US2730434A - Catalytic contacting unit - Google Patents

Catalytic contacting unit Download PDF

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US2730434A
US2730434A US159191A US15919150A US2730434A US 2730434 A US2730434 A US 2730434A US 159191 A US159191 A US 159191A US 15919150 A US15919150 A US 15919150A US 2730434 A US2730434 A US 2730434A
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elements
unit
catalytic
end members
members
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Eugene J Houdry
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Oxy Catalyst Inc
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Oxy Catalyst Inc
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    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01JCHEMICAL OR PHYSICAL PROCESSES, e.g. CATALYSIS OR COLLOID CHEMISTRY; THEIR RELEVANT APPARATUS
    • B01J35/00Catalysts, in general, characterised by their form or physical properties
    • B01J35/30

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  • Another object is to support the contacting and catalyticielernents in such a manner that friction and attrition are avoided thereby to prolong the life and effective use of 'such elements.
  • Another object is to provide the contacting elements in units for convenient handling, assembly, impregnation fwith catalysts, and mounting, while furnishing a desired degree of flexibility as to number, disposition, and arrangement of elements for control of temperature, pressure, and time of contact.
  • the fluid contacting or catalytic elements are formed in units or assemblies which may be utilized individually or stacked adjacent to or upon one another like bricks.
  • the parts of these units or assemblies are of dense hard material having any suitable or desired degree of porosity or absorptivity, usually slight or low, such as ceramic material including porcelain, and the latter may be of the type used for the cores of spark plugs, and which has been heated to high temperatures of the order of 2000" and above.
  • the unitary structure comprises upper and lower apertured members or plates maintained in fixed spaced relation by one or more posts or spacer bars, the apertures in the members or plates being disposed in alignment for the individual insertion of elongate elements in the form of rods or sticks.
  • Fig. 3 is a longitudinal sectional view, taken on the line 3-3 of Fig. 4, showing a modification of the invention
  • Fig. 4 is an end elevational or top plan view of the unit shown in Fig. 3, the left half of unit being without elements;
  • Fig. 5 is a perspective view on an enlarged scale of one form of element for mounting in the unit shown in Figs. 3 and 4;
  • Fig. 6 is a transverse sectional view on a still larger scale, the section being taken on the line 66 of Fig. 5;
  • Fig. 7 is a plan or end elevational view similar to Fig. 4 of a modified form of unit, elements to fit the apertures being omitted;
  • Figs. 8 and 9 are perspective views on an enlarged I scale of elements to be mounted in the unit of Fig. 7;
  • Fig. 10 is a transverse sectional view on a still larger scale on the line 10-10 of Fig. 9.
  • the contacting or catalytic unit comprises a pair of apertured end members or plates 11 in spaced relation to each other and secured to a central spacer or post 12 to form a frame, adapted to support a multiplicity of contacting or catalytic elements 13.
  • elements 13 are round in cross section and extend between end members 11 and have their ends seated in aligned pairs of apertures 11a.
  • Spacer or post 12 is square in cross section and extends through openings of the same configuration in end members or plates 11, inwardly directing bosses 11b on the latter insuring secure attachment between post 12 and members 11 and imparting strength and rigidity to the frame.
  • Elements 13 are in the form of rods which are inserted endwise through aligned apertures 11a to be supported individually and independently of one another.
  • elements or rods 13 are cemented, glazed or otherwise anchored in the apertures of one of endmembers 11 while care is taken to see that their other ends are freely slidable in the apertures of the other end member 11. This arrangement prevents breakage of elements 13 or of end members 11 when temperature differences occur in the parts of the unit.
  • apertures 11a in members or plates 11 dispose elements 13 in rows with adjacent elements in staggered arrangement so that fluids sent through this unit from the side, as in the direction of the arrow d on Fig. 1, are caused to flow over and around each element.
  • the lower end member or plate 21 of the frame has its apertures 21a extending only partly therethrough to provide a positive stop for the lower ends of elements 23 which are mounted in the frame by inserting them through the apertures 22a in upper end member or plate 22.
  • a central spacer or post 24 is attached at its ends to members or plates 21 and 22 to form the frame of the unit, the ends 24a of the spacer 24 being reduced in size to provide stop shoulders 24b to engage the inner faces of members 21 and 22 as indicated in Fig. 3.
  • Figs. 4 5 and 6 elements 23 to be mounted in the frame of Fig.
  • FIGS. 3 are of teardrop or streamlined design in cross section and the apertures 21a and 22a in end members or plates 21 and 22 are of complementary shape and are all disposed in the same direction. Since the elements or rods, 23, are rounded at one vertical edge 23a and tapered toward the opposite vertical edge 23b (as shown in Figs. 4, 5 and 6) to produce a streamlined effect, they offer the possibility of a minimum pressure drop in reactants passing thereover in the direction of movement indicated by arrow d of Fig. 4 and at the same time give the best contact of the reactants with the surfaces of elements 23 while producing a minimum of turbulence.
  • the lower ends of elements 23 will be secured in apertures 21a of lower member or plate 21 by cementing, glazing or otherwise while their upper ends will be freely slidable in apertures 22a of upper member or plate 22.
  • Figs. 7, 8, 9 and 10 illustrate further modifications of the contacting unit and of the elements supported thereby, in this instance, for creating turbulence and a greater period and extent of contact of reactants with the elements.
  • FIG. 7 there are two spacers or posts 34 (similar to spacer 24 of Figs. 3 and 4) to support and hold end members or plates 31 (only one of which is shown) in spaced relation.
  • Apertures 31a to receive elements 33 (Fig. 8) or elements 36 (Fig. 9 and Fig. 10) are rectangular in shape and are not only staggered relative to the apertures in adjacent rows (as in the modifications of Figs. 1 and 2 and of Figs.
  • Fig. 8 shows element 33 provided with a series of cross or transverse ribs 330 on its widest sides While element 36 of Figs. 9 and 10 has longitudinally extending or vertical ribs 36:: on all its sides.
  • Element 33 is shown in Fig. 8 as having rectangular ends 33b loosely to fit apertures 31a in end members or plates 31 of Fig. 7.
  • the transverse ribs 33a may be formed throughout the length of element 33 without interference with its mounting in the frame of the unit or its use when so mounted.
  • the longitudinal or vertical ribs 36a of element 36 of Figs. 9 and 10 may be extended to the veryends of the element, thus eliminating the rectangular ends 36b shown thereon, in which case the apertures 31ain members 31 could be made, if desired, to conform to the cross section of element 36 shown in Fig. 10.
  • both elements 33 and 36 in any desired distribution may be mounted in the same unit.
  • the elements 33 and 36 will be secured at one end to one of the end members or plates 31 while their other ends are freely slidable in the apertures 31a of the other end member or plate.
  • the various parts making up the herein described units may be of any suitable or desired materials, catalytically active or inactive, and if absorbent, of any suitable or de sired degree of porosity, so as to assist or to promote any desired type of operation or reaction.
  • One kind of material particularly adapted to units of the present invention is ceramic material, such as porcelain.
  • the latter can be readily molded, cast or extruded into the forms illustrated and can by composition and subsequent firing be made of any desired degree of porosity in the range of substantially no or slight porosity to about 60% porosity. By firing into the range of 2300 to 3900 F. it can be made stable both physically and chemically as well as catalytically inert.
  • the unit can be made of any desired size and the end members or plates may be shaped as required to fit, or for use in, a particular reaction chamber.
  • the elements may be in any desired number, form and arrangement.
  • a square or rectangular shape for the end members or plates, as shown in Figs. 2, 4 and 7, is desirable for stacking or side-by-side disposition of units.
  • Figs. 1 and 2 makes provision for 196 round elements or rods 13
  • the modification of Figs. 3 and 4 provides for 73 streamlined elements or rods 23, while the modification of Fig. 7 will hold 63 elements or rods such as 33 and 36.
  • One use of units of the type of Figs. 1 and 2 is set forth in my copending application Serial No. 117,490 filed September 23, 1949.
  • a firmly adherent base or film of active alumina may be applied in any suitable or desired manner to the unit or its parts followed by impregnating such base or film with other and additional finely divided metals or oxides.
  • Such a combination and arrangement of catalytic materials has been found to be characterized in many instances by exceptionally high activity for the promotion of many reactions, both endothermic and exothermic, and to be further characterized by long life.
  • a nickel catalyst should be deposited on the base film of active alumina.
  • the parts of the unit should be formed of porcelain or the like which is practically impervious or of extremely low porosity so that only the catalytically active material deposited on the surface of the parts of the unit will contact the oil or fats undergoing hydrogenation. Separation of reactants can then be easily efiected with obvious economies and advantages.
  • the present invention provides a contacting or catalytic unit in which contacting or catalytic elements may be fixedly mounted 'so that each element is independent of the other, thereby avoiding friction and consequent damage to the elements and partial or complete destruction of catalysts impregnated therein or applied thereto in the form of films, that the elements are not in compact relationship with one anotherbut are spaced from one another so that low pressure drops through the units are easily obtained and the problem of excessive temperatures can be solved by adjusting the number and distribution of elements in each unit, and that the units and elements therefor may be formed and arranged to produce a minimum of turbulence and contact or great turbulence and extensive contact thereby effectively to control the rate and extent of a catalytic or contacting reaction.
  • a catalytic unit through which a fluid may flow comprising a pair of end members secured to one another in spaced relation by a single post extending between said members and to which said members are rigidly fastened, and a plurality of elongated elements extending between said end members and supported at both ends thereby, each .of said elements providing a surface of catalytic material exposed to the flow of fluid passing through the unit, said unit being open laterally for the passage of fluid therethrough in a direction transverse to said elongated elements.
  • a catalytic unit according to claim 1 in which the surfaces of catalytic material are provided by coatings on said elements.
  • a catalytic unit through which a fluid may flow comprising a pair of end members secured to one another in spaced relation by a single post extending between said members and to which said members are rigidly fastened, and a plurality of elongated elements extending between said end members and supported at both ends thereby, said elements being disposed in rows with the elements in each row in staggered relation with the elements in adjacent rows, and each of said elements providing a surface of catalytic material exposed to the flow of fluid passing through the unit, said unit being open laterally for the passage of fluid therethrough in a direction transverse to said elongated elements.
  • a catalytic unit through which a fluid may flow comprising a pair of end members secured to one another in spaced relation by a single post extending between said members and to which said members are rigidly fastened, and a plurality of elongated elements extending between said end members and supported at both ends thereby, each of said elements having at least one end free to move longitudinally with respect to an end member, each of said elements providing a surface of catalytic material exposed to the flow of fluid passing through the unit, said unit being open laterally for the passage of fluid therethrough in a direction transverse to said elongated elements.
  • a catalytic unit through which a fluid may flow comprising a pair of end members secured to one another in spaced relation by a single post extending between said members and to which said members are rigidly fastened, and a plurality of elongated elements extending between said end members and supported at both ends thereby, each of said elements having in transverse section rounded and tapered portions forming a streamlined contour to minimize turbulence in the flowing fluid, and each of said elements providing a surface of catalytic material exposed to the flow of fluid passing through the unit, said unit being open laterally for the passage of fluid therethrough in a direction transverse to said elongated elements.
  • a catalytic unit through which fluid may. flow which comprises a pair of platelike end members, a single post for rigidly positioning said end members in parallel, spaced relaionship, said end members being centrally fastened to said post at either end thereof, a plurality of elongated elements extending between said end members and supported at both ends thereby, at least one end of each of said elements being free to move longitudinally with respect to one of said end members, each of said elements providing a surface of catalytic material exposed to the flow of fluid passing through the unit, said unit being open laterally for the passage of fluid therethrough in a direction transverse to said elongated elements.
  • a multi-unit catalytic assembly for providing an extended area of catalytic surface, each unit of said assembly comprising a pair of end members secured to one another in spaced relation by a single post extending between said members and to which said members are rigidly fastened, and a plurality of elongated elements extending between said end members and supported at both ends thereby, each of said elements providing a surface of catalytic material exposed to the flow of a fluid passing through the unit, said units being open laterally for the passage of fluid therethrough in a direction transverse to said elongated elements.
  • a catalytic unit for carrying out high temperature catalytic reactions which comprises a pair of plate-like end members composed of ceramic material, a single post composed of ceramic material for rigidly positioning said end members in parallel, spaced relationship, said end members being centrally fastened to said post at either end thereof, a plurality of elongated, rod-like, elements composed of ceramic material extending between said end members and supported at both ends thereby, at least one end of each of said elements being free to move longitudinally with respect to one of said end members, each of said rod-like elements being provided with a relatively thin film of catalytic material exposed to the flow of fluid passing through the unit, said unit being open laterally for the passage of fluid therethrough in a direction transverse to said elongated elements.
  • a ceramic unit for use in carrying out high temperature reactions which comprises a pair of plate-like end members of ceramic material, a single post of ceramic material for rigidly positioning said end members in parallel, spaced relationship, said end members being centrally fastened to said post at either end thereof, a plurality of elongated rod-like elements composed of ceramic material extending between said end members and supported at both ends thereby, at least one end of each element being free to move longitudinally with respect to one of said end members, said unit being open laterally for the passage of fluid therethrough in a direction transverse to said elongated elements.
  • a catalytic unit adapted for high temperature catalytic reactions which comprises a pair of plate-like end members composed of ceramic material, a single post composed of ceramic material for rigidly positioning said end members in parallel, spaced relationship, said end members being centrally fastened to said post at either end thereof, a plurality of elongated rod-like elements extending between said end members and supported at both ends thereby, said elements being disposed in rows With the elements in each row in staggered relation with respect to the elements in adjacent rows, each of said elements having in transverse section rounded and tapered portions forming a streamlined contour to minimize turbulence in the flowing fluid, at least one end of each of said elements being free to move longitudinally with respect to one of said end members, each of said rod-like elements being provided with a relatively thin film of catalytic material exposed to the flow of fluid passing through the unit, said unit being open laterally for the passage of fluid therethrough in a direction transverse to said elongated elements.

Description

Jan. 10, 1956 HOUDRY 2,730,434
CATALYTIC CONTACTING UNIT Filed May 1, 1950 3 Sheets-Sheet l Ila llb
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Jan. 10, 1956 E. J. HOUDRY 2,730,434
CATALYTIC CONTACTING UNIT Filed May 1. 1950 5 Sheets-Sheet 2 75:4 Il 600000666 A F/G4. Q
INVENTOR. F EUGENE J, HOUDRV ATTORNEY.
Jan. 10, 1956 INVENTOR. EUGENE J1 HOUDR) .xgtq 0C AITORNEY.
United States Patent CATALYTIC CONTACTING UNIT Eugene J. Houdry, Ardmore, Pa., assignor to Oxy-Catalyst, Inc., a corporation of Pennsylvania Application May 1, 1950, Serial No. 159,191
Claims. (Cl. 23-288) and support of contacting and catalytic elements.
Another object is to support the contacting and catalyticielernents in such a manner that friction and attrition are avoided thereby to prolong the life and effective use of 'such elements.
Another object is to provide the contacting elements in units for convenient handling, assembly, impregnation fwith catalysts, and mounting, while furnishing a desired degree of flexibility as to number, disposition, and arrangement of elements for control of temperature, pressure, and time of contact.
.Other objects and advantages will be apparent from the detailed description which follows.
In accordance with the present invention the fluid contacting or catalytic elements are formed in units or assemblies which may be utilized individually or stacked adjacent to or upon one another like bricks. By preference, the parts of these units or assemblies are of dense hard material having any suitable or desired degree of porosity or absorptivity, usually slight or low, such as ceramic material including porcelain, and the latter may be of the type used for the cores of spark plugs, and which has been heated to high temperatures of the order of 2000" and above. The unitary structure comprises upper and lower apertured members or plates maintained in fixed spaced relation by one or more posts or spacer bars, the apertures in the members or plates being disposed in alignment for the individual insertion of elongate elements in the form of rods or sticks. Each element is by preference secured at one end to one of the end members or plates and is endwise movable in the aperture therefor in the other member or plate so as to avoid breakage from expansion and contraction during temperature changes. Time and extent of contact of fluids is determined in part by the number of elements mounted in the apertures in the end members of each unit and by the size, shape, arrangement and cross sectional contour of Fig. 3 is a longitudinal sectional view, taken on the line 3-3 of Fig. 4, showing a modification of the invention;
Fig. 4 is an end elevational or top plan view of the unit shown in Fig. 3, the left half of unit being without elements;
Fig. 5 is a perspective view on an enlarged scale of one form of element for mounting in the unit shown in Figs. 3 and 4;
Fig. 6 is a transverse sectional view on a still larger scale, the section being taken on the line 66 of Fig. 5;
Fig. 7 is a plan or end elevational view similar to Fig. 4 of a modified form of unit, elements to fit the apertures being omitted;
Figs. 8 and 9 are perspective views on an enlarged I scale of elements to be mounted in the unit of Fig. 7;
and
Fig. 10 is a transverse sectional view on a still larger scale on the line 10-10 of Fig. 9.
As shown in Figs. 1 and 2 the contacting or catalytic unit comprises a pair of apertured end members or plates 11 in spaced relation to each other and secured to a central spacer or post 12 to form a frame, adapted to support a multiplicity of contacting or catalytic elements 13. As indicated in Fig. 2 elements 13 are round in cross section and extend between end members 11 and have their ends seated in aligned pairs of apertures 11a. Spacer or post 12 is square in cross section and extends through openings of the same configuration in end members or plates 11, inwardly directing bosses 11b on the latter insuring secure attachment between post 12 and members 11 and imparting strength and rigidity to the frame. Elements 13 are in the form of rods which are inserted endwise through aligned apertures 11a to be supported individually and independently of one another. By preference elements or rods 13 are cemented, glazed or otherwise anchored in the apertures of one of endmembers 11 while care is taken to see that their other ends are freely slidable in the apertures of the other end member 11. This arrangement prevents breakage of elements 13 or of end members 11 when temperature differences occur in the parts of the unit.
As indicated by Fig. 2 apertures 11a in members or plates 11 dispose elements 13 in rows with adjacent elements in staggered arrangement so that fluids sent through this unit from the side, as in the direction of the arrow d on Fig. 1, are caused to flow over and around each element.
In the modification of the invention shown in Figs. 3-6 the lower end member or plate 21 of the frame has its apertures 21a extending only partly therethrough to provide a positive stop for the lower ends of elements 23 which are mounted in the frame by inserting them through the apertures 22a in upper end member or plate 22. A central spacer or post 24 is attached at its ends to members or plates 21 and 22 to form the frame of the unit, the ends 24a of the spacer 24 being reduced in size to provide stop shoulders 24b to engage the inner faces of members 21 and 22 as indicated in Fig. 3. As clearly shown by Figs. 4, 5 and 6 elements 23 to be mounted in the frame of Fig. 3 are of teardrop or streamlined design in cross section and the apertures 21a and 22a in end members or plates 21 and 22 are of complementary shape and are all disposed in the same direction. Since the elements or rods, 23, are rounded at one vertical edge 23a and tapered toward the opposite vertical edge 23b (as shown in Figs. 4, 5 and 6) to produce a streamlined effect, they offer the possibility of a minimum pressure drop in reactants passing thereover in the direction of movement indicated by arrow d of Fig. 4 and at the same time give the best contact of the reactants with the surfaces of elements 23 while producing a minimum of turbulence. The lower ends of elements 23 will be secured in apertures 21a of lower member or plate 21 by cementing, glazing or otherwise while their upper ends will be freely slidable in apertures 22a of upper member or plate 22.
Figs. 7, 8, 9 and 10 illustrate further modifications of the contacting unit and of the elements supported thereby, in this instance, for creating turbulence and a greater period and extent of contact of reactants with the elements. In the form shown in Fig. 7 there are two spacers or posts 34 (similar to spacer 24 of Figs. 3 and 4) to support and hold end members or plates 31 (only one of which is shown) in spaced relation. Apertures 31a to receive elements 33 (Fig. 8) or elements 36 (Fig. 9 and Fig. 10) are rectangular in shape and are not only staggered relative to the apertures in adjacent rows (as in the modifications of Figs. 1 and 2 and of Figs. 3 and 4) but are also zig-zagged to baflie and to create turbulence and frequent changes in direction in reactants sent through the unit from any side. In order to effect further turbulence and extended contact with the elements mounted in apertures 31a the surfaces of the elements are made irregular or of increased extent in any desired manner. One way to accomplish this is to form ribs on the elements. Fig. 8 shows element 33 provided with a series of cross or transverse ribs 330 on its widest sides While element 36 of Figs. 9 and 10 has longitudinally extending or vertical ribs 36:: on all its sides.
Element 33 is shown in Fig. 8 as having rectangular ends 33b loosely to fit apertures 31a in end members or plates 31 of Fig. 7. However, it is obvious that, if desired, the transverse ribs 33a may be formed throughout the length of element 33 without interference with its mounting in the frame of the unit or its use when so mounted. In a similar manner the longitudinal or vertical ribs 36a of element 36 of Figs. 9 and 10 may be extended to the veryends of the element, thus eliminating the rectangular ends 36b shown thereon, in which case the apertures 31ain members 31 could be made, if desired, to conform to the cross section of element 36 shown in Fig. 10. By providing rectangular apertures 31a in end members or plates 31 both elements 33 and 36 in any desired distribution may be mounted in the same unit. As in the previously described forms of the invention the elements 33 and 36 will be secured at one end to one of the end members or plates 31 while their other ends are freely slidable in the apertures 31a of the other end member or plate.
The various parts making up the herein described units may be of any suitable or desired materials, catalytically active or inactive, and if absorbent, of any suitable or de sired degree of porosity, so as to assist or to promote any desired type of operation or reaction. One kind of material particularly adapted to units of the present invention is ceramic material, such as porcelain. The latter can be readily molded, cast or extruded into the forms illustrated and can by composition and subsequent firing be made of any desired degree of porosity in the range of substantially no or slight porosity to about 60% porosity. By firing into the range of 2300 to 3900 F. it can be made stable both physically and chemically as well as catalytically inert. It is then useful as a support, in or on which catalytic materials can be incorporated in any known or suitable manner as by dipping, immersing, spraying, etc. Bonding of the elements such as 13, 23, 33 and 36 to one of the end members or plates of the frame is frequently incidental to incorporating or applying catalytic materials to the assembled unit, as by dipping the latter up to but not including the top end member or plate (as 22 of Fig. 3), followed by heating step to decompose the solution or mixture so as to deposit the catalytic material in active form in or on the frame and elements mounted therein. On the other hand, the individual parts making up the units may have catalytic material incor- 4 porated therein or deposited thereon prior to assembly of the unit.
The unit can be made of any desired size and the end members or plates may be shaped as required to fit, or for use in, a particular reaction chamber. The elements may be in any desired number, form and arrangement. A square or rectangular shape for the end members or plates, as shown in Figs. 2, 4 and 7, is desirable for stacking or side-by-side disposition of units. Of the units shown on the drawings, that of Figs. 1 and 2 makes provision for 196 round elements or rods 13, the modification of Figs. 3 and 4 provides for 73 streamlined elements or rods 23, while the modification of Fig. 7 will hold 63 elements or rods such as 33 and 36. One use of units of the type of Figs. 1 and 2 is set forth in my copending application Serial No. 117,490 filed September 23, 1949.
In general in utilizing the unit as a support for catalysts, a firmly adherent base or film of active alumina (or alternatively of magnesia, beryllia or thoria) may be applied in any suitable or desired manner to the unit or its parts followed by impregnating such base or film with other and additional finely divided metals or oxides. Such a combination and arrangement of catalytic materials has been found to be characterized in many instances by exceptionally high activity for the promotion of many reactions, both endothermic and exothermic, and to be further characterized by long life. For example, for catalytic reactions of the oxidation type, such as oxidation of CO to CO2, the base film of alumina or the like should be impregnated with platinum, or silver, or copper; for oxidation of S02 to $03, platinum or vanadium oxide should be deposited on the base film; for synthesis of methane by the reaction of CO+3H2=CH4+H2O, cobalt or nickel should be added to the base film of active alumina or the like.
If the unit is to be used to promote a hydrogenation reaction, such as the hydrogenation of fats, a nickel catalyst should be deposited on the base film of active alumina. When the nickel hydrogenation of fats is in the liquid phase, the parts of the unit should be formed of porcelain or the like which is practically impervious or of extremely low porosity so that only the catalytically active material deposited on the surface of the parts of the unit will contact the oil or fats undergoing hydrogenation. Separation of reactants can then be easily efiected with obvious economies and advantages.
Both oxidizing and hydrogenating reactions being exothermic, the liberation of heat diminishes as the reactants progress through the reaction zone. Consequently to efiect a uniform operation the rate of reaction should be adjusted as the reaction progresses. Control of the rate of reaction per unit volume of the reaction zone is readily accomplished by adjusting the number of elements in the catalytic units in accordance with the location of the units within the reaction zone. Thus the first unit, or first group of units, to be contacted by the react.- ants in an exothermic operation would be provided with fewer elements and/ or in a more open arrangement than subsequent units so as to adjust the extent and rate of the reaction.
For catalytic cracking of petroleum, active alumina is first deposited on the parts of the unit followed by a deposition of silica; and for aromatization of naphtha, finely divided molybdenum oxide is deposited upon a base film of alumina. In these operations which are both endothermic the rate of reaction changes as the hydrocarbon vapors flow through the catalytic zone, with the result that coke is not evenly deposited on the catalyst, with the further result that during regeneration, effected by burning off the coke, heat is liberated unevenly, thusrendering control of temperature of the catalyst difiicult. Here again adjustment of the number and arrangement of elements mounted in the contacting units of the present invention will be efiective in establishing proper time and extent of contact to control the rate of reaction.
The above examples indicate some of the catalytic reactions for which the contacting unit may be employed; others are synthesis of alcohol, oxidation of acetylene to acetone, dehydration of ethyl alcohol, hydrogenation of fuels,-destructive hydrogenation of mineral oils, desulphurization of crude oils in liquid phase, chlorination reactions, etc., and still others which will occur to those skilledin the art of catalysis.
From the above it will be apparent that the present invention provides a contacting or catalytic unit in which contacting or catalytic elements may be fixedly mounted 'so that each element is independent of the other, thereby avoiding friction and consequent damage to the elements and partial or complete destruction of catalysts impregnated therein or applied thereto in the form of films, that the elements are not in compact relationship with one anotherbut are spaced from one another so that low pressure drops through the units are easily obtained and the problem of excessive temperatures can be solved by adjusting the number and distribution of elements in each unit, and that the units and elements therefor may be formed and arranged to produce a minimum of turbulence and contact or great turbulence and extensive contact thereby effectively to control the rate and extent of a catalytic or contacting reaction.
While the invention has been herein shown and described in connection with certain preferred forms of apparatus, it is to be understood that the invention is not restricted to the specific features thereof but covers all changes, modifications and adaptations within the scope of the appended claims.
I claim as my invention:
1. A catalytic unit through which a fluid may flow comprising a pair of end members secured to one another in spaced relation by a single post extending between said members and to which said members are rigidly fastened, and a plurality of elongated elements extending between said end members and supported at both ends thereby, each .of said elements providing a surface of catalytic material exposed to the flow of fluid passing through the unit, said unit being open laterally for the passage of fluid therethrough in a direction transverse to said elongated elements.
2. A catalytic unit according to claim 1 in which said elements are of ceramic material.
3. A catalytic unit according to claim 1 in which the surfaces of catalytic material are provided by coatings on said elements.
4. A catalytic unit through which a fluid may flow comprising a pair of end members secured to one another in spaced relation by a single post extending between said members and to which said members are rigidly fastened, and a plurality of elongated elements extending between said end members and supported at both ends thereby, said elements being disposed in rows with the elements in each row in staggered relation with the elements in adjacent rows, and each of said elements providing a surface of catalytic material exposed to the flow of fluid passing through the unit, said unit being open laterally for the passage of fluid therethrough in a direction transverse to said elongated elements.
5. A catalytic unit through which a fluid may flow comprising a pair of end members secured to one another in spaced relation by a single post extending between said members and to which said members are rigidly fastened, and a plurality of elongated elements extending between said end members and supported at both ends thereby, each of said elements having at least one end free to move longitudinally with respect to an end member, each of said elements providing a surface of catalytic material exposed to the flow of fluid passing through the unit, said unit being open laterally for the passage of fluid therethrough in a direction transverse to said elongated elements.
. 6. A catalytic unit through which a fluid may flow comprising a pair of end members secured to one another in spaced relation by a single post extending between said members and to which said members are rigidly fastened, and a plurality of elongated elements extending between said end members and supported at both ends thereby, each of said elements having in transverse section rounded and tapered portions forming a streamlined contour to minimize turbulence in the flowing fluid, and each of said elements providing a surface of catalytic material exposed to the flow of fluid passing through the unit, said unit being open laterally for the passage of fluid therethrough in a direction transverse to said elongated elements.
7. A catalytic unit through which fluid may. flow which comprises a pair of platelike end members, a single post for rigidly positioning said end members in parallel, spaced relaionship, said end members being centrally fastened to said post at either end thereof, a plurality of elongated elements extending between said end members and supported at both ends thereby, at least one end of each of said elements being free to move longitudinally with respect to one of said end members, each of said elements providing a surface of catalytic material exposed to the flow of fluid passing through the unit, said unit being open laterally for the passage of fluid therethrough in a direction transverse to said elongated elements.
8. A multi-unit catalytic assembly for providing an extended area of catalytic surface, each unit of said assembly comprising a pair of end members secured to one another in spaced relation by a single post extending between said members and to which said members are rigidly fastened, and a plurality of elongated elements extending between said end members and supported at both ends thereby, each of said elements providing a surface of catalytic material exposed to the flow of a fluid passing through the unit, said units being open laterally for the passage of fluid therethrough in a direction transverse to said elongated elements.
9. A catalytic unit for carrying out high temperature catalytic reactions which comprises a pair of plate-like end members composed of ceramic material, a single post composed of ceramic material for rigidly positioning said end members in parallel, spaced relationship, said end members being centrally fastened to said post at either end thereof, a plurality of elongated, rod-like, elements composed of ceramic material extending between said end members and supported at both ends thereby, at least one end of each of said elements being free to move longitudinally with respect to one of said end members, each of said rod-like elements being provided with a relatively thin film of catalytic material exposed to the flow of fluid passing through the unit, said unit being open laterally for the passage of fluid therethrough in a direction transverse to said elongated elements.
10. A unit in accordance with claim 9 in which said end members, said post, and said rod-like elements are composed of a dense, relatively impervious porcelain.
11. A ceramic unit for use in carrying out high temperature reactions which comprises a pair of plate-like end members of ceramic material, a single post of ceramic material for rigidly positioning said end members in parallel, spaced relationship, said end members being centrally fastened to said post at either end thereof, a plurality of elongated rod-like elements composed of ceramic material extending between said end members and supported at both ends thereby, at least one end of each element being free to move longitudinally with respect to one of said end members, said unit being open laterally for the passage of fluid therethrough in a direction transverse to said elongated elements.
12. A unit constructed in accordance with claim 11 in which said end members, said post, and said rod-like elements are composed of a relatively dense and impervious porcelain.
13. A unit constructed in accordance with claim 11 in which said rod-like elements have in transverse section rounded and tapered portions forming a streamlined contour to minimize turbulence in the fluid flowing through said unit.
14. A catalytic unit adapted for high temperature catalytic reactions which comprises a pair of plate-like end members composed of ceramic material, a single post composed of ceramic material for rigidly positioning said end members in parallel, spaced relationship, said end members being centrally fastened to said post at either end thereof, a plurality of elongated rod-like elements extending between said end members and supported at both ends thereby, said elements being disposed in rows With the elements in each row in staggered relation with respect to the elements in adjacent rows, each of said elements having in transverse section rounded and tapered portions forming a streamlined contour to minimize turbulence in the flowing fluid, at least one end of each of said elements being free to move longitudinally with respect to one of said end members, each of said rod-like elements being provided with a relatively thin film of catalytic material exposed to the flow of fluid passing through the unit, said unit being open laterally for the passage of fluid therethrough in a direction transverse to said elongated elements.
15. A unit constructed in accordance with claim 14 in which said elongated rod-like elements are supported in apertures provided in said plate-like end members.
References Cited in the file of this patent UNITED STATES PATENTS Eldred Nov. 5, 1912 Lowe et al. Sept. 7, 1920 Selden Nov. 1,1927 Duke Mar. 6,1934 Houdry Jan. 15, 1935 Houdry Jan. 15, 1935 Houdry Jan. 15, 1935 Snow Feb. 5,1935 Harrison Mar. 5,1935 Pohl Jan. 21,1936 Prickett June 22, 1937 Finn, Ir. Feb. 1, 1938 Bejarno Dec. 6,1938 Shapleigh Sept. 26, 1939 Simpson et al Jan. 2, 1940 McCausland July 30, 1940 Houdry Sept. 9,1941 Foster Sept. 24,1946
OTHER REFERENCES Chem. Eng. Catalog, l9421943, page 544, publ. by Reinhold Publishing Co., N. Y. C.

Claims (1)

1. A CATALYTIC UNIT THORUGH WHICH A FLUID MAY FLOW COMPRISING A PAIR OF END MEMBERS SECURED TO ONE ANOTHER IN SPACED RELATION BY A SINGLE POST EXTENDING BETWEEN SAID MEMBERS AND TO WHICH SAID MEMBERS ARE RIGIDLY FASTENED, AND PLURALITY OF ELONGATED ELEMENTS EXTENDING BETWEEN SAID END MEMBERS AND SUPPORTED AT BOTH ENDS THEREBY, EACH OF SAID ELEMENTS PROVIDING A SURFACE OF CATALYTIC MATERIAL EXPOSED TO THE FLOW OF FLUID PASSING THROUGH THE UNIT, SAID UNIT BEING OPEN LATERALLY FOR THE PASSAGE OF FLUID THERETHROUGH IN A DIRECTION TRANSVERSE TO SAID ELONGATED ELEMENTS.
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Cited By (12)

* Cited by examiner, † Cited by third party
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US3240698A (en) * 1962-12-27 1966-03-15 Texaco Inc Catalytic processes and catalysts therefor
US3247276A (en) * 1962-07-09 1966-04-19 Texaco Inc Catalytic treatment of hydrocarbons
US3397154A (en) * 1963-07-09 1968-08-13 Du Pont Preparation of alumina-supported catalyst compositions and the products thereof
US3444925A (en) * 1957-05-07 1969-05-20 Minnesota Mining & Mfg Structural articles and method of making
US3895918A (en) * 1973-01-16 1975-07-22 James H Mueller High efficiency, thermal regeneration anti-pollution system
US4028275A (en) * 1973-01-24 1977-06-07 Mitsui Mining & Smelting Co., Ltd. Process for preparing catalytic materials for purifying exhaust gas and catalytic materials prepared thereby
US4080282A (en) * 1976-07-12 1978-03-21 Gulf Research & Development Company Catalytic reactor and process for hydrogenating solid-containing carbonaceous materials in said reactor
US4134733A (en) * 1975-07-09 1979-01-16 Deutsche Gold- Und Silber-Scheideanstalt Vormals Roessler Apparatus for treatment of exhaust gases
US4719090A (en) * 1984-02-28 1988-01-12 Ngk Insulators, Ltd. Porous structure for fluid contact
US4882130A (en) * 1988-06-07 1989-11-21 Ngk Insulators, Ltd. Porous structure of fluid contact
US5180561A (en) * 1989-11-27 1993-01-19 Ishikawajima-Harima Heavy Industries Co., Ltd. Plate type reformer assembly
US20070089417A1 (en) * 2005-10-06 2007-04-26 Khanna Vivek K Catalytic reformer with upstream and downstream supports, and method of assembling same

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US3444925A (en) * 1957-05-07 1969-05-20 Minnesota Mining & Mfg Structural articles and method of making
US3247276A (en) * 1962-07-09 1966-04-19 Texaco Inc Catalytic treatment of hydrocarbons
US3240698A (en) * 1962-12-27 1966-03-15 Texaco Inc Catalytic processes and catalysts therefor
US3397154A (en) * 1963-07-09 1968-08-13 Du Pont Preparation of alumina-supported catalyst compositions and the products thereof
US3895918A (en) * 1973-01-16 1975-07-22 James H Mueller High efficiency, thermal regeneration anti-pollution system
US4028275A (en) * 1973-01-24 1977-06-07 Mitsui Mining & Smelting Co., Ltd. Process for preparing catalytic materials for purifying exhaust gas and catalytic materials prepared thereby
US4134733A (en) * 1975-07-09 1979-01-16 Deutsche Gold- Und Silber-Scheideanstalt Vormals Roessler Apparatus for treatment of exhaust gases
US4080282A (en) * 1976-07-12 1978-03-21 Gulf Research & Development Company Catalytic reactor and process for hydrogenating solid-containing carbonaceous materials in said reactor
US4121909A (en) * 1976-07-12 1978-10-24 Gulf Research & Development Company Catalytic reactor
US4719090A (en) * 1984-02-28 1988-01-12 Ngk Insulators, Ltd. Porous structure for fluid contact
US4882130A (en) * 1988-06-07 1989-11-21 Ngk Insulators, Ltd. Porous structure of fluid contact
US5180561A (en) * 1989-11-27 1993-01-19 Ishikawajima-Harima Heavy Industries Co., Ltd. Plate type reformer assembly
US20070089417A1 (en) * 2005-10-06 2007-04-26 Khanna Vivek K Catalytic reformer with upstream and downstream supports, and method of assembling same

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