SE451324B - GASAL BEACH TREATMENT, SEPARATELY ROTATING OR YEASTING, OF ORGANIC MATERIAL INCLUDED IN A FLUID SLIDE - Google Patents

Description

10 451 324 2 treatment plant performed with the invention, namely a digestion plant; Fig. 2 shows the plant in Fig. 1 in cross section; Figs. 3 and 4 are cross-sectional views of the treatment drum in a sleep mode resp. during movement between two resting positions and serves to illustrate the rotational drive of the drum.

Fig. 5 is a perspective view, partly in section, showing means which provide axial transport of both sedi- mented material such as the so-called the swimming blanket in the drum.

The plant shown has an outer container 11, for example of concrete, which is for the most part filled with temperate water 12. The outer container ll accommodate a rot chamber in the form of a horizontal, circular-cylindrical drum 13, which is for the most part immersed in the water and supported for rotation about its horizontal geometric shaft L of a number of support rollers 14. The drum 13 has in the center on one end end 15 an inlet pipe 16, which by a rotating connection is connected to a device 17 for conti- modern or intermittent feeding of the material shall be digested. This material consists mainly of a water slurry of organic material, but also organic non-digestible material may be included. In the center of it second drum end 18 is an outlet pipe 19 for the outlet digested the material. The inlet pipe 16 and the outlet pipe 19 are liquid-tight and rotatably mounted in the outer container 11 end walls 11A and 11B.

Apart from the inlet and the outlet in the ends 15 and 18 are the drum made of plastic, sheet steel or concrete 13 closed.

The space inside the drum 13 is by means of a transverse wall 20 divided into two sections 13A and 13B, which communicate with each other through a center opening 20A and small peripherals openings 20B in the transverse wall. A corresponding division of the outer container 11 is made with a partition wall 11C. Both the compartments of the outer container may have different water temperatures. so that the material in the two drum compartments 13A and l3B are maintained at different temperatures. It is of course possible to divide the drum and the outer container into more than two 451 324 departments.

The Central opening 20A in the transverse wall 20 of the drum provides transfer of material from drum unit 13A to drum department l3B.

Inside the drum 13 there is also an over substantially whole drum length going arrangement of three planes, on the drum inside 130 at 1200 angles to each other fixedly attached wings 21A, 21B, 21C. As best seen in Figures 3 and 4 are the width of the wings is almost as large as that of the drum radius, but by the radially inner free edges of the wings 22A, 22B, 22C are offset in the same direction from the radii R A the outer longitudinal edges of the wings attached to the drum, can , RB, RC passing through the axis of rotation L of the drum and the three spaces 23A, 23B and 23C in the drum located between adjacent wings 21A, 2lB, 21C communicate freely together.

The width of the open passages or gaps 24A, 24B, 24C between adjacent inner edges of the wings 21A, 21B, 21C is not critical but is preferably 0.2-0.6 times the inside radius of the drum. The width of the wings, thus the distance between them fixed on the inside 13C of the drum outer edge and their free inner edge 22A-22C, are not either critical but is preferably not less than 0.5 times that of the drum inside radius.

Here, the drum 13 is assumed to rotate intermittently in steps about 120 ° each, ie. each full rocation lap includes three consecutive steps. A control not shown in more detail device takes care of the division of the rotational movement into steps.

The driving force for the rotational movement is generated completely or at least most of the material in the drum to due to an "unbalanced" distribution of this, which caused by the gas developed during digestion on it below in connection with Figs. 3 and 4 as described.

Fig. 3 shows the state when the drum 13 is in one of the three sleep modes.

During the rest period when the drum 13 is in that of Fig. 3 shown situation, the bulk of the flue gas that develops is collected in the left part of the drum 13, i.e., in the part of the material under the wing? 21A, in a gaseous 451 324 4 collection space 25A, which is delimited upwards by the inside 13C of the drum 13 and the wing 21A and which are delimited downwards by it horizontal, between the inside of the drum and the wing 2lA walking surface SA of the digestion material, more specifically so called the swimming blanket.

During the rest period, it increases in the gas collection space 25A collected and enclosed the gas volume gradually, so that it the lower boundary surface SA is gradually displaced downwards.

The gas that develops in the digestion material in the right the drum part under the wing 2lB is similarly assembled in one gas collection room 26B. However, the amount of gas that is developed in the material under the wing 2lB less than the amount of gas that during the same time develops in the material under the wing 21A (the amount of material is smaller), and in addition the gas is led in room 26B over to room 25A through a number of transfer tubes 27, which are arranged at suitable intervals throughout the drum length.

The rest of the flue gas developed in the drum goes to a space 28 at the top of the drum, from which the gas discharged through a peripheral gas outlet port 29B adjacent to the drum gaveln 15.

The gas outlet opening 29B is in the position shown in open connection with a gas space 30 in the top the part of an end chamber 31 immediately inside the drum end . This end chamber, which is constantly in the open connection also with additional peripheral gas outlet openings 29A and 29C, are for the most part filled with digestion material. let. In the gas space 30 there is a gas outlet hood 32, which via a 16 line 33 is connected shown gas storage room. through the inlet pipe with a no closer As can be seen from Fig. 3 arises during the rest period time as a result of the gas entrapment in the gas collection space 25A an unbalanced distribution of the digestible material on them parts of the drum lying on either side of the vertical plane C through the center and axis of rotation of the drum line L. The digestion material therefore exerts on the drum one resulting torque, which tends to rotate the drum clockwise, as shown in Fig. 3.

However, the previously mentioned control device prevents 451 324 rotation of the drum until a certain fixed time has elapsed and / or until the torque has been reached a certain definite value or until a certain other condition has been met.

When the condition in question has been met, the drum is allowed turn 1200, so that the wing 21A assumes the position of the Wing 2lB took over during the rest period, Wing 2lB takes that position which Wing 21C took during the rest period and Wing 21C occupies the position that the Wing 21A assumed during the rest period.

The gas in the gas collection space 22A is then drained through the gas outlet the flange opening 29A, which is located after the rotation at the top of the drum. The whole process described above then repeated.

The rotation of the drum takes place relatively quickly with a corresponding rapid agitation and thorough mixing of held in the drum as a result. The agitation facilitates one separation of certain solid, light parts of the drum contents.

These parts, which under the influence of the hydrostatic lifting the force seeks its way up to the swimming blanket and thus lays itself on the surface of the actual slurry in the drum, can consist, for example, of plastic film pieces and other light materials commonly found in household waste.

The self-propulsion of the drum 13 described above can completely or almost completely eliminate the need for external operation of the drum during normal operation. It can still be appropriate to provide the plant with a separate drive which can be used to apply the drum if necessary an external torque. Such a need may exist for example during commissioning or shutdown of when the drum is only partially filled with digestible material or in other situations where the gas generation is insufficient. However, the drive device can be made in such a case considerably smaller, simpler and cheaper than in the case then it must constantly be responsible for all operation of the drum. One such a drive device is symbolically indicated in Fig. 2 and denoted by 35. It is in this case integrated with it the above-mentioned control device.

At the same time the wings 21A, 21B, 21C form a part of drum drive system, they form part of a material 451 324 6 transport system in the drum 13. For this purpose, the wings on both sides provided with upright flanges 37, 38 as extends from the inside of the drum to the free, inner longitudinal edge 22A-22C on the wings. The flanges on each side are substantially parallel to each other and arranged in pointed angle to the parallel longitudinal edges of the wings and thus against a geometric axis perpendicular to the drum plan. In this case, the flanges 37 are on the wing side which is turned against the direction of rotation of the drum 13 - the drum rotates clockwise, seen as in Figs. 2-5 - so arranged that they seen from the inside of the drum towards the free, inner longitudinal edge of it the associated wing moves away from the outlet end of the drum.

The flanges 38 on the opposite side, on the other hand, are so arranged, that they are seen from the inside of the drum towards the free, inner longitudinal the edge of the associated wing gradually approaches the drum man's outlet end.

The material transport system also includes a number from the inside of the drum, fixed flanges 39, which each extends along a left-hand helix.

These flanges 39 are arranged over substantially the entire drum. length and extends over substantially the entire circumference of the drum.

That of the wings 21A, 21B, 21C and the flanges 37, 38, 39 formed transport system serves above all to arrange for a rapid transport through the drum of such material which has a tendency to settle in the drum, such as sand, stone, metal parts and other non-rotten materials and whose presence in the drum should therefore be so as short as possible. It is still referred to as such materials for the sake of simplicity as sedimenting materials or sediment. Even the material that tends to lay on top of the actual slurry and as such forms the so-called floating blanket thanks to the flanges 37 a fast passage through the drum. f The operation of the transport system is explained below in connection to Figs. 3-5.

During the rest period when the drum 13 is in that of Fig. 3 shown position, the sedimentary material sinks in the drum, wherein a portion of the material is captured by the wing 21A, a V, 451 324 7 part is captured by the wing 2lB, part is captured by that part of the inside 13C of the drum 13 which lies between the wings 21l and 2lC, and some are captured by it to the left of the wing 2lC lying portion of the inside of the drum. A larger or smaller part of the sediment captured by the wing 21A can thereby sliding towards the free longitudinal edge 22A of the wing, whereby it at the same time being guided in the direction of the outlet end of the drum by it against this face the flank 38A of the flanges 38. At the free one the long edge 22A of the wing 21A falls off a portion of this material against the wing 2lB next to its free long edge 22B, from where some of the material may fall further towards the lower part of the inside of the drum near the vertical plane C.

When the drum 13 rotates clockwise one third turn towards and past the position shown in Fig. 4 until the next mode, the following occurs.

The sediment that remains on the wing 21A slides out from this in the manner described above and moved thus simultaneously in the direction of the outlet end of the drum the flank 38A of the flanges 38. When the sediment reaches the wing 2lB it comes along with the sediment that is already on this to slide towards the inside of the drum and thereby be moved further in the direction of the outlet end of the drum towards it this facing flank 37A on the flanges 37. The sediment becomes then for the time being lying next to the inside of the drum.

Of the sediment that lies on the inside of the drum between the wings 2lB and 2lC come at or after the rotation it mostly to walk along the inside towards the point on the drum which is currently the lowest. In doing so, this sedi- also to be moved in the direction of the outlet of the drum. end of the flank 39A facing it on those of the drum inside the flanges 39.

The sediment collected at the inside of the drum on the clockwise the side of the wing 21C follows the rotation until the wing 21C has the position assumed in Fig. 3 by the wing 21B. At- at least some of this sediment can then begin to migrate the wing 21C towards the center of the drum, at the same time guiding it against the outlet end of the drum by the flank 38A of the flanges 38 on this wing.

During the rotation, the part of the swimming blanket that 451 324 8 is trapped under the wing 2lB to slide upwards along the side thereof (cf. Fig. 4), the flank 38A of the flange 38 leads this part of the floating blanket in the direction of the drum outlet end until it leaves the wing 2lB at its free edge 22B and rises to the top of the drum.

During the rest period following the rotation and at the subsequent rotation (after which the drum thus turning two thirds of a turn) it is repeated above described separation and transfer procedure, which then repeated for each subsequent rest period and rotation.

From the foregoing it appears that the main part of the sediment and part of the floating blanket is moved in the direction of the drum outlet end in connection with each rotational movement of the drum. A sediment particle or body or a light particle entering the drum 13 at the inlet end can thus passing through the drum in a time that is short in comparison with the residence time of the majority of the sludge in the drum.

The flanges 37, 38, the height of which is not critical (it can amount to, for example, 0.01-0.05 times the radius of the drum) on each wing should, of course, be so arranged in to the flanges of the other wings and flanges 39 on the inside of the drum, that as large a part as possible of the length of each flange is used for axial transport.

At the discharge end of the drum is the shape of the wings 21A-21C and the flanges 37-39 modified on a no closer shown, so that the sediment and the floating blanket are led to the outlet pipe 19 and out from the drum 13 to a receiving l1D in the outer container ll. To this room is discharged also the eradicated material from the drum 13. Also at the transverse wall 20 of the drum is the shape of the wings and flanges modified, so that the sediment and the flood cover are led to and through the center opening of the transverse wall.

Extends along the geometric axis of the digestion chamber drum 13 a recirculation pipe 40, through which in a non-proximity mare shown way a small part of the exterminated or almost the eradicated material is returned from a place near the outlet end of the drum to a location near the inlet ll) 451 324 9 the end to act as a vaccine on the newly fed the material and thereby accelerate its digestion.

In the one shown as an exemplary embodiment and described above In the embodiment, there are three circumferentially evenly distributed wings 21A-21C, which has been found to be preferred at least in some cases. However, it is within the framework of the invention to have a different number of wings and to design and arrange them in a different way than shown and described. The wings can e.g. be curved or angled in different ways in cross section, and their angle to the radius through the outer long edge can vary within wide limits.

In the example shown as an example, the wings are on the co-rotation side of this radius RA, RB, also possible to let the wings lie on the opposite side; C, but it is the angle of the wings towards said radius is preferably at most in ao °.

The invention is of course also applicable in the case then the drum is operated continuously or intermittently for a lot small steps.

Claims (4)

10 15 20 25 30 35 451 324 10 Patent claims A plant for gas-producing treatment, in particular digestion or fermentation, of organic material contained in a liquid slurry, which comprises an elongate, horizontal treatment drum rotatable about its geometric axis with a material inlet at one end and a material outlet at the other end and with co-rotating material transport means arranged therein, characterized in that the drum (13) has wings (21A, 21B, 21C) lying down on the inside and parallel, non-radially planar, extending into the interior. of the drum, and that the material transport means comprise a plurality in the longitudinal direction of the drum (13) separated, at an acute angle to a transverse plane lying guide rails (37,38,39), which are attached to the inside {13C) of the drum and / or to the wings ( 21A, 21B, 21C) and so directed that particles settling in the drum which are captured by a side surface (37A, 38A, 39A) on the guide rails are deflected in the direction of said second drum end of this side surface. Plant according to claim 1, characterized in that a group (37) of the guide rails is attached to the side of the wings (21A, 21B, 21C) facing in the direction of rotation and that another group (39) of the guide rails is attached to the drum (13) inner circumferential surface (13C). Plant according to claim 2, characterized in that a further plurality of guide rails (38) separated in the longitudinal direction of the drum (13) and at an acute angle to a transverse plane in the drum are attached to the side of the wings (21A-21C) facing the direction of rotation. ) and so arranged that particles ascending in the drum, which are captured by a side surface (37A) on these further guide rails, are deflected in the direction of the said second drum end of this side surface. Plant according to claim 2 or claim 3, characterized in that the wings (21A-21C) and the guide rails (37-39) at said second drum end are arranged to also deflect the particles towards the central area (19) of the drum. y.