WO1995007744A1 - Systeme et procede de traitement d'un melange de solides et de liquides - Google Patents

Systeme et procede de traitement d'un melange de solides et de liquides Download PDF

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Publication number
WO1995007744A1
WO1995007744A1 PCT/EP1994/003093 EP9403093W WO9507744A1 WO 1995007744 A1 WO1995007744 A1 WO 1995007744A1 EP 9403093 W EP9403093 W EP 9403093W WO 9507744 A1 WO9507744 A1 WO 9507744A1
Authority
WO
WIPO (PCT)
Prior art keywords
auger
liquid
collecting
screening
solid material
Prior art date
Application number
PCT/EP1994/003093
Other languages
English (en)
Inventor
Günther Abel
Original Assignee
Abel Guenther
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Priority claimed from CA002106291A external-priority patent/CA2106291A1/fr
Priority claimed from CA002107172A external-priority patent/CA2107172A1/fr
Application filed by Abel Guenther filed Critical Abel Guenther
Priority to AU78081/94A priority Critical patent/AU7808194A/en
Priority to EP19940928784 priority patent/EP0719171A1/fr
Priority to JP50899895A priority patent/JPH09502418A/ja
Publication of WO1995007744A1 publication Critical patent/WO1995007744A1/fr

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Classifications

    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01DSEPARATION
    • B01D21/00Separation of suspended solid particles from liquids by sedimentation
    • B01D21/28Mechanical auxiliary equipment for acceleration of sedimentation, e.g. by vibrators or the like
    • B01D21/283Settling tanks provided with vibrators
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01DSEPARATION
    • B01D21/00Separation of suspended solid particles from liquids by sedimentation
    • B01D21/0018Separation of suspended solid particles from liquids by sedimentation provided with a pump mounted in or on a settling tank
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01DSEPARATION
    • B01D21/00Separation of suspended solid particles from liquids by sedimentation
    • B01D21/24Feed or discharge mechanisms for settling tanks
    • B01D21/2433Discharge mechanisms for floating particles
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01DSEPARATION
    • B01D21/00Separation of suspended solid particles from liquids by sedimentation
    • B01D21/24Feed or discharge mechanisms for settling tanks
    • B01D21/245Discharge mechanisms for the sediments
    • B01D21/2461Positive-displacement pumps; Screw feeders; Trough conveyors
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01DSEPARATION
    • B01D24/00Filters comprising loose filtering material, i.e. filtering material without any binder between the individual particles or fibres thereof
    • B01D24/28Filters comprising loose filtering material, i.e. filtering material without any binder between the individual particles or fibres thereof with the filter bed moving during the filtration
    • B01D24/32Rotation
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01DSEPARATION
    • B01D24/00Filters comprising loose filtering material, i.e. filtering material without any binder between the individual particles or fibres thereof
    • B01D24/38Feed or discharge devices
    • B01D24/44Feed or discharge devices for discharging filter cake, e.g. chutes
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01DSEPARATION
    • B01D24/00Filters comprising loose filtering material, i.e. filtering material without any binder between the individual particles or fibres thereof
    • B01D24/46Regenerating the filtering material in the filter
    • B01D24/4631Counter-current flushing, e.g. by air
    • B01D24/4636Counter-current flushing, e.g. by air with backwash shoes; with nozzles
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01DSEPARATION
    • B01D33/00Filters with filtering elements which move during the filtering operation
    • B01D33/01Filters with filtering elements which move during the filtering operation with translationally moving filtering elements, e.g. pistons
    • B01D33/03Filters with filtering elements which move during the filtering operation with translationally moving filtering elements, e.g. pistons with vibrating filter elements
    • B01D33/0346Filters with filtering elements which move during the filtering operation with translationally moving filtering elements, e.g. pistons with vibrating filter elements with flat filtering elements
    • B01D33/0353Filters with filtering elements which move during the filtering operation with translationally moving filtering elements, e.g. pistons with vibrating filter elements with flat filtering elements self-supporting
    • B01D33/0361Bar screens
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01DSEPARATION
    • B01D33/00Filters with filtering elements which move during the filtering operation
    • B01D33/01Filters with filtering elements which move during the filtering operation with translationally moving filtering elements, e.g. pistons
    • B01D33/03Filters with filtering elements which move during the filtering operation with translationally moving filtering elements, e.g. pistons with vibrating filter elements
    • B01D33/0346Filters with filtering elements which move during the filtering operation with translationally moving filtering elements, e.g. pistons with vibrating filter elements with flat filtering elements
    • B01D33/0353Filters with filtering elements which move during the filtering operation with translationally moving filtering elements, e.g. pistons with vibrating filter elements with flat filtering elements self-supporting
    • B01D33/0369Filters with filtering elements which move during the filtering operation with translationally moving filtering elements, e.g. pistons with vibrating filter elements with flat filtering elements self-supporting with curved filtering elements
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01DSEPARATION
    • B01D33/00Filters with filtering elements which move during the filtering operation
    • B01D33/06Filters with filtering elements which move during the filtering operation with rotary cylindrical filtering surfaces, e.g. hollow drums
    • B01D33/11Filters with filtering elements which move during the filtering operation with rotary cylindrical filtering surfaces, e.g. hollow drums arranged for outward flow filtration
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01DSEPARATION
    • B01D33/00Filters with filtering elements which move during the filtering operation
    • B01D33/44Regenerating the filter material in the filter
    • B01D33/48Regenerating the filter material in the filter by flushing, e.g. counter-current air-bumps
    • B01D33/50Regenerating the filter material in the filter by flushing, e.g. counter-current air-bumps with backwash arms, shoes or nozzles
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01DSEPARATION
    • B01D33/00Filters with filtering elements which move during the filtering operation
    • B01D33/58Handling the filter cake in the filter for purposes other than for regenerating the filter cake remaining on the filtering element
    • B01D33/62Handling the filter cake in the filter for purposes other than for regenerating the filter cake remaining on the filtering element for drying
    • B01D33/64Handling the filter cake in the filter for purposes other than for regenerating the filter cake remaining on the filtering element for drying by compression
    • B01D33/648Handling the filter cake in the filter for purposes other than for regenerating the filter cake remaining on the filtering element for drying by compression by screws
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01DSEPARATION
    • B01D33/00Filters with filtering elements which move during the filtering operation
    • B01D33/70Filters with filtering elements which move during the filtering operation having feed or discharge devices
    • B01D33/76Filters with filtering elements which move during the filtering operation having feed or discharge devices for discharging the filter cake, e.g. chutes
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B03SEPARATION OF SOLID MATERIALS USING LIQUIDS OR USING PNEUMATIC TABLES OR JIGS; MAGNETIC OR ELECTROSTATIC SEPARATION OF SOLID MATERIALS FROM SOLID MATERIALS OR FLUIDS; SEPARATION BY HIGH-VOLTAGE ELECTRIC FIELDS
    • B03BSEPARATING SOLID MATERIALS USING LIQUIDS OR USING PNEUMATIC TABLES OR JIGS
    • B03B5/00Washing granular, powdered or lumpy materials; Wet separating
    • B03B5/28Washing granular, powdered or lumpy materials; Wet separating by sink-float separation
    • B03B5/30Washing granular, powdered or lumpy materials; Wet separating by sink-float separation using heavy liquids or suspensions
    • B03B5/36Devices therefor, other than using centrifugal force
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B03SEPARATION OF SOLID MATERIALS USING LIQUIDS OR USING PNEUMATIC TABLES OR JIGS; MAGNETIC OR ELECTROSTATIC SEPARATION OF SOLID MATERIALS FROM SOLID MATERIALS OR FLUIDS; SEPARATION BY HIGH-VOLTAGE ELECTRIC FIELDS
    • B03BSEPARATING SOLID MATERIALS USING LIQUIDS OR USING PNEUMATIC TABLES OR JIGS
    • B03B9/00General arrangement of separating plant, e.g. flow sheets
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B03SEPARATION OF SOLID MATERIALS USING LIQUIDS OR USING PNEUMATIC TABLES OR JIGS; MAGNETIC OR ELECTROSTATIC SEPARATION OF SOLID MATERIALS FROM SOLID MATERIALS OR FLUIDS; SEPARATION BY HIGH-VOLTAGE ELECTRIC FIELDS
    • B03BSEPARATING SOLID MATERIALS USING LIQUIDS OR USING PNEUMATIC TABLES OR JIGS
    • B03B9/00General arrangement of separating plant, e.g. flow sheets
    • B03B9/06General arrangement of separating plant, e.g. flow sheets specially adapted for refuse
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B30PRESSES
    • B30BPRESSES IN GENERAL
    • B30B11/00Presses specially adapted for forming shaped articles from material in particulate or plastic state, e.g. briquetting presses, tabletting presses
    • B30B11/22Extrusion presses; Dies therefor
    • B30B11/221Extrusion presses; Dies therefor extrusion dies
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B30PRESSES
    • B30BPRESSES IN GENERAL
    • B30B11/00Presses specially adapted for forming shaped articles from material in particulate or plastic state, e.g. briquetting presses, tabletting presses
    • B30B11/22Extrusion presses; Dies therefor
    • B30B11/224Extrusion chambers
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B30PRESSES
    • B30BPRESSES IN GENERAL
    • B30B9/00Presses specially adapted for particular purposes
    • B30B9/02Presses specially adapted for particular purposes for squeezing-out liquid from liquid-containing material, e.g. juice from fruits, oil from oil-containing material
    • B30B9/12Presses specially adapted for particular purposes for squeezing-out liquid from liquid-containing material, e.g. juice from fruits, oil from oil-containing material using pressing worms or screws co-operating with a permeable casing
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B30PRESSES
    • B30BPRESSES IN GENERAL
    • B30B9/00Presses specially adapted for particular purposes
    • B30B9/02Presses specially adapted for particular purposes for squeezing-out liquid from liquid-containing material, e.g. juice from fruits, oil from oil-containing material
    • B30B9/12Presses specially adapted for particular purposes for squeezing-out liquid from liquid-containing material, e.g. juice from fruits, oil from oil-containing material using pressing worms or screws co-operating with a permeable casing
    • B30B9/121Screw constructions
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01DSEPARATION
    • B01D2201/00Details relating to filtering apparatus
    • B01D2201/08Regeneration of the filter
    • B01D2201/088Arrangements for killing microorganisms
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02WCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO WASTEWATER TREATMENT OR WASTE MANAGEMENT
    • Y02W30/00Technologies for solid waste management
    • Y02W30/40Bio-organic fraction processing; Production of fertilisers from the organic fraction of waste or refuse
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02WCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO WASTEWATER TREATMENT OR WASTE MANAGEMENT
    • Y02W30/00Technologies for solid waste management
    • Y02W30/50Reuse, recycling or recovery technologies
    • Y02W30/52Mechanical processing of waste for the recovery of materials, e.g. crushing, shredding, separation or disassembly

Definitions

  • the present invention relates to a method of processing a mixture of solids and liquids and is useful in particular, but not exclusively, for the processing of waste water and for the separation of solids, for example paper fibres or fruit residues, from a mixture of such solid material and a liquid.
  • a method of processing a mixture of solids and liquids which comprises the steps of subjecting the mixture to a first screening to screen at least a portion of the liquid from the solids, and then subjecting the thus-screened liquid portion to a second screening to screen further liquid from the solids.
  • the liquid which is in this way screened by the first and second screenings is collected and aerated and then passed through a fine filter to remove further solids from the liquid.
  • the fine filter is provided by a rotatable cylindrical filter bed, and the aerated liquid is fed into a hollow central space within the cylindrical filter bed structure. The liquid is then allowed to flow radially outwardly and downwardly through the cylindrical filter bed structure, which is then rotated, so that an upper portion of the filter bed structure can be backwashed.
  • Liquid used for the backwashing, together with impurities backwashed from the filter bed structure, are collected in an auger extending actually through the filter bed structure and are thereby conveyed from the filter bed structure.
  • a cylindrical mesh filter is preferably provided within the filter bed structure, around the central hollow space, and the aerated liquid flows radially outwardly and downwardly from the central hollow space through the mesh filter to the filter bed structure.
  • the mesh filter is rotated and an upper portion of the mesh filter is then backwashed.
  • the present invention relates furthermore to compactors and is useful, in particular, for compactors for use in compacting solid material which has been separated from liquid, for example from waste water.
  • a separating apparatus comprising a rotary screen, comprising screen bars extending around and spaced from an inclined axis of rotation, with an auger extending upwardly along the axis.
  • a mixture of liquid and solid material is caused to flow into the interior of the screen, through an open lower end of the screen, so that the liquid can drain downwardly between the bars of the screen.
  • the solid material is retained in the interior of the screen, on the bars.
  • the screen is rotated intermittently to cause the solid material to be raised to an upper part of the screen, from which it falls downwardly through an upper opening in an auger tube forming part of the auger.
  • a compactor which comprises a first feed auger section for advancing a mass of material which is to be compacted, a compact auger section for receiving and compacting the material from the first feed auger section, a second feed auger section for receiving and advancing the material from the compactor auger section, the first and second feed auger sections and the compactor auger section having co-axial auger screws, an eccentric rotor for receiving the material from the second feed auger section and deflecting the material radially outwardly of the eccentric rotor, at least two compactor passages for receiving the material deflected by the eccentric rotor and dimensioned to compact the material as the material passes there through and expansion passages for receiving the material from the compactor passages, the expansion passages being dimensioned to allow expansion of the material as the material passes there through.
  • the auger screws of the first and second feed auger sections each have a screw pitch greater than that of the auger screw of the compactor auger section.
  • the first feed auger section preferably includes an auger tube co-axial with the auger screw of the first feed auger section and a plurality of bars extending longitudinallyalong the interior of the auger tube, between the auger tube and the auger screw of the first feed auger section, for cutting and guiding material as the material is advanced along the first feed auger section.
  • the invention further relates to an apparatus for separating solids from flowing liquids and to a collecting cage for use in such apparatuses.
  • Such systems are used, for example, in the field of sewage purification, where usually screening systems, which can be paternoster systems, rotary systems, climbing systems, arch systems or lifting systems, are employed. All these systems include a standing .grating which extends through the sewer transversely to the direction of flow and by means of which solids, such as sand, fine gravel, stones, mud, or - in the case of sewage-purification plants sanitary waste, fibres etc. can be retained.
  • screening systems which can be paternoster systems, rotary systems, climbing systems, arch systems or lifting systems. All these systems include a standing .grating which extends through the sewer transversely to the direction of flow and by means of which solids, such as sand, fine gravel, stones, mud, or - in the case of sewage-purification plants sanitary waste, fibres etc. can be retained.
  • screen cleaners which may be designed, e.g., as clearing rakes and engage with the clearance between the grating of the screening system and remove the solids upwards out of the sewer and feed them to a transport device by which the solids are supplied to a further treatment or a waste disposal site.
  • Such screening systems have the drawback that the structure of the mechanical cleaning means is relatively complex and that it is very costly and labour-intense to completely remove adhering solids, fats and oils from the grating.
  • a brush system by which solids can be completely removed from the grating has to be provided.
  • the cleaning means themselves have to be cleaned, in turn, by high-pressure cleaning devices to be prepared for the next cleaning interval.
  • the clearing members are likewise cleaned from the solids by high-pressure cleaning nozzles which are formed in a portion of the cylinder jacket projecting from the liquid surface.
  • rotary rakes as they are called, which are provided with a rotating collecting surface, wherein a forward-running portion of the collecting surface retains the solids, a subsequent portion of the collecting surface is moved out of the liquid and cleaned there and a return portion of the collecting surface is again immersed into the liquid so as to be transformed, after another reversal, into the forward-running portion again.
  • the object underlying the invention is to provide an apparatus for separating solids and a collecting cage for use in such apparatuses by which an improvement of the separating capacity can be achieved with a minimum effort concerning the apparatus.
  • the collecting means can be cleaned in a complete and simple manner by the measure to move the major portion of the collecting surface out of the liquid flow for cleaning so that an optimum efficiency is ensured after the cleaning operation.
  • the separating capacity of the collecting means can be substantially increased when a further collecting means is connected in parallel to the first collecting means so that the collecting surfaces of the two means are alternately brought into the working and cleaning position, resp., so that one collecting means at a time constantly separates the solid material while the other collecting means is cleaned.
  • the two collecting means should be arranged one behind the other seen in the direction of flow. Since only one collecting means immerses into the liquid at a time, the pressure loss can be considerably reduced in this way.
  • each collecting means can be further increased when the collecting means is upwardly ascending while being inclined toward the flow so that the effective collecting surface is increased.
  • the latter can be further increased when the ascending portion is curved.
  • a collecting means which can be adapted especially easily to different sewer geometries is obtained, when the collecting surface is formed by a plurality of collecting cages which are preferably hinged to one another and guided in the guide of a guiding base.
  • a collecting means having an optimum separating degree and a minimum overall height can be obtained by designing the guide to have a comparatively large radius of curvature inside the liquid flow and to have a return portion with a comparatively small radius of curvature outside the flow, which is transformed into a nearly linear or only slightly curved cleaning portion.
  • This structure of the guide ensures that the collecting cages inside of the liquid flow constitute a largest possible collecting surface which extends in an upward curved way, whereas in their cleaning position they are lined up practically upside down along the slightly curved portion above the liquid surface. That is, the collecting cages can be arranged at the smallest possible distance above the liquid surface and can be cleaned in a simple and thorough manner from "behind", i.e. the rear side, due to the upside-down position. The removed solids then fall into the collecting means arranged between the collecting cages and the liquid surface.
  • the control of the collecting cages from the cleaning portion into the respective guide can then be effected via a switch adapted to be driven by a central control.
  • the collecting cages are guided via rollers in the guides.
  • a particularly simple collecting cage for the above-described apparatus is obtained when the collecting cage is provided with a cylinder jacket through the open front of which the liquid flows. Between the fronts the collecting surface is formed which, can be designed as lamella packs, the lamellas of which are spaced apart from one another via spacers and thereby form passage gaps for the liquid. Then the solids deposit on the lamellas.
  • a "multi-stage" separation can be attained when three lamella packs are staggered with respect to each other, seen in the direction of flow, and these staggered lamella packs again form a unity which, multiple connected side by side, constitutes the collecting surface. I.e., in this case the collecting surface has a wave-shaped design.
  • the solids e.g. fibres, cling to the corners of the spacers so that they can easily be removed during the cleaning operation.
  • filter elements of any combination of the materials listed below can be formed.
  • the above-described apparatus can easily be adapted to different sewer widths by juxtaposing plural collecting means.
  • a collecting means can be employed the collecting surface of which is adapted to be swivelled, about an axis of rotation disposed transversely to the direction of flow, out of the liquid into the cleaning position.
  • the separated solids then can be rinsed out against the normal direction of flow, e.g. by a cleaning system and fed to the transport means, e.g. by a funnel tube.
  • the collecting means is swivelled out of its operating position in the form of a pendulum.
  • the collecting cages are adapted to be employed in particular in the above-described apparatus, whereby an especially good efficiency can be achieved.
  • Figure 1 shows a block diagram illustrating successive stages in a method embodying the present invention
  • Figure 2 shows a view in longitudinal cross-section through a pre-treatment module for processing a mixture of liquid and solid material
  • Figure 3 shows an end view of the apparatus of Figure 2
  • Figure 4 shows a view taken in cross-section along the line 4-4 of Figure 2;
  • Figure 5 shows a view taken in longitudinal cross-section through module containing first and second screens for screening the mixture
  • Figure 6 shows an end view, with one-half of an end plate removed, of one of the rotary screens of the apparatus of Figure 5;
  • Figure 7 shows a view taken in cross-section along the line 7-7 of Figure 6;
  • Figure 8 shows a broken-away view taken in cross-section along the line 8-8 of Figure 9;
  • Figure 9 shows a broken-away view, in end elevation, of parts of bars shown in Figure 6;
  • Figure 10 shows a view in elevation of a spacer plate
  • Figure 11 shows a view taken in the direction of the arrow A of Figure 9;
  • Figure 12 shows sub-assembly tie bolt forming part of the apparatus of Figure 11;
  • Figure 13 shows a view in end elevation, of the second rotary screen of Figure 5, with one-half of an end plate removed to show underlying parts of the screen;
  • Figure 14 shows a view taken in cross-section along the line 14-14 of Figure 13;
  • Figure 15 shows a view in front elevation of a screen element forming part of the second rotary screen of Figure 5;
  • Figure 16 shows a view in side elevation of the screen element of Figure 15;
  • Figure 17 shows a view in end elevation of the screen element of Figure 15;
  • Figure 18 shows a broken-away view in cross-section taken along the line 18-18 of Figure 16;
  • Figure 19 shows a broken-away view, in cross-section, of one end of the screen element of Figure 15;
  • Figure 20 shows a plan view of an aeration tank
  • Figure 21 shows a view taken in vertical longitudinal cross- section through the tank of Figure 20;
  • Figure 22 shows a view taken in vertical cross-section through a further aeration stage and a fine screening apparatus
  • Figure 23 shows a view in vertical cross-section through the • screening apparatus of Figure 22,
  • Figure 24 shows a view taken in vertical cross-section along the line 24-24 of Figure 23
  • Figure 25 shows a view in vertical cross-section through part of an outer rotor forming-part of the apparatus of Figure 23;
  • Figure 26 shows a partly broken-away view, in axial elevation, of the screening apparatus of Figure 22, taken from one end of the screening apparatus;
  • Figure 27 shows a view in end elevation of the opposite end of the screening apparatus of Figure 22;
  • Figure 28 shows a view taken in vertical cross-section through a composting and bagging module
  • Fig. 29a shows an other embodiment of the modul of Fig. 5;
  • Figure 29b shows a view in longitudinal cross-section through apparatus for separating the solid material from liquid and then compacting and extruding the solid material
  • Figure 30 shows a view taken in cross-section along the line 2-2 of Figure 29b;
  • Figure 31 shows a view taken in cross-section along the line 3-3 of Figure 29b;
  • Figure 32 shows a first modification of the apparatus of Figure 29
  • Figure 33 shows a view taken in cross-section along the line 5-5 of Figure 32;
  • Figure 34 shows a view taken in vertical cross-section through a further modification of the apparatus of Figure 29;
  • Figure 35 sliows a view taken in vertical cross-section through a still further modification of the apparatus of Figure 29;
  • Figures 36, 37 and 38 show views taken in cross-section along the lines 8-8; 9-9 and 10-10, respectively, of Figure 35;
  • Figure 39 shows a view taken in vertical cross-section through a still further modification of the apparatus of Figure 29;
  • Figures 40, 41 and 42 show views taken in cross-section along the lines 12-12; 13-13 and 14-14, respectively of Figure 39;
  • Figure 43 shows a view taken in cross-section through a modification of the apparatus of Figure 39;
  • Figures 44, 45 and 46 show views taken in cross-section along the lines 16-16; 17-17 and 18-18, respectively, of Figure 43;
  • Figures 47 and 48 show views of two possible forms of extrusion opening for use in the apparatus of Figure 43;
  • Figure 49 shows a view taken in vertical cross-section through a modification of parts of the apparatus of Figure 43;
  • Figure 50 shows a diagrammatic view of a first embodiment of an apparatus according to the invention.
  • Figure 51a shows a section along the line A'-A' of Figure 50/
  • Figure 51b shows a section along the line A''-A'' of Figure 50;
  • Figure 52 shows a section along the line B-B of Figure 50
  • Figures 53a, 53b show a section along the line C-C of Figure 52;
  • Figure 54a shows another embodiment of a collecting cage in a section along the line B-B of Figure 50;
  • Figure 54b shows a section along the line D-D of Figure 54a;
  • Figures 55 to 57 show detailed views of the guide and a connecting structure for the collecting cages;
  • Figure 58 shows another embodiment of the apparatus according to the invention.
  • Figure 59 shows further variants of arranging the apparatus according to the invention in liquid sewers
  • Figures 60a, 60b show views of a sediment separating means for the apparatus of Figure 50;
  • Figures 61a, 61b show details of the separating means of Figures 60a, 60b;
  • Figure 62 shows a collecting cage of the apparatus according to Figure 50 in its cleaning position
  • Figure 63 shows in detail the collecting cage of the apparatus according to Figure 50 in its cleaning position.
  • Figures AA1 and AA2 show a variation of the inventive embodi ⁇ ment of a filter station according to Figure 50.
  • Figure BB1 shows a further modification of the cleaning station according to Figure 63.
  • Figure BB2 shows a compactor-auger consisting of a plurality of auger modules, wherein one module has a housing shell made of two shell halves.
  • Figure BB3 defines further variations of a compactor.
  • Figure BB4 is a schematical view of an auger-compactor system composed of several modules according to Figures BB2 and BB3.
  • Figure CC1 shows an .alternative to the micro mesh filters used for example in the embodiment according to Figure 22.
  • Figures TT1 and TT2 show a modified embodiment of the pre- treatment unit according to Figure 2 of this invention.
  • Figures XXI and XX2 show a further variant of a mesh filter according to the invention.
  • Figures YY1 to YY3 show an alternative development of a cleaning station for example according to Figure BB1.
  • Figures ZZ1 to ZZ3 show in detail the structure of an auger tube, particulary the structure of the shell forming the auger tube in the neighbourhood of the cleaning station.
  • reference numeral 10 indicates a pre- treatment process, in which an incoming mixture of liquids and solids is treated so as to remove floating material, rocks, particulate material and oil, and other liquids imissable with water from waste water.
  • the waste water may then, if required, be passed into a buffer tank, indicated by reference numeral 12, which may serve as a surge tank for containing higher than average flows, for example during rainy weather.
  • a buffer tank indicated by reference numeral 12, which may serve as a surge tank for containing higher than average flows, for example during rainy weather.
  • the liquid is then subjected to a first screening operation 14, which separates further solid material from the liquid, the separated solid material being passed to a compacting stage 16, while liquid drained from the separated solid material is returned to the main body of liquid, which passes ' from the first screening stage 14 to a second screening stage 18.
  • this second screening stage 18 the liquid is subjected to finer screening to remove further solid material, which is then mixed with the compacted solid material from the compacting stage 16 in a mixing stage 20.
  • the screened liquid from the second screening stage 18 is passed through a first aeration stage 22 and a second aeration stage 24 to a third screening stage 26, at which the liquid is subjected to fine screening to remove further solids from the liquid.
  • the mixture of solid materials in the mixing stage 20 is subjected to further draining and then to extrusion at an extrusion stage 28, the liquid drained from the mixing stage 20 being fed, together with the main body of liquid from the second screening stage 18, into the aeration stage 22.
  • the extruded solid material from the extrusion stage 28 is then passed to a composting stage 30, and the thus-composted solid material is bagged at a bagging stage 32.
  • the pre-treatment stage 10 is illustrated in greater detail in Figures 2 - 4.
  • the incoming, untreated mixture of liquid and solid material which may for example be waste water from domestic dwellings or sewage from storm sewers, is fed in through an inlet pipe 100 into a tank indicated generally by reference numeral 102.
  • the inlet pipe 100 discharges into a generally semi- cylindrically shaped vibratory grating 104, which is downwardly inclined into the tank 102 above an auger, indicated generally by reference numeral 106, comprising a screw 108 rotating within a tube 110.
  • the top of the tube 110 is open below the grating 104, so that particulate material such as stones, sand and the like, which drops through the grating 104, is contained within the tube 110 and is withdrawn upwardly along the tube 110 by the screw 108, for discharge through an outlet spout 112 into a removable container 114.
  • the auger 116 comprises an auger screw 120, which is rotatable within an auger tube 122.
  • the auger tube 122 is upwardly inclined from the lower end of the auger 106 and is formed, at the top of the lower end of the auger tube 122, with an opening 124 through which the heavy solid objects falling downwardly along the grating 104 can enter the auger tube 122, so as to be conveyed upwardly and outwardly of the tank 102 by the auger screw 120, which is driven by a motor 126 mounted at the upper end of the auger screw 120.
  • the solid objects fed upwardly by the auger screw 120 are discharged through an outlet spout 128 into a removable container 130.
  • Floating material from the incoming mixture is temporarily retained by downwardly displaccable gate 132, projecting downwardly through the surface of the liquid in the tank 102.
  • the tank 102 is provided with upwardly pivotable covers 134 and the grating 104 is provided with correspondingly upwardly pivotable covers 136, which allow access for the removal of large floating objects, for example logs and branches, from the liquid within the tank 102.
  • the gate 132 is lowered periodical-ly to allow other floating material remaining in the tank 102 to pass into a transverse auger indicated generally by referen-ce numeral 138 and comprising an auger screw 140 rotating in a cylindrical auger screw housing 142.
  • the auger 138 is connected, at the exterior of the tank 102, to a laterally upwardly inclined auger indicated generally by reference numeral 144, which comprises an auger screw 146 connected to the auger screw 142 by a universal joint 148 and rotating within an auger tube 150.
  • a drive motor 152 drives the auger screw 146 and, thus, the auger screw 142, and also drives a compactor 154.
  • the material fed by the auger screw 146 to the compactor 154 is compacted and discharged through an outlet spout 156 into a removable container 158.
  • the tank 102 has an outlet 160 for the outflow of the liquid from the tank 102.
  • the mixture of solid material and liquid fed into the tank through the inlet pipe 100 is discharged from the latter in a direction which is opposite to the direction of flow of the liquid from the tank 102 through the outlet 160.
  • the incoming flow causes the floating material to float along the liquid surface in the tank 102 towards the gate 132, which is periodically lowered to allow the floating material to pass into the auger 138.
  • the vibration of the grating 104 is required to be effected only periodically, in order to prevent the formation of an accumulation of sand or other particulate material and to ensure that large rocks and other large sinking objects are dropped into the auger 116.
  • the grating 104 has a length which provides a long settlement and classification section for the mixture which is travelling in a direction opposite to the outflow of the liquid from the tank 102, so that even relatively fine particulate material is extracted by the auger 106.
  • the tank 102 is also provided with a compressed air pipe 162 having an outlet nozzle 164 for aeration of the liquid in the tank 102.
  • the bottom of the tank 102 which is indicated by reference numeral 166, has a corrugated shape, to strengthen the tank, and to provide bottom transverse troughs 168 which are connected to a common outlet pipe 170 for the withdrawal of sediment from the bottom of the tank 102.
  • the tank 102 is also provided with compressed air pipes 172 and outlet nozzles 174, which extend upwardly inclined at opposite sides of the grating 104 as shown in Figure 4, and with further air outlet nozzles 176, at the bottom of the tank, to ensure a thorough aeration of the liquid in the tank.
  • the purpose of this aeration is to separate floating material from the sinking material, to keep the floating material in movement so that it floats through the outlet 160, and also to counteract settlement of solid material on the bottom of the container and in the corners of the container, while keeping oil and fat at the surface of tile liquid and, also, while enriching the oxygen content of the liquid.
  • an oil skimmer (not shown) , which removes oil and discharges it into an oil container (not shown) .
  • the apparatus of Figures 2 through 4 is provided as a module in a container (not shown) , so that the entire device can be transported on a low loader.
  • the tank 102 is provided with a sliding cover 180 and an equipment housing 182 at the top of the tank 102.
  • the tank 102 may also be provided with at least three air extraction devices for air circulation and ventilation through a compressor station (not shown) , so as to provide a closed system.
  • the containers 112, 130 and 158 are provided with lifting devices indicated generally by reference numeral 184, which can raise and lower the containers into and out of sealing engagement with overhead hoods 186.
  • the materials removed in the containers 112, 130 and 158 may, if desired, be subjected to further processing.
  • the liquid outflow from the outlet 160 is fed through a pipe 200 ( Figure 5) , the lower end of which discharges into the hollow interior of a rotary screen indicated generally by reference numeral 202.
  • the rotary screen 202 is installed, with its longitudinal axis at an upward inclination, in a tank indicated generally by reference numeral 204, and a first semi-circular weir 206 at the bottom of the tank 204 has a semi-circular seal 208. in sealing engagement with one end of the rotary screen 202.
  • an electric motor 210 driving a gear 212 secured to the upper end of the rotary screen 202, the latter is rotated periodically.
  • the liquid which is discharged into the rotary screen 202 drains under gravity through the screen 202, while the screen 202 remains stationary, into a collecting chamber 214, while solid material in the incoming liquid is retained within the rotary screen 202.
  • the solid material can drop downwardly through a hopper 214 into an auger tube 216, which is provided with an auger screw 218 and which extends co-axially through the screen 202.
  • a grating 220 at the underside of the auger tube 216 allows liquid to drain from the auger tube 216, and the grating 220 can be periodically cleaned by sprays from a compressed water pipe 222 underlying the grating 220.
  • a further water supply 224 is provided above the screen 202 with a downwardly directed water nozzle 226 for directing water sprays downwardly onto the screen 202 to assist in dislodging the solid material from the upper part of the screen 202 into the auger tube 216.
  • the screen 202 has end plates 230 and 232, with a plurality of bars indicated generally by reference numeral 234 spaced apart from one another along the length of the screen 202.
  • Each of the bars 234 is formed of a curved outer metal strip 236 connected to a pair of straight inner metal strips 238.
  • the bars 234 are provided in groups of three different sizes, so as. to present, along the length of the inner periphery of the screen 202, a series of steps, as shown in Figure 7, forming a plurality of axially spaced annular recesses 240.
  • the bars 234 also form recesses 242 which extend radially outwardly from a housing around the auger tube 216.
  • the bars 234 are secured together by rods 246, which are secured at opposite ends to the end plates 230 and 232 and which, as shown in Figure 11, connect the largest bars 234, and also by sub-assembly tie bolts, as indicated generally reference numeral 248 in Figure 12, which connect together the groups of bars 234, together with spacer plates 250 provided between the bars 234.
  • metal strips 252 which have a width in the radial direction of the screen which is greater than that of the remainder of the bars 234, serve to interconnect the groups of bars 234.
  • the screened liquid in the chamber 214 passes over a second weir 254 into the hollow interior of a mesh screen indicated generally by reference numeral 256.
  • the weir 254 has a semi-cylindrical seal 258 in sealing engagement with one end of the mesh screen 256, which is co ⁇ axial with the screen 202.
  • the liquid supplied into the mesh screen 256 flows outwardly and downwardly through the mesh screen 256 into a collecting chamber 258, while further solid material, of a finer size than that screened by the first screen 202, is retained at the inner side of the mesh screen 256.
  • An electric motor 260 driving a gear 262 secured to the upper end of the mesh screen 256 is energized periodically to rotate the mesh screen 256 so as to raise the trapped solid material to an upper part of the mesh screen 256, from which this collected solid material then falls through a hopper 264 into an auger tube 266. Liquid from the thus-deposited solid material drains downwardly through a grating 268 in the bottom of the auger tube 266, and the grating 268 is periodically cleaned by sprays from a water supply pipe 270.
  • the solid material in the auger tube 266 is fed upwardly along the tube 266 by means of an auger screw 272, which is connected to the auger screw 218 through a compactor screw 274.
  • the compactor screw 274 has double the number of flights of the screws 218 and 272, with a smaller pitch, and serves to compact the solid material delivered to it by the auger screw 218. This compacted material is then mixed, in the auger tube 266, with the solid material deposited from the screen 256 and to the auger tube 266.
  • the compactor screw 274, and the auger screws 218 and 272 connected to the compactor screw 274, are driven by an electric motor 276 which drives a ring gear 278 connected to a tube 280.
  • the tube 280 is co-axial with, and rotatable relative to, the auger tubes 216 and 266 and is connected to the flights of the auger screw 274 for transmitting drive to the latter.
  • the mesh screen 256 as shown in Figures 13 and 14, has a pair of opposite end plates 282 and 284, which are connected by rods 286.
  • the lower end plate 282 is formed with generally triangularly shaped openings 288, having rounded corners, through which the liquid flows over the weir 254 into the interior of the mesh screen 256.
  • the rods 286 serve to connect adjacent ends of pairs of screen elements, one of which is shown in Figures 15, 16 and 17 and indicated generally by reference numeral 290.
  • the screen elements 290 are arranged in a pairs which are respectively associated with the openings 288 in the end plate 282, each pair of the screen elements 290 defining therebetween a generally triangular recess or chamber which is open, at its radially in most end, towards the auger tube 266. Successive pairs of the screen elements 290 are separated from one another by radially extending gaps 294, which open radially outwardly of the screen.
  • the screen elements 290 each have a frame 296, with a screen mesh 298 secured at its end in the frame 296 and reinforced, by longitudinal and transverse reinforcement wires 300.
  • the inner end of the frame 300 has a scaling face 302 ( Figure 19) for scaling abutment against one side of a channel member 304 at the inner most end of each gap 294.
  • the liquid which collects in the collection chamber 258 passes through an outlet opening 322 into the inlet opening 324 of an aeration tank indicated generally by reference numeral 326 in Figures 20 and 21.
  • the solid material which is conveyed upwardly by the screw 272 passes into an extruder, indicated generally by reference numeral 328, at which a pair of eccentric rotors, one of which is indicated by reference numeral 330, press the solid material radially outwardly through extension openings 332 to form pellets, which arc then conveyed upwardly by an auger indicated generally by reference numeral 334 and provided with a drive motor 336.
  • the liquid flows along a horizontally serpentine and vertically serpentine path of flow defined by a plurality of upper partitions 340, and alternating lower partitions 342, which are offset- laterally and, also, vertically downwardly with respect to the partitions 340.
  • a compressed air supply pipe system 344 feeds compressed air into air outlet nozzles 346 provided at the bottoms of the partitions 340 and 342.
  • the bottom of the tank 326 is corrugated so as to form a plurality of transverse troughs 348, from which sediment can be removed through a common outlet drainage pipe 350.
  • the top of the tank 326 is provided with a retractable cover 352, and an air compressor 354 having an air intake 356 within the tank 326, and a second air inlet 358, supplies compressed air to the compressed air pipe system 344.
  • the liquid which is aerated in the tank 326 passes through a tank outlet 360 from the tank 326 into a further aeration tank indicated generally by reference numeral 400 in Figure 22.
  • the liquid is introduced into the tank 400 through an inlet 402.
  • the tank 400 is provided with vertical baffles 404, which extend transversely of the tank 400 and which are staggered from one another in both the vertical and the horizontal directions so as to provide a vertically horizontally serpentine path of flow through the 400 as indicated by arrows in Figure 22.
  • the baffles 404 are provided, along the bottom edges thereof, with pipe 406 having horizontally directed outlet openings for discharging air into the mixture for aerating and agitating the mixture.
  • the pipes 406 are provided with a supply of compressed air by the compressor 354.
  • the air flows to the inlet duct 358 of the compressor from an air inlet duct 408, having an air inlet end 410 in the tank 400 above the level of the liquid under the control of a regulator valve 412.
  • a rotatable screen and filter structure indicated generally by reference numeral 414, which has a horizontal axis of rotation extending in the longitudinal direction of the tank 400 and comprises an inner rotor indicated generally by reference numeral 416, and an outer rotor indicated generally by reference numeral 418, which is co-axial with the inner rotor 416.
  • the inner rotor 416 extends around and is co-axial with an auger screw 420, which has a shaft 422 and a tube 424 extending around the auger screw 420 and forcing a tubular housing for the auger screw 420.
  • the inner rotor 416 is supported on the auger tube 424 by means of bearings 426, which allow the inner rotor 426 to rotate about the auger tube 424.
  • An internally-toothed ring gear 428 secured to one side of the inner rotor 416 meshes with a pinion 430 on the output shaft of a reduction gearing 432 driven by an electric motor 434, so that upon energization of the motor 434 the ring gear 428 is driven by the pinion 430 to cause the rotation of the inner rotor 416 about the auger tube 424.
  • the outer rotor 418 is supported at its right-hand side, as viewed in Figure 22, by means of a bearing 436 on the auger tube and, at its opposite side, on a pair of support rollers 438 in rolling engagement with the inner periphery of an annular plate 440 on an end wall 442 of the outer rotor 418.
  • the support rollers 438 are rotatably mounted on a triangular support 444 ( Figure 26), which is mounted on the auger tube 424.
  • An electric motor 446 ( Figure 22), through a reduction gearing 448, drives a pinion 450 meshing with a ring gear 452.
  • the ring gear 452 is mounted on a circular end wall 454 of the outer rotor 418. By energization of the electric motor 446, the outer rotor 48 is rotated about the auger tube 424.
  • the -inner rotor 416 comprises a metal mesh screen 460, which is shaped to form eight radially out ⁇ wardly extending, radially inwardly open chambers or "pockets" 462, which arc equiangularly spaced around the auger tube 424 and which are spaced from one another by radially outwardly open spaces 464.
  • the screen 460 is supported on rods 466, opposite ends of which are secured to an end wall 468 carrying the ring gear 428 and to a second circular end wall 470 at the opposite side of the inner rotor 416.
  • the wall 468 closes off the spaces 464 between the pockets 462 from the tank 400 and is formed with eight openings 472 ( Figure 26) through which the liquid in the tank 400 can flow into the screen pockets 462 of the inner rotor, as described in greater detail below.
  • Figure 24 also shows four spray pipes 474 located between the inner and outer rotors and provided with spray nozzles, which are directed so as to spray radially inwardly onto the mesh and into the radially outwardly open spaces 464.
  • a cylindrically arch-shaped baffle or cover 476 which extends over the top of the inner rotor and which is provided with inclined gutters 478.
  • a weir structure 480 ( Figure 23) in the tank 400 has, at a semi-circularly curved upper edge of the weir structure 480 a semicircular seal 482, which is in sliding, scaling contact with a side face of the ring gear 428.
  • the weir 480 and the seal 482 ensure that the liquid flowing through the tank 400, in the direction of the arrows of Figure 22, flows firstly through the openings 472 in the end wall 468 and into the pockets 462 of the inner rotor and then passes through the screen mesh before passing radially outwardly through the outer rotor, as described below.
  • Solid material which is retained within the pockets 462 of the inner rotor 416 at the lower half of the inner rotor 416 is carried upwardly on the screen mesh, as the inner rotor is rotated until it is dislodged by water directed radially inwardly from the spray nozzles 474.
  • the rotation of the inner rotor and the spraying from the spray nozzles 474 are effected intermittently, at time intervals which are selected in accordance with the rate of deposition of the solid material on the screen mesh.
  • the auger tube 424 has an upwardly directed opening through which the solid material which is dislodged by the sprays from the spray nozzles 474 and by gravity from the pockets 462 is deposited into the auger tube 424.
  • the shaft 422 of the screw 420 is rotated by an electric motor 476 through a reduction gearing 478.
  • the rotation of the auger screw shaft 422 causes the solid material deposited into the auger 478 to be fed along the auger tube 424 for discharge through an outlet pipe 478 into a container (not shown) or the like.
  • the construction of the pockets 462 of the inner rotor is similar to those of the mesh screen 202 and is therefore not described in greater detail.
  • the outer rotor 418 forms a filter structure and has three annular walls 480 extending transversely of the axis of rotation of the outer rotor.
  • the walls 480 are secured to one another and to the opposite end walls 442 and 454 of the outer rotor by means of inner and outer perforated cylindrically curved plates 482, which support wire meshes 484. Between the inner and outer plates 482, the outer rotor is packed with sand 486, which serves as a filter medium.
  • the liquid which passes radially outwardly through the screen mesh of the inner rotor 416 then passes through the sand 486 of the outer rotor and is retained in an end portion 488 of the tank 400, which is provided with an overflow pipe 490, through which the filtered liquid can flow from the tank end portion 488.
  • the weir structure 480 is provided with a semi-circular seal 492, in sliding, sealing contact with the end wall 468 of the outer rotor.
  • the seal 492 ensures that the liquid which has passed through the screen mesh of the inner rotor is retained in the outer rotor until it flows through the sand 486.
  • a water pipe 494 with spray nozzles 496 is provided above the outer rotor for periodically backwashing the sand 486.
  • the tank 400 is provided with retractable cover 498, which can close off the top of the tank from the atmosphere.
  • the inner and outer rotors 416 and 418 are rotated periodically, and independently of one another, when they require cleaning by backwashing from the water sprays, which preferably employ a portion of the liquid treated by the apparatus and discharged through the outlet pipe 490.
  • the extruded solid material conveyed upwardly by the auger 333 ( Figure 5) is discharged under gravity into a pre- composting unit 500 ( Figure 28), which allows this solid material to trickle into the lower end of an upwardly inclined first auger indicated generally by reference numeral 502, containing auger screw 504.
  • the auger screw 504 includes a hollow flight 506, into which a heat exchange fluid, for example cold water, can be fed through an inlet pipe 508.
  • a heat exchange fluid for example cold water
  • a water sprinkling system 510 is provided for sprinkling water into the interior of the auger 502.
  • the heat exchange fluid is passed downwardly through rotary hydraulic couplings 512 and 514 and a connecting pipe 516 to the lower end of a second auger, indicated generally by reference numeral 518.
  • the solid material which travels upwardly along the auger 502 can be mixed with air through an adjustable air vent 520 at the upper end of the auger 502 and is sterilized at 75°C and at least partially composted during its upward travel along 502.
  • the solid material is discharged onto an adjustable screen 522, which deflects any non-biodegradable solid material down an outlet duct 524 and through a hood 526 into a removable waste container 528.
  • the solid material falls downwardly through the screen 522 is directed by a hopper 530 into the lower end of the auger 518 which, as can be seen from Figure 28, is inclined upwardly in a direction opposite to the auger 502.
  • the auger 518 is provided with a water sprinkling system 532 and adjustable air vents 534, and includes an auger screw 536 having a hollow flight 538 through which the heat exchange liquid from the connecting pipe 516 flows upwardly along the auger 518. At the upper end of the auger 518, this heat exchange liquid is discharged, as hot water, through a rotary hydraulic coupling 536 and an outlet pipe 538.
  • the solid material which is fed upwardly along the auger 518 is forced, at the upper end of the auger 518, into an extrusion device indicated generally by reference numeral 540, which has a pair of eccentric rotors 542, by which the solid material is forced through extrusion openings 544, by which it is formed into pellets.
  • the thus extruded and pelletized solid material drops downwardly into a bagging machine indicated generally by reference numeral 546.
  • Exhaust gases from this composting process rise upwardly through a serpentine flu 548 in a chimney indicated generally by reference numeral 550.
  • the chimney 50 is mounted on the top of a housing indicated generally by reference numeral 552, and is pivotable about- a hinge 554 between a lowered position, in which it is shown in Figure 28 and in which it is located for transportation of the apparatus, and into an upright position, in which it extends upwardly over an outlet opening 556 in the housing 552.
  • the chimney 550 may be employed to extract heat from the exhaust gases by a heat exchange process.
  • the optional buffer tank 12 when provided, may be identical to the aeration tank 326 of Figures 20 and 21.
  • the first screening stage 14 and the second screening stage 18 correspond to the first screen 202 and the second screen 256 of Figure 5.
  • the first aeration stage 22 is the aeration effected in the aeration tank 326 of Figures 20 and 21, whereas the second aeration step 24 is the aeration which is effected in the tank 400 of Figure 22.
  • the third, fine screening step 26 is effected in the inner and outer rotors 416 and 418 of Figure 22.
  • stage 16 The first drainage and compacting of stage 16 are effected by the grating 220 and the compactor 274 of the Figure 5, while the mixing and drainage of stage 20 take place in the auger tube 266.
  • stage 28 is effected by the extrusion head 328
  • the sterilization and composting of stage 30 is effected by the augers 502 and 518 of Figure 28
  • the final bagging of the solids, in stage 32 is effected in the bagging machine 546.
  • the method of processing a mixture of liquid comprising the steps of:
  • the method further includes composting the solid material removed by the first and second screenings.
  • the third screening step comprises feeding the aerated liquid into a hollow central space within a rotatable, generally cylindrical filter bed structure; allowing the liquid to flow radially outwardly and downwardly through said cylindrical filter bed structure; rotating said filter bed structure and backwashing an upper portion of said filter bed structure.
  • the method further includes collecting a mixture of liquid used for the backwashing, together with impurities backwashed from said filter bed structure, in an auger extending axially through said filter bed structure and conveying said mixture of backwash liquid and impurities in said auger from said filter bed structure.
  • the method further includes providing a cylindrical mesh screen filter within said filter bed structure around said central hollow space; causing the aerated liquid to flow radially outwardly and downwardly from said central hollow space through.said mesh screen; rotating said mesh screen and backwashing an upper portion of said mesh screen.
  • the method showing the step of subjecting the mixture to a first screening comprises feeding the mixture with a hollow interior of a rotatable screen; allowing the liquid to drain downwardly through said rotatable screen; intermittently rotating said screen; depositing solid material from an upper part of said screen into an auger; conveying the deposited solid material in the auger and compacting the thus-conveyed solid material.
  • the method further comprises collecting the liquid which drains downwardly through the rotatable screen; feeding the thus-colleted liquid into a hollow interior space of a rotatable mesh screen; allowing the material to drain downwardly through said mesh screen while collecting solid material on said mesh screen; intermittently rotating said mesh screen; feeding the compacted material axially through said mesh screen and depositing the solid material from an upper part of said mesh screen into the compacted material passing through said mesh screen to form a mixture of the materials.
  • the method includes extruding the compacted material to form pellets.
  • the method further showing the step of subjecting the mixture to a first screening comprises passing the mixture into radially inwardly open and radially outwardly extending recesses formed by said first screen, intermittently rotating said first screen and backwashing the upper part of said first screen to dislodge the solid material radially inwardly from said recesses into said auger.
  • the method includes allowing liquid to drain downwardly from said auger while conveying the solid material along said auger.
  • the method further includes allowing liquid to drain downwardly from the mixture of a material within said mesh screen.
  • the method comprises providing in the interior of said screen a plurality of steps extending around the inner periphery of said screen and forcing axially spaced annular recesses in the inner periphery of said screen.
  • the method providing the step of aerating the liquid comprises feeding the liquid along a serpentine path while discharging air into the liquid.
  • the method further comprises employing spaced baffles which are alternately laterally offset and alternately vertically offset to define the serpentine path of the liquid.
  • the method further comprising the step of pre-treating the mixture of solids and liquids to remove large solid objects and floating material from the mixture prior to the first screening step.
  • the method shows the step that the pre-treating of the mixture includes removing particulate material from the mixture separately from the large solid objects and the floating material.
  • the pre-treating of the mixture includes aerating the mixture.
  • the treatment units used for the individual method steps according to Figure 1 are preferably formed as individual devices constructed as modules which can be interchanged like in a unit construction assembly, and which can be arranged one after the other in an arbitrary order.
  • the pre-treatment apparatus of Figures 2 to 4 is provided as a single module which can selectively be arranged in front of the modular double filter unit according to Figure 5.
  • This double filter unit could of course be assembled from two or more individual filter means which are constructed independently of each other as module units.
  • the first ventilation stage, the second ventilation stage together with the third microfilter station as well as the subsequent pre-composting unit 500 also form individual modules which, depending on the use of the whole system, are selectively connected to the preceding filter modules, and which can of course also be exchanged for differently designed units of the kind which will be described in the following.
  • the buffer tank 12 is also preferably formed as a ventilation means.
  • This ventilation may either be provided by a natural ventilation obtained for example by installing swirling obstacles, or by a forced ventilation achieved by the arrangement of additional aerating nozzles, or by a combination of these variants.
  • a basically closed ventilation cycle is respectively provided by taking in gases rising from the liquid via the intake openings 356 or 410 by employing a compressor, and, after a possible filtration by means of an activated carbon filter and an enrichment with oxygen effected by supplying ambient air, by pressing the gases out again via the aerating nozzles 346 or 406.
  • the microfilter station uses a sand filling disposed between wire meshes as a liquid filter.
  • sand can be replaced by other filter materials such as for example activated carbon etc.
  • the driving motor 276 of the auger screw 218, 272 is formed at the right end of the auger, with the auger tube 266 being formed as one piece in this embodiment.
  • a necked-down portion 266A having an adjustable dia-meter is provided in the auger tube 266 in the auger according to Figure 29a; by means of this necked-down portion the compression pressure exerted on the solid material can be controlled.
  • an annular duct 328A is connected to the auger's discharge opening formed as an extruder 328; in the following this annular duct will be explained in greater detail in the description passage concerning the individual auger variants.
  • the solid material conveyed by the auger screw 218, 272 is pressed through the extruder 328 into the annular duct 328A in which a further compression of the solid material takes place due to the frictional resistance at the annular walls.
  • the degree of compression can be influenced by means of two necked-down portions 328B in the annular duct 328A, the diameter of the necked-down portions being adjustable.
  • a further externally driven auger screw 334 arranged behind the necked-down portions 328B is employed for removing the solid material from the annular duct.
  • reference numeral 10A indicates generally a rotary screen of known type, which is rotatable by means of an electric drive motor 12A about the axis of an auger, which is indicated generally by reference numeral 14A, the drive motor 12A having a drive pinion 16A in driving engagement with a ring gear 18A secured to one end of the rotary screen 10A.
  • the rotary screen 10A is arranged with its axis of rotation at an inclination, to allow a mixture of solid and liquid material to flow into the open lower end of the screen 10A.
  • the auger 14A comprises an auger screw 20A, which forms a first feed auger section, and which is rotatable within auger tube 22A.
  • the upper end of the screen 10A is supported on the auger tube 22A by means of a bearing 24A, while the lower end of the screen 10A is supported by a support roller 26A, which is mounted on the lower end of the auger tube 22A and which is in rolling engagement with the inner periphery of an annular plate 28A at the lower end of the screen 10A.
  • the auger tube 22A is provided, within the screen 10A, with an upper opening 28 through which solid material can be deposited into the auger, as described below, and is also provided at its underside with a drainage grating 30A.
  • a high pressure water spray system 32A is provided above the screen for backwashing the screen, and a further high pressure water spray system 34A is provided beneath the grating 30A for backwashing the grating 30A.
  • the mixture of liquid and solid material flows into the lower end of the screen 10A, so that the liquid can then flow radially outwardly of the screen 10A, while the solid material is retained on the interior of the screen.
  • the screen 10A is rotated periodically to raise the retained solid material to an upper part of the screen, from which it can drop through the opening 28A into the interior of the auger tube 22A.
  • the high pressure spray system 32A is used to spray water downwardly onto the upper part of the screen to assist in dislodging the solid material from the interior of the screen.
  • the material deposited into the auger tube for 22 is advanced along the tube 22A by rotation of the auger screw 20A and liquid can drain downwardly from the tube 22A through the grating 30A, which is periodically cleaned by backwashing from the high pressure spray system 34A.
  • the first feed auger section 20A extends to a compactor, which is indicated generally by reference numeral 36A and which comprises a compactor auger section 38A.
  • the flights of the compactor auger section 38 have a pitch which is substantially less than the pitch of the flights of the .first feed auger section 20A so that as the material is advanced from the latter into the compactor, the speed of advance of the material decreases and, therefore, the material becomes compressed.
  • a second feed auger section which is indicated generally by reference numeral 40A and which comprises a feed auger screw 42A.
  • an extension section indicated generally by reference numeral 44A, which comprises a rotary extruder head formed by a pair of dia-metrically opposite, eccentric, curved pressure members 46A, which are mounted on a shaft 48A.
  • the shaft 48A is common to the auger 14A, the compactor 40A and the extrusion head 44A and is journalled at opposite ends in bearings 50A and 52A.
  • the shaft 48A, and thus the auger 14A, the compactor 40A and the extruder head 44A, are driven by an electric drive motor 54A, through a pinion 56A on the output shaft of the motor 54A and a gear 58A on the upper end of the shaft 48A.
  • Longitudinally extending, circumferentially spaced bars 60A are provided between the auger screws 20A, 38A and 42A, and the pressure members 46A, on the one hand, and the inner surface pf the auger tube 22 and a cylindrical housing 62A in the extruder section 44A, on the other hand.
  • the cylindrical housing 62A is formed with circumferentially spaced extrusion openings 64A, through which solid material is extruded, as described below, the extruded material then being broken into separate pieces by deflector members 66A mounted at the exteriors of the extrusion openings 64A.
  • the first feed auger section 20A and the-second feed auger section 42A each have a pitch which is substantially greater than that of the compactor auger section 38A. Also, the compactor auger section 38A has a number of flights, i.e. four, which is double that of the first feed auger section 60A.
  • the lower pitch of the compactor auger screw 38 as compared with the feed auger screw section 20A causes the solid material to be compacted into a plug, which is desirable to ensure intensive compacting of the material and also, comminution and dewatering of the compacted material. Water which is expressed from the compacted material at the compactor 36A can flow downwardly along the auger tube 22A.
  • the pitch and the number of flights of the auger screws may be varied in accordance with the requirements of the material to be processed.
  • the bars 60A counteract about the shaft 48A of the solid mate-rial being advanced and compacted by the auger screws, thereby ensuring that the pressure in the material is increased at the compactor 36A and the extrusion section 44A.
  • the bars 60A are made of sharp-edged stainless steel, and also serve to cut the solid material, as it is advanced along the auger tube 22A.
  • the solid material is compacted to about 50% solid material content.
  • the rotary extruder head formed by the eccentric pressure members 46A is provided, at its upper end, with an auger blade 68A having a pitch which is opposite to that of the second feed auger section 42A, so that the solid material which advances between the auger blade 68A and the uppermost end of the second feed auger section 42A is caught and is pressed outwardly, by the rotation of the eccentric pressure members 46A.
  • the solid material which is extruded outwardly through each of the openings 66A is broken into small pieces or pellets by the deflectors 66A. In the extrusion section 44A, the solid material is further compressed to a solid material content of 50 - 80%.
  • the extrusion section 44A has an outer housing 70A, which guides the pieces or pellets of solid material into a discharge spout 72A for discharge into a suitable container (not shown) .
  • the high pressure water spray systems 32A and 34A may, if desired, be replaced by compressed air sprays.
  • the screen 10A may be varied, as required, and may be formed of spaced bars and/or a mesh filter screen.
  • the screen 10A can be periodically rotated through 180° independently of the operation of the auger screws. In this way, it can be ensured that the screen 10A remains stationary for long periods of time.
  • the water sprayed from ' the high pressure spray systems 32A and 34A may be heated for example by heat exchangers as described below with reference to Figure 49 of the accompanying drawings, and may, if appropriate, have cleaning chemicals added.
  • first feed auger screw 20A is replaced by a first feed auger screw 11A, which is connected through a universal joint 13K to a frusto- conically shaped compactor auger screw 15A, which extends to a second feed auger screw section 17A.
  • the compactor auger screw 15A is rotatable in a generally frusto-conically shaped housing 19A, which merges with a cylindrical tube 21A containing the auger screw section 17A.
  • a hopper 23A through which additional material can be added to the solid material conveyed by the first feed auger screw section 11A, is provided with a pivotable lid 25A.
  • the lid 25A may serve as a toilet and is provided with a pivotable cover 27A.
  • the second feed auger screw section 17A extends to an extrusion head, similar to the extrusion head of Figure 29 having diametrically opposed, eccentric, curved pressure members 46A, carried on shaft 29A which also carries the auger screws 15A and 17A.
  • the extrusion head is provided in an extrusion section 31A similar to the extrusion section 44A of Figure 29 but with the extrusion openings 64A replaced by relatively large outlet openings 33A in a cylindrical housing 47A.
  • the pressure members 46A rotate within the cylindrical inner housing 47A, which is provided within and spaced from cylindri-cal outer housing 35A, which opens into a discharge spout 37A.
  • the shaft 29A which is driven by an electric drive motor 45A, has a greater inclination than the axis of the first feed auger screw section 11A.
  • the auger screw section 11A has only a single flight, but it may alternatively have two or more flights.
  • first feed case serves to compress the solid material and which discharges into second feed auger screw section 42A.
  • Drive motor 154A, through pinion 156A and gear 158A drives the first feed auger screw section 120A and the rotor of the ex-truder head 144A, and drive motor 112A, through pinion 116A.
  • gear 118A and a drive tube 119A extending from the gear 118A to the screen 110A, drives the screen 110A.
  • the gear 118A drives a further gear 121A at the lower end of the second feed auger screw section 142A, so that the latter is also driven by the drive motor 112A.
  • the gears 118A and 121A By suitable selection of the gears 118A and 121A, the second feed auger screw section 142A can be driven at a speed greater than that of the first feed auger screw section 120A.
  • 210A is provided with auger tube 222A, which con-tains a first feed auger section 238A.
  • the compactor auger screw section 238A is connected by second feed auger screw section 242A to an extruder head 244A.
  • An inner auger screw 280A extends co-axially through the auger screws 220A, 238A and 242A and through the extruder head 244A. Beyond the extruder head 244A the auger screw 280A extends upwardly through an auger tube 282A to a discharge spout 284A. At the upper end of the auger screw 280A an electric drive motor 286A is provided for driving the auger screw 280A and, also, a classifier screw assembly indicated generally by reference numeral 288A, which is connected to the lower end of the auger screw 280A by a universal joint 290A and which is arranged beneath a grating 292A.
  • the compactor screw section 238A is connected, at its outer periphery, to a tubular housing 294A, which is connected at one end to a gear 296A.
  • the compactor auger screw section 238A has a lesser pitch, and twice the number of flights, as compared with the feed auger screw sections 220A and 242A.
  • a semi-circular weir 291A, having a semi-circular seal 293A in sealing engagement with the lower end of the screen 210A is provided for ensuring that the mixture of liquids and solids flows into the interior of the screen 210A.
  • Figure 39 shows a further modification of the apparatus of Figure 29, and parts of the apparatus of Figure 39 which correspond to those of Figure 29 have been indicated by the same reference numeral, increased by 300A and are therefore not described again in detail herein.
  • the material is forced into wider passages 382A, which allow expansion of the material, and the material is then extracted from the passages 382A by an output auger indicated generally by reference numeral 384A -having an output spout 386A.
  • the output auger 384A is driven from the upper end of shaft 348A through a universal joint 388A.
  • Shaft 348 is driven by electric drive motor 388A through gears 389A and 390A and a tubular housing 391A, which is connected to compactor auger screw section 338A and to gear 390A.
  • the output auger 384A comprises an auger screw 392A extending through an auger tube 393A with a plurality of bars 394A extending longitudinally between the auger screws 392A and the tube 393A. Like the bars 60A of Figure 29, the bars 394A serve to shear the material, and to counteract rotation of the material, as the material is fed along the auger 384A.
  • extrus-ion openings 364A are provided around extruder head 344A.
  • the extrusion openings 364A are provided with deflectors 366A, similar to the deflector 66A of Figure 31.
  • the apparatus is provided with four compactor passages 396A for receiving the material pressed radially outwardly from the extruder head 344A and for further compacting this material.
  • the passages 396A extend to wider passages 397A, which allow expansion of the material, as the material is fed into the output auger 384A.
  • the extruder openings 364A may be circular in shape, as shown in Figure 47 or may be modified so as to be in the form of slots, one of which is illustrated in Figure 48.
  • Figure 49 shows a modification, indicated generally by reference numeral 400A, of the output auger 384A of Figures 39 and 43.
  • the output auger 400A has an auger screw 402 rotating in a tubular housing 404A, with longitudinal bars of 406A spaced around the auger screw 402A between the auger screw 402A and housing 404A.
  • the auger tube 404A is provided with a heat- insulating jacket 408A, and with a hot gas outlet 410A and a hot gas inlet 412A at the upper and lower ends, respectively, of the auger screw 402A.
  • the auger screw 402A extends to an extrusion section indicated generally by reference numeral 414A, which is similar to the extruder section 44A of Figure 29 and which is provided with a hot gas outlet 416A.
  • the hot gas outlets 410A and 416A one connected by pipes 418A and 420A to the hot gas inlet 412A and an air inlet 422A connects to the pipe 418A for supplying fresh air with the auger 400A.
  • the material is fed for about an hour into the auger 400A while the auger 400A in stationary.
  • the auger 400A is then rotated in one direction through 180°, and the material is again fed into the auger for one hour, after which the auger is rotated through 180° in the opposite direction.
  • the material is thereby mixed and rearranged, so that oxygen is distributed so as to promote the growth of bacteria for composting the aeration also provides a temperature rise, by which the mate-rial is maintained at about 75°.
  • the motor rotates the auger screw 402A through 360° and the solid material is conveyed through the length of one turn of the auger screw 402A.
  • the auger screw 402A has two flights and can then convey about twice the amount that would be conveyed by a single flight auger.
  • the above-described operation is repeated until the material, after being composted is extruded by the extrusion section 414A.
  • the material then has a solid content of 50-80% depending on its intended use.
  • screened and sieved solid waste materials from sanatoria, hospitals and the like can be separated, compacted and hy-gienized and finally can be pelletized.
  • the resulting pellets can be combusted or the non-biological solid material can be removed and the remaining organic material can be mixed with additives in the form of carbons for subsequent further corn-posting or for return into the auger 400A.
  • the auger 400A may be replaced by a double-walled auger, used for heaat exchange, whereby fluid passed through the auger is heated, the flow being controlled to ensure that the temperature of the solid material is maintained at about 75°C, so that the bacteria in the material are not killed.
  • the fluid can be heated to 250°C to speed up the hygienization of the material.
  • the compactor comprising:
  • This compactor further comprising at least two compactor, passages for receiving the material deflected by said eccentric rotor, said compactor passages being dimensioned to compact the material as the material passes therethrough; and expansion passages for receiving the material from said compactor passages, said expansion passages being dimensioned to allow the expansion of the material as the material passes therethrough.
  • said auger screws of said first and second feed auger sections each have a screw pitch greater than that of said auger screw of said compactor auger section.
  • the compactor has the feature that said first feed auger section includes an auger tube co-axial with said auger screw of said first feed auger section and a plurality of bars extending longitudinally along the interior of said auger tube, between said auger tube and said auger screw of said first feed auger section, for cutting and guiding the material as the material is advanced along said first feed auger section.
  • the compactor has the further feature that said auger screw of said compactor auger section has a greater number of flights than said auger screws of said first and second feed auger.
  • the compactor shows that said eccentric rotor is co-axial with said second feed auger section and comprises a pair of curved impellers at opposite sides of the axis of rotation of said eccentric rotor and an auger screw at an axial end of said eccentric rotor remote from said second feed auger section and having a screw thread opposite to that of said second feed auger section-preventing movement of the material along said axis beyond said eccentric rotor.
  • the compactor further comprising an extrusion head extending around said eccentric rotor and formed with extrusion openings for extruding the material deflected radially outwardly by said eccentric rotor.
  • the compactor shows that said extrusion head is provided with means for breaking into separate individual pieces the material extruded through each of said extrusion openings.
  • the output auger 400 according to Fig. 49 can be used as a pre-composting module already directly connected to, for example, the double filter unit according to Figure 5 or 29a, whereby in this case the external pre-compostinq unit 500 according to Figure 28 could be dispensed with.
  • this variant makes it - in an advantageous manner possible that, by way of a heat exchanger which is merely outlined, spray water used for backwashing the screens in the double filter unit is heated by the waste heat of the pre-compostinq module (according s to tests possible up to 75°C) , in order to wash off grease and oil residues.
  • FIG 50 a first embodiment of an apparatus IB according to the invention for separating solids from flowing liquids is shown.
  • the apparatus IB is arranged in a sewer 2B the ground area 4B of which is indicated in Figure 50.
  • the maximum water level is indicated by a triangle in Figure 50 and the reference numeral 5B denotes the upper edge of the sewer.
  • the apparatus comprises two guides 6B, 7B disposed in a base 3B, the guide 7B being disposed behind the guide means 6B - seen in the direction of flow Y.
  • a plurality of collecting cages 8B e.g. seven in the shown embodiment which are movable along the guide 6B and 7B resp., is guided.
  • the two guides 6B,7B extend from the ground area 4B of the sewer in the direction of flow concavely curved upwards above the water level so that the guide portions 6B, 7B extend in U-shape against .the flow direction Y above the water level.
  • the radius of curvature of this portion of the guides 6B, 7B may have any curvature, for instance that of an elliptic portion or of a circular arc portion.
  • the radius of curvature may be reduced so as to save overall height.
  • the radius of curvature below the water level is chosen to be approximately equal for both guides 6B, 7B
  • the radius of curvature above the water level is chosen for the guides 6B, 7B such that the guides 6B, 7B are transformed into a common cleaning portion 9B which extends approximately in parallel to the liquid surface.
  • the cleaning portion 9B can be straight or can have a comparatively large radius of curvature.
  • the two successively arranged guides 6B, 7B thus have an approximately U-shaped design including a common U-leg formed by the cleaning portion 9B.
  • the collecting cages 8B are connected to each other by hinge means 12B, the design of which is described in detail further below. Accordingly, the plurality of collecting cages 8B forms a chain of collecting cages which is movable via a drive means 10B along the guide 6B and 7B, respectively.
  • the drive means 10B is provided with a drive motor acting on a tension means 11B which engages in the collecting cages 8B.
  • Each chain of collecting cages can be moved out of the shown operating position along the guide 6B and 7B, resp., via the drive means 10B, which may be, e.g., a cable or chain drive, out of the liquid flow.
  • the chain of collecting cages is moved along the curved portion toward the cleaning portion 9B of the guides 6B, 7B so that the collecting cages 8B are brought into a position in which their inlet opening 14B is directed downwards, i.e. toward the water level.
  • cleaning systems 15B including, for instance, discharge nozzles for highpressure vapour or high-pressure fluid are provided by which the collecting surfaces of the "upside-down" collecting cages 8B can be cleaned.
  • a removable buffer (not shown) may be provided which restricts the movement of the chain of collecting cages. By removing the buffer new or further collecting cages may be added to the apparatus IB.
  • the buffer is provided with a limit switch through which the drive means 10B receives the pulse for interrupting the drive when the collecting cages 83 have reached their "upside-down" cleaning position.
  • a roller path 18B (hatched line in Figure 50) which is formed approximately in extension of the guides 6B, 7B or, more exactly, of the cleaning portion 9B can be provided in the final area of the guide 6B, 7B.
  • a funnel tube 20B is provided, the funnel-shaped portion of which immerses partly into the liquid.
  • the length of the funnel tube 2OB corresponds to the length of the cleaning portion 9B of the guides 6B, 7B so that the solid material rinsed out by means of the cleaning system 15B can be collected.
  • a worm conveyor 22B driven by a drive 23B extends out of the funnel tube 20B .
  • the solid material can be discharged out of the funnel tube 20B upwardly inclined (view according to Figure 50) through the worm conveyor 22B.
  • the worm conveyor 22B may be, as can be taken from Figure 50, a double-lead worm conveyor, the worm conveyor having a comparatively small gradient in a portion which is partly below the water level.
  • a compacting portion 25B having a comparatively large worm gradient is connected in which the collected solids are dehydrated and compacted (compactor) .
  • the compacting portion 25B is equipped with four worm spirals (four-start), as one -can infer in particular from Figure 51b. Then the dehydrated solids are discharged via a discharge opening of the worm conveyor 22B. In the area of this discharge opening the worm conveyor is provided with opposed gradients so that the bearing of the worm conveyor at the side of the discharge opening is relieved.
  • shear or guide beads 24B which are arranged at small distance from the outer diameter of the worm conveyor 22B and are distributed along a circumferential portion are provided. These shear beads prevent a rotation of the solids to be transported and thus a formation of dough or clods so that a complete removal of the solids is guaranteed.
  • the lower portion of the funnel tube 20B in which the worm conveyor runs open is designed as filter or grate surface 26B so that residual liquid in the solids and superfines can be returned to the liquid flow.
  • a further high-pressure cleaning means 28B may be provided by which cleaning fluid (vapour, fluid) can be sprayed at high pressure onto the grate surface 26B so that solids or other impurities (fats, oils etc.) adhering thereto are rinsed off and returned to the liquid flow.
  • the housing shell 29B encloses the worm conveyor 22B in the area of the four-start compacting portion 25B, the shear beads 24B being distributed along the inner circumference of the housing shell 29B.
  • the funnel tube 20B is supported via braces 31B at the sewer 2B.
  • the solids can be supplied to another step of treatment, as for instance a pelleting means, via the worm conveyor 22B (not shown) .
  • the guide 6 is designed as switch 30B by which it is safeguarded that the chain of collecting cages is moved out of the cleaning position from the cleaning portion 9B back into the provided guide 6B or 7B.
  • the switch 30 can be swivelled by means of a drive means 32 so that either the guide 6B is connected to the cleaning portion 9B or the switch 30B is moved out of the collision area of the guide 7B.
  • the drive means can act against the force e.g. of a tension spring 34B so that for resetting the switch 30B into a home position no separate control pulse for the appropriate movement of the drive means must be transmitted, but the tensile force of the spring is exploited.
  • a guide plate 34B and 36B is provided from the portions arranged in the liquid to the cleaning portion 9B, the guide plate 34B being assigned to the guide 6B and the guide plate 36B being assigned to the guide 7B.
  • the guide plates 34B,36B are arranged at a distance from the guides 6B and 7B which corresponds approximately to the height H of a collecting cage. Moreover the guide plates 34B,36B are adapted to the curvature of the assigned guides 6B and 7B.
  • the guide plates 34B, 36B extend approximately away from the water level in the direction of the funnel tube 20B, the guide plate 36B assigned to the rear guide 7B being pivoted in the guiding base 3B.
  • the curvature of the guide plates 34B and 36B is selected so that they are arranged, when moving the collecting cages 8B out of their operating position into the cleaning position, only at a small distance from the inlet opening 14B of the collecting cages and thus prevent the solids from falling out of the collecting cages when they are moved toward the cleaning portion 9B.
  • the length of the guide plates 34B, 36B is designed such that the solids cannot miss the funnel.
  • the movable guide plate 36B is swivelled, when the collecting cages are moved along the guide 6B out of the position shown in Figure 50 away from the guide 6B so that the collecting cages 8B cannot collide with the guide plate 36B on the guide 6B.
  • the guide plate 36B is brought into its position shown in Figure 50 when the collecting cages 8B are moved on the guide 7B.
  • the apparatus comprises a water level sensor 38B including an associated circuit by which the drive means of the collecting cages 8B is controlled, when the water level rises due to added collecting surfaces, so that the collecting cages 8B are moved out of their operating position into the cleaning position.
  • a stepped elevation 40B which at the same time forms a stop for the collecting cages 8B is provided for each of the guides 6B, 7B.
  • the leading surface 42B seen in the flow direction Y of the elevation 40B is adapted approximately to the curvature of the guide 7B and extends approximately in extension of the inlet openings of the collecting cages 8B.
  • a sediment separating means 4IB by which sand, pebbles, fruit stones etc. can be discharged is indicated in broken lines. This means is optionally provided and is described in more detail in connection with Figures 60 to 62.
  • FIG 52 a section across a collecting cage 8B is shown in a first embodiment along the line B-B in Figure 50.
  • the collecting cage 8B comprises a shell 50B the open front sides of which form the inlet opening 14B and an outlet opening 52B for the liquid.
  • the shell 50B has a necking 54B at its upper part so that the shell 50B is enlarged toward the inlet opening 14B and toward the outlet opening 52B.
  • other cross-sections can be used as well.
  • sealing lips 56aB,bB or the like are approximately in parallel to the guides 6B, 7B which are in contact with or at least at a small distance from guide plates 58B, 59B which are fixed to the side wall 60B of the sewer.
  • the sealing lips 56aB,bB are approximately adapted to the curvature of the guides 6B, 7B.
  • the guide plates 58B, 59B ensure that the liquid flow X is deflected in the direction of the center of the collecting cage 8B and cannot flow laterally past the collecting cage. Thus a further improvement of the degree of separation is permitted by these guide plates 58B,59B.
  • the sealing lip 56B also gets in contact with or in the vicinity of the guide plates 34B, 36B so that a sealing locking of the collecting cage in its upside-down position is guaranteed until it reaches the collect-ing area of the funnel tube 20B.
  • a stripping member 57B is provided which, when the collecting cages 8B are moved in the direction of the cleaning portion 9B, gets in contact with the guide plate 34B or 36B so that the separated solids are prevented from falling downward out of the collecting cage.
  • the necking 54B likewise supports the liquid flow toward the center of the collecting cage 8B so that solids at first deposit in the center of the collecting surface 62B and only afterwards in the marginal areas.
  • the collecting surface 62B seen in the flow direction X - is arranged below the necking 54B.
  • the collecting surface 62B is formed by lamellas 64B which extend in circular arc shape across the interior of the collecting cage 8B.
  • the lamellas are concavely curved in the direction of flow, wherein initially solids deposit in the lower part of the lamellas 64 due to the necking 54B and the effect of the guide plates 58B, 59B.
  • the structure of the collecting surface 62B can be taken from the Figures 53a, 53b, Figure 53a being a side view of Figure 52 and Figure 53b being a magnified detailed view of the lamellas 64B.
  • the collecting surface 62B is formed by a plurality of lamella packs 66B, 68B, 70B which are staggered in the flow direction X so that the collecting surface 62B extends in approximatly rectangular wave shape transversely to the flow direction X.
  • five lamella packs are staggered in series so that a concave profile is resulting (cf. Figure 53a) .
  • the lamella packs 66B consist of a plurality of individual lamellas 64B ( Figure 53b). which are held in parallel distance from one another via spacers 72B. Thereby passage gaps 74B for the liquid to be purified are formed between the lamellas 64B of a lamella pack.
  • fastening bolts 77B, 78B which are screwed with the shell 50B are guided through the lamella packs 66B, 68B.
  • the lamella pack 70B which is positioned lowest in the flow direction X is screwed with the lamella packs 68B and/or the shell 50B through fastening means, which are not shown, so that the entire lamella pack is detachable from the collecting cage 8B merely by unscrewing (cf. Figure 54b) the fastening bolts 77B, 78B.
  • the lamellas of each lamella pack are likewise screwed to one another through bolts.
  • the spacers 72B have a rectangular approximately plate-shaped structure, one corner being arranged in the direction of flow X. In this way the spacers 72B have a conical flow surface on which solid material, such as e.g. fibres, can settle down.
  • the special arrangement of the spacers 72B also facilitates the rinsing of the added solids in the cleaning position of the collecting cage 8B because - as described in the foregoing - the cleaning nozzles act against the flow direction X and thus the solids are easily removable from the tapered flow surfaces of the spacers 72B.
  • triangular spacers 80B are provided so that the desired gap width, which may be up to 10 mm, preferably 1 mm, depending on the application, is also ensured in the marginal area of the lamellas.
  • These spacers 80B may likewise be used for fixing the lamellas at the shell 50B.
  • the collecting cage 8B is provided with a roller means further below described in more detail which runs in the guides 7B of the guiding base for the collecting cages 8B.
  • each lamella 64B of a lamella pack 66B, 68B, 70B comprises an approximately circular arc- shaped or elliptically curved central portion 82B which is transformed into approximately straight marginal portions 84B extending to a shell portion in the area of the inlet opening 14B.
  • the marginal portions 84B form a funnel through which the liquid is guided to the central portions 82B.
  • the necking 54B of the shell 50B provided in the above-described embodiment can be omi tted or at least made smaller so as to considerably reduce the manu-facturing costs of the shell .
  • the lamellas 64B are in turn held at the desired distance from one another by the spacers 72B and 80B.
  • the lamellas 64B shown in Figures 54a,b may have a multipart structure, wherein the central portion 82B may be manufactured of a circular arc-shaped member adapted to the modular dimensions of usual sewers, whereas the marginal portions 84B may be manufactured in different lengths so that the lamellas 64B can easily be adapted to different sewer widths.
  • the central portions 82B may be connected to the marginal portions 84B via the spacers 72B.
  • the other components of this collecting cage correspond to those of the collecting cage shown in Figures 52, 53a, 53b so that, to simplify matters, in this respect reference is made to the above description.
  • the collecting cage 8B need not be equipped with the above-described lamella structure as collecting surface 62B, but any filter elements may be used, such as e.g. sand, activated carbon or ceramic fillings or .else perforated plates or filter cloths.
  • filter elements such as e.g. sand, activated carbon or ceramic fillings or .else perforated plates or filter cloths.
  • Such filter structures are described in the Canadian applications No. 2,106,291 and 2,107,172 of the Applicant relating to a BIOVERTER System, which are herewith referred to, to simplify matters, and the content of which shall belong to the disclosure of the present application.
  • Each guide 6B or 7B includes two guide rails 86B, 87B arranged on a common base 88B.
  • the distance of the guide rails 86B, 87B approximately corresponds to the width (cf. Fiqure 52) of a collecting cage 8B.
  • an axis 90B is assigned to a collecting cage 8B at the end of the axis there are formed guide rollers 92B which run in the guide rails 86B, 87B.
  • the guide rails 86B, 87B are U-profiles the legs of which extend approximately in parallel to the axis 90B.
  • a retaining means would have to be provided so as to retain the rollers in the upside-down position of the collecting cages 8B in the cleaning portion 9B.
  • the collecting cages 8B of a chain of collecting cages are connected to each other via hinge clips of the hinge means 12B disposed at the upper edge (view according to Figure 53) of the collecting cage.
  • this hinge means includes strap hinges 94B and 96B which are arranged alternately on the axis 90B.
  • the fixing clips of the strap hinges 94B are fixed to a collecting cage 8aB while the fixing clips of the further strap hinges 96B are fixed to the adjacent collecting cage 8bB.
  • This hinge means ensures that the collecting cages 8B are adapted to follow the arc shape of the guide 6B, 7B, wherein the relative position of the collecting cages 8aB 8bB to each other may change.
  • the collecting cages 8B are fixed to one another via the strap hinges 94B, 96B so as to form the above-described chain of collecting cages.
  • the axis 90B has a double function which consists, on the one hand, in supporting each collecting cage 8B on the guides 6B,7B and, on the other hand, in supporting the strap hinges 94B, 96B.
  • FIG 58 another variant of the apparatus according to the invention is illustrated. While in the foregoing embodiment the collecting surface was formed by a plurality of collecting cages 8B permitting a variable adaptation of the apparatus to different sewer widths, in Figure 58 a variant having a simpler structure is suggested. According to this embodiment, the collecting surfaces are formed by segment faces 98B and 100B each being supported in a rigid frame 102B, 103B which is pivotable about a rotatable axis 104B.
  • Each of the segment faces 98B, 100B as a circular arc-shaped or elliptic design so that the collecting surface 62B has approximately the same shape upwardly ascending in a curved manner as in the case of the foregoing embodiment.
  • At the ground area of the sewer steppings having appropriate stops are formed for restricting the rotary movement of the frames 102B, lo3B with the segment faces 98B, 100B.
  • the segment faces 98B, 100B may be provided with the above-described lamellas or else be filled in any way with other filter mediums - as in the case of the a.m. PCT applications.
  • the segment faces 98B, 100B can be swivelled upwards into a cleaning position in which the collecting sur ⁇ faces are upside down.
  • rinsing fluid can be applied to the segment faces 98B, 100B against the normal flow direction X via high-pressure fluid nozzles 15B so that the separated solids are rinsed out and transported into a funnel tube (not shown) or the like.
  • rinsing fluid can be applied to the segment faces 98B, 100B against the normal flow direction X via high-pressure fluid nozzles 15B so that the separated solids are rinsed out and transported into a funnel tube (not shown) or the like.
  • the embodiment shown m Figure 58 works m the same way as m the foregoing Figures.
  • each apparatus includes a separate drive and a separate guide comprising collecting cages 8B or segment faces 98B, 100B.
  • each collecting cage plural preferably convexly curved lamellas 64B may be formed side by side so that the collecting surface can be enlarged at will.
  • a retaining gate 48B may be provided at the ground area 4B ahead of the guide 6B, the retaining gate being brought in its verti-cal position shown in broken lines, when the separating means 4IB is moved upwards so that the deposited solids are retained m the bottom area at the retaining gate, until the separating means has been returned to its operating position. Then the retaining gate is swivelled back into the position indicated by a continuous line.
  • FIG. 60 to 62 embodiments of the sediment separating means 41B are shown.
  • the separating means 41B is formed in extension of the front guide 6B.
  • the elevation 14B for the guide 6B has been omitted and the guide rails 86B, 87B have been enlarged until they extend approximately in parallel to the ground area 4B.
  • a plurality of separating screens 108B are successively guided in the guide rails 86B, 87B each rear wall 112B of a separating screen 108B overlapping with the adjacent end portion of the bottom portion HOB so that the rear wall 112B is located between the two side walls 114B of the adjacent separating screen 108B.
  • the separating screens 108B are supported with their side walls by an axis 90S including guide rollers 92B which, in turn, are received in the guide rails 86B, 87B.
  • the selfsupporting end portions of the side walls 114B are curved conically outwardly and overlap with the guide plates 116B arranged in extension of the guide plates 56B so that a sealing is formed between the side wall 116B and the side wall of the sewer.
  • two further impact walls 118B are fixed on the latter so that the area between two adjacent rear walls 112B is divided into three sections of approximately equal size.
  • the rear walls and the impact walls 118B are arranged to be ascending toward each other, seen in the direction of flow, so that the last rear wall 112B, seen in the direction of flow, of the separating means 41 has almost the height H of a collecting cage 8B.
  • the side walls of the successively arranged separating screens 108B are formed to have an ascending height so that the side wall 114B of the rearmost separating screen 108B has about the height H of a collecting cage 8B.
  • the side wall 114B of a separating screen 108B rises above the rear walls 112B by a predetermined distance.
  • the sediments deposit on the screen ⁇ like bottom portions HOB, the fluid and the superfines being able to flow through the screen mesh.
  • the screen-like bottom portion HOB can be made of cross struts HB arranged in parallel to each other around which a screen material (steel, plastic) is wound in wave shape.
  • the bottom portion may be formed of one layer (cross struts 11 and a screening surface) or of two superimposed layers 132aB, 132bB .
  • the separating means 41B When moving the collecting cages 8B along the guide 6B into the cleaning position, also the separating means 41B is entrained and brought into an upside-down position so that the solids, possibly with the help of a cleaning means, fall out of the separating means and are supplied to a transport means, e.g. a worm conveyor (not shown).
  • a transport means e.g. a worm conveyor (not shown).
  • FIG 62 another embodiment for a separating means is shown. This embodiment may be used for a construction of the guiding base as it is visible in Figure 50, without the front elevation 40B for the guide 6B having to be omitted.
  • a transverse recess 120B is formed in which a transverse worm conveyor 122B is formed to which laterally in the area of the sewer side wall or outside the sewer a discharge -worm conveyor 124B is connected.
  • the sediments are conveyed from the transverse worm conveyor 122B to the discharge worm conveyor 124B and are then conveyed laterally out of the sewer to a storage means or to a further treatment.
  • other conveying means can be used instead of the worm conveyor.
  • This variant has the advantage that the construction of the conveying base needs not to be modified and moreover the flow resistance in the central area of the sewer is reduced to a minimum.
  • the collecting cages 8B arranged on the guide 6B are in their shown operating position in which they are immersed into the liquid.
  • the collecting cages 8B arranged on the guide 7B are in their cleaning position in which they are lined up upside down along the cleaning portion 9B.
  • high pressure, vapour or fluid which flows in through the outlet opening 52B passes through the passage gaps 74B between the lamellas and flows out through the inlet opening 14B of each collecting cage 8B, flows past the collecting cages 8B_in the cleaning position. Due to the flow of the rinsing fluid the solids are entrained and fall in the funnel tube 20B provided below the cleaning system 15B.
  • the rinsed out solids are dehydrated and supplied to a further treatment via the worm conveyor.
  • the solids are separated in the liquid flow in the sewer, wherein the liquid to be purified enters through the inlet opening 14B into the collecting cages 8B, the solids are separated at the lamellas 64B and the liquid free of solids flows out of the collecting cages 8B, through the outlet opening 52B. Since the collecting cages 8B of the guide 7B which are located behind the collecting cages 8B provided on the guide 6B are not immersed in the liquid, the pressure loss of the liquid is determined by the collecting cages 8B which are in operating position. In the rotary means described in tne beginning the pressure loss was influenced, on the one hand, by the collecting surfaces in forward motion and, on the other hand, by the collecting surfaces in return motion.
  • the passage gaps 74B between the lamellas are filled so that the water level is slowly rising.
  • a signal is transmitted via the water level sensor 38B to the system control so that the collecting cages 8B in cleaning position are lowered into the water level along the guide 7B via the drive means.
  • the switch 30 is in a position closing off the guide 6B.
  • the switch 30 and the guide plate 36B are swivelled into a position releasing the guide 6B and the collecting cages 8B on the guide 6B are transported upwards to the cleaning portion 9B.
  • the collecting cages 8B are brought into their upside-down position, the separated solids being prevented from falling out by the guide plate 34B and the sealing lips 56B in the strongly curved portion of the guide between the water level and the cleaning portion 9B.
  • the cleaning system 15B is actuated and the solids are rinsed out against the direction of flow in Z direction out of the collecting cage 8B into the funnel tube 20B, until the collecting cages 8B are completely freed from the adhering solids, oils and fats.
  • the solids fall through the funnel 20B onto the open-running portion of the worm conveyor 22B and are conveyed by the latter out of the funnel 20B and compacted and dehydrated in the compacting portion.
  • the apparatus for separating solids from flowing liquids corn-prising a first collecting means for the solids which can be discharged from the area of said collecting means by a first transport means, wherein the collecting surface 62B of said first collecting means 1 is movable out of an operating position in the liquid flow into a cleaning position outside the liquid flow by a drive means.
  • a further collecting means is associated to said first collecting means and said collecting means are adapted to be alternately brought into the operating position and the cleaning position, respectively.
  • said first collecting means and said further collecting means are arranged in series in the direction of flow (Y) .
  • said collecting means has a preferably curved collecting surface 64B obliquely ascending from the ground area of the liquid flow in the direction of flow (Y) to the liquid surface.
  • said collecting means comprises one or a plurality of collecting cages 8B forming said collecting surface 64B.
  • said collecting cages 8B are hinged to one another and are guided by a guide 6B, 7B along which said collecting cages 8B are movable out of the operating position into the cleaning position.
  • said guide 6B, 7B has a substantially circular arcshaped curvature in the area of the liquid flow and is returned above the liquid level preferably with a smaller radius of curvature and subsequently comprises a cleaning portion 9B extending substantially in parallel distance from the liquid surface.
  • a guide 6B, 7B ending in a common cleaning portion 9B is assigned to each collecting means.
  • a switch 30B is disposed in the area between said common cleaning portion 9B and a branching to the guides 6B, 7B.
  • each collecting cage 8B is guided via guide rollers 92B in guide rails 86B, 87B.
  • each collecting cage 8B is disposed approximately in parallel to the guide 6B, 7B.
  • a funnel tube 2OB assigned to said transport means 22B is provided in the area between the liquid surface and said cleaning portion 9B of said guide 6B, 7B.
  • each collecting cage 8B comprises a shell 50B the open rectangular fronts of which form the inlet opening 14B for the fluid loaded with solids and an outlet opening 52B for the fluid free from solids and which encloses a cage collecting surface 62B.
  • Said collecting cages 8B are hinged to one another along adjacent shell faces.
  • said cage collecting surface 62B comprises a plurality of lamellas 64B spaced apart from one another which are concavely curved toward said inlet opening 14B, wherein passage gaps 74B for the fluid are formed between said lamellas 64B.
  • each lamella 64B is strip-shaped, the large areas restricting said passage gaps 74B and the front faces being arranged transversely to the direction of flow X.
  • spacers 72B, 80B defining the gap width are arranged between said lamellas 64B.
  • spacers 72B have rectangular bearing surfaces, a diagonal being aligned approximately in parallel to the direction of flow X.
  • each lamella 54B comprises a curved central portion 82B and two approximately straight marginal portions 84B connected thereto which extend away from said central portion 82B in the direction of said inlet opening 14B.
  • the apparatus has futhermore preferably triangular fastening elements 80B disposed between said lamellas 64B for fastening said lamellas 64B at the shell 50B, said fastening elements at the same time serving as spacers 72B.
  • a plurality of spaced lamellas 64B is combined to a lamella pack 66B,68B,70B and plural lamella packs 66B,68B,70B are staggered with respect to each other in flow direction X.
  • said cage collecting surface 62B includes filter elements of sand, ceramics, activated carbon, carbon, perforated plates or filter cloth.
  • a plurality of collecting means are juxtaposed transversely to the liquid flow Y.
  • said collecting means is pivoted about an axis of rotation 104B.
  • a collecting cage in particular for use in the above- described apparatus, shows a combination of the features listed above.
  • the essential difference of the embodiment according to Figure 50 compared to the embodiment according to Figure 5 or Figure 29 consists in that the collecting surfaces of the screen are no longer moved in a rotatory manner - as before - but in a translatory manner from the working position to the cleaning position and vice versa.
  • the collecting cage according to Figure 52 can selectively also be designed as a mesh filter as shown m Figure 14, or as a microfilter having a cross section as shown in Figure 25, or as a combination of both variants.
  • the collecting surface of the mesh filter is formed by a number of three or more bags arranged side by side and having different depths, with a staggered, curved collecting surface contour being formed, as can be gathered from Figure XXI.
  • the separating walls forming the bags are cut out of an impermeable material in the form of trapezoids.
  • the upper, lower, and rear side of each bag is formed by a micro-mesh having a structure described before.
  • the separating walls furthermore show a trapezoidal recess at the respective front edge.
  • the collecting surfaces are first cleaned off by means of compressed air before they are rinsed out with water.
  • the dumped solid material in particular the superfines and the solid mud particles contained therein, are not again liquefied and flushed out, but can already be discharged in a simple manner as a solid filter cake.
  • the cleaning station can be extended by a further funnel tube forming the blow-out portion. This means that the collecting surfaces are first guided over the funnel tube in the blow-out portion and, after they have been cleaned off by means of compressed air, are returned over the funnel of the liquid washing device.
  • the cleaning water is heated, for example, by means of the above mentioned heat exchanger and/or can be mixed with a chemical cleansing agent.
  • dosing devices can be arranged in the funnel tubes at an appropriate position; by means of these dosing devices various chemical and/or biological additives can be added to the solid material.
  • Biological additives may be the following: biological waste, scraps of any kind from trees and plants, sawdust (as carbon-containing substance and as thicken-ing substance) .
  • the compactor module can be designed as a four-speed clogging compactor for compressing and disintegrating the solid material in the transitional area between the auger tube and the compactor whose housing shell consists of two shell halves. This offers the possibility to eliminate possibly occurring cloggings by folding out the shell halves.
  • a cone-shaped discharge module according to Figure BB3 would be conceivable which consists of individual rings axially arranged side by side and having a different diameter.
  • the above mentioned necked-down portion having an adjustable diameter can preferably be designed as an individual module and can be arranged in the auger-compactor system at any position whatsoever.
  • FIG. YY1 to YY3 A further development of the cleaning station is shown by Figures YY1 to YY3.
  • the above described cleaning station is designed with an additional washing device extending from the top to the bottom.
  • solids discharged by the auger screw can additionally be washed.
  • a kind of tub or casing can be perceived in Figure YY3 which, underneath the cleaning station, is formed around the auger screw or the spray means arranged therebelow.
  • the tub is arranged such that the lower end portion of the auger screw is permanently under water irrespective of the current liquid level. Due to overflow openings arranged in the tub, the liquid level within the tub is constantly kept at a predetermined level.
  • the auger tube is, in the feed area for the solid material, preferably formed as a kind of grating allowing excess liquid to drip off.
  • an additional mesh a fine mesh or micromesh, is arranged above the grating. This additional mesh is supported by the grating and is selectively held by guide beads. In this manner, fine, superfine or micro mud particles, which had previously again be returned to the liquid, are largely held back in the solid material and are discharged by the auger screw.
  • Figures TT1 to TT3 show a modified embodiment of the pretreatment unit 10 according to Figure 2 of this invention.
  • the tank shows two slides or weirs at a side wall thereof, which, during normal operation according to the above description, block the access to two deflection sewers.
  • the deflection sewers only have a low depth, with the liquid level being preferably 20 cm, and are provided with aerating nozzles at the respective sewer bottom and/or side walls.
  • Each of the sewers leads to a respective oil separating device; in their operating position, these oil separating devices block the corresponding sewer. If, for example, a sensor detects oil in the waste water, the weirs open. As a result, the waste water surface is drawn into the sewers and hot air from the aerating nozzles flows therethrough.
  • the heated oil and grease contents can easily be separated by means of the oil separating devices and can be stored in the corresponding tanks so as to be reused.
  • the oil separating devices are lifted out of the sewers, thus releasing the sewer exits.
  • the liquid cleaned in this manner can subsequently be supplied to the first filter station, with the floating upper layer, which consists of flotable solid material, being swept away by the current in the sewer.
  • the weirs are closed again so that new waste water can be collected in the tank.
  • the pre-treatment unit 10 can selectively be equipped with an additional buffer tank for the quick and complete collection of faecal matter; from this buffer tank these feacal wastes, for example, from house filter plants, can be added to the waste water via a valve.
  • FIGs AA1 and AA2- a variation of the inventive embodiment of a filter station according to Figure 50 is shown.
  • a sewer is subdivided into two separate channels each of which can be opened or closed by means of a flow switch.
  • the two collecting cage trains which, according to Figure 50, are arranged one after the other, are now arranged side by side in the channels.
  • Behind the first filter station the sewer exhibits a curvature of 180° after which a second filter station exhibiting a preceding switch is provided. It has the same design as the first filter station.
  • the individual collecting cage trains of each station are alternately moved to and from between the working position and the cleaning position, with the switches being caused to swivel accordingly.
  • the discharge of the solid material at the two filter stations can be effected into one and the same funnel tube of a single auger system, so that in this way construction space and production costs are saved.
  • several filter stations comprising differently formed collecting cages (mesh, micro mesh, etc.) can be arranged one after the other.
  • the sewer or the corresponding channel in the effective range of the collecting cage train according to Fig. AA2 is designed with a deepening, whereby the effective total filter surface can be increased.
  • the embodiment according to Figure CCl is an alternative to the above described micro mesh filters. It consists of at least one, but preferably two containers, each of which is subdivided into individual chambers.
  • the side walls of the containers are fluid-tight, and the upper and lower side is formed by a micro-mesh texture including a supporting wire, as is already described above with regard to Figure 25.
  • the containers are filled with sand, activated carbon, or with a similar filter material, and they are pivoted about a swivel axis.
  • Above each container a sprinkler system is arranged which is respectively connected to a collecting container as a buffer tank. Each of the collecting containers is also supported such that it can swivel.
  • the prefiltered and possibly aerated liquid is distributed over the first container by means of the first sprinkler system and passed through the filter material. Below the first container the liquid is then collected and, if necessary, supplied to a further filter process by means of a second container. This filtering can then be concluded by an irradiation of the liquid by ultraviolet light, whereby germs can be destroyed.

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  • Chemical & Material Sciences (AREA)
  • Chemical Kinetics & Catalysis (AREA)
  • Engineering & Computer Science (AREA)
  • Mechanical Engineering (AREA)
  • Treatment Of Sludge (AREA)
  • Filtration Of Liquid (AREA)
  • Agricultural Chemicals And Associated Chemicals (AREA)

Abstract

L'invention concerne un système et un procédé destinés au traitement d'un mélange d'un liquide, dans lesquels plusieurs filtrations sont effectuées par un ou plusieurs moyens de tamisage doté(s) de différents milieux filtrants tels que des plaques, des mailles, des micromailles, du sable et/ou des filtres à charbon actif, permettant de tamiser à chaque opération de tamisage au moins une partie du matériau solide contenu dans un liquide, et dans lesquels le matériau solide enlevé par les tamisages est placé dans une installation de compostage et le liquide filtré est soumis à un procédé de destruction des bactéries.
PCT/EP1994/003093 1993-09-15 1994-09-15 Systeme et procede de traitement d'un melange de solides et de liquides WO1995007744A1 (fr)

Priority Applications (3)

Application Number Priority Date Filing Date Title
AU78081/94A AU7808194A (en) 1993-09-15 1994-09-15 System and method of processing mixture of solids and liquids
EP19940928784 EP0719171A1 (fr) 1993-09-15 1994-09-15 Systeme et procede de traitement d'un melange de solides et de liquides
JP50899895A JPH09502418A (ja) 1993-09-15 1994-09-15 固形物と液体との混合物を処理するシステムおよび方法

Applications Claiming Priority (4)

Application Number Priority Date Filing Date Title
CA002106291A CA2106291A1 (fr) 1993-09-15 1993-09-15 Methode de traitement d'un melange de solides et de liquides
CA2,106,291 1993-09-28
CA002107172A CA2107172A1 (fr) 1993-09-28 1993-09-28 Compacteurs
CA2,107,172 1993-09-28

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WO1995007744A1 true WO1995007744A1 (fr) 1995-03-23

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PCT/EP1994/003093 WO1995007744A1 (fr) 1993-09-15 1994-09-15 Systeme et procede de traitement d'un melange de solides et de liquides

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EP (1) EP0719171A1 (fr)
JP (1) JPH09502418A (fr)
AU (1) AU7808194A (fr)
WO (1) WO1995007744A1 (fr)

Cited By (10)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO2012126584A1 (fr) * 2011-03-18 2012-09-27 Röhren- Und Pumpenwerk Bauer Ges. M. B. H. Séparateur à vis de presse
US9597618B2 (en) 2009-11-05 2017-03-21 Daritech, Inc. Systems and methods for extracting sand from raw slurry material
US9610521B2 (en) 2009-11-05 2017-04-04 Daritech, Inc. Systems and methods for extracting particulate from raw slurry material
US10286340B2 (en) 2014-05-27 2019-05-14 Daritech, Inc. Feed systems and methods for rotary screen separators
US10603675B2 (en) 2014-11-02 2020-03-31 Dari-Tech, Inc. Systems and methods for extracting particulate from raw slurry material
US10603611B2 (en) 2014-05-30 2020-03-31 Daritech, Inc. Cleaning systems and methods for rotary screen separators
WO2022013531A3 (fr) * 2020-07-16 2022-02-24 SEM Energy Limited Appareil et procédé de traitement de l'eau
EP2478762B1 (fr) * 2011-01-20 2023-06-07 Daritech, Inc. Systèmes et procédés d'extraction de particules provenant d'un matériau de boue
CN116621318A (zh) * 2023-07-25 2023-08-22 四川永沁环境工程有限公司 污水消毒保障系统
CN118491161A (zh) * 2024-07-15 2024-08-16 山东永豪发展集团有限公司 一种尾气处理液出液过滤装置

Families Citing this family (1)

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CN114516688B (zh) * 2022-01-10 2023-12-05 郴州中化氟源新材料有限公司 氟化工生产废水处理设备

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JPH04227899A (ja) * 1991-05-13 1992-08-17 Ebara Infilco Co Ltd し尿処理方法

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Cited By (11)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US9597618B2 (en) 2009-11-05 2017-03-21 Daritech, Inc. Systems and methods for extracting sand from raw slurry material
US9610521B2 (en) 2009-11-05 2017-04-04 Daritech, Inc. Systems and methods for extracting particulate from raw slurry material
EP2478762B1 (fr) * 2011-01-20 2023-06-07 Daritech, Inc. Systèmes et procédés d'extraction de particules provenant d'un matériau de boue
WO2012126584A1 (fr) * 2011-03-18 2012-09-27 Röhren- Und Pumpenwerk Bauer Ges. M. B. H. Séparateur à vis de presse
US10286340B2 (en) 2014-05-27 2019-05-14 Daritech, Inc. Feed systems and methods for rotary screen separators
US10603611B2 (en) 2014-05-30 2020-03-31 Daritech, Inc. Cleaning systems and methods for rotary screen separators
US10603675B2 (en) 2014-11-02 2020-03-31 Dari-Tech, Inc. Systems and methods for extracting particulate from raw slurry material
WO2022013531A3 (fr) * 2020-07-16 2022-02-24 SEM Energy Limited Appareil et procédé de traitement de l'eau
CN116621318A (zh) * 2023-07-25 2023-08-22 四川永沁环境工程有限公司 污水消毒保障系统
CN116621318B (zh) * 2023-07-25 2023-09-19 四川永沁环境工程有限公司 污水消毒保障系统
CN118491161A (zh) * 2024-07-15 2024-08-16 山东永豪发展集团有限公司 一种尾气处理液出液过滤装置

Also Published As

Publication number Publication date
AU7808194A (en) 1995-04-03
JPH09502418A (ja) 1997-03-11
EP0719171A1 (fr) 1996-07-03

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