US2570697A - Filtering apparatus - Google Patents

Filtering apparatus Download PDF

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US2570697A
US2570697A US789152A US78915247A US2570697A US 2570697 A US2570697 A US 2570697A US 789152 A US789152 A US 789152A US 78915247 A US78915247 A US 78915247A US 2570697 A US2570697 A US 2570697A
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belt
suction
vessel
trays
belts
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US789152A
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Nordengren Sven Gunnar
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    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01DSEPARATION
    • B01D33/00Filters with filtering elements which move during the filtering operation
    • B01D33/333Filters with filtering elements which move during the filtering operation with individual filtering elements moving along a closed path

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  • the present invention' relates to an improved apparatus of the vessel-belt type for filtering and' 'washing mixtures of solid and liquid substances.
  • the irivennorrthevessei beit is mountedtorevolv'e 'on' an endless trackway andis connected tothe suction belt' ⁇ in 'such a manner that the movement of' one controls the'movernent of the other' so that the two rn'ove simultaneously and retain the saine relative positions.
  • the vessel belt is preferably built in such a way that'a number of trays orboxes of the saine size are united@ to an endless belt. Between the trays are suitably mounted shafts connected with the trays bybendable joints. On said shafts are mounted wheels which support the trays and roll on the framework. In this way each link of the belt containing one tray or box Will be given a length equal to the distance between the centre lines of ⁇ two adjacent shafts.
  • Oneway of driving the vessel belt is to equip each linkwith a row of cogs on each side and driven by a pairofcogwheels. With this construction no drums are needed at the turning ends of the beltsince the framework may be given such a form that the travelling course of the" belt is fixed by the wheels running ⁇ on the framework. If the trays are all made of equal size, which construction is recommended, the number of cogs in the Vessel belt will beV an even multiple of the number of vessels.
  • a suitable construction of the means for moving the flexible' suctionbe'lt is to let-'these' means be constituted of cogsr orl projecting parts of the belt itself cooperating with parts on thel vessel belt.
  • Another possible construction is to place a link-chain on one or both sides of the suction belt and to lengthen the bolts'of the link chains so that they can be put through holes in the suction belt, vwhich in this case should be given a square or rectangular section with a relatively large height compared with the width.
  • one belt can drive the other in a direct way. If, for instance, chains are mounted on both sides of the suction belt this belt can be driven by a pair of cog-Wheels. It is then possible to mount tractive means on the chains and to let those means act on corresponding means mounted on the vessel belt so that the latter belt will be driven with the same speed as the suction belt. It is also possible to mount tractive means on the vessel belt which act on corresponding means mounted on the suction belt, for instance in the form of bolts or pipes put through the said belt. This has in fact proved to be the best construction in practice.
  • both belts have the same eiective length the position of each belt will be completely xed in a vertical section as soon as the number of links at the turning points of the vessel belt has been fixed.
  • the vessel belt is generally built in such a way that it is bent at its turning ends in a hexagonal or octagonal form.
  • the distance between the two belts will be varying and the communicating means between them must therefore be constructed in such a way that the suction belt can move freely in a vertical plane through its centre line.
  • the vacuum connections between the bottoms of the vessels and the suction belt must be made of a flexible material, for instance of rubber to lallow of such a movement.
  • T-formed channels should be arranged between the above mentioned connecting means mounted for the driving of the suction belt. It is also possible to let the pipes, which are placed horizontally in the T-formed channels, serve as means to be acted upon by the driving means mounted on the vessel belt. If the size of the lter is comparatively large two or more T-formed channels should be used for each vessel.
  • Fig. 1 is -a diagrammatical side elevation of a tray-belt filter
  • Fig. 2 is a vertical cross-section through the filter in Fig. 1 on a larger scale
  • Fig. 3 shows an arrangement of the suction belt
  • Fig. 4 shows a suitable Yarrangement of means on the suction belt for cooperating with corresponding driving means on the tray belt.
  • Figs. 5 and 6 show cross-sectional details of the arrangement in Fig. 4.
  • Fig. l is a diagrammatical side elevation of a tray-belt filter.
  • An endless belt of trays I is rolling on wheels 2 on the frame-work I5. Inside this belt a suction belt 4 slides over a suction box 5.
  • the suction box is provided with partition walls 6 for collecting diierent filtrates and with outlets connected to recipients under vacuum.
  • Each tray is on both sides provided with cogs 3 on which act a couple of cog-Wheels 8, one on each side. In this way the belt is driven.
  • suitable connecting means or prongs 9 fastened to the bottom of the trays the tray belt drives the suction belt 4 with the same 4 velocity as its own and also with the same nurnber of rotations per hour, the two belts being of the same length.
  • connecting means 9 which have the form of prongs engage with pins I8 fastened to the suction belt, as shown in Figure 4.
  • Figure 1 In the right hand side of Figure 1 is seen how the rubber suction belt at the turning ends approaches the bottoms of the trays as previously described.
  • Figure l as well as Figure 2 shows the form of the prongs 9 which permit the suction belt to move in a vertical plane through the centre line of the belt in yaccordance with this approach at the turning points.
  • FIG 2 is a cross section through the :filter shown in Figure 1 on an enlarged scale taken through one of the trays in a horizontal position.
  • the tray I is moving on wheels 2 rolling on the frame-work I5 of the apparatus.
  • the wheel shafts form part of the cogs 3 which are operated on by the cog-Wheels 8.
  • the filtering trays are provided with perforated false inner bottoms l0 which are kept at some distance from the outer bottom. Over this inner bottom the filter cloth II is placed.
  • From the outer bottoms of the trays metal pipes I2 and rubber pipes I3 are provided for leading the iiltrates to the suction belt 4. Through T-formed channels in said belt are stuck metal pipes I4 which have openings communicating with the vertical channels leading to the suction box 5.
  • the elements I2, I3 and I4 constitute flexible tubes connecting the suction conduit with the lter trays.
  • the suction belt 4 slides over the suction box 5 and is pressed by the atmospheric pressure against its upper part.
  • the suction belt is driven by the prongs 9 which either can cooperates with the pipes I4 or with bolts or pipes I8 as shown in Figure 4.
  • Figure 3 shows an arrangement of the suction belt When it is desired to have this belt driven separately.
  • link chains I6 On each side of the suction belt 4 are placed link chains I6, both chains having lengthened bolts I7 placed through holes in the suction belt.
  • the means driving these chains should be connected to the cog-wheels 8 driving the tray-belt in such a Way that the number of revolutions of each belt during a certain time will be the same.
  • Figure 4 shows the arrangement of the pins or bolts I8 which are acted upon by the cooperating means mounted on the tray belt as already described.
  • Figure 4 also shows the T-formed channels I9 into which are stuck the pipes I4 shown in Fig. 2.
  • Figures 5 and 6 are cross-sectional details of the belt arrangement shown in Fig. 4.
  • a filtering device of the endless vessel-belt type comprising a frame, an endless trackway mounted on said frame, an elongated stationary suction box mounted at the top of said frame having a longitudinal channel connected with suction means, an endless vessel-belt supported by and movable along said trackway comprising a plurality of ltering trays mounted in series and adapted to move around said trackway, the bottoms of said trays serving as filters, an endless ⁇ suction belt having the same eiective length .and mounted concentrically with said vessel-belt 4to move along said trackway in Contact with said bsuction box to close the channel thereof, conduit means in said suction-belt communicating With said channel in an airtight manner, a plurality of ilexible conduits connecting said conduit means with each of the filter trays to produce suction at the bottoms thereof, means for driving said vessel-belt around said ltrackway and a plurality of connections between said vessel-belt and said suction-belt permitting relative movement in a radi
  • a ltering device of the endless vessel-belt type comprising a frame, an endless trackway mounted on said frame, an elongated stationary suction box mounted horizontally at the top of said frame having a longitudinal channel provided with a conduit for connection to a suction means, an endless vessel-belt supported by and movable along said trackway comprising a plurality of separate ltering trays mounted in series and adapted to move around said track- Way, the bottoms of said trays serving as filters, a separate endless suction-belt having 'the same eiective length as said vessel-belt and mounted concentrically with said vessel-belt to move along said trackway in contact with said suction box to close the channel thereof, conduit means in said suction-belt communicating with the suction box channel in an air-tight manner, flexible tubes connecting said conduit means with each of the lter trays individually to produce suction at the bottoms thereof and providing for relative radial movement between said belts as they pass around said trackway, and means permitting relative radial movement
  • conduit means in the suction belt is T-shaped, one branch of the T communicating with the channel of the suction box and the other branches extending transversely from the belt and being connected to said flexible tubes.

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  • Chemical & Material Sciences (AREA)
  • Chemical Kinetics & Catalysis (AREA)
  • Filtration Of Liquid (AREA)
  • Structure Of Belt Conveyors (AREA)

Description

Oct. 9, 1951 s. G, NORDENGREN 2,570,697
FILTERING APPARATUS Filed DSC. 2, 1947 Patented Oct. 9, 1951 oFFlcE" 22,570,697v y FIL'IIRING AiPAnA'rUs' Sven Gunnar' Nordengren, Landskrbna, Sweden Application Deeember 2, 1947,- sueeiai- No. 789,152' In Sweden December 11,1946.
4 claims. (ci. 21o-'1.97)
The present invention' relates to an improved apparatus of the vessel-belt type for filtering and' 'washing mixtures of solid and liquid substances.
In"` so-called belt-filtersy the main parts of whichconsist of a rubber belt with upstanding or"upturned sides sliding over a suction box, an auxiliary belt of anl elastic material is sometimes introduced between the'main belt and the suctionbo'x' in order to spare the main belt from Wearing effects. By n'ieans of channels in this s'o-called suction belt those parts of the main belt which are to be set under vacuum communicate with' the suction box; It is of no consequence which of 'the two belts is driving the other since the driven belt firmly adheres to the driving one on account of ther vacuum which is set up when bothibelts, 'closely vriressed together, are' driven overithe 'suction'box In fltersof the Sto-called' vessel-belt type, for example travelling traybelt nlters, the 'continu- Olisinan rubberbelt has" been changed to a belt made' upY 'of a series of vessels. These vessels arfe suitably provided-with perforated false inner bottomsover which the iter' ciotii is fastened.v Trie spacebetween the' two bottoms of 'each tray can be placed under vacuum by beingconnectedwith Channels inthe Sticft'oi'f belt, 'which' Channels in turn ar/e'connected to the suction box. It is, however', impossiblto causethe two belts to cooperate'in such a wayV that they will adhere to each other'l as an effect of thevacuum. This is preventedibythe' diiferent'wayin which the two belts behaveatl their turning points', where the. trays or vessels will follow a different pathy than the elastic suction belt. Another difficulty' is caused by'the fact that in larger"sizednlt"ers the individual filtering boxesioftheve'ssel belt4 have tobe supborted'by'wheels, and consequently cannot' be pressed by gravity' against the' suction belt which wol'dbe necessary ifi-order to establish a vacuumcciineetie b'y cireeveontaet between the t;W'0""be1tS.V 'y "'Th object of the present invention is to provi'deineans for' sttairii'ng a suitable cooperation between thevessel belt and the suction belt. According te the irivennorrthevessei beit is mountedtorevolv'e 'on' an endless trackway andis connected tothe suction belt'` in 'such a manner that the movement of' one controls the'movernent of the other' so that the two rn'ove simultaneously and retain the saine relative positions. 'Various fneans may lbe used -for'l connecting'th'e two belts suchasfa rigid connectionby' useof interlocking pins or' theyin'ay becon'nected by' the' cogs of an endless chain with' the cogs' interconnected to produce synchronization between the movement of the' belts so that a complete revolution of'one will result ina complete revolution of the other.
The vessel belt is preferably built in such a way that'a number of trays orboxes of the saine size are united@ to an endless belt. Between the trays are suitably mounted shafts connected with the trays bybendable joints. On said shafts are mounted wheels which support the trays and roll on the framework. In this way each link of the belt containing one tray or box Will be given a length equal to the distance between the centre lines of `two adjacent shafts. Oneway of driving the vessel belt is to equip each linkwith a row of cogs on each side and driven by a pairofcogwheels. With this construction no drums are needed at the turning ends of the beltsince the framework may be given such a form that the travelling course of the" belt is fixed by the wheels running `on the framework. If the trays are all made of equal size, which construction is recommended, the number of cogs in the Vessel belt will beV an even multiple of the number of vessels.
A suitable construction of the means for moving the flexible' suctionbe'lt is to let-'these' means be constituted of cogsr orl projecting parts of the belt itself cooperating with parts on thel vessel belt. Another possible construction is to place a link-chain on one or both sides of the suction belt and to lengthen the bolts'of the link chains so that they can be put through holes in the suction belt, vwhich in this case should be given a square or rectangular section with a relatively large height compared with the width.
Itis also possiblel to arrange the driving of the two belts insuch a way that one belt is driven by the other'. If this is to be performed in a direct way the outer circumference of the suction belt must be equal to the inner'fcircumference of the vessel belt, i. e. the effective lengths of the two belts must be the same. This is a consequence of the fact that if the velocities of the belts are equal and the revolutions per minute the same, the respective routes must also be equal. This fact can also be explained in the following way. When the suction belt is sliding over the suction box and at thevsame time is driving the vessel belt or is being driven by the same, each link of the vessel belt must correspond to a part of the suction belt of exactly the same length. Consequently the total effective length of both belts must be equal.
If this condition is fulfilled one belt can drive the other in a direct way. If, for instance, chains are mounted on both sides of the suction belt this belt can be driven by a pair of cog-Wheels. It is then possible to mount tractive means on the chains and to let those means act on corresponding means mounted on the vessel belt so that the latter belt will be driven with the same speed as the suction belt. It is also possible to mount tractive means on the vessel belt which act on corresponding means mounted on the suction belt, for instance in the form of bolts or pipes put through the said belt. This has in fact proved to be the best construction in practice. It is, however, to be observed that if both belts have the same eiective length the position of each belt will be completely xed in a vertical section as soon as the number of links at the turning points of the vessel belt has been fixed. The vessel belt is generally built in such a way that it is bent at its turning ends in a hexagonal or octagonal form. In a vertical and radial projection the distance between the two belts will be varying and the communicating means between them must therefore be constructed in such a way that the suction belt can move freely in a vertical plane through its centre line. The consequence of this is that the vacuum connections between the bottoms of the vessels and the suction belt must be made of a flexible material, for instance of rubber to lallow of such a movement.
It is recommended to give the channels in the suction belt a T-form permitting the ltrate from the vessels to enter from both sides horizontally and to pass to the suction box through a vertical :n
channel. Such T-formed channels should be arranged between the above mentioned connecting means mounted for the driving of the suction belt. It is also possible to let the pipes, which are placed horizontally in the T-formed channels, serve as means to be acted upon by the driving means mounted on the vessel belt. If the size of the lter is comparatively large two or more T-formed channels should be used for each vessel.
In the following are described suitable embodiments of the invention by way of example having reference to the accompanying drawing in which- Fig. 1 is -a diagrammatical side elevation of a tray-belt filter;
Fig. 2 is a vertical cross-section through the filter in Fig. 1 on a larger scale;
Fig. 3 shows an arrangement of the suction belt;
Fig. 4 shows a suitable Yarrangement of means on the suction belt for cooperating with corresponding driving means on the tray belt.
Figs. 5 and 6 show cross-sectional details of the arrangement in Fig. 4.
Similar parts are denoted by same numerals in all figures.
Fig. l is a diagrammatical side elevation of a tray-belt filter. An endless belt of trays I is rolling on wheels 2 on the frame-work I5. Inside this belt a suction belt 4 slides over a suction box 5. The suction box is provided with partition walls 6 for collecting diierent filtrates and with outlets connected to recipients under vacuum. Each tray is on both sides provided with cogs 3 on which act a couple of cog-Wheels 8, one on each side. In this way the belt is driven. By means of suitable connecting means or prongs 9, fastened to the bottom of the trays the tray belt drives the suction belt 4 with the same 4 velocity as its own and also with the same nurnber of rotations per hour, the two belts being of the same length. These connecting means 9 which have the form of prongs engage with pins I8 fastened to the suction belt, as shown in Figure 4. In the right hand side of Figure 1 is seen how the rubber suction belt at the turning ends approaches the bottoms of the trays as previously described. Figure l as well as Figure 2 shows the form of the prongs 9 which permit the suction belt to move in a vertical plane through the centre line of the belt in yaccordance with this approach at the turning points.
Figure 2 is a cross section through the :filter shown in Figure 1 on an enlarged scale taken through one of the trays in a horizontal position. The tray I is moving on wheels 2 rolling on the frame-work I5 of the apparatus. The wheel shafts form part of the cogs 3 which are operated on by the cog-Wheels 8. The filtering trays are provided with perforated false inner bottoms l0 which are kept at some distance from the outer bottom. Over this inner bottom the filter cloth II is placed. From the outer bottoms of the trays metal pipes I2 and rubber pipes I3 are provided for leading the iiltrates to the suction belt 4. Through T-formed channels in said belt are stuck metal pipes I4 which have openings communicating with the vertical channels leading to the suction box 5. The elements I2, I3 and I4 constitute flexible tubes connecting the suction conduit with the lter trays. The suction belt 4 slides over the suction box 5 and is pressed by the atmospheric pressure against its upper part. The suction belt is driven by the prongs 9 which either can cooperates with the pipes I4 or with bolts or pipes I8 as shown in Figure 4.
Figure 3 shows an arrangement of the suction belt When it is desired to have this belt driven separately. On each side of the suction belt 4 are placed link chains I6, both chains having lengthened bolts I7 placed through holes in the suction belt. The means driving these chains should be connected to the cog-wheels 8 driving the tray-belt in such a Way that the number of revolutions of each belt during a certain time will be the same.
Figure 4 shows the arrangement of the pins or bolts I8 which are acted upon by the cooperating means mounted on the tray belt as already described. Figure 4 also shows the T-formed channels I9 into which are stuck the pipes I4 shown in Fig. 2. Figures 5 and 6 are cross-sectional details of the belt arrangement shown in Fig. 4.
I claim:
1. A filtering device of the endless vessel-belt type comprising a frame, an endless trackway mounted on said frame, an elongated stationary suction box mounted at the top of said frame having a longitudinal channel connected with suction means, an endless vessel-belt supported by and movable along said trackway comprising a plurality of ltering trays mounted in series and adapted to move around said trackway, the bottoms of said trays serving as filters, an endless `suction belt having the same eiective length .and mounted concentrically with said vessel-belt 4to move along said trackway in Contact with said bsuction box to close the channel thereof, conduit means in said suction-belt communicating With said channel in an airtight manner, a plurality of ilexible conduits connecting said conduit means with each of the filter trays to produce suction at the bottoms thereof, means for driving said vessel-belt around said ltrackway and a plurality of connections between said vessel-belt and said suction-belt permitting relative movement in a radial direction between said belts for driving the latter at the same velocity and revolutions per minute as the former.
2. A ltering device of the endless vessel-belt type comprising a frame, an endless trackway mounted on said frame, an elongated stationary suction box mounted horizontally at the top of said frame having a longitudinal channel provided with a conduit for connection to a suction means, an endless vessel-belt supported by and movable along said trackway comprising a plurality of separate ltering trays mounted in series and adapted to move around said track- Way, the bottoms of said trays serving as filters, a separate endless suction-belt having 'the same eiective length as said vessel-belt and mounted concentrically with said vessel-belt to move along said trackway in contact with said suction box to close the channel thereof, conduit means in said suction-belt communicating with the suction box channel in an air-tight manner, flexible tubes connecting said conduit means with each of the lter trays individually to produce suction at the bottoms thereof and providing for relative radial movement between said belts as they pass around said trackway, and means permitting relative radial movement between said belts for driving saidvessel-belt and said suction-belt in synchronism at the same velocity and revolutions per minute so that they move simultaneously and retain the same relative positions as they pass around the endless trackway.
3. The filtering device of claim 2 in which only one of said endless belts is positively driven and connecting means are provided between the two belts to drive the second belt whereby their movements are synchronized to retain them in the same relative positions as they revolve around the endless trackway.
4. The filtering device of claim 2 in which the conduit means in the suction belt is T-shaped, one branch of the T communicating with the channel of the suction box and the other branches extending transversely from the belt and being connected to said flexible tubes.
SVEN GUNNAR NORDENGREN.
REFERENCES CITED The following references are of record in the iile of this patent:
UNITED STATES PATENTS Number Name Date 910,075 Lynch Jan. 19,'1909 1,793,449 Bassler Feb. 17, 1931 1,862,050 Donaldson June 7, 1932 2,094,350 Cartigny Sept. 28, 1937 2,314,294 Wallny Mar. 16, 1943 2,342,468 Hallwood Feb. 22, 1944 2,377,252 Lehrecke May 29, 1945
US789152A 1946-12-11 1947-12-02 Filtering apparatus Expired - Lifetime US2570697A (en)

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Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2677467A (en) * 1953-01-06 1954-05-04 Dorr Co Traveling tray-belt filter
US2873028A (en) * 1955-09-06 1959-02-10 Bried Henry Francis Filters
US2895614A (en) * 1955-12-12 1959-07-21 Komline Sanderson Eng Corp Filtering unit
US2935200A (en) * 1956-06-06 1960-05-03 Dorr Oliver Inc Pan seal for travelling pan filter
US3097653A (en) * 1957-02-01 1963-07-16 Gooijer Gerrit De Tobacco sheet and method of making same
US3460674A (en) * 1966-09-09 1969-08-12 William S Eakins Apparatus and method for continuous filtering

Families Citing this family (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPS5354368A (en) * 1976-10-28 1978-05-17 Asahi Glass Co Ltd Continuous solid and liquid separator
NL173603C (en) * 1978-10-20 1984-02-16 Esmil Bv VACUUM FILTER BELT INSTALLATION.

Citations (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US910075A (en) * 1905-10-23 1909-01-19 Edward P Lynch Apparatus for extracting liquids from ores or other substances.
US1793449A (en) * 1927-11-01 1931-02-17 D J Murray Mfg Company Filter
US1862050A (en) * 1928-11-12 1932-06-07 Donaldson George Automatic filtering apparatus
US2094350A (en) * 1935-06-26 1937-09-28 Kemiska Patenter Ab Filtering apparatus
US2314294A (en) * 1937-07-16 1943-03-16 Wallny John Gunnar Apparatus for filtering and washing solid matter
US2342468A (en) * 1940-07-05 1944-02-22 Nathan A Hallwood Food preserving and storage apparatus
US2377252A (en) * 1942-07-28 1945-05-29 Kemiska Patenter Ab Filtering apparatus

Patent Citations (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US910075A (en) * 1905-10-23 1909-01-19 Edward P Lynch Apparatus for extracting liquids from ores or other substances.
US1793449A (en) * 1927-11-01 1931-02-17 D J Murray Mfg Company Filter
US1862050A (en) * 1928-11-12 1932-06-07 Donaldson George Automatic filtering apparatus
US2094350A (en) * 1935-06-26 1937-09-28 Kemiska Patenter Ab Filtering apparatus
US2314294A (en) * 1937-07-16 1943-03-16 Wallny John Gunnar Apparatus for filtering and washing solid matter
US2342468A (en) * 1940-07-05 1944-02-22 Nathan A Hallwood Food preserving and storage apparatus
US2377252A (en) * 1942-07-28 1945-05-29 Kemiska Patenter Ab Filtering apparatus

Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2677467A (en) * 1953-01-06 1954-05-04 Dorr Co Traveling tray-belt filter
US2873028A (en) * 1955-09-06 1959-02-10 Bried Henry Francis Filters
US2895614A (en) * 1955-12-12 1959-07-21 Komline Sanderson Eng Corp Filtering unit
US2935200A (en) * 1956-06-06 1960-05-03 Dorr Oliver Inc Pan seal for travelling pan filter
US3097653A (en) * 1957-02-01 1963-07-16 Gooijer Gerrit De Tobacco sheet and method of making same
US3460674A (en) * 1966-09-09 1969-08-12 William S Eakins Apparatus and method for continuous filtering

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DE911129C (en) 1954-05-10

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