US1342651A - Apparatus for the electrical treatment of gases - Google Patents

Apparatus for the electrical treatment of gases Download PDF

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US1342651A
US1342651A US241430A US24143018A US1342651A US 1342651 A US1342651 A US 1342651A US 241430 A US241430 A US 241430A US 24143018 A US24143018 A US 24143018A US 1342651 A US1342651 A US 1342651A
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electrodes
casing
gases
electrical treatment
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Harold W Squires
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    • 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
    • B03CMAGNETIC OR ELECTROSTATIC SEPARATION OF SOLID MATERIALS FROM SOLID MATERIALS OR FLUIDS; SEPARATION BY HIGH-VOLTAGE ELECTRIC FIELDS
    • B03C3/00Separating dispersed particles from gases or vapour, e.g. air, by electrostatic effect
    • B03C3/34Constructional details or accessories or operation thereof
    • B03C3/36Controlling flow of gases or vapour
    • 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
    • B03CMAGNETIC OR ELECTROSTATIC SEPARATION OF SOLID MATERIALS FROM SOLID MATERIALS OR FLUIDS; SEPARATION BY HIGH-VOLTAGE ELECTRIC FIELDS
    • B03C3/00Separating dispersed particles from gases or vapour, e.g. air, by electrostatic effect
    • B03C3/02Plant or installations having external electricity supply
    • B03C3/04Plant or installations having external electricity supply dry type
    • B03C3/06Plant or installations having external electricity supply dry type characterised by presence of stationary tube electrodes

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  • This invention relates to apparatus for the electrical treatment of gases and more particularly to the class of apparatus used for separating from gases, particles held in suspension therein.
  • Fi ure 1 is an elevation of a device embodylng the invention, a part ofthe casing being broken away;
  • Fig. 2 is avertical section on line 22 of Fig. 1;
  • Fig. 3 is a section on line 3-3 of Fig. 2;
  • Fig. 4 is a plan view, the portion above the line 44, Fig. 2 being removed;
  • Fig. 5 is a vertical section through a modified form of treater
  • Fig. 6 is a vertical section through another modification.
  • Fig. 7 is a vertical section through still another modification.
  • 1 is a casing for the treater elements.
  • the gas to be cleaned may be admitted through one or more flues 2 and the clean gas passes into the top of the apparatus from whence it may pass into the atmosphere or may be conducted to a place for additional treatment or for consumption.
  • the arrangement may be reversed so that the gases enter at the top and pass out at the bottom.
  • the treater unit comprises a plurality of collecting electrodes 3 and a plurality of discharge electrodes 4 in alternating superposed relation. Both the collecting electrodes and the discharge electrodes have the form of hipped roofs and may be made of a The discharge electrodes are held in spaced relation to the walls of the casing 1 and insulated therefrom by suitable insulators.
  • the discharge electrodes are supported by elements 5 of conducting material insulated from the casing by insulator bushings 6. These elements serve also the purpose of conducting the current to the electrodes from bus bars 7 which may be supported on the outer surface of the casing 1 by insulators 8.
  • the collecting electrodes extend to the walls of the casing and make a substantially air and water-tight connection therewith.
  • the outer surface of the walls of the casing are disposed as many troughs 9 as there are collecting electrodes and these troughs are in communication with the collecting electrodes through a series of openmgs 10 in the walls of the casing.
  • the top of the collecting electrodes may be perforated or entirely open to form a passage for the gases.
  • the lower edge of the discharge electrode 4 may be advantageously stiffened by a small pipe 11 and the edge defined by the opening 12 in the collecting electrode may be similarly stiffened by a pipe 13.
  • This lower surface of the collecting electrode through the wall-of the casing 1 and communicate with a suitable source of liquid under pressure.
  • the collecting electrode structures may be additionally strengthened by braces across the openings 12.
  • the discharge electrodes are provided with prongs 17 to facilitate the formation of an intense corona discharge directed to the collecting electrode'aj
  • These prongs may be formed in any desired manner.
  • ribs might be formed on the surface of the electrodes. Such ribs placed transversely of the direction of gas flow would avoid a dead space adjacent the surface of the electrode.
  • the gas to be treated is admitted through the flues 2, rises through a central flue or fiues 18, then passes through the opening 12 of the lowermost collecting electrode 3 into the space defined by the latter and the first discharge electrode 4 down close to the wall of the casing, then flows upwardly through the space between the discharge ele ctrode changed in various ways.
  • the liquid discharged from pipes 13 forms a film or sheet of continuously flowing liquid whichcarries the particles down with it and discharges them through openings 10 into the troughs 9 where the material may be collected for further treatment or discharged.
  • openings 10 and the troughs are so proportioned that the liquid in the trough forms a li uid seal for the gas in the treater.
  • the precipitated particles may slide down the sloping surface of the collecting electrodes by gravity and may be collected in suitable receptacles outside the walls of the casing.
  • the spacing between consecutive pairs of electrodes may successively vary in accordance with the gradually changing conditions of the gas during its passage through the treater and the consequential change of the dielectric.
  • the length of the discharge points or prongs 17 may be successively changed in proportion to the change of dielectric strength of the gas in the treater.
  • the space between alternately smooth surfaces of the electrodes may be narrower than the space between the working surfaces.
  • the arrangement shown can by slight modification be changed to a downdraft system.
  • the direction of gas flow is aloruptly changed at frequent intervals so that separation of suspended particles is facilitated by centrifugal force as well as by electric discharge.
  • the shape of the electrodes may be Instead of a hipped roof, the electrodes may assume the form of a gable roof or of a cone as indicated in Fig. 5. In this'case the frame is cylindrical.
  • the discharge electrode system may be mounted 23 to the negative pole of a rectifier, the
  • the collecting electrodes 26 are in all respects similar to the collecting elecl trodes previously-described.
  • the discharge electrodes 23 are connected in the usual way to the source of current, preferably to the negative pole thereof. As indicated the discharge electrode may be interconnected by a conductor 23 disposed on the pole 20 and one of them may be connected by a conductor 23 nassin through an insulator bushing positive pole being connected to the collecting electrodes and to ground.
  • r 1g. 6 is shown a device similar to that disclosed in Fig. 5. All the electrodes extend substantially to the same horizontal plane.
  • the collecting electrodes 30 extend directly to the floor or other support, while the discharge electrodes 31 terminate a dis; tance from it to provide insulationand afford a passage-way for the gas from one electrode unit to another.
  • the precipitated material may be collected in hoppers 32 or in a single hoover as desired.
  • 33 and 34 are pipes for feeding liquid to the distributers.
  • both electrodes are used as discharge'and collecting electrodes.
  • Pron'gs 41 are placed on the under side of the electrodes 40 which are connected to one terminal of the source of supplv and prongs 43 are placed on the under side of the electrodes 42 which are connected to the opposite terminal.
  • the prongs 41 cause substantially unidirectional migration of ions of one sign from electrode 40 to the smooth top surface of electrode 42 while the prongs 43 cause migration of ions from the electrode 42 to the smooth upper surface of the electrode 40 next following.
  • the spacing of the electrodes is made uniform, while in connection with D. G. the electrodes are preferably alternately spaced for negative and positive discharge. It is well known that by causing the discharge to pass mainly from the negative electrode to the positive electrode the *potential difference may be increased without disrupting the dielectric. Applying this principle to the present case, it is obvious that the discharge distance'between the negativelycharged prongs and the cooperating In Fig. 7 the electrodes 40 are connected to the negative pole and the electrodes 42 to the positive pole of a source of unidirectional current. Prongs 43 are also provided on the roof 44.
  • the ca acity of the treater is thus ap roximatel oubled as compared v. ith the orms of device shown in the preceding figures.-
  • roof-shaped is intended to include all sloping structures having a plurality of angularly related sides.
  • annular is intended to define an area confinedbetween two reentrant lines or two lines closed upon themselves, irrespective of the exact shape.
  • Apparatus for the electrical treatment of gases comprising a pair of sloping electrodes defining a passageway for the gas substantially annular in cross-section,- and means for causing the gas to be treated to pass through said passageway.
  • Apparatus for the electrical treatment of gases comprising a pair of sloping electrodes defining a passageway for the gas substantially annular in cross-section, and means for irrigatingthe lower of said electrodes.
  • Apparatus for the electrical treatment of gases comprising a pair of sloping electrodes defining a passageway for the gas substantially annular in cross-section, means for causing all the gas to be treated to pass through said passageway, and means for collecting the precipitated matter at the bottom of the electrodes.
  • Apparatus for the electrical treatment of gases comprising a pair of sloping electrodes defining a passageway for the gas substantially annular in cross section, means for passing the gas through said passageway in a downward direction and away in an upward direction, and mean for collecting the precipitated matter at the bottom of the electrodes.
  • Apparatus for the electrical treatmentof gases comprising a substantially air-tight casing having an inlet and an outlet, and a pair of sloping electrodes defining a passageway substantially annular in cross-section, said electrodes being so disposed within the casing that all the gas passing through the casing must pass through the said passagewav.
  • Apparatus for the electrical treatment of gases comprising a substantially air-tight casing having an inlet and an outlet, and a pair of sloping electrodes defining a passageway substantially annular in cross-section, one of said electrodes being connected at its bottom with the casing to make a tight fit therewith and being open at its top, the other of said electrodes being spaced from the casing at its bottom and closed at its top.
  • Apparatus for the electrical treatment of gases comprising a substantially air-tight casing having an inlet and an outlet, and a pair of slowing electrodes defining a passageway substantially annular in cross-section, one of said electrodes being connected at its bottom with the casing to make a tight fit therewith and being open at its top, the other of said electrodes being spaced from the casing at its bottom and closed at its top, means connected with the first, of said electrodes for producing thereon a continuous film of flowing liquid, means near the.
  • Apparatus for the electrical treatment of gases comprising .a plurality .of roofshaped elements arranged in superposed spaced relation to alternately form discharge electrodes and collecting electrodes, and means for successively conducting the gas to be treated through the spaces defined by the said elements.
  • Apparatus for the electrical treatment of gases comprising a substantially air-tight casing having an inlet and an outlet, a plurality of roof-shaped elements arranged in the casing in superposed spaced relation to alternately form discharge electrodes and collecting electrodes, said electrodes and said casing being so related that all the gas passing through the casing must pass successively through the spaces defined by said elements.
  • Apparatus for the electrical treatment of gases comprising a substantially air-tight casing having an inlet and an outlet, a plurality of superposed roof-shaped elements in the casing constituting alternately discharge electrodes and collectin electrodes, the collecting electrodes being connected at their bottom portion to the casing to make a tight fit therewith and being open at the top, the discharge electrodes being spaced from the casing and being closed at the top, and openings near the bottom of each collecting electrode through the walls of the casing for withdrawing precipitated material. 4
  • Apparatus for the electrical treatment of gases comprising an air-tight casing having an inlet and an outlet, a roofshaped electrode within the casing forming a diaphragm, said electrode having a central aperture, a roof-shaped electrode in superposed relation'to the first electrode to define a symmetrical passageway for the gas, said latter electrode being electrically in- I sulated from the former and spaced from the walls of the casing to define a passageway for the gas.
  • Apparatus for the electrical treatment of gases comprising a plurality of spaced plates alternately connected to op- Apparatus for the electrical treatment of gasescomprising a plurality of spaced plates alternately connected to the opposite poles of a source of electric current, each plate having one surface smooth and the other surface provided with means for facilitating corona discharge, said means on all the plates facing in the same direction.
  • Apparatus for the electrical treatment of gases comprising a substantially air-ti ht casing having an inlet and an outlet, a p urality of roof-shaped elements arranged in thecasin r in superposed spaced relation and alternate y connected to the opposite poles of a source of electric current, each element having one surface smooth and the other surface provided with means facilitating corona discharge, said means on all the said elements facing in one direction.

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  • Treating Waste Gases (AREA)

Description

H. W. SQUIR ES. APPARATUS FOR THE ELECTRICAL TREATMENT OF GASES APPLICATION FILED JUNE 22,1918.
1,342,651. Patented June 8,1920.
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APPARATUS FOR THE ELECTRICAL TREATMENT OF GASES.
APPLICATION FILED JUNE 22, 1918.
42,651 Patented June 8, 1920.
YSHEETS-SHEET Z- awvewtoz H. W. SQUIRES. APPARATUS FOR THE ELECTRICAL TREATMENT OF .GASES.
APPLICATION FILED JUNE 22., 1.918.
Patented J1me 8, 1920.
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wuuxtoz H. W. SQUIRES. APPARATUS FOR THE ELECTRICAL TREATMENT OF GASES. APPLICATION, FILED JUNE 22,1918.
1,342,655 1 Patented June 8, 1920.
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(1mm as J H. w'. SQUIBES. APPARATUS FOR THE ELECTRICAL TREATMENT OF GASES.
APPLICATION FILED JUNE 22 I918.
1,342,65 1. Patented June 8, 1920.
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TH'HNSFORMER L I INMJ RECTIFIER 2 "/x H. W. SQUIRES. APPARATUS FOR THE ELECTRICAL TREATMENT OF GASES.
APPLICATION FLLED. JUNE 22. 1 918.
1,342,651 PatentedJune 8, 1920.
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H. W. SQUIRES. APPARATUS FOR THE ELECTRICAL TREATMENT OF GASES.
APPLICATION FILED JUNE 22,1918- 1,342,651 Pa entedJune 8, 1920.
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7766 Tina UNITED STATES PATENT OFFICE.
HAROLD W. SQUIRES, OF- AMITYVILI E, NEW YORK, ASSIGNOR T0 RESEARCH CORPORATION, OF NEW YORK, N. Y., A CORPORATION OF NEW YORK.
APPARATUS FOR THE ELECTRICAL TREATMENT OF GASES.
Specification of Letters Patent.
Patented June 8, 1920.
Application filed June 22, 1918. Serial No. 241,430.
l-\mityville, L. I., in the county of Suffolk and State of New York, have invented certain new and useful Improvements in Apparatus for the Electrical Treatment of Gases, of which the following is a specification.
This invention relates to apparatus for the electrical treatment of gases and more particularly to the class of apparatus used for separating from gases, particles held in suspension therein.
It is the purpose of the invention to provide an apparatus of the class referred to in which a maximum of the space taken up by the apparatus is effectively utllized.
With this object in View the invention consists in the construction and arrangement of parts more fully described in the specification and more particularly pointed out in the claims.
In the drawings which form a part of the specification,-
Fi ure 1 is an elevation of a device embodylng the invention, a part ofthe casing being broken away;
Fig. 2 is avertical section on line 22 of Fig. 1;
Fig. 3 is a section on line 3-3 of Fig. 2;
Fig. 4; is a plan view, the portion above the line 44, Fig. 2 being removed;
Fig. 5 is a vertical section through a modified form of treater;
Fig. 6 is a vertical section through another modification; and
Fig. 7 is a vertical section through still another modification. I
Having reference to Figs. 1-4, 1 is a casing for the treater elements. The gas to be cleaned may be admitted through one or more flues 2 and the clean gas passes into the top of the apparatus from whence it may pass into the atmosphere or may be conducted to a place for additional treatment or for consumption. The arrangement, however, may be reversed so that the gases enter at the top and pass out at the bottom. The treater unit comprises a plurality of collecting electrodes 3 and a plurality of discharge electrodes 4 in alternating superposed relation. Both the collecting electrodes and the discharge electrodes have the form of hipped roofs and may be made of a The discharge electrodes are held in spaced relation to the walls of the casing 1 and insulated therefrom by suitable insulators. In the construction shown the discharge electrodes are supported by elements 5 of conducting material insulated from the casing by insulator bushings 6. These elements serve also the purpose of conducting the current to the electrodes from bus bars 7 which may be supported on the outer surface of the casing 1 by insulators 8.
The collecting electrodes extend to the walls of the casing and make a substantially air and water-tight connection therewith. Along the outer surface of the walls of the casing are disposed as many troughs 9 as there are collecting electrodes and these troughs are in communication with the collecting electrodes through a series of openmgs 10 in the walls of the casing. The top of the collecting electrodes may be perforated or entirely open to form a passage for the gases.
The lower edge of the discharge electrode 4 may be advantageously stiffened by a small pipe 11 and the edge defined by the opening 12 in the collecting electrode may be similarly stiffened by a pipe 13. This lower surface of the collecting electrode through the wall-of the casing 1 and communicate with a suitable source of liquid under pressure. If desired, the collecting electrode structures may be additionally strengthened by braces across the openings 12. y
The discharge electrodesare provided with prongs 17 to facilitate the formation of an intense corona discharge directed to the collecting electrode'aj These prongs may be formed in any desired manner. In place of points 17 ribs might be formed on the surface of the electrodes. Such ribs placed transversely of the direction of gas flow would avoid a dead space adjacent the surface of the electrode.
The gas to be treated is admitted through the flues 2, rises through a central flue or fiues 18, then passes through the opening 12 of the lowermost collecting electrode 3 into the space defined by the latter and the first discharge electrode 4 down close to the wall of the casing, then flows upwardly through the space between the discharge ele ctrode changed in various ways.
and the'wall into the space between the discharge electrode'and thenext collecting electrbde and upwardly therethrough, then through the opening 12 of the second collecting electrode and so on until it finally passes out through the top of the roof of the casing. During its passage through the electric field produced between the electrodes, the dust and other particles suspended in the .gases are precipitated and deposited on the collecting electrodes as is well understood. The liquid discharged from pipes 13 forms a film or sheet of continuously flowing liquid whichcarries the particles down with it and discharges them through openings 10 into the troughs 9 where the material may be collected for further treatment or discharged.
As is particularly indicated in Fig. 2, the,
openings 10 and the troughs are so proportioned that the liquid in the trough forms a li uid seal for the gas in the treater.
hile the application of liquidoffers definite advantages, it is not necessary for successful operation of the apparatus. The precipitated particles may slide down the sloping surface of the collecting electrodes by gravity and may be collected in suitable receptacles outside the walls of the casing.
The spacing between consecutive pairs of electrodes may successively vary in accordance with the gradually changing conditions of the gas during its passage through the treater and the consequential change of the dielectric. I
It is also obvious that the length of the discharge points or prongs 17 may be successively changed in proportion to the change of dielectric strength of the gas in the treater.
In the arrangement shown and described the space between alternately smooth surfaces of the electrodes may be narrower than the space between the working surfaces.
The arrangement shown can by slight modification be changed to a downdraft system. In this form of treater the direction of gas flow is aloruptly changed at frequent intervals so that separation of suspended particles is facilitated by centrifugal force as well as by electric discharge.
. The shape of the electrodes may be Instead of a hipped roof, the electrodes may assume the form of a gable roof or of a cone as indicated in Fig. 5. In this'case the frame is cylindrical. For relatively small units the discharge electrode system may be mounted 23 to the negative pole of a rectifier, the
lipes 25 or other stiffening means may be applied to the lower edge to prevent'buckling similar to the construction shown in Figs. l-4. The collecting electrodes 26 are in all respects similar to the collecting elecl trodes previously-described. The discharge electrodes 23 are connected in the usual way to the source of current, preferably to the negative pole thereof. As indicated the discharge electrode may be interconnected by a conductor 23 disposed on the pole 20 and one of them may be connected by a conductor 23 nassin through an insulator bushing positive pole being connected to the collecting electrodes and to ground.
- In r 1g. 6 is shown a device similar to that disclosed in Fig. 5. All the electrodes extend substantially to the same horizontal plane. The collecting electrodes 30 extend directly to the floor or other support, while the discharge electrodes 31 terminate a dis; tance from it to provide insulationand afford a passage-way for the gas from one electrode unit to another. In this form the precipitated material may be collected in hoppers 32 or in a single hoover as desired. 33 and 34 are pipes for feeding liquid to the distributers.
In the form of device shown in Fig. 7 both electrodes are used as discharge'and collecting electrodes. Pron'gs 41 are placed on the under side of the electrodes 40 which are connected to one terminal of the source of supplv and prongs 43 are placed on the under side of the electrodes 42 which are connected to the opposite terminal. The prongs 41 cause substantially unidirectional migration of ions of one sign from electrode 40 to the smooth top surface of electrode 42 while the prongs 43 cause migration of ions from the electrode 42 to the smooth upper surface of the electrode 40 next following.
In connection with the use of A. C. the spacing of the electrodes is made uniform, while in connection with D. G. the electrodes are preferably alternately spaced for negative and positive discharge. It is well known that by causing the discharge to pass mainly from the negative electrode to the positive electrode the *potential difference may be increased without disrupting the dielectric. Applying this principle to the present case, it is obvious that the discharge distance'between the negativelycharged prongs and the cooperating In Fig. 7 the electrodes 40 are connected to the negative pole and the electrodes 42 to the positive pole of a source of unidirectional current. Prongs 43 are also provided on the roof 44.
The ca acity of the treater is thus ap roximatel oubled as compared v. ith the orms of device shown in the preceding figures.-
In the claims the term roof-shaped is intended to include all sloping structures having a plurality of angularly related sides.
The term annular is intended to define an area confinedbetween two reentrant lines or two lines closed upon themselves, irrespective of the exact shape.
I claim:
1. Apparatus for the electrical treatment of gases comprising a pair of sloping electrodes defining a passageway for the gas substantially annular in cross-section,- and means for causing the gas to be treated to pass through said passageway.
2. Apparatus for the electrical treatment of gases comprising a pair of sloping electrodes defining a passageway for the gas substantially annular in cross-section, and means for irrigatingthe lower of said electrodes.
3. Apparatus for the electrical treatment of gases comprising a pair of sloping electrodes defining a passageway for the gas substantially annular in cross-section, means for causing all the gas to be treated to pass through said passageway, and means for collecting the precipitated matter at the bottom of the electrodes.
4. Apparatus for the electrical treatment of gases comprising a pair of sloping electrodes defining a passageway for the gas substantially annular in cross section, means for passing the gas through said passageway in a downward direction and away in an upward direction, and mean for collecting the precipitated matter at the bottom of the electrodes. 1
Apparatus for the electrical treatmentof gases comprising a substantially air-tight casing having an inlet and an outlet, and a pair of sloping electrodes defining a passageway substantially annular in cross-section, said electrodes being so disposed within the casing that all the gas passing through the casing must pass through the said passagewav.
(3. Apparatus for the electrical treatment of gases comprising a substantially air-tight casing having an inlet and an outlet, and a pair of sloping electrodes defining a passageway substantially annular in cross-section, one of said electrodes being connected at its bottom with the casing to make a tight fit therewith and being open at its top, the other of said electrodes being spaced from the casing at its bottom and closed at its top.
nected at its bottom with the casing to make a tight fit therewith and being open at its top, the other of said electrodes being spaced from the casing at its bottom and closed at its top, and means near the bot-- tom of the electrodes for withdrawing precipitated material from the casing.
8. Apparatus for the electrical treatment of gases comprising a substantially air-tight casing having an inlet and an outlet, and a pair of slowing electrodes defining a passageway substantially annular in cross-section, one of said electrodes being connected at its bottom with the casing to make a tight fit therewith and being open at its top, the other of said electrodes being spaced from the casing at its bottom and closed at its top, means connected with the first, of said electrodes for producing thereon a continuous film of flowing liquid, means near the.
bottom of said first electrode for drawing off the liquid from the casing, and means for forming a liquid seal.
9. Apparatus for the electrical treatment of gases comprising .a plurality .of roofshaped elements arranged in superposed spaced relation to alternately form discharge electrodes and collecting electrodes, and means for successively conducting the gas to be treated through the spaces defined by the said elements.
10. Apparatus for the electrical treatment of gases comprising a substantially air-tight casing having an inlet and an outlet, a plurality of roof-shaped elements arranged in the casing in superposed spaced relation to alternately form discharge electrodes and collecting electrodes, said electrodes and said casing being so related that all the gas passing through the casing must pass successively through the spaces defined by said elements.
. 11. Apparatus for the electrical treatment of gases comprising a substantially air-tight casing having an inlet and an outlet, a plurality of superposed roof-shaped elements in the casing constituting alternately discharge electrodes and collectin electrodes, the collecting electrodes being connected at their bottom portion to the casing to make a tight fit therewith and being open at the top, the discharge electrodes being spaced from the casing and being closed at the top, and openings near the bottom of each collecting electrode through the walls of the casing for withdrawing precipitated material. 4
12. Apparatus for the electrical treatment of gases comprising an air-tight casing having an inlet and an outlet, a roofshaped electrode within the casing forming a diaphragm, said electrode having a central aperture, a roof-shaped electrode in superposed relation'to the first electrode to define a symmetrical passageway for the gas, said latter electrode being electrically in- I sulated from the former and spaced from the walls of the casing to define a passageway for the gas.
'13. Apparatus for the electrical treatment of gases comprising a plurality of spaced plates alternately connected to op- Apparatus for the electrical treatment of gasescomprising a plurality of spaced plates alternately connected to the opposite poles of a source of electric current, each plate having one surface smooth and the other surface provided with means for facilitating corona discharge, said means on all the plates facing in the same direction.
15. Apparatus for the electrical treatment of gases comprising a substantially air-ti ht casing having an inlet and an outlet, a p urality of roof-shaped elements arranged in thecasin r in superposed spaced relation and alternate y connected to the opposite poles of a source of electric current, each element having one surface smooth and the other surface provided with means facilitating corona discharge, said means on all the said elements facing in one direction. 7
In testimony whereof 'I afiix my signature.
' HAROLD W. SQUIRES.
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Cited By (11)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2614652A (en) * 1951-08-13 1952-10-21 Research Corp Electrical precipitator
US2726731A (en) * 1951-08-29 1955-12-13 Air Maze Corp Rigid charging electrode for electrostatic filter
DE1036819B (en) * 1955-10-20 1958-08-21 Dr Phil Holger Lueder Device for the electrical separation of floating bodies from gases under increased pressure
DE1084247B (en) * 1955-03-18 1960-06-30 Dr Gaylord W Penney Electrostatic precipitator
US3248857A (en) * 1961-09-27 1966-05-03 Metallgesellschaft Ag Chlorine filter
US3533222A (en) * 1965-09-01 1970-10-13 Mediterranea Compagnia Ind Com De-dusting device for smoke and other gaseous fluids
DE1557031B2 (en) * 1967-04-19 1971-08-26 Berckheim Graf Von ELECTRIC SEPARATOR
US3785118A (en) * 1972-03-22 1974-01-15 Mead Corp Apparatus and method for electrical precipitation
US3948625A (en) * 1972-07-24 1976-04-06 Environmental Master Systems, Inc. Irradiation and electrostatic separator
US4496375A (en) * 1981-07-13 1985-01-29 Vantine Allan D Le An electrostatic air cleaning device having ionization apparatus which causes the air to flow therethrough
US4861355A (en) * 1987-04-06 1989-08-29 Lawrence Macrow Ionizer diffuser air purifier

Cited By (11)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2614652A (en) * 1951-08-13 1952-10-21 Research Corp Electrical precipitator
US2726731A (en) * 1951-08-29 1955-12-13 Air Maze Corp Rigid charging electrode for electrostatic filter
DE1084247B (en) * 1955-03-18 1960-06-30 Dr Gaylord W Penney Electrostatic precipitator
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