US3763029A - Chemical equipment structures - Google Patents

Chemical equipment structures Download PDF

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US3763029A
US3763029A US00190521A US3763029DA US3763029A US 3763029 A US3763029 A US 3763029A US 00190521 A US00190521 A US 00190521A US 3763029D A US3763029D A US 3763029DA US 3763029 A US3763029 A US 3763029A
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shell
bus bar
polyvinylchloride
insulator
support
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US00190521A
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W Karn
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    • CCHEMISTRY; METALLURGY
    • C25ELECTROLYTIC OR ELECTROPHORETIC PROCESSES; APPARATUS THEREFOR
    • C25CPROCESSES FOR THE ELECTROLYTIC PRODUCTION, RECOVERY OR REFINING OF METALS; APPARATUS THEREFOR
    • C25C7/00Constructional parts, or assemblies thereof, of cells; Servicing or operating of cells

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  • PATENTS material such as chlorinated polyvinylchloride are ceg h p 3 mented onto the insulator where the hot bus bar will uc anan 04/279 3,088,539 5/1963 Mathues et al. 264/45 Contact the msulator m Service 3,556,975 1/1971 Hass et al 204/297 R 5 Claims, 2 Drawing Figures CHEMICAL EQUIPMENT STRUCTURES
  • Another object of this invention is to provide convenient means for forming a thermosetting material into a structural member while simultaneously providing for protection of the surface of the thermosetting material.
  • FIG. 1 is the insulator.
  • FIG. 2 is a cross sectional view of the insulator along the line A-A of FIG. 1.
  • wood has been widely used as bus bar insulator supports in electrolytic cells for refining copper.
  • Wood has also been used in structural service in other acid containing tanks and systems.
  • organic polymeric materials such as polyolefins, polyvinylchloride, chlorinated polyethers, among the thermoplastic materials and the polyesters and epoxies among the thermosetting materials have lent new scope to construction materials for chemical equipment.
  • One electrolytic copper refining plant employed slabs of polyvinylchloride to support the copper bus bars which are placed along the edges of the electrolytic refining tanks. The copper bus grows hot from the heavy current which it conducts.
  • polyvinylchloride slabs scorched slightly and turned brown in the vicinity of contact with the hot copper. Also the free ends of the polyvinylchloride slabs bowed upward under the weight of the copper combined with the thermal softening action. Aside from these difficulties, polyvinylchloride was a meritorious choice for its chemical resistance to the hot l7 percent sulfuric acid copper sulfate bath solution.
  • My design offers means for removing the hot bus bar from immediate contact with the polyvinylchloride.
  • My design offers means for using a rigid, thermosetting material for the structural support while still having the freedom to select an exposed surface material of high chemical resistance.
  • EXAMPLE I I made a pattern for thermovacuum forming. It was several feet long, about 6 inches wide, about 1 inch high, with sloped sides, with rounded edges, and with certain desired salient contours. A sheet of polyvinylchloride one-sixteenth inch thick was thermoformed over the pattern. The sheet was not afterward trimmed of the flared edges. Instead I exposed a narrow line to a reheating step and folded each edge inward to form a pan with re-entrant lips (See section A-A, FIG. 1). After making several short slits I similarly folded in the ends. The thermoformed shell was then laid open side up on a frame that held it bent slightly concave downward. This was to off-set a shrinkage distortion that occurs in the casting step.
  • Amixture of percent by weight dry quartz sand, 40 percent by weight catalyzed polyester resin was prepared and poured into the shell to form a core. After the resin had cured the composit structure made a very strong, durable structure suitable as a mechanical support in industrial chemical service.
  • Example I The structure of Example I was formed, but several layers of glass fiber mat were applied to'the interior of the shell as the initial interior layer and as the final core surface (pieces 3 and 4 of FlG.l, section A-A). In ad- 'dition, pads of fiberglass mat were cemented with a rubber cement onto the top surface of the core filled structural member where the copper bus bars would bear. Some alternate pad materials are chlorinated polyvinylchloride and chlorinated polyether cemented with a tetrahydrofuran solvent base cement. Any one of these attached pad materials is considered a second surface material as described in the claims section. It may be noted that this was a sample test piece and a full length insulator may be about 15 feet long and support electrodes every 2 inches.
  • EXAMPLE in The shell of Example I is prepared. A thin layer of fiberglass mat wetted with a thermosetting resin is placed against the interior surface. After curing of the resin the remainder of the void is filled with concrete prepared with a hydraulic cement.
  • Example III the shell and concrete may be the only materials used to form the structural member. With a convoluted shell there can be sufficient keying to lodge the concrete securely.
  • One may form the structural members as described in the examples. The members may then be grouped or stacked so as to form tanks, walls, troughs, pans, etc.
  • the joints may be readily closed with an appropriate plastic cement or plastic welding technique.
  • thermosetting any material capable of being cast, poured, or molded after which it sets to an infusable, unworkable mass.
  • materials include polyester resins and epoxies.
  • the hydraulic cements such as portland cement also fall within the scope of a thermosetting material.
  • thermoplastic material includes the many common plastics like polyvinylchloride, chlorinated polyvinylchloride, polyolefins and new materials under development, all of which are repeatedly formable by the application of heat. I choose also to include under my usage of the term thermoplastie in this patent application such materials as are commonly thought of as thermoplastics but may by such means as incorporation of peroxides or exposure to ionizing radiation become crosslinked and rendered infusable, e.g. crosslinked polyethylene.
  • a bus bar insulator support for electrolytic cells comprising a shell formed from sheet thermoplastic material selected from the group consisting of polyvinylchloride, chlorinated polyvinyl chloride and polyolefin and having a rigid core formed of a thermosetting plastic material, selected from the group consisting of polyester and epoxy resins said core being formed by 4.
  • the bus bar insulator support of claim 1 wherein said shell has pads of glass fiber attached to the surface of said shell in the bus bar support bearing regions of said shell.
  • bus bar insulator support of claim 2 wherein said shell has pads of chlorinated polyvinylchloride attached to the surface of said shell in the bus bar support bearing regions of said shell.

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  • Chemical & Material Sciences (AREA)
  • Engineering & Computer Science (AREA)
  • Chemical Kinetics & Catalysis (AREA)
  • Electrochemistry (AREA)
  • Materials Engineering (AREA)
  • Metallurgy (AREA)
  • Organic Chemistry (AREA)
  • Laminated Bodies (AREA)

Abstract

An insulator to be used on electrolytic copper refining cells to support the bus bars and electrodes is constructed of a thin sheet of polyvinylchloride thermoformed into a pan shaped cavity into which is cast a mixture of polyester resin and quartz sand. After casting, the piece is inverted and strips of more refractory material such as chlorinated polyvinylchloride are cemented onto the insulator where the hot bus bar will contact the insulator in service.

Description

I United States Patent 1 1111 3,763,029 Karn 1 Oct. 2, 1973 [54] CHEMICAL EQUIPMENT STRUCTURES 3,563,878 2/I97l Grotheer 204/297 R Inventor: W am Snyder Karn, 5'8 Dickson 3,697,404 l0/I972 Paige 204/267 Ave, Pittsburgh, Pa. 15202 FOREIGN PATENTS OR APPLICATIONS [22 pu Oct. 9 197 873,518 7/I967 Great Britain 264/45 [21] Appl' 9052! Primary ExaminerF C. Edmundson [52] [1.8. CI 204/279, 52/309, 52/406, 57] ABSTRACT 204/286, 204/297 R [51] Int Cl 0 C23, 5,70, Bulk 1/00 Bulk 3/0() An msulator to be used on electrolytic copper refining [58] Field of Search 52,309 264/45 cells to support the bus bars and electrodes is con- 204/279 297 structed of a thin sheet of poly'vinylchloride thermoformed into a pan shaped cavity into which is cast a [56] References Cited mixture of polyester resin and quartz sand. After cast- 7 ing, the piece is inverted and strips of more refractory UNITED STATES PATENTS material such as chlorinated polyvinylchloride are ceg h p 3 mented onto the insulator where the hot bus bar will uc anan 04/279 3,088,539 5/1963 Mathues et al. 264/45 Contact the msulator m Service 3,556,975 1/1971 Hass et al 204/297 R 5 Claims, 2 Drawing Figures CHEMICAL EQUIPMENT STRUCTURES Another object of this invention is to provide convenient means for forming a thermosetting material into a structural member while simultaneously providing for protection of the surface of the thermosetting material.
FIG. 1 is the insulator. FIG. 2 is a cross sectional view of the insulator along the line A-A of FIG. 1.
A fuller understanding of the invention may be had by referring to the description taken in conjunction with the accompanying drawing which shows a structural member comprising, a shell (piece I), a core (piece 2), additional variations of core and shell compositions (pieces 3 and 4), and second surface materials (pieces 5) attached to the shell.
In the past wood has been widely used as bus bar insulator supports in electrolytic cells for refining copper. Wood has also been used in structural service in other acid containing tanks and systems. In more recent years some of the organic polymeric materials such as polyolefins, polyvinylchloride, chlorinated polyethers, among the thermoplastic materials and the polyesters and epoxies among the thermosetting materials have lent new scope to construction materials for chemical equipment. One electrolytic copper refining plant employed slabs of polyvinylchloride to support the copper bus bars which are placed along the edges of the electrolytic refining tanks. The copper bus grows hot from the heavy current which it conducts. In this particular installation the polyvinylchloride slabs scorched slightly and turned brown in the vicinity of contact with the hot copper. Also the free ends of the polyvinylchloride slabs bowed upward under the weight of the copper combined with the thermal softening action. Aside from these difficulties, polyvinylchloride was a meritorious choice for its chemical resistance to the hot l7 percent sulfuric acid copper sulfate bath solution. My design offers means for removing the hot bus bar from immediate contact with the polyvinylchloride. My design offers means for using a rigid, thermosetting material for the structural support while still having the freedom to select an exposed surface material of high chemical resistance.
EXAMPLE I I made a pattern for thermovacuum forming. It was several feet long, about 6 inches wide, about 1 inch high, with sloped sides, with rounded edges, and with certain desired salient contours. A sheet of polyvinylchloride one-sixteenth inch thick was thermoformed over the pattern. The sheet was not afterward trimmed of the flared edges. Instead I exposed a narrow line to a reheating step and folded each edge inward to form a pan with re-entrant lips (See section A-A, FIG. 1). After making several short slits I similarly folded in the ends. The thermoformed shell was then laid open side up on a frame that held it bent slightly concave downward. This was to off-set a shrinkage distortion that occurs in the casting step. Amixture of percent by weight dry quartz sand, 40 percent by weight catalyzed polyester resin was prepared and poured into the shell to form a core. After the resin had cured the composit structure made a very strong, durable structure suitable as a mechanical support in industrial chemical service.
EXAMPLE [I The structure of Example I was formed, but several layers of glass fiber mat were applied to'the interior of the shell as the initial interior layer and as the final core surface (pieces 3 and 4 of FlG.l, section A-A). In ad- 'dition, pads of fiberglass mat were cemented with a rubber cement onto the top surface of the core filled structural member where the copper bus bars would bear. Some alternate pad materials are chlorinated polyvinylchloride and chlorinated polyether cemented with a tetrahydrofuran solvent base cement. Any one of these attached pad materials is considered a second surface material as described in the claims section. It may be noted that this was a sample test piece and a full length insulator may be about 15 feet long and support electrodes every 2 inches.
EXAMPLE in The shell of Example I is prepared. A thin layer of fiberglass mat wetted with a thermosetting resin is placed against the interior surface. After curing of the resin the remainder of the void is filled with concrete prepared with a hydraulic cement.
In Example III the shell and concrete may be the only materials used to form the structural member. With a convoluted shell there can be sufficient keying to lodge the concrete securely. One may form the structural members as described in the examples. The members may then be grouped or stacked so as to form tanks, walls, troughs, pans, etc. The joints may be readily closed with an appropriate plastic cement or plastic welding technique.
Below are presented a definition of several terms and their scope as used in'this patent application.
By a thermosetting'material is meant any material capable of being cast, poured, or molded after which it sets to an infusable, unworkable mass. Such materials include polyester resins and epoxies. The hydraulic cements such as portland cement also fall within the scope of a thermosetting material.
An organic polymeric thermoplastic material includes the many common plastics like polyvinylchloride, chlorinated polyvinylchloride, polyolefins and new materials under development, all of which are repeatedly formable by the application of heat. I choose also to include under my usage of the term thermoplastie in this patent application such materials as are commonly thought of as thermoplastics but may by such means as incorporation of peroxides or exposure to ionizing radiation become crosslinked and rendered infusable, e.g. crosslinked polyethylene.
I claim:
1. A bus bar insulator support for electrolytic cells comprising a shell formed from sheet thermoplastic material selected from the group consisting of polyvinylchloride, chlorinated polyvinyl chloride and polyolefin and having a rigid core formed of a thermosetting plastic material, selected from the group consisting of polyester and epoxy resins said core being formed by 4. The bus bar insulator support of claim 1 wherein said shell has pads of glass fiber attached to the surface of said shell in the bus bar support bearing regions of said shell.
5. The bus bar insulator support of claim 2 wherein said shell has pads of chlorinated polyvinylchloride attached to the surface of said shell in the bus bar support bearing regions of said shell.

Claims (4)

  1. 2. A bus bar insulator support for electrolytic cells comprising a shell formed from sheet polyvinylchloride and having a rigid core formed by casting a mixture of polyester resin and sand in said shelL.
  2. 3. The bus bar insulator support of claim 1 wherein said shell has pads of chlorinated polyvinylchloride attached to the surface of said shell in the bus bar support bearing regions of said shell.
  3. 4. The bus bar insulator support of claim 1 wherein said shell has pads of glass fiber attached to the surface of said shell in the bus bar support bearing regions of said shell.
  4. 5. The bus bar insulator support of claim 2 wherein said shell has pads of chlorinated polyvinylchloride attached to the surface of said shell in the bus bar support bearing regions of said shell.
US00190521A 1971-10-19 1971-10-19 Chemical equipment structures Expired - Lifetime US3763029A (en)

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Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US4009916A (en) * 1973-09-21 1977-03-01 Mcclure Furniture Industries, Inc. Chipcore panel with rounded and bevelled edges overlaid with a sheet of plastic material
US4213842A (en) * 1978-08-04 1980-07-22 Dufresne Jean L Capping board for electrolytic metal refining
US4479863A (en) * 1983-04-05 1984-10-30 Cominco Ltd. Cell top insulator
US5645701A (en) * 1996-03-08 1997-07-08 Dufresne; Jean L. Capping board with pultruded filling bars

Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US4009916A (en) * 1973-09-21 1977-03-01 Mcclure Furniture Industries, Inc. Chipcore panel with rounded and bevelled edges overlaid with a sheet of plastic material
US4213842A (en) * 1978-08-04 1980-07-22 Dufresne Jean L Capping board for electrolytic metal refining
US4479863A (en) * 1983-04-05 1984-10-30 Cominco Ltd. Cell top insulator
US5645701A (en) * 1996-03-08 1997-07-08 Dufresne; Jean L. Capping board with pultruded filling bars

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