bottom of the pipe.