Apparatus for the controlled optimized addition of reactants in continuous flow reaction systems
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
B01J-010/00
F28B-007/00
출원번호
US-0565779
(2000-05-05)
발명자
/ 주소
Adris, Alaa Eldin M.
Al-Sherehy, Fahad A.
Soliman, Mustafa A.
Hakeem, Tarique
Kareemuddin, Shickh
Al-Nutaifi, Abdullah A.
Saudagar, Munawwar
Azam, Shahid M.
출원인 / 주소
Saudi Basic Industries Corporation
대리인 / 주소
Naftalis &
인용정보
피인용 횟수 :
15인용 특허 :
18
초록▼
An apparatus for performing continuous flow chemical reactions such as oxidation, oxidative dehydrogenation and partial oxidation processes involving a reactor design characterized by controlled/optimized addition of a reactant with the objective of: (i) avoiding the explosion regime of the reactant
An apparatus for performing continuous flow chemical reactions such as oxidation, oxidative dehydrogenation and partial oxidation processes involving a reactor design characterized by controlled/optimized addition of a reactant with the objective of: (i) avoiding the explosion regime of the reactant mixture (e.g., hydrocarbon/oxidant mixture); (ii) maximizing the selectivity of the reaction to the desired product; (iii) limiting the reactor temperature gradient and therefore the threat of reaction runaway; and (iv) controlling the operating temperature of the reaction zone so that desirable temperature range is maintained over the entire zone.
대표청구항▼
1. A continuous flow chemical reaction apparatus comprising a tubular reaction zone having a length and having a first fluid feed inlet at a first end and a product outlet at a second end, said tubular reaction zone having an interior conduit extending lengthwise within said tubular reaction zone, s
1. A continuous flow chemical reaction apparatus comprising a tubular reaction zone having a length and having a first fluid feed inlet at a first end and a product outlet at a second end, said tubular reaction zone having an interior conduit extending lengthwise within said tubular reaction zone, said conduit having a second fluid feed inlet and a multiplicity of injectors spaced apart along the length of said conduit, each of said injectors capable of introducing a controlled amount of a second fluid reactant into said tubular reaction zone, and at least one of said injectors having a pressure drop control means in said conduit proximate to said injector.2. The chemical reaction apparatus of claim 1, further comprising a catalyst within the tubular reaction zone.3. A continuous flow chemical reaction apparatus comprising a plurality of tubular reaction zones within a heat transfer vessel having at least one heat transfer zone, each of said heat transfer zones having a heat transfer fluid inlet and a heat transfer fluid outlet, each of said tubular reaction zones having a length, a first fluid feed inlet at a first end, a product outlet at a second end and an interior conduit extending lengthwise within said tubular reaction zone, said interior conduit having a second fluid feed inlet and a multiplicity of injectors spaced apart along the length of said tubular reaction zone and each of said injectors being adapted to introduce a controlled amount of a second fluid reactant into said tubular reaction zone, and at least one of said injectors having a pressure drop control means in said conduit proximate to said injector.4. The chemical reaction apparatus of claim 3, wherein said heat transfer vessel comprises a plurality of heat transfer zones.5. The chemical reaction apparatus of claim 3, further comprising catalyst in the interior of at least one of the tubular reaction zones.6. The chemical reaction apparatus of claim 1, wherein said interior conduit is concentric with said tubular reaction zone.7. The chemical reaction apparatus of claim 3, wherein said interior conduit is concentric with said tubular reaction zone.8. The chemical reaction apparatus of claim 1, further comprising pressure drop control means in said conduit proximate to atetach of said injectors.9. The chemical reaction apparatus of claims 3, further comprising pressure drop control means in said conduit proximate to at least one of each of said injectors.10. The chemical reaction apparatus of claim 3, wherein said heat transfer vessel is a cylindrical vessel.11. The chemical reaction apparatus of claim 1, further comprising a catalyst bed within said tubular reaction zone and surrounding said interior conduit.12. The chemical reaction apparatus of claim 3, further comprising a catalyst bed within each of said tubular reaction zones and surrounding said interior conduits.13. The chemical reaction apparatus of claim 1, wherein said multiplicity of injectors comprises between 2 and 40 injectors.14. The chemical reaction apparatus of claim 1, wherein said tubular reaction zone has a cross-section which is a substantially circular, said interior conduit is concentric with said tubular reaction zone and said tubular reaction zone comprises a catalyst bed surrounding said interior conduit.15. The chemical reaction apparatus of claim 3, wherein each of said tubular reaction zones has a cross-section which is a substantially circular, said interior conduits are concentric with said tubular reaction zones and each of said tubular reaction zones comprises a catalyst bed surrounding said interior conduit.16. A continuous flow chemical reaction apparatus comprising a fluidized bed reaction zone having a height and having a first fluid feed inlet at a lower end and a product outlet at an upper end, said fluidized bed reaction zone having a multiplicity of injectors in fluid communication with an interior conduit extending vertically within said fluidized bed reaction zone and located within the fluidized bed reaction zone and at least two different heights thereof, each of said injectors capable of introducing a controlled amount of a second fluid reactant into said fluidized bed reaction zone, and at least one of said injectors having a pressure drop control means in said conduit proximate to said injector.17. The apparatus of claim 16, wherein said fluidized bed reaction zone operates in the bubbling regime.18. A continuous flow chemical reaction apparatus comprising a plurality of fluidized bed reaction zones within a heat transfer vessel having at least one heat transfer zone, each of said heat transfer zones having a heat transfer fluid inlet and a heat transfer fluid outlet; each of said fluidized bed reaction zones having a height, a first fluid feed inlet at a lower end, a product outlet at an upper end and a multiplicity of injectors in fluid communication with an interior conduit extending vertically within said fluidized bed reaction zone and located within said fluidized bed reaction zones at least two different heights thereof and each of said injectors being adapted to introduce a controlled amount of a second fluid reactant into said fluidized bed reaction zones, and at least one of said injectors having a pressure drop control means in said conduit proximate to said injector.19. A continuous flow chemical reaction apparatus comprising a fluidized bed reaction zone having a height, a first fluid feed inlet at a lower end, a product outlet at an upper end and a multiplicity of conduits along the height of said fluidized bed reaction zone, each of said conduits being perpendicular to fluid flow within the fluidized bed reaction zone and each being adapted to introduce a controlled amount of a second fluid reactant feed into said fluidized bed reaction zone.
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이 특허에 인용된 특허 (18)
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Asher William J. (Half Moon Bay CA) Roberts Daryl L. (Winchester MA) Jones Jerry L. (Menlo Park CA) Gottschlich Douglas E. (Mountain View CA), Exothermic process with porous means to control reaction rate and exothermic heat.
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Manyik Robert M. (St. Albans WV) Brockwell Jonathan L. (South Charleston WV) Kendall John E. (Charleston WV), Process for oxydehydrogenation of ethane to ethylene.
Minet Ronald G. (South Pasadena) Tsotsis Theodore T. (Huntington Beach) Champagnie Althea M. (Los Angeles CA), Process for production of ethylene from ethane.
Lucas,Jamie D.; Lewis,Guy H.; Wright,Harold A.; McIntyre,Dale R.; Minahan,David M.; Anderson,David H., Compact mixer for the mixing of gaseous hydrocarbon and gaseous oxidants.
Lehr,Manfred; Egner,Franz; Claussen,Michael; Maly,Markus, Method and tube bundle reactor for carrying out endothermic and exothermic gas phase reactions.
Bachman, Gene W.; Jones, Raymond M.; Cloeter, Michael D.; Lipp, Charles W.; Bartel, Mark J.; Coomes, Brady J.; Daigle, Scott J.; Janda, Steve F., Mixer for continuous flow reactor.
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Aigner, Rudolf; Hirsch, David; Lagnaz, Alfred, Process and apparatus for continuous high temperature short-time alkoxylation (ethoxylation, propoxylation) of chemical substances with active hydrogen atoms.
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