US3042602A - Horizontal electrolytic cell - Google Patents
Horizontal electrolytic cell Download PDFInfo
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- US3042602A US3042602A US66378A US6637860A US3042602A US 3042602 A US3042602 A US 3042602A US 66378 A US66378 A US 66378A US 6637860 A US6637860 A US 6637860A US 3042602 A US3042602 A US 3042602A
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- C—CHEMISTRY; METALLURGY
- C25—ELECTROLYTIC OR ELECTROPHORETIC PROCESSES; APPARATUS THEREFOR
- C25B—ELECTROLYTIC OR ELECTROPHORETIC PROCESSES FOR THE PRODUCTION OF COMPOUNDS OR NON-METALS; APPARATUS THEREFOR
- C25B11/00—Electrodes; Manufacture thereof not otherwise provided for
- C25B11/02—Electrodes; Manufacture thereof not otherwise provided for characterised by shape or form
- C25B11/033—Liquid electrodes
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- C—CHEMISTRY; METALLURGY
- C25—ELECTROLYTIC OR ELECTROPHORETIC PROCESSES; APPARATUS THEREFOR
- C25B—ELECTROLYTIC OR ELECTROPHORETIC PROCESSES FOR THE PRODUCTION OF COMPOUNDS OR NON-METALS; APPARATUS THEREFOR
- C25B9/00—Cells or assemblies of cells; Constructional parts of cells; Assemblies of constructional parts, e.g. electrode-diaphragm assemblies; Process-related cell features
- C25B9/30—Cells comprising movable electrodes, e.g. rotary electrodes; Assemblies of constructional parts thereof
- C25B9/303—Cells comprising movable electrodes, e.g. rotary electrodes; Assemblies of constructional parts thereof comprising horizontal-type liquid electrode
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- C—CHEMISTRY; METALLURGY
- C25—ELECTROLYTIC OR ELECTROPHORETIC PROCESSES; APPARATUS THEREFOR
- C25B—ELECTROLYTIC OR ELECTROPHORETIC PROCESSES FOR THE PRODUCTION OF COMPOUNDS OR NON-METALS; APPARATUS THEREFOR
- C25B9/00—Cells or assemblies of cells; Constructional parts of cells; Assemblies of constructional parts, e.g. electrode-diaphragm assemblies; Process-related cell features
- C25B9/70—Assemblies comprising two or more cells
Definitions
- This invention relates to electrolytic cells for the electrolysis of electrolytes in the form of fused salts or as solutions.
- the invention particularly relates to a novel construction for such a cell wherein the capacity of the cell is more than ⁇ doubled relative to prior art cells and the cell is safe to operate by semi-skilled workers without automatic expensive short-circuiting switches or warning devices.
- the invention will be described as applied to a horizontal mercury cell and it will be obvious that the principles of the invention can .be applied to all types of electrolysis cells of the mercury or other types in which the cathode is a fluid body of mercury owing over thecell bottom or base or another metal which is uid at the temperature of the electrolytic operation.
- the anodes are generally composed of flat rectangular plates of graphite suspended from graphite or copper rods in such a manner that their at surface is spaced a short distance above the flowing mercury cathode.
- the body and sides of the trough are generally steel.
- the sides of the trough in contact with the electrolytic solution are lined with a resistant substance, for example, hard rubber, resins, natural stone set in concrete, or other suitable nonconducting material.
- the electrolytic fluid which may be an aqueous solution of any electrolyte compound or a fused salt which upon electrolytic decomposition will give the products desired, is usually introduced at the upper end of the cell and flows toward the lower end of the cell.
- a solution of sodium chloride may be electrolyzed in such a cell. Electric current passes through the solution between the anodes and the mercury cathode.
- sodium chloride is the electrolyte
- chlorine is formed at the anode and passes to the top of the cell and out through an opening in the cell cover which is provided'for this purpose.
- Sodium is formed at the cathode and amalgamates with the mercury cathode.
- the sodium amalgam is withdrawn at the lower end of the cell, cycled to a decomposer, packed with graphite where it is contacted with water to form sodium hydroxide, hydrogen and mercury.
- the mercury is recycled to the cell for reuse as the cathode.
- electrolytes such as potassium chloride, lithium chloride, barium chloride, sodium sulfate, as well as fused salts and the like, may be electrolyzed in such a cell.
- the base of the cell is generally made of steel and is in contact with the negative bus bar.
- the mercury layer (for example) flows over the steel and actually constitutes the cathode in contact with the electrolyte.
- mercury is relatively expensive the amount of mercury in circulation is kept as low as possible and the mercury cathode layer is kept relatively thin. Consequently, there has always been the problem of obtaining even distribution of the mercury over the base of the cell. This has made it necessary to use great care in the machining of the steel bottom interior of the cell to assure that it has an even substantially level surface.
- the base has been made of a non-conductive material having conductive materials placed therein.
- the conductive materials consisted either of steel strips extending crosswise of the cell and spaced at intervals along the length of the cell or of circular metallic disks spaced over the bottom of the cell.
- neither of these methods has made it possible to increase the width of the cell since there is still the danger of exposure of portions of the conductive steel strips when the cell width is increased, and mercury and current distribution is notgood in either of these alternatives.
- fIt is an object of this invention to provide a horizontal mercury cell having improved mercury distribution over the base of the cell.
- Another object of this invention is to provide a cell which will continue to operate safely with a substantially reduced mercury flow.
- Another object is to provide a horizontal mercury cell having improved current ⁇ distribution through the cathode.
- Another object is to provide a horizontal mercury cell having greater width and increased capacity than previous horizontal mercury cells.
- ⁇ A further object of this invention is to provide an electrolytic cell which allows dissipation Iof explosive forces wit-hin the cell without serious damage to the electrolytic cell.
- a further object of this invention is to provide a cell which will continue to operate safely without expensive short-circuit systems for each cell even when the mercury does not cover the entire base of the cell.
- a cell comprised of a flexible stretchable, plastic cell cover and a cell base of alternate strips of non-conductive and conductive material running the length of the cell.
- the conductive strips are narrower than the nonconductive strips and have their top surface below the level of the surface of the non-conductvie strips. Thus in effect the space above each conductive strip and between the two adjacent non-conductive strips forms a narrow and shallow channel extending the entire ⁇ length of the cell.
- the conductive strips are preferably steel and the non-conductive strips may be made of hard rubber, resin, concrete, natural stone, and the like. The number and relative width of the conductive and nonconductive strips may vary as desired.
- the conductive strips may be covered with less mercury and still not become exposed to the electrolyte or to gases even during periods of reduced mercury flow.
- the base may consist of sheet steel which has been coated with strips of a resinous material or nonconductive paint over portions of its area so as to leave lengthwise strips of the conductive steel base exposed between the non-conducting strips.
- the ilexib-le, stretchable plastic cell cover comprises adjustably ysupporting the anodes from a rigid spidershaped metal frame structure supported on the cell trough or on a support structure outside the trough, and providing a flexible stretchable plastic cell cover to close the space between the anode frames and the cell trough.
- the metal framework consists of support members extending transversely of the cell and provided with means at their outer ends for tting the frame upon vertical posts which rest upon or are attached to the trough of the electrolytic cell.
- the anodes are attached to and suspended from ⁇ these rigid transverse frame members and the position of each anode can be adjusted independently.
- the height of the metal frame above the cell may be adjusted by suitable ⁇ adjusting nuts located on ysaid posts on which the transverse members of the frame are attached. By adjustment of the height of the frame, the distance between the anodes and the inside bottom or cathode of the cell is also adjusted.
- a cell cover of this type is more completely described in my copending -application Serial No. 704,982 filed December 24, 1957 (now 'Patent 2,958,635).
- the top of the cell is closed by providing a cover of flexible material, such as rubber, polyvinyl chloride, orV other sheet plastic, or the like, which is fastened to the sides of the cell either by bolting or by a suitable clamping means. Holes are provided in the -exible cover through which the anode connections protrude, and means are provided for sealing between the cover and the anode connections.
- the supporting frame has sufficient flexibility to allow lowering of one section of the frame while the rest of the adjusting screws have not yet been adjusted.
- the lowering of the frame is usually less than V16 at la given adjustment. Because of the flexibility of the rubber or plastic cover, it has sucient give to allow adjustment of the anodes without disturbing the cover or destroying the seal between the cover and the cell trough or between the cover land the anodes.
- the distribution of the mercury over the base of the cell may be further improved by providing cross channels, depressions or ridges in the non-conductive surfaces at intervals throughout the length of the cell.
- Such channels are not, however, as deep as the level of the conductive surfaces and operate to direct the mercury flow onto the conductive surfaces in the event the mercury is not suflicient to cover the entire cell bottom.
- riles or other lateral holdbackf means at intervals along the length of the conductive strips, which will maintain a layer of mercury on the strips throughout the entire length7 it is possible to completely eliminate the possibility of exposure of the conductive strips to the electrolyte solution or gases even after the flow of mercury has stopped.
- FIG. 1 is a top view of a cell and decomposer with parts broken away to show anode placement and parts broken away to show the cell base construction.
- FIG. 2 is a cross-sectional View of the cell taken along the lines 2-2 of FIG. l.
- FIGS. 3 and 4 illustrate modifications of the base to improve mercury distribution and also holdback means for the mercury on the conductive strips.
- FIGS. 5 and 6 illustrate modifications of the cell base structure.
- the main components of the electrolytic apparatus are the cell 1 and decomposer 2.
- Cell 1 is made up mainly of the trough 3, cover frame 4 and anodes 8.
- the trough 3 consists of sides 1A, bottom 1B, and end compartments 3A and 3C.
- the cell cover consists of flexible sheet plastic covering 17, such as rubber, polyvinyl chloride or the like, bolted to the sides of the trough 3 by stripsv 24 to prevent escape of gases, other means of securing the plastic cell cover to the base are illustrated in said copending application Serial No. 704,982.
- the anodes 8 preferably comprise flat horizontal graphite plates attached to vertical cylindrical graphite anode rods 27, which in turn are provided with metallic conductor bolts 3i) for attachment to the anode supporting frame i5 forming part of the cover frame 4. Holes are provided in cover 17' for bolts Sil and these holes are sealed against the escape of gas by nuts on bolts 3i) pressing the cover 17 against the top of the anode rods 27. An outlet 45 for the withdrawal of chlorine is located at the high end of the cell.
- the anode supporting frame comprises longitudinal members 21 to which are welded transverse bars 2Q which rest upon adjustable posts 19 resting on the sides 1A of trough 3.
- Anode rods 27 are supported from the transverse bars 4o, which are welded to members 2 at spaced intervals, by the conductor 1bolts Sti.
- the cell trough 3 comprises end compartments 3A and 3C and center compartment 3B which may be divided into a plurality of sections covered by separate cover frame members 15 as more fully described in said copendiug application.
- Compartment 3A is open at the top and is the inlet for mercury, and is separated from compartment 3B by a weir 3D, under which the mercury flows, this forming a gas tight seal.
- Compartment 3B which is much longer than compartments 3A and 3C is the electrolysis compartment and compartment 3C is the amalgam separation compartment. Compartment 3C is separated from compartment 3B by weir 3E under which amalgam flows.
- the trough 3 is preferably formed of steel I beams 1A and steel bottom 1B.
- the cover 17 is indicated as broken away at the lower left end of FIG. l to show the position of the anodes 8 in the cell and adjacent the numeral 3B the cover and anodes have been removed to show the cell bottom construction.
- the inside of the steel bottom comprises a surface of alternating longitudinal conductive and non-conductive surface strips, the conductive surfaces being lower than the non-conductive surfaces.
- the trough 3 is lined with concrete 6 into which stone slabs 5 are set on the sides of the cell trough.
- the non-conductive surfaces are also natural stone slabs 5A.
- the conductive surfaces are steel T bars 9 which are embedded in concrete 6 be- 6 tween the slabs 5A in such a Way that the upper surface of the Ts which come into contact with the mercury is slightly below the surface of slabs 5A.
- channels running the entire length of the compartment 3B are formed with the top of the T bars 9, indicated as conductive strips 9A, as the bottom of these channels.
- the lower ends of Ts i) are electrically connected to steel ibase 1B as by welding or the like.
- Such a construction provides a rigid at base substantially free from warpage and assures that the mercury will always cover the conductive surfaces of the base even when the quantity of flow is substantially reduced.
- the mercury will continue to flow in the narrow channels over the conductive strips 9A and to cover the conductive surfaces.
- the cell since there can be no lateral ow from one channel to another, and the conductive surfaces ⁇ are narrow relative to the width of the cell, the cell may be made wide without the usual risk of exposure of areas ⁇ of the conductive surface to electrolyte in the event of unevenness of the cell bottom.
- the cell will continue to operate even with a reduced ow of mercury, lalthough a-t reduced efciency and with a higher voltage requirement.
- Holdback riffles 48 such as shown in exaggerated form in FIG. 4, and in the cut-away section ⁇ of FIG. l showing the cell bottom, ⁇ may be provided at intervals along the conductive strips if desired to maintain mercury on the entire length of the conductive strips in spite of the slope of the cell so that the mercury flow may stop altogether and the conductive surfaces will still be covered with mercury. It is possible, therefore, to build a cell of greatly increased capacity and greater safety and to achieve considerable economy in cell construction.
- lateral means may be provided on the nonconductive surfaces to direct the tlowing mercury preferentially to the mercury channels formed by the top of strips 9A.
- These lateral directive means may be either ridges 49 or grooves 56 in the non-conductive surfaces, as shown also in somewhat exaggerated form in FIGS. 3 and 4.
- these lateral means if ridges should not be higher than the normal thickness of the layer of mercury which flows on the cell base, which is about 1/e inch, or if grooves, should not be as low as the conductive surfaces formed by the vconductive strips 9A so as to permit iiow of the mercury laterally from one channel to another.
- Copper bus bars 12 provide electric connections for the cathode through the bottom ⁇ of pla-te 1B and through metal T beams 9 which are embedded in the lining of the cell and which come into Contact with the mercury flowing along the bottom of the cell.
- Electric connection 28 is provided to the anodes 8 through bus bars 11 which are further attached to the connectors 16 which are secured to the bolts 30 connected to each of the posts 27 of each anode.
- a sodium chloride solution is introduced into the compartment 3B of the cell through inlet 41 in weir 3D.
- Mercury is introduced into compartment 3A from conduit 10 and flows under weir 3D into compartment 3B.
- the mercury and brine in compartmentSB flow towards the opposite end of the cell during which the brine is electrolyzed, forming chlorine gas and an amalgam of sodium with the mercury.
- Chlorine is withdrawn through the chlorine outlet 45 at the high end of the cell and depleted brine is withdrawn at the lower end of the cell by outlet 4S.
- the sodium-amalgam passes under Weir 3E into compartment 3C and is withdrawn by conduit 33 which extends under the trough 3 to decomposer 2.
- the sodium-mercury amalgam is reacted with water to form sodium hydroxide and hydrogen, and the mercury is returned to the cell by pump 39.
- Water is aca-anos fed to the decomposer through inlet 35.
- Hydrogen is withdrawn from outlet and sodium hydroxide through outlet 37.
- the quantity of mercury flowing is substantially reduced for any reason, the remaining mercury will tend to ilow in the channels formed between the stone slabs 5A on steel surfaces 9A of Ts 9.
- the ridges 49 or channels 50 will aid in directing the flow of mercury to these channels. lf the quantity is low enough to cause the formation of islands on surfaces 5A, or the complete exposure of these surfaces, it is of no serious consequence as long as surfaces' 9A are covered.
- the layer of mercury on the conductive surfaces 9A may be maintained by providing holdback riles 48, such as illustrated in FIG. 4, at suitable intervals along the length of conductor strips 9A or in any other suitable way.
- a cell of the type described is almost completely protected from the possibility of the Contact of the steel cathode conductive surface with the electrolytic solution or with gases, however if there should be an exposure of the conductive surfaces by an interruption of the mercury flow so that a mixture of explosive gases is formed, there is no danger of the cell being seriously damaged by an explosion, because in the event of an explosion, the flexible plastic cell cover 17 expands or blows up similar to a balloon and if the expansion continues it ruptures a small area in the cover, letting the expanded gases escape harmlessly, and the ruptured sec-tion can be sealed by patching or vulcanizing the cover at this point, or the cover may be replaced without material expense or delay in the operation of the cell.
- the lbase of the cell can also be constructed in a different manner as illustrated in FIGS. 5 and 6.
- the non-conductive surfaces may be formed by coating a flat steel base 1B with strips ⁇ or strips of a resinous or other non-conductive material 5B, leaving strips of the steel base uncoated or exposed to form the conductive surface channels such as shown in FIG. 5 or the base may be formed by fastening together alternate strips of nonconductive material 5C and conductive materials 9B side by side with the conductive strips 9B being lower than the non-conductive strips 5C, :as shown in FIG. 6. It is only necessary that the base comprise alternate non-conductive and conductive surfaces, with the conductive surfaces being lower than the non-conductive surfaces.
- An apparatus for conducting the electrolysis of electrolytes which comprises an elongated inclined trough, a metal frame comprising transverse and longitudinal members, anodes suspended from said transverse members of said frame, a flexible, rupturable, plastic sheet cover attached to the sides of said trough, openings in said cover through which said anodes protrude, a mercury cathode flowing along the base of said trough, a cathode contact surface in said trough base comprising alternate longitudinal conductive and non-conductive surfaces, said conductive surfaces being lower iand narrower than said non-conductive surfaces whereby during periods of reduced mercury flow the conductive surfaces remain covered with mercury, and means for imposing an electrical current on said anodes and said cathode.
- An apparatus for conducting the electrolysis of electrolytes which comprises an elongated inclined trough, a metal frame comprising transverse and longitudinal members, anodes suspended from said transverse members of said frame, a flexible, rupturable, plastic sheet cover attached to the sides of said trough and forming a gas tight enclosure for said cell, openings in said cover through which said anodes protrude, said openings forming ⁇ a gas tight seal around said anodes, a mercury cathode flowing along the base of said trough, a cathode contact surface in said trough base comprising alternate longitudinal conductive and non-conductive surfaces, said conductive surfaces being lower and narrower than said non-conductive surfaces whereby during periods of reduced mercury flow the conductive surfaces remain covered with mercury, and means for imposing an elecrtioal current on said anodes and said cathode.
- An apparatus for conducting the electrolysis of electrolytes which comprises an elongated inclined trough, a metal frame above said trough comprising transverse and longitudinal member, adjustable means to maintain Said transverse members at a specified height above said trough, anodes suspended from said transverse members of said frame, a flexible, rupturable, plastic sheet cover attached to the sides of said cell and forming a gas tight enclosure for said cell, openings in said cover through which said anodes protrude, said openings forming a gas tight seal around said anodes, a mercury cathode flowing along the base of said trough, a cathode contact surface in said trough base comprising alternate longitudinal conductive and non-conductive surfaces, said lconductive surfaces being lower and narrower than said non-conductive surface whereby during periods of reduced mercury llow the conductive surfaces remain covered with mercury, and means for imposing an electrical current on said anodes and said cathode.
- An apparatus for conducting the electrolysis of electrolytes which comprises an elongated inclined trough, a metal frame above said trough comprising transverse and longitudinal members, adjustable means to maintain said transverse members at a specied height above said trough, anodes suspended from said transverse members of said frame, a flexible, rupturable, plastic sheet cover attached to the sides of said ⁇ cell and forming a gas tight enclosure for said cell, openings in said cover through which said anodes protrude, said openings forming a gas tight seal around said anodes, a mercury cathode lflowing Ialong the base of said trough, a cathode contact surface in said trough base comprising alternate longitudinal conductive and non-conductive surfaces, said conductive surfaces being lower and narrower than said non-conductive surface whereby during periods of reduced mercury flow the conductive surfaces remain covered with mercury, and lateral means on said non-conductive surface to direct the flow of mercury to said conductive surfaces, means for imposing an electrical current on said anodes -
- An apparatus for conducting the electrolysis of electrolytes which comprises an elongated inclined trough, Va metal frame above said trough comprising transverse and longitudinal members, adjustable means to maintain said transverse members at a specified height above said trough, anodes suspended from said transverse members of said frame, a flexible, rupturalble, plastic sheet cover attached to the sides of said cell and forming a gas tight enclosure for said cell, openings in said cover through which said anodes protrude, said openings forming a gas tight seal 4around said anodes, a mercury cathode flowing along the base of said trough, a cathode contact surface in said trough base comprising alternate longitudinal conductive and non-conductive surfaces, said conductive surfaces being lower and narrower than said non-conductive surface and holdback riflles on said conductive surfaces whereby during periods of interrupted mercury flow the conductive surfaces rem-ain covered with mercury, and
- a horizontal electrolysis cell for the electrolysis of electrolytes which comprises an elongated, inclined trough, a metal frame above said trough comprising transverse and longitudinal members, anodes suspended from said transverse members of said frame, ⁇ a flexible, rupturable, plastic lsheet cover attached to the sides of said trough, openings in said cover through which said anodes protrude, a mercury cathode flowing along the base of said trough, a cathode contact surface in said trough base comprising a sheet steel base covered with la non-conductive material, steel strips inserted into said non-conductive material and making contact with said sheet steel base, said strips being inserted so as to form a contact surface for the mercury cathode of alternate longitudinal conductive and non-conductive surfaces, said conductive surfaces lbeing lower and narrower than said non-conductive surfaces.
- a horizontal mercury electrolysis cell for the electrolysis of electrolytes comprising an elongated trough, cover means, ⁇ anode means, and a lbase surface over which the mercury flows comprising alternate longitudinal, flat conductive and non-conductive surfaces, said conductive surfaces being lower and narrower than said non-conductive surfaces, the relative elevation of said conductive and non-conductive surfaces being such that said mercury cathode flows over the entire base surface during normal flow of said mercury and preferentially on the conductive surfaces during reduced and interrupted How of ysaid mercury, and lateral holdback ries on said conductive ⁇ surfaces.
- a horizontal mercury electrolysis cell for the electrolysis of electrolytes comprising an elongated trough, cover means, anode means, land la base surface over which the mercury flows comprising alternate longitudinal, at steel conductive and corrosion-resistant, non-conductive surfaces, said conductive surfaces being lower and narrower than said non-conductive surfaces, the relative elevation of said ⁇ conductive and non-conductive surfaces being such that said mercury cathode flows over the entire Ibase surface during normal ilow of said mercury and preferentially on the conductive surfaces during reduced and interrupted flow of said mercury, lateral lioldback rilles on said conductive surfaces and lateral means on said noncondncti've surfaces to direct the ow of mercury preferentially to said conductive surfaces during reduced and interrupted flow of mercury.
- a horizontal mercury electrolysis cell for the electrolysis of electrolytes comprising ⁇ an elongated trough, a flexible sheet cover Ine-ans, anode means, and a base surface over which ⁇ the mercury flows comprising alternate longitudinal, fiat conductive and non-conductive surfaces, said conductive surfaces being lower and narrower than said non-conductive surfaces, the relative elevation of said conductive and non-conductive surfaces being such that said mercury cathode ilows over the entire base surface during normal flow of said mercury and preferentially on the conductive surfaces during reduced and interrupted flow of said mercury.
Description
July 3, 1962 v. DE NORA HORIZONTAL ELECTROLYTIC CELL Filed Oct. 25. 1960 fm m Am. 4m@
Hlnmlllum'm United States Patent Olitice snizoz Patented July 3, 1962 3,042,602 HORZONTAL ELECTRLYTIC CELL Vittorio de Nora, Milan, Italy, assigner to Oronzio de Nora Impianti Elettrochirnici, Milan, Italy, a corporation of Italy Filed Get. 25, 1%0, Ser. No. 66,378 9 Ciairns. (Cl. 20d-220) This invention relates to electrolytic cells for the electrolysis of electrolytes in the form of fused salts or as solutions. The invention particularly relates to a novel construction for such a cell wherein the capacity of the cell is more than `doubled relative to prior art cells and the cell is safe to operate by semi-skilled workers without automatic expensive short-circuiting switches or warning devices. The invention will be described as applied to a horizontal mercury cell and it will be obvious that the principles of the invention can .be applied to all types of electrolysis cells of the mercury or other types in which the cathode is a fluid body of mercury owing over thecell bottom or base or another metal which is uid at the temperature of the electrolytic operation.
Examples of cells of this type, used in the prior art, are described in U.S. Patent No. 2,544,138, granted March 6, 1951; in Industrial and Engineering Chemistry, 1953 (vol. 45 No. 6), pages 1162-1172; and in Chemical Engineering Progress, September 1957 (vol. 53, No. 9), pages 409-417. The use of the cell base structure, such as herein described, on other cells of similar construction is also included within the scope of this invention. These cells, generally designated as horizontal mercury cells, consist of an enclosed elongated trough sloping slightly towards one end. The cathode is a ilowing layer of mercury which is introduced at the higher end of the cell and ows along the bottom of the cell toward the lower end. The anodes are generally composed of flat rectangular plates of graphite suspended from graphite or copper rods in such a manner that their at surface is spaced a short distance above the flowing mercury cathode. The body and sides of the trough are generally steel. The sides of the trough in contact with the electrolytic solution are lined with a resistant substance, for example, hard rubber, resins, natural stone set in concrete, or other suitable nonconducting material.
In the operation of this type of cell the electrolytic fluid, which may be an aqueous solution of any electrolyte compound or a fused salt which upon electrolytic decomposition will give the products desired, is usually introduced at the upper end of the cell and flows toward the lower end of the cell. For example, a solution of sodium chloride may be electrolyzed in such a cell. Electric current passes through the solution between the anodes and the mercury cathode. When sodium chloride is the electrolyte, chlorine is formed at the anode and passes to the top of the cell and out through an opening in the cell cover which is provided'for this purpose. Sodium is formed at the cathode and amalgamates with the mercury cathode. The sodium amalgam is withdrawn at the lower end of the cell, cycled to a decomposer, packed with graphite where it is contacted with water to form sodium hydroxide, hydrogen and mercury. The mercury is recycled to the cell for reuse as the cathode. It will be understood that other electrolytes, such as potassium chloride, lithium chloride, barium chloride, sodium sulfate, as well as fused salts and the like, may be electrolyzed in such a cell.
In cells of this type the base of the cell is generally made of steel and is in contact with the negative bus bar. The mercury layer (for example) flows over the steel and actually constitutes the cathode in contact with the electrolyte. As mercury is relatively expensive the amount of mercury in circulation is kept as low as possible and the mercury cathode layer is kept relatively thin. Consequently, there has always been the problem of obtaining even distribution of the mercury over the base of the cell. This has made it necessary to use great care in the machining of the steel bottom interior of the cell to assure that it has an even substantially level surface.
It has not been possible to build cells of high current density such as 80,000 or 120,000 amp. because the capacity of the cells is determined by the length and width of the cell. The capacity of the cells could not be increased by extending the length of the cell since, as in the case of sodium chloride solutions, too much sodium in the amalgam makes the amalgam Viscous and difficult to handle.
In the past it has been necessary to keep the cells relatively narrow in width because of the extreme diiculty of providing an absolutely level surface for the base of a Wide cell from side to side thereof. When the base is not absolutely level, the thin layer of mercury i-s not evenly distributed over the base and various portions or islands of the lbase will be exposed. These exposed islands result in contact of the electrolyte solution with the steel base and present operating diiculties. When the cell is operating, a dilferent reaction may take place because the steel and not the mercury is acting as the cathode. If aqueous salt solutions are used, hydrogen will be evolved which is a hazard since mixture of chlorine gas and hydrogen gas are frequently explosive. During periods when the cell is not operating, the exposure of the base to the electrolyte or gases will result in corrosion where the islands have formed because of accumulation of dirt and formation of local cell areas.
Another problem with the prior art cells has been the danger of destruction of the cell with possible injury to the operating personnel in the cell room due to the hydrogen and chlorine gas mixtures formed in the: cell exploding with sufcient force to blow the cell apart. The prior art cells have rigid stone or similar covers which are usually tightly sealed to the rigid base and which are destroyed in an explosion. Therefore, elaborate warning systems and/ or automatic short-circuit switches are necessary in order to short-circuit the cell when there is a reduction or interruption in the flow of mercury across the cell bottom. These add considerably to the installation costs of thecell and complicate the operation and up-keep of the cell.
Various attempts have been made to solve the problem of obtaining even distribution of the mercury on the cell base and to prevent exposure of the base. For example, the base has been made of a non-conductive material having conductive materials placed therein. The conductive materials consisted either of steel strips extending crosswise of the cell and spaced at intervals along the length of the cell or of circular metallic disks spaced over the bottom of the cell. However, neither of these methods has made it possible to increase the width of the cell since there is still the danger of exposure of portions of the conductive steel strips when the cell width is increased, and mercury and current distribution is notgood in either of these alternatives.
Another attempt to solve this problem is described in swiss Patent No. 297,829 published June 16, 1954, in which the cathode or cell base on which the mercury flows is divided into a plurality of individual troughs by the use of chlorine resistant separating strips secured to the conductive cell bottom and extending above the iner-v cury level. In this type of cell construction Ilarge areas of the conductive cell base on which the mercury ows may still become exposed to the electrolyte in the event unevenness of the cell base or reduced mercury ow leaves exposed Surfaces of the cathode between pools of :ge-rasca mercury and the wider the individual troughs constituting the cell the greater this danger.
fIt is an object of this invention to provide a horizontal mercury cell having improved mercury distribution over the base of the cell.
It is a further object of this invention to provide a horizontal mercury cell which prevents exposure of the cathode conductive surfaces underlying the mercury to the electrolyte and gases.
Another object of this invention is to provide a cell which will continue to operate safely with a substantially reduced mercury flow.
Another object is to provide a horizontal mercury cell having improved current `distribution through the cathode.
Another object is to provide a horizontal mercury cell having greater width and increased capacity than previous horizontal mercury cells.
\A further object of this invention is to provide an electrolytic cell which allows dissipation Iof explosive forces wit-hin the cell without serious damage to the electrolytic cell.
A further object of this invention is to provide a cell which will continue to operate safely without expensive short-circuit systems for each cell even when the mercury does not cover the entire base of the cell.
Various other objects and advantages of 4the invention will become apparent as this description proceeds.
These objects are accomplished and the `disadvantages of t-he prior art structures are overcome by the use of a cell comprised of a flexible stretchable, plastic cell cover and a cell base of alternate strips of non-conductive and conductive material running the length of the cell. The conductive strips are narrower than the nonconductive strips and have their top surface below the level of the surface of the non-conductvie strips. Thus in effect the space above each conductive strip and between the two adjacent non-conductive strips forms a narrow and shallow channel extending the entire `length of the cell. The conductive strips are preferably steel and the non-conductive strips may be made of hard rubber, resin, concrete, natural stone, and the like. The number and relative width of the conductive and nonconductive strips may vary as desired. In this way the conductive strips may be covered with less mercury and still not become exposed to the electrolyte or to gases even during periods of reduced mercury flow. As an alternative the base may consist of sheet steel which has been coated with strips of a resinous material or nonconductive paint over portions of its area so as to leave lengthwise strips of the conductive steel base exposed between the non-conducting strips.
The ilexib-le, stretchable plastic cell cover comprises adjustably ysupporting the anodes from a rigid spidershaped metal frame structure supported on the cell trough or on a support structure outside the trough, and providing a flexible stretchable plastic cell cover to close the space between the anode frames and the cell trough. The metal framework consists of support members extending transversely of the cell and provided with means at their outer ends for tting the frame upon vertical posts which rest upon or are attached to the trough of the electrolytic cell. The anodes are attached to and suspended from `these rigid transverse frame members and the position of each anode can be adjusted independently. The height of the metal frame above the cell may be adjusted by suitable `adjusting nuts located on ysaid posts on which the transverse members of the frame are attached. By adjustment of the height of the frame, the distance between the anodes and the inside bottom or cathode of the cell is also adjusted. A cell cover of this type is more completely described in my copending -application Serial No. 704,982 filed December 24, 1957 (now 'Patent 2,958,635).
The top of the cell is closed by providing a cover of flexible material, such as rubber, polyvinyl chloride, orV other sheet plastic, or the like, which is fastened to the sides of the cell either by bolting or by a suitable clamping means. Holes are provided in the -exible cover through which the anode connections protrude, and means are provided for sealing between the cover and the anode connections. By this construction the height or distance of all the anodes from the cathode may be adjusted simultaneously by adjusting the nuts which determine the height of the supporting frame above the cell trough. The supporting frame has sufficient flexibility to allow lowering of one section of the frame while the rest of the adjusting screws have not yet been adjusted. The lowering of the frame is usually less than V16 at la given adjustment. Because of the flexibility of the rubber or plastic cover, it has sucient give to allow adjustment of the anodes without disturbing the cover or destroying the seal between the cover and the cell trough or between the cover land the anodes.
With this type of cell it is possible to greatly increase the width of the cell and thereby the capacity of the cell without the hazards of possible destruction of the cell by mixtures of explosive gases. Since the conductive sur-faces are relatively narrow with respect to the total width of the cell, there is no problem of unevenness. Moreover, since the conductive surfaces are at a lower level, the remainder of the cell base surfaces of non-conducting material may have islands formed with little likelihood that the conductive surfaces will be exposed. In addition, should the flow of mercury be substantially reduced for any reason, the mercury will ilow preferentially in the narrow channels formed over the conductive surfaces preventing -their exposure to the electrolyte, and the cell will continue to operate although at reduced efficiency and with a higher voltage requirement.
lf there should be an exposure of the conductive surfaces by an interruption in the iiow of mercury so that a mixture of explosive gases is formed, there is no danger of the cell being seriously damaged by an explosion as in prior art cells. In the event of an explosion, the flexible cover merely expands similar to a balloon under the pressure of these gases, and if the expansion is continued, it merely results in the rupture of a small area of the cover, thereby etting the expanded gases escape harmlessly without any disturbance of the remainder of the structure of the cell or the dangers ordinarily accompanying an explosion. Repair or replacement of the cover is readily accomplished by replacing the torn cover section or by merely sealing, patching, or vulcanizing the ruptured section.
Since the cell itself will not be destroyed by an explosion as in prior art cells, the margin of safety is much greater than before possible. The expensive and complex automatic short-circuiting switches which are required in many present electrolytic cells can be eliminated without material danger to the cell or to the operating personnel in the cell room. Manual current shutoff switches may be used.
The distribution of the mercury over the base of the cell may be further improved by providing cross channels, depressions or ridges in the non-conductive surfaces at intervals throughout the length of the cell. Such channels are not, however, as deep as the level of the conductive surfaces and operate to direct the mercury flow onto the conductive surfaces in the event the mercury is not suflicient to cover the entire cell bottom. Thus, it may be seen that the chances of exposure of the conductive surfaces of the base are greatly reduced regardless of the width of the cell as long as some mercury is flowing. By placing riles or other lateral holdbackf means at intervals along the length of the conductive strips, which will maintain a layer of mercury on the strips throughout the entire length7 it is possible to completely eliminate the possibility of exposure of the conductive strips to the electrolyte solution or gases even after the flow of mercury has stopped.
The invention may be more readily understood by referring to the drawings which illustrate a preferred embodiment of the invention.
FIG. 1 is a top view of a cell and decomposer with parts broken away to show anode placement and parts broken away to show the cell base construction.
FIG. 2 is a cross-sectional View of the cell taken along the lines 2-2 of FIG. l.
FIGS. 3 and 4 illustrate modifications of the base to improve mercury distribution and also holdback means for the mercury on the conductive strips.
FIGS. 5 and 6 illustrate modifications of the cell base structure.
Referring to the drawings, the main components of the electrolytic apparatus are the cell 1 and decomposer 2. Cell 1 is made up mainly of the trough 3, cover frame 4 and anodes 8. The trough 3 consists of sides 1A, bottom 1B, and end compartments 3A and 3C. The cell cover consists of flexible sheet plastic covering 17, such as rubber, polyvinyl chloride or the like, bolted to the sides of the trough 3 by stripsv 24 to prevent escape of gases, other means of securing the plastic cell cover to the base are illustrated in said copending application Serial No. 704,982. The anodes 8 preferably comprise flat horizontal graphite plates attached to vertical cylindrical graphite anode rods 27, which in turn are provided with metallic conductor bolts 3i) for attachment to the anode supporting frame i5 forming part of the cover frame 4. Holes are provided in cover 17' for bolts Sil and these holes are sealed against the escape of gas by nuts on bolts 3i) pressing the cover 17 against the top of the anode rods 27. An outlet 45 for the withdrawal of chlorine is located at the high end of the cell.
As shown in FIGS. l and 2, the anode supporting frame comprises longitudinal members 21 to which are welded transverse bars 2Q which rest upon adjustable posts 19 resting on the sides 1A of trough 3. Anode rods 27 are supported from the transverse bars 4o, which are welded to members 2 at spaced intervals, by the conductor 1bolts Sti. By this construction the entire anode frame with the anodes attached thereto may be removed from the cell by first loosening the ileXible covering 17 by removing the strips 24 and lifting the anode frame with the anodes attached thereto by a crane or the like to expose the interior of the cell trough 3 for inspection or repair. A more complete description of this cell cover construction will be found in my copending application Serial No. 704,982, iiled December 24, 1957.
The cell trough 3 comprises end compartments 3A and 3C and center compartment 3B which may be divided into a plurality of sections covered by separate cover frame members 15 as more fully described in said copendiug application.
The inside of the steel bottom comprises a surface of alternating longitudinal conductive and non-conductive surface strips, the conductive surfaces being lower than the non-conductive surfaces. In the embodiment of FIGS. 1, 2, 3 and 4, the trough 3 is lined with concrete 6 into which stone slabs 5 are set on the sides of the cell trough. In the base of the cell, the non-conductive surfaces `are also natural stone slabs 5A. The conductive surfaces are steel T bars 9 which are embedded in concrete 6 be- 6 tween the slabs 5A in such a Way that the upper surface of the Ts which come into contact with the mercury is slightly below the surface of slabs 5A. Thus, channels running the entire length of the compartment 3B are formed with the top of the T bars 9, indicated as conductive strips 9A, as the bottom of these channels. The lower ends of Ts i) are electrically connected to steel ibase 1B as by welding or the like.
Such a construction provides a rigid at base substantially free from warpage and assures that the mercury will always cover the conductive surfaces of the base even when the quantity of flow is substantially reduced. When there is insucient mercury to cover the entire bottom surface of the cell, the mercury will continue to flow in the narrow channels over the conductive strips 9A and to cover the conductive surfaces. Moreover, since there can be no lateral ow from one channel to another, and the conductive surfaces `are narrow relative to the width of the cell, the cell may be made wide without the usual risk of exposure of areas `of the conductive surface to electrolyte in the event of unevenness of the cell bottom. Thus, the cell will continue to operate even with a reduced ow of mercury, lalthough a-t reduced efciency and with a higher voltage requirement.
Holdback riffles 48, such as shown in exaggerated form in FIG. 4, and in the cut-away section `of FIG. l showing the cell bottom, `may be provided at intervals along the conductive strips if desired to maintain mercury on the entire length of the conductive strips in spite of the slope of the cell so that the mercury flow may stop altogether and the conductive surfaces will still be covered with mercury. It is possible, therefore, to build a cell of greatly increased capacity and greater safety and to achieve considerable economy in cell construction.
In order to improve the circulation of the mercury over the cell base, lateral means may be provided on the nonconductive surfaces to direct the tlowing mercury preferentially to the mercury channels formed by the top of strips 9A. These lateral directive means may be either ridges 49 or grooves 56 in the non-conductive surfaces, as shown also in somewhat exaggerated form in FIGS. 3 and 4. However, these lateral means if ridges should not be higher than the normal thickness of the layer of mercury which flows on the cell base, which is about 1/e inch, or if grooves, should not be as low as the conductive surfaces formed by the vconductive strips 9A so as to permit iiow of the mercury laterally from one channel to another.
Copper bus bars 12 provide electric connections for the cathode through the bottom `of pla-te 1B and through metal T beams 9 which are embedded in the lining of the cell and which come into Contact with the mercury flowing along the bottom of the cell. Electric connection 28 is provided to the anodes 8 through bus bars 11 which are further attached to the connectors 16 which are secured to the bolts 30 connected to each of the posts 27 of each anode.
In the operation of a cell of the type shown in FIGS. l and 2 for the electrolysis of sodium chloride, for eX- ample, a sodium chloride solution is introduced into the compartment 3B of the cell through inlet 41 in weir 3D. Mercury is introduced into compartment 3A from conduit 10 and flows under weir 3D into compartment 3B. The mercury and brine in compartmentSB flow towards the opposite end of the cell during which the brine is electrolyzed, forming chlorine gas and an amalgam of sodium with the mercury. Chlorine is withdrawn through the chlorine outlet 45 at the high end of the cell and depleted brine is withdrawn at the lower end of the cell by outlet 4S. The sodium-amalgam passes under Weir 3E into compartment 3C and is withdrawn by conduit 33 which extends under the trough 3 to decomposer 2. In the decomposer, the sodium-mercury amalgam is reacted with water to form sodium hydroxide and hydrogen, and the mercury is returned to the cell by pump 39. Water is aca-anos fed to the decomposer through inlet 35. Hydrogen is withdrawn from outlet and sodium hydroxide through outlet 37. Mercury llows yout of the decomposer through conduit 38 and is recycled to the cell by pump 39 via conduit 1t).
If the quantity of mercury flowing is substantially reduced for any reason, the remaining mercury will tend to ilow in the channels formed between the stone slabs 5A on steel surfaces 9A of Ts 9. The ridges 49 or channels 50 will aid in directing the flow of mercury to these channels. lf the quantity is low enough to cause the formation of islands on surfaces 5A, or the complete exposure of these surfaces, it is of no serious consequence as long as surfaces' 9A are covered.
When the llow of mercury is completely stopped, the layer of mercury on the conductive surfaces 9A may be maintained by providing holdback riles 48, such as illustrated in FIG. 4, at suitable intervals along the length of conductor strips 9A or in any other suitable way.
Thus, a cell of the type described is almost completely protected from the possibility of the Contact of the steel cathode conductive surface with the electrolytic solution or with gases, however if there should be an exposure of the conductive surfaces by an interruption of the mercury flow so that a mixture of explosive gases is formed, there is no danger of the cell being seriously damaged by an explosion, because in the event of an explosion, the flexible plastic cell cover 17 expands or blows up similar to a balloon and if the expansion continues it ruptures a small area in the cover, letting the expanded gases escape harmlessly, and the ruptured sec-tion can be sealed by patching or vulcanizing the cover at this point, or the cover may be replaced without material expense or delay in the operation of the cell.
The lbase of the cell can also be constructed in a different manner as illustrated in FIGS. 5 and 6. For example, the non-conductive surfaces may be formed by coating a flat steel base 1B with strips `or strips of a resinous or other non-conductive material 5B, leaving strips of the steel base uncoated or exposed to form the conductive surface channels such as shown in FIG. 5 or the base may be formed by fastening together alternate strips of nonconductive material 5C and conductive materials 9B side by side with the conductive strips 9B being lower than the non-conductive strips 5C, :as shown in FIG. 6. It is only necessary that the base comprise alternate non-conductive and conductive surfaces, with the conductive surfaces being lower than the non-conductive surfaces.
The present application is a continuation-in-part application of my copending applications Serial No. 704,982 filed December 24, 1957 now Patent No. 2,958,635 and Serial No. 706,375, led December 31, 1957, now abandoned.
While I have set forth preferred embodiments of my invention to enable those skilled in the art to understand and practice my invention, it will be understood that the invention is not limited thereto and that various modifications may be made without departing from the spirit thereof and the scope of the following claims.
I claim:
1. An apparatus for conducting the electrolysis of electrolytes which comprises an elongated inclined trough, a metal frame comprising transverse and longitudinal members, anodes suspended from said transverse members of said frame, a flexible, rupturable, plastic sheet cover attached to the sides of said trough, openings in said cover through which said anodes protrude, a mercury cathode flowing along the base of said trough, a cathode contact surface in said trough base comprising alternate longitudinal conductive and non-conductive surfaces, said conductive surfaces being lower iand narrower than said non-conductive surfaces whereby during periods of reduced mercury flow the conductive surfaces remain covered with mercury, and means for imposing an electrical current on said anodes and said cathode.
2. An apparatus for conducting the electrolysis of electrolytes which comprises an elongated inclined trough, a metal frame comprising transverse and longitudinal members, anodes suspended from said transverse members of said frame, a flexible, rupturable, plastic sheet cover attached to the sides of said trough and forming a gas tight enclosure for said cell, openings in said cover through which said anodes protrude, said openings forming `a gas tight seal around said anodes, a mercury cathode flowing along the base of said trough, a cathode contact surface in said trough base comprising alternate longitudinal conductive and non-conductive surfaces, said conductive surfaces being lower and narrower than said non-conductive surfaces whereby during periods of reduced mercury flow the conductive surfaces remain covered with mercury, and means for imposing an elecrtioal current on said anodes and said cathode.
3. An apparatus for conducting the electrolysis of electrolytes which comprises an elongated inclined trough, a metal frame above said trough comprising transverse and longitudinal member, adjustable means to maintain Said transverse members at a specified height above said trough, anodes suspended from said transverse members of said frame, a flexible, rupturable, plastic sheet cover attached to the sides of said cell and forming a gas tight enclosure for said cell, openings in said cover through which said anodes protrude, said openings forming a gas tight seal around said anodes, a mercury cathode flowing along the base of said trough, a cathode contact surface in said trough base comprising alternate longitudinal conductive and non-conductive surfaces, said lconductive surfaces being lower and narrower than said non-conductive surface whereby during periods of reduced mercury llow the conductive surfaces remain covered with mercury, and means for imposing an electrical current on said anodes and said cathode.
4. An apparatus for conducting the electrolysis of electrolytes which comprises an elongated inclined trough, a metal frame above said trough comprising transverse and longitudinal members, adjustable means to maintain said transverse members at a specied height above said trough, anodes suspended from said transverse members of said frame, a flexible, rupturable, plastic sheet cover attached to the sides of said `cell and forming a gas tight enclosure for said cell, openings in said cover through which said anodes protrude, said openings forming a gas tight seal around said anodes, a mercury cathode lflowing Ialong the base of said trough, a cathode contact surface in said trough base comprising alternate longitudinal conductive and non-conductive surfaces, said conductive surfaces being lower and narrower than said non-conductive surface whereby during periods of reduced mercury flow the conductive surfaces remain covered with mercury, and lateral means on said non-conductive surface to direct the flow of mercury to said conductive surfaces, means for imposing an electrical current on said anodes -and said cathode.
5. An apparatus for conducting the electrolysis of electrolytes which comprises an elongated inclined trough, Va metal frame above said trough comprising transverse and longitudinal members, adjustable means to maintain said transverse members at a specified height above said trough, anodes suspended from said transverse members of said frame, a flexible, rupturalble, plastic sheet cover attached to the sides of said cell and forming a gas tight enclosure for said cell, openings in said cover through which said anodes protrude, said openings forming a gas tight seal 4around said anodes, a mercury cathode flowing along the base of said trough, a cathode contact surface in said trough base comprising alternate longitudinal conductive and non-conductive surfaces, said conductive surfaces being lower and narrower than said non-conductive surface and holdback riflles on said conductive surfaces whereby during periods of interrupted mercury flow the conductive surfaces rem-ain covered with mercury, and
means for imposing lan electrical current on said anodes and said cathode.
6. A horizontal electrolysis cell for the electrolysis of electrolytes ywhich comprises an elongated, inclined trough, a metal frame above said trough comprising transverse and longitudinal members, anodes suspended from said transverse members of said frame, `a flexible, rupturable, plastic lsheet cover attached to the sides of said trough, openings in said cover through which said anodes protrude, a mercury cathode flowing along the base of said trough, a cathode contact surface in said trough base comprising a sheet steel base covered with la non-conductive material, steel strips inserted into said non-conductive material and making contact with said sheet steel base, said strips being inserted so as to form a contact surface for the mercury cathode of alternate longitudinal conductive and non-conductive surfaces, said conductive surfaces lbeing lower and narrower than said non-conductive surfaces.
7. A horizontal mercury electrolysis cell for the electrolysis of electrolytes comprising an elongated trough, cover means, `anode means, and a lbase surface over which the mercury flows comprising alternate longitudinal, flat conductive and non-conductive surfaces, said conductive surfaces being lower and narrower than said non-conductive surfaces, the relative elevation of said conductive and non-conductive surfaces being such that said mercury cathode flows over the entire base surface during normal flow of said mercury and preferentially on the conductive surfaces during reduced and interrupted How of ysaid mercury, and lateral holdback ries on said conductive `surfaces.
8. A horizontal mercury electrolysis cell for the electrolysis of electrolytes comprising an elongated trough, cover means, anode means, land la base surface over which the mercury flows comprising alternate longitudinal, at steel conductive and corrosion-resistant, non-conductive surfaces, said conductive surfaces being lower and narrower than said non-conductive surfaces, the relative elevation of said `conductive and non-conductive surfaces being such that said mercury cathode flows over the entire Ibase surface during normal ilow of said mercury and preferentially on the conductive surfaces during reduced and interrupted flow of said mercury, lateral lioldback rilles on said conductive surfaces and lateral means on said noncondncti've surfaces to direct the ow of mercury preferentially to said conductive surfaces during reduced and interrupted flow of mercury.
9. A horizontal mercury electrolysis cell for the electrolysis of electrolytes comprising `an elongated trough, a flexible sheet cover Ine-ans, anode means, and a base surface over which `the mercury flows comprising alternate longitudinal, fiat conductive and non-conductive surfaces, said conductive surfaces being lower and narrower than said non-conductive surfaces, the relative elevation of said conductive and non-conductive surfaces being such that said mercury cathode ilows over the entire base surface during normal flow of said mercury and preferentially on the conductive surfaces during reduced and interrupted flow of said mercury.
References Cited in the file of this patent UNITED STATES PATENTS 1,176,551 Heinemann Mar. 2l, 1916 2,688,594 Oosterman Sept. 7, 1954 2,958,635 De Nora Nov. l, 1960 FOREIGN PATENTS 155,936 Australia Apr. 1, 1954 650,799 Great Britain Mar. 7, 1951
Claims (1)
1. AN APPARATUS FOR CONDUCTING THE ELECTROLYSIS OF ELECTROLYTES WHICH COMPRISES AN ELONGATED INCLINED TROUGH, A METAL FRAME COMPRISING TRANSVERSE AND LONGITUDINAL MEMBERS, ANODES SUSPENDED FROM SAID TRANSVERSE MEMBERS OF SAID FRAME, A FLEXIBLE, RUPTURABLE, PLASTIC SHEET COVER ATTACHED TO THE SIDES OF SAID TROUGH, OPENINGS IN SAID COVER THROUGH WHICH SAID ANODES PROTRUDE, A MERCURY CATHODE FLOWING ALONG THE BASE OF SAID TROUGH, A CATHODE CONTACT SURFACE IN SAID TROUGH BASE COMPRISING ALTERNATE LONFITUDINAL CONDUCTIVE AND NON-CONDUCTIVE SURFACES, SAID CONDUCTIVE SURFACES BEING LOWER AND NARROWER THAN SAID NON-CONDUCTIVE SURFACES WHEREBY DURING PERIODS OF REDUCED MERCURY FLOW THE CONDUCTIVE SURFACES REMAIN COVER WITH MERCURY, AND MEANS FOR IMPOSING AN ELECTRICAL CURRENT ON SAID ANODES AND SAID CATHODE.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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US66378A US3042602A (en) | 1960-10-25 | 1960-10-25 | Horizontal electrolytic cell |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
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US66378A US3042602A (en) | 1960-10-25 | 1960-10-25 | Horizontal electrolytic cell |
Publications (1)
Publication Number | Publication Date |
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US3042602A true US3042602A (en) | 1962-07-03 |
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Family Applications (1)
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US66378A Expired - Lifetime US3042602A (en) | 1960-10-25 | 1960-10-25 | Horizontal electrolytic cell |
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Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US3293161A (en) * | 1963-09-27 | 1966-12-20 | Oronzio De Nora Impianti | Method for starting up mercury cathode electrolytic cells |
US3502561A (en) * | 1966-09-05 | 1970-03-24 | Basf Ag | Alkali-chlorine cell having a horizontal mercury cathode |
US3853738A (en) * | 1969-11-28 | 1974-12-10 | Electronor Corp | Dimensionally stable anode construction |
US20100237576A1 (en) * | 2009-03-23 | 2010-09-23 | Maccario Susan C | Wheeled golf club bag carrier |
Citations (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US1176551A (en) * | 1914-03-27 | 1916-03-21 | Karl Heinemann | Apparatus for decomposing alkali-chlorid solutions. |
GB650799A (en) * | 1946-04-26 | 1951-03-07 | Sadir Carpentier | Frequency band filters |
US2688594A (en) * | 1948-12-27 | 1954-09-07 | American Enka Corp | Mercury cell |
US2958635A (en) * | 1957-12-24 | 1960-11-01 | Oronzio De Nora Impianti | Electrolytic cell cover |
-
1960
- 1960-10-25 US US66378A patent/US3042602A/en not_active Expired - Lifetime
Patent Citations (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US1176551A (en) * | 1914-03-27 | 1916-03-21 | Karl Heinemann | Apparatus for decomposing alkali-chlorid solutions. |
GB650799A (en) * | 1946-04-26 | 1951-03-07 | Sadir Carpentier | Frequency band filters |
US2688594A (en) * | 1948-12-27 | 1954-09-07 | American Enka Corp | Mercury cell |
US2958635A (en) * | 1957-12-24 | 1960-11-01 | Oronzio De Nora Impianti | Electrolytic cell cover |
Cited By (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US3293161A (en) * | 1963-09-27 | 1966-12-20 | Oronzio De Nora Impianti | Method for starting up mercury cathode electrolytic cells |
US3502561A (en) * | 1966-09-05 | 1970-03-24 | Basf Ag | Alkali-chlorine cell having a horizontal mercury cathode |
US3853738A (en) * | 1969-11-28 | 1974-12-10 | Electronor Corp | Dimensionally stable anode construction |
US20100237576A1 (en) * | 2009-03-23 | 2010-09-23 | Maccario Susan C | Wheeled golf club bag carrier |
US8146927B2 (en) | 2009-03-23 | 2012-04-03 | Maccario Susan C | Wheeled golf club bag carrier |
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