FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W1972051323> ?p ?o ?g. }

• W1972051323 endingPage "792" @default.
• W1972051323 startingPage "784" @default.
• W1972051323 abstract "All three of these Texas thermal recovery projects-Glen Hummel, Gloriana, and Trix-Liz-are engineering and economic successes. As with any advanced recovery process, such success is due mainly to a thorough understanding of the reservoir geology, the mineralogy, and the fluid system as they apply uniquely to each reservoir, and to the application of this understanding to project design. project design. Introduction During the past 60 years many schemes have been proposed for increasing the rate and ultimate yield proposed for increasing the rate and ultimate yield from petroleum reservoirs. The most promising methods have received research attention and some have been field tested. The general consensus is that no single oil recovery method can be optimally applied to all reservoirs. The selection of a displacement process, whether it be solution gas drive, gravity process, whether it be solution gas drive, gravity drainage, waterflooding, gas drive, miscible displacement or thermal recovery, is based on a combination of technical and economic factors. Historically, the most economically successful process for supplementing recovery energy has been process for supplementing recovery energy has been waterflooding. However, waterflooding, although monetarily rewarding in most cases, does leave in the reservoir a relatively large percentage of the oil originally in place. Much effort has been directed by the industry toward understanding and reducing the proportion of the original oil remaining in the proportion of the original oil remaining in the reservoir when the reservoir's economic productive limit is reached. As a result of this effort, several advanced processes have been researched and field tested. processes have been researched and field tested. The advanced oil-displacement processes can be classified into three broad categories:1. Thermal recovery processes, which convert arelatively small fraction of the in-place orproduced oil by a kinetic reaction to energy forreducing the viscosity of the rest of theremaining oil,2. Miscible displacement processes, which concentrateattention on the crude-oil properties,3. Sophisticated waterfloods, in which the physicalproperties, such as the viscosity, surfacetension, and density of an aqueous displacingphase are manipulated. In-situ combustion has been demonstrated to be a viable recovery process in crude-oil systems having gravities ranging from 12 degrees to 40 degrees API. This process has already undergone extensive field testing in a process has already undergone extensive field testing in a wide variety of reservoirs. The management of the in-situ-generated heat and the distribution of air flow has been improved through the simultaneous injection of air and water and through rate control of producing wells. Glen Hummel In-Situ Combustion Project The Reservoir The Glen Hummel field, situated in Wilson County, Tex., was discovered in Oct., 1963. The reservoir is Eocene in age and is in the Poth A sand formation of the Upper Midway group. The development of the field was completed in early 1965 with the drilling of 32 producing wells. The average depth of the Glen Hummel reservoir is 2,432 ft subsurface. The reservoir dips from northwest to southeast approximately 200 ft over a distance of 5,000 ft. The reservoir was formed by a stratigraphic trap bounded on the northwest, or updip side, by a sealing fault, and on the southeast, or downdip side, by an inactive aquifer. The lateral extremities of the reservoir are terminated by thinning out of the sand into shale. P. 784" @default.
• W1972051323 created "2016-06-24" @default.
• W1972051323 creator A5025618500 @default.
• W1972051323 creator A5040164787 @default.
• W1972051323 creator A5056098426 @default.
• W1972051323 date "1973-07-01" @default.
• W1972051323 modified "2023-10-01" @default.
• W1972051323 title "Case Histories of Three In-Situ Combustion Projects" @default.
• W1972051323 doi "https://doi.org/10.2118/3781-pa" @default.
• W1972051323 hasPublicationYear "1973" @default.
• W1972051323 type Work @default.
• W1972051323 sameAs 1972051323 @default.
• W1972051323 citedByCount "10" @default.
• W1972051323 countsByYear W19720513232013 @default.
• W1972051323 countsByYear W19720513232015 @default.
• W1972051323 countsByYear W19720513232018 @default.
• W1972051323 countsByYear W19720513232022 @default.
• W1972051323 countsByYear W19720513232023 @default.
• W1972051323 crossrefType "journal-article" @default.
• W1972051323 hasAuthorship W1972051323A5025618500 @default.
• W1972051323 hasAuthorship W1972051323A5040164787 @default.
• W1972051323 hasAuthorship W1972051323A5056098426 @default.
• W1972051323 hasConcept C111919701 @default.
• W1972051323 hasConcept C127313418 @default.
• W1972051323 hasConcept C127413603 @default.
• W1972051323 hasConcept C134121241 @default.
• W1972051323 hasConcept C151730666 @default.
• W1972051323 hasConcept C183250156 @default.
• W1972051323 hasConcept C191897082 @default.
• W1972051323 hasConcept C192562407 @default.
• W1972051323 hasConcept C2779681308 @default.
• W1972051323 hasConcept C39432304 @default.
• W1972051323 hasConcept C41008148 @default.
• W1972051323 hasConcept C548081761 @default.
• W1972051323 hasConcept C548895740 @default.
• W1972051323 hasConcept C68189081 @default.
• W1972051323 hasConcept C78762247 @default.
• W1972051323 hasConcept C98045186 @default.
• W1972051323 hasConceptScore W1972051323C111919701 @default.
• W1972051323 hasConceptScore W1972051323C127313418 @default.
• W1972051323 hasConceptScore W1972051323C127413603 @default.
• W1972051323 hasConceptScore W1972051323C134121241 @default.
• W1972051323 hasConceptScore W1972051323C151730666 @default.
• W1972051323 hasConceptScore W1972051323C183250156 @default.
• W1972051323 hasConceptScore W1972051323C191897082 @default.
• W1972051323 hasConceptScore W1972051323C192562407 @default.
• W1972051323 hasConceptScore W1972051323C2779681308 @default.
• W1972051323 hasConceptScore W1972051323C39432304 @default.
• W1972051323 hasConceptScore W1972051323C41008148 @default.
• W1972051323 hasConceptScore W1972051323C548081761 @default.
• W1972051323 hasConceptScore W1972051323C548895740 @default.
• W1972051323 hasConceptScore W1972051323C68189081 @default.
• W1972051323 hasConceptScore W1972051323C78762247 @default.
• W1972051323 hasConceptScore W1972051323C98045186 @default.
• W1972051323 hasIssue "07" @default.
• W1972051323 hasLocation W19720513231 @default.
• W1972051323 hasOpenAccess W1972051323 @default.
• W1972051323 hasPrimaryLocation W19720513231 @default.
• W1972051323 hasRelatedWork W1976865691 @default.
• W1972051323 hasRelatedWork W1989103078 @default.
• W1972051323 hasRelatedWork W201527725 @default.
• W1972051323 hasRelatedWork W2086004183 @default.
• W1972051323 hasRelatedWork W2316255445 @default.
• W1972051323 hasRelatedWork W2946387448 @default.
• W1972051323 hasRelatedWork W3145877469 @default.
• W1972051323 hasRelatedWork W3207557017 @default.
• W1972051323 hasRelatedWork W4241596600 @default.
• W1972051323 hasRelatedWork W70886252 @default.
• W1972051323 hasVolume "25" @default.
• W1972051323 isParatext "false" @default.
• W1972051323 isRetracted "false" @default.
• W1972051323 magId "1972051323" @default.
• W1972051323 workType "article" @default.