AT394995B - Apparatus for separating off and compressing solids - Google Patents

Abstract

The invention describes an apparatus 1 for separating off and compressing solids 55 of a liquid/solid mixture 24. The apparatus has a moisture-removing zone 54 and a transport device 5 which is coupled to a drive and has a receiving device for the solids 55 separated off in the transport device 5. The transport device is formed by a screw conveyor 6 which transports the solids 55 against the action of gravity from a lower first level to a higher second level, the conveyor screw 8 of which has a pitch 53 which decreases in the direction of transport. A bottom region 16 and an end wall 5 of the transport shell 7 holding the conveyor screw 8 is formed as a screen. The end wall 15 forms a part of a receiving chamber 13 into which a wastewater feed line opens. The transport device 5 is disposed in a shell 20 which seals odour-tightly, which shell is provided at its lowest point with an outlet which opens into especially a biological sewage treatment plant, for example a biotope 86. The transport shell 7 has guide tracks 67 for the liquid/solid mixture 24 which are disposed to run in parallel to a central axis 26 of the screw conveyor 6 or to run spirally to this. <IMAGE>

Description

AT 394 995 B

The invention relates to a device for separating and compressing solids of a liquid-solid mixture with a dehumidification zone and a conveyor device coupled to a drive and a receiving device for the solids separated in the conveyor device, in which the conveyor device passes the solids against the action of gravity from one low first level to a higher 5 second level conveying screw conveyor and a pitch of a screw conveyor of the screw conveyor is reduced in the conveying direction and that a bottom region and an end wall of the tubular screw housing receiving openings with openings, in particular sieve-shaped, and the end wall is part of a Receiving chamber into which a wastewater supply line forms, and that the conveyor is arranged in an odor-tightly sealed housing, which is at its lowest point 10 is provided with an outlet, which in a particular biological sewage treatment plant, for. B. opens a biotope.

Devices are known in which screw conveyors are used to discharge solids from a liquid-solid mixture. The liquid-solid mixture flows through a receiving area of the screw, which is provided with a lattice-shaped casing. With these devices, the screws are dimensioned according to the maximum required delivery rate and the resulting low efficiency requires high drive powers. These devices also have an almost uniform conveying speed for the material to be conveyed.

Another known device - according to US Pat. No. 4,041,854 - for better compaction of solid residues, it is known to arrange resistance strips in the housing accommodating the screw. However, since these resistance strips run in a plane perpendicular to the screw axis, they cause a higher power requirement of such systems.

Furthermore, devices for removing, removing and dewatering solids from liquids, in particular from channels in sewage treatment plants, are known in accordance with EP-OS 0 040 425, DE-PS 30 19 127 and DE-PS 31 22 131. These devices are equipped with special training details, in particular cleaning arms for the solids, restrained computing devices, as well as 25 conveyor pipe sections coupled with their own drive for compressing the conveyed goods.

The present invention has for its object to provide a device in which the total energy consumption for the disposal and distribution of a liquid-solid mixture, in particular feces, is possible with a low total expenditure of energy.

This object of the invention is achieved in that the conveyor housing has guideways for the liquid-30 mixture of solids, which are arranged parallel to a central axis of the screw conveyor or spirally to this. The surprising advantages of this seemingly simple solution according to the invention lie in the fact that, on the one hand, there is a mechanical separation between the liquids and the solids and, due to the winding height of the screw becoming smaller in the feeding direction, the conveying speed of the solid in conveying direction is reduced.This leads to a compression of the solid and a further 35 mechanical pressing of the liquid content contained in the solid so that the solids separated out in the liquid-solid mixture can be packaged and transported to central disposal points with little energy expenditure. At the same time, however, this exact separation of solid and liquid enables the liquids to be clarified, which is made possible in a biological sewage treatment plant, so that a further expenditure of energy for liquid cleaning can also be saved. The surprising advantage of this solution lies in the fact that it is possible to dispose of liquid-solid mixtures, especially faeces, in an environmentally friendly manner without odor nuisance and away from extensive infrastructures such as large sewage treatment plants. Due to the special design of the screw conveyor, the conveying capacity, drive power and the »required overall length of the screw conveyor» can be reduced to e.g. B. installation-related circumstances. Furthermore, the guideway in the conveyor housing reduces the drive power as well as 45 d »overall length.

According to a further advantageous embodiment, it is provided that the guideways are formed by at least one guide web projecting on the inner circumference of the conveyor housing in the direction of the central axis d »screw conveyor, whereby a continuous conveying of the solid is achieved by the constant self-cleaning d» screw conveyor. It is also possible from »that the guideways are spiraled out with a spiral running in the opposite direction to the screw conveyor, whereby a higher resistance to counteracting the conveying force» and thus a higher compression and dehumidification of the solids is achieved.

It is also advantageous that the guideways in the area of a receiving chamber are arranged in a straight line and approximately parallel to the center axis of the screw conveyor, whereby the liquid of the liquid mixture in the area of the receiving chamber can be separated.

Furthermore, it is possible for the spiral winding of the guideway »i to have a different winding height, thereby accelerating or reducing the conveying speed. This makes it -2-

AT 394 995 B allows a better squeezing of the liquid in the compression area while reducing the drive power of the screw. If the incline of the screw is slightly increased after the compression area, the dry medium is crumbled. The spiral arrangement of the guideways also enables the worm to be centered, as a result of which even smaller radial forces acting on the worm and its bearing are sufficient.

According to a further advantageous embodiment, it is provided that the guide tracks are formed by grooves in the conveyor housing, because additional components can be saved as a result.

It is also advantageous, however, that the conveyor device is designed as a self-operable unit with an in particular housing-shaped transport and / or assembly frame in which control, monitoring and energy supply devices, and optionally a solar arrangement, are arranged. In this way, an independently operable structural unit is achieved which can be used as a functional module, in particular in areas in which disposal, in particular faeces, is difficult with the lack of a suitable infrastructure.

An advantageous further development is also that the screw conveyor is constructed in several parts and screw elements IS are coupled to the drive arrangement via coupling devices. By dividing the screw into more areas to be operated independently of one another, which can be coupled to the drive in a sequential order, a low drive power for driving the screw can be achieved. It is also possible that each of the screw elements is coupled with its own drive arrangement. As a result, the screw parts can be operated both independently of one another and simultaneously. 20 But it is also advantageous that an end-side discharge opening of the screw conveyor is an admixing and / or

A metering device with a container and an opening for an admixture arranged in the direction of the screw conveyor is assigned, because this allows additives to be added to the sealed solid, thereby accelerating biodegradation of the solids with the environmentally harmful pollutants contained therein. 25 It is also possible for the discharge opening to be arranged downstream of the housing in the conveying direction of the solid

Coupling device for a container, in particular is arranged via a coupling device for the solid to be tightly connected to the housing, whereby a gas-tight device is achieved which does not release any odorous substances into the environment.

It is also advantageous that the screw conveyor, the conveyor housing, the casing of the housing and the admixing and / or metering device are made of rustproof material, because the device is used, in particular for aggressive media, and due to this design, a long lifespan »is reached.

A possible embodiment is also that the drive arrangement has a gear which is motionally connected to the screw conveyor, whereby a correspondingly high torque is achieved with a small drive power. 35 It is also possible that an overflow device for the liquid is integrated in the end wall of the collecting container, whereby an emergency function of the device is given even in the event of a failure of the drive arrangement or the conveyor device.

Finally, it is also possible for the admixing and / or metering device to have an electromotive drive, as a result of which the admixture is supplied to the medium uniformly and continuously. 40 For a better understanding of the invention, this will be explained in more detail with reference to the embodiment examples shown in the drawings:

Show it:

Figure 1 shows a device according to the invention with a conveyor device formed by a screw conveyor in side view, in a simplified representation. 45 FIG. 2 shows the conveyor device according to FIG. 1 in a side view and enlarged view;

3 shows the conveyor device in front view, according to the lines (ΙΠ-ΙΠ) in FIG. 2;

4 shows another embodiment variant of the conveyor device in a side view;

5 shows a further embodiment variant of the conveyor device with guideways, cut in a side view; 50 Fig. 6 another embodiment variant of the conveying device cut in front view.

In Fig. 1, a device (1) is shown as an independently functional unit (2) of a disposal system (3) for a liquid-solid mixture, in particular for faeces. A conveyor (5), in particular a screw conveyor (6), is arranged in a transport and / or assembly frame (4). This consists of a tubular conveyor housing (7), in which a screw conveyor (8) with the drive shaft (9) 55 is arranged concentrically. The drive shaft (9) is at an angle (11) relative to a contact surface (10) d »device (1) ) between 10 ° and 60 °, preferably 30 °, inclined. One direction of conveyance - arrow (12) - is increasing from one formed by a widening »! Receiving chamber (13) of the conveyor housing (7) in the direction of an end-side -3-

AT 394 995 B

Discharge opening (14) of the conveyor housing (7). An end wall (15) of the receiving chamber (13) and at least one bottom region (16) of the conveyor housing (7) is designed in the form of a sieve or provided with openings (17).

The conveyor housing (7) is surrounded on all sides at a distance (18) by a housing (20) forming a sealed casing (19). In the area of the receiving chamber (13) of the conveyor housing (7), a pipe socket (22) for connecting a line (23) for supplying a liquid / solid mixture (24) is arranged in a cover plate (21) of the housing (20).

In a front wall (25) of the housing (20) assigned to the front wall (15) of the conveyor housing (7) there is a pipe socket (27) for connecting a discharge pipe (28) approximately parallel to a »central axis (26) of the drive shaft (9). arranged for a liquid (29) from the liquid-solid mixture (24).

In the area of the discharge opening (14) of the conveyor housing (7) on the circumference of the casing (19) is a tubular connecting piece (30) with a coupling device (31) for a container (32), e.g. B. a sack (33). The discharge opening (14) of the conveyor housing (7) spaced opposite is in the housing (20) in a plane perpendicular to the central axis (26) extending an end wall (34) for fastening a drive arrangement (35), for. B. a geared motor (36).

The conveyor housing (7) has in the area of the discharge opening (14) a receptacle (37) of an admixing and / or metering device (38) for an approximately vertically directed supply of an admixture (39), e.g. B. lime, grape pomace, etc. For this purpose, the receptacle (37) of the admixing and / or metering device (38) has an opening (40) which, if necessary, is opened or closed via a flap (41) and a drive arrangement (42) which is operatively connected to the flap (41) can be. The receptacle (37) has an odor-tight cover (43) for the feeding of the admixture (39).

The admixture (39) causes rapid biodegradation, odor control and the conversion of the solid into a biological fertilizer or into humus.

In the transport and / or assembly frame (4) there is also a control device (44) and an energy supply device (45), for. B. batteries (46), for the long-term supply of the geared motor (36) with energy and for the control and monitoring of the functions of the device (1) arranged with the transport and / or mounting frame (4) z. B. a solar array (47) for converting sunlight into electrical energy, which can be stored in the batteries (46). Swivel devices (48) serve to align the solar cell panel (49) in the direction of incident light rays - arrow (50).

The device (1) thus achieves an independent and functional disposal system (3) which is independent of external connections and which can be operated independently of an external energy supply. Due to the structure, as such a compact unit (2), this seal (l) or waste disposal system (3) is particularly suitable for the environmentally friendly disposal of faeces for civilized buildings, such as, for. B. mountain huts or for non-stationary facilities such as means of transport, z. B. ships, buses, etc.

As can also be seen in FIG. 1, the screw conveyor (6) has a screw (51), formed from the drive shaft (9), and a screw spiral (52) connected to it, in particular welded, spiraling in the longitudinal direction of the drive shaft (9) ). The screw spiral (52) has a pitch (53) between adjacent windings, which decreases in the direction of conveyance - arrow (12). This leads to a reduction in the conveying speed in the conveying direction-Pfeü (12) -, which in a dehumidification zone (54), through the drainage of the liquid (29) over the openings (17) and the pipe socket (27), pre-dried liquid-solid mixture (24 ) pressed by the compression process occurring and the residual liquid still contained therein is squeezed out. The solid (55) is thus compressed to a small volume and subsequently deposited in the container (32)

As building material for the liquid-solid mixture (24), liquid (29) and solid (55) coming into contact with components, such as. B. the conveyor housing (7), screw conveyor (8) and housing (20) is advantageously used due to the aggressiveness of these media to prevent corrosion of stainless steel or plastic, or a combination of these materials.

The liquid (29) derived from the device (1) can be fed to an infiltration or a biotope. The solid (55) present in compact form can be rapidly biodegraded by composting or removal to a sewage treatment plant, in a digestion tower etc.

In this way, harmful environmental influences such as those frequently encountered in the disposal of domestic waste water, in particular faeces, from buildings for which there are no municipal facilities such as sewage treatment plants can be effectively avoided. These include impairments due to pollution, smell, flies, etc.

Of course, the pipe socket (22) for connecting a line (23) supplying the medium, as well as the pipe socket (27) for connecting the discharge pipe (28) to others with respect to the screw conveyor (8) and the line of the liquid (29) more suitable positions, e.g. B. through the end wall (15).

Furthermore, it may be advantageous to set up the energy supply device (45) and the solar arrangement (47) independently of the location of the device (1) and to connect them to one another via lines. -4-

AT 394 995 B

2 shows a device (1) with a multi-part screw conveyor (8), in which screw elements (56, 57) arranged one behind the other in the conveying direction - arrow (12) - can be coupled independently of one another to the drive arrangement (35). For this purpose, the screw element (57) closer to the drive arrangement (35) has a hollow shaft (58) in which a drive shaft (59) of the screw element (56) is rotatably mounted. The hollow shaft (58) with the screw element (57) and the drive shaft (59) for the screw element (56) mounted therein is rotatably supported in a bearing arrangement (61) which is supported relative to the conveyor housing (7) by means of rib ribs (60). Via a coupling device (62), the drive device (35) is optionally coupled to the drive shaft (59) of the screw element (56) or the hollow shaft (58) of the screw element (57) by dividing the screw conveyor (8) into the screw element (56) with a length (63) and the screw element (57) with a length (64), which are alternately coupled to the drive arrangement (35), a lower output for the geared motor (36) can be achieved overall. The starting torque of the screw element (57) after the device (1) has been idle for some time and partially dried and compressed solid in the area of the discharge opening (14) is decisive for the performance of the drive arrangement (35). This starting torque can be kept low with a correspondingly short length (64).

The screw element (56) assigned to the receiving chamber (13) has a greater pitch (65) than a pitch (66) of the screw element (57) arranged downstream in the conveying direction - arrow (12). In connection with the alternate operation of the screw elements (56, 57), the liquid-solid mixture (24) is dehumidified and compressed in the direction of the discharge opening (14).

On the inner periphery of the conveyor housing (7) are guideways (67), for. B. in the partial area of the conveyor housing (7), spirally coiled guide webs (68). The guide webs (68) are firmly connected to the conveyor housing (7), in particular welded to the conveyor housing. This prevents the liquid-solid mixture from becoming stuck in the screw conveyor (8) or from rotating in the conveyor housing (7). The guideway (67) or guide webs (68) are advantageously formed in a helix which runs in the opposite direction from the worm helix (52). In the dehumidification zone (54), however, they are arranged in a straight line parallel to the central axis (26).

Instead of the guide webs (68), the guide tracks (67) can be arranged by groove-shaped guide tracks (67) widening into the conveyor housing (7) and its inner circumference. It is also expedient in this embodiment to arrange the guideways in the area of the receiving chamber (13) parallel to the central axis (26) and in the direction of the discharge opening (14) in a spiral fashion. The pitch (53) can be designed to vary, whereby the effect of the compression or the lump-like division of the compressed solid can be controlled.

In Fig. 3, the conveyor (5) of the device (1) is shown in cross section. In the housing (20) at a distance (18) via spacer (69) the conveyor housing (7) is held approximately concentrically.

The conveyor housing (7) has in the bottom area (16) the openings (17) for discharging the liquid in the direction of the pipe socket (27) with the discharge pipe (28) connected to it. The screw conveyor (8) is concentrically rotatably mounted in the conveyor housing (7), a diameter (70) of the screw conveyor (8) being smaller than an inner diameter (71) of the conveyor housing (7). In an annular area formed by the difference in the inner diameter (71) minus the diameter (70), the guideways (67) are fastened to the inner circumference of the conveyor housing (7), in particular welded to the latter. B. straight, but also spirally along the inner circumference of the conveyor housing (7), the spiral of the spiral guideways (67) is preferably designed in the opposite direction to the spiral of the screw helix (52). the area with the cover plate (21) tightly sealed, in which the pipe socket (22) for the introduction of the liquid-solid mixture (24) is arranged

4 shows a further embodiment variant of the conveyor device (5). In this embodiment variant, the conveyor housing (7) is made up of several parts, namely by the receiving chamber (13) and a tubular conveyor channel (72) arranged downstream in the conveying direction - arrow (12) the screw (51) concentrically enveloping jacket (73) of the conveying channel (72) is formed from helically arranged windings of a strip-shaped band (74) or a profile. Between the windings of the band (74) or profile are circular openings (75) Designed to drain the liquid (29) The screw conveyor (8) has the pitch (65). This becomes smaller in the conveying direction -arrow (12) -, as a result of which a compression region (76) is formed in the direction of the discharge opening (14) in which the liquid-solid mixture (24) compresses and residual quantities of the liquid (29) are pressed out of the liquid-solid mixture will. The helical turns of the band (74) are preferably arranged in opposite directions to the turns of the screw (51), whereby a conveying resistance is achieved and a rotational entrainment of the liquid which prevents the conveyance.

Claims (15)

AT 394 995 B solid mixture (24) in the delivery channel (72) is prevented. The screw conveyor (8) can from the drive assembly (35), for. B. operated via a gear (77) with variable speeds. 5 and 6, a portion of the screw conveyor (6) with the guideways (¢ 7) is shown. The conveyor housing (7) with the inside diameter (71) and the diameter (70) of the screw (51) has guide webs (68) projecting in the direction 5 of the central axis (26). A height (78) of the guide webs (68) is slightly less than half the difference between the inside diameter (71) and the diameter (70). In the area of the receiving chamber (13), the guide webs (68) run in a straight line and approximately parallel to the central axis (26). In the compression area (76), the guide webs (68) are spirally wound in the opposite direction to the spiral of the screw (51), as a result of which an angle (79) is formed between the guide tracks (67) and the screw (51). 79) the compression effect, the conveying speed and the power requirement of the drive arrangement (35) can be influenced. At an angle (79) of z. B. 60 ° reduces the conveying speed and the power requirement to about 50%. As can be better seen in FIG. 6, the guideways (67) can be formed by grooves (80) formed in the conveyor housing (7) and distributed uniformly over the circumference. In this arrangement, too, it is of course advantageous to design the grooves (80) in the area of the receiving chamber (13) in a straight line and parallel to the axis (26) and in the compression area (76) in the opposite direction to the screw (51). The discharge opening (14) can be seen from FIG. 5 by a z. B. made of an elastic material baffle plate (81) partially covered. As a result, the compression effect in the compression zone (76) is increased and the degree of dehumidification is increased by more pressing out of the liquid (29). B. 20 pot-shaped and attached to the circumference of the conveyor housing (7) with a hose clamp (82) and has a central bore (83) outgoing, radially arranged slots (84). With this design, the medium is dammed up in front of the baffle plate (81) and occurs when a corresponding «! Back pressure in compact form through the elastically deforming baffle plate. To dispose of the liquid-solid mixture (24), this is now introduced into the receiving chamber (13) of the 25 conveying device (5), with some of the liquid (29) already passing through the openings (17) or via an overflow device (85) Housing (20) and in the discharge pipe (28) is derived. From the receiving chamber (13), the remaining liquid / solid mixture (24) is now conveyed from the screw conveyor into the compression area (76) and compressed as a result of the formation of the screw conveyor (8) and the guideways (67), the further dehumidification he follows. In the solid (55), the admixture (39) is added to accelerate the digestion by means of the admixing and / or metering device (38). The solid (55) treated in this way is further conveyed by the screw conveyor (8) in a container (32), eg. B. the bag (33), whereby a disposal of the solid (55) z. B. by removal to a landfill or a sewage treatment plant. The liquid (29) derived from the disposal system (3) can be fed via a line system to an infiltration system arranged further away from the device (1), or in particular to a biotope (86). Finally, it should be pointed out that, for better understanding, a schematic form of representation has been selected in some cases and individual parts are shown disproportionately enlarged. It is of course possible within the scope of the invention to change the arrangement of the individual elements as desired or to combine them differently in addition to the exemplary embodiments shown. Individual 40 features from the exemplary embodiments shown, such as the guide tracks (67), the separate screw elements (56, 57), which can be coupled to the drive arrangement (35), etc. via the coupling device (62), can represent independent solutions according to the invention. 45 PATENT CLAIMS 50 1. Apparatus for separating and compressing solids of a liquid-solid mixture with a dehumidification zone and a conveying device coupled to a drive and a receiving device for the solids separated in the conveying device, in which the conveying device by means of the solids 55 against the action of gravity is formed from a lower first level to a higher second level conveying screw conveyor and a pitch of a screw conveyor of the screw conveyor decreases in the direction of conveyance, and that a bottom region and an end wall of the tubular screw housing -6- AT 394 995 B conveyor housing with openings, in particular sieve-like is formed and the end wall forms part of a receiving chamber into which a wastewater supply line, and that the conveyor is arranged in an odor-tight sealed housing, which se is provided in the deepest point with an outlet which opens into a particular biological clarifier, e.g. a biotope, characterized in that the conveyor housing S (7) has guideways (67) for the liquid-solid mixture (24) which are parallel to a central axis (26) of the screw conveyor (6) or arranged spirally to this. 2. Apparatus according to claim 1 or 2, characterized in that the guide tracks (67) by at least one on the inner circumference of the conveyor housing (7) in the direction of the central axis (26) of the screw conveyor (8) projecting 10 arranged guide web (68) is formed 3. Apparatus according to claim 1 or 2, characterized in that the guideways (67) are formed spirally with the screw (8) in opposite directions. 4. Device according to one or more of claims 1 to 3, characterized in that the guide tracks (67) in the region of a receiving chamber (13) are arranged in a straight line and approximately parallel to the central axis (26) of the screw conveyor (6). 5. The device according to one or more of claims 1 to 4, characterized in that the spiral winding 20 of the guide tracks (67) has a different winding height. 6. Device according to one or more of claims 1 to 5, characterized in that the guide tracks (67) are formed by grooves (80) in the conveyor housing (7). 7.Device according to one or more of the claims 6 to 6, characterized in that the conveying device (5) is designed as a self-operable unit (2) with an in particular housing-shaped transport and / or assembly frame (4), in which control, monitoring and energy supply devices (44, 45), optionally a solar array ( 47) are arranged. 8. The device according to one or more of claims 1 to 7, characterized in that the screw conveyor (8) is formed in several parts and screw elements (56, 57) are coupled to the drive arrangement (35) via coupling devices (62). 9. The device according to one or more of claims 1 to 8, characterized in that each of the 35 screw elements (56, 57) is coupled with its own drive arrangement (35). 10. The device according to one or more of claims 1 to 9, characterized in that an end discharge opening (14) of the screw conveyor (6), an admixing and / or metering device (38) with a container (37) and one in the direction of the screw conveyor (8) arranged opening (40) for an admixture (39) is assigned 40. 11. The device according to one or more of claims 1 to 10, characterized in that the discharge opening (14) downstream in the conveying direction of the solid on the housing, a coupling device (31) for a container (32), in particular via a coupling device (31) with tight the housing (20) to be connected sack 45 (33) for the solid (55) is arranged 12. The device according to one or more of claims 1 to 11, characterized in that the screw conveyor (8), the conveyor housing (7), the casing (19) of the housing (20) and the admixing and / or metering device (38) stainless material are formed. 50 13. The device according to one or more of claims 1 to 12, characterized in that the drive arrangement (35) has a gear (77) which is motionally connected to the screw conveyor (8). 14. The device according to one or more of claims 1 to 13, characterized in that an overflow device (85) for the liquid is integrated in the end wall 55 (15) of the collecting container. -7- AT 394 995 B 15. Device according to one or more of claims 1 to 14, characterized in that the admixing and / or metering device (38) has an electromotive drive. Including 3 sheets of drawings -8-