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Course Criteria
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0.00 - 3.00 Credits
(3:3:0) Prerequisites: PHYS 2401, MATH 2350, and PETR 3402 with a C or higher; department approval; 2.5 GPA; corequisite PETR 3306. Use of open-hole well logs including logging suites for the electric survey to the induction and laterlog suites to determine volume and relative producibility of hydrocarbon reserves. Analysis and design techniques of actual well logging packages are emphasized.
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3.00 Credits
(3:3:0) Prerequisites: PETR 2302, PETR 3402, PHYS 2401, and MATH 2350 with a C or higher; department approval; 2.5 GPA. Corequisite: PETR 3304. Understanding the fundamentals of fluid flow through porous media, reservoir types and recovery mechanisms. Estimation of hydrocarbon in place for oil and gas reservoirs. Application of material balance calculations for various reservoir types and applications of fluid flow through porous media in predicting production performance.
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3.00 Credits
(3:3:0) Prerequisites: ENGL 1301,1302, junior or senior standing, department approval. Written and oral communication techniques for professional engineers, including writing matrix, fog index, computer analysis, and visual aid production, proposal writing, and other tools. (Writing Intensive)
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0.00 - 4.00 Credits
(4:3:3) Prerequisites: PETR 2302, MATH 1352, CE 3305 or ME 3370, and PHYS 1408 with a C or higher; 2.5 GPA; department approval. Understanding the basic properties of reservoir rocks and how they relate to the storage and production of oil and gas. Important concepts such as heterogeneity, capillary pressure, relative permeability, resistivity are included as part of the course. The course is complemented by relevant lab experiments where the students get hands on experience on measuring some of the single and multiphase flow properties of reservoir rocks. (Writing Intensive)
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1.00 - 6.00 Credits
(V1-6) Prerequisite: Department and instructor approval. Individual studies in petroleum engineering areas of special interest. Can be used for practical curriculum training, but petroleum engineering majors may not use it as a substitute for PETR 4331, PETR elective. May be repeated for credit
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1.00 Credits
(1) Prerequisites: CE 2301 or ME 2364, CE 3302 or ME 3331, CE 3303 or ME 3464, CE 3305, ME 2322, IE 3301, and CHEM 1307/1107 with a C or higher; senior standing; 2.5 GPA; department approval. Study of engineering problems of special interest and value to the student.
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0.00 - 3.00 Credits
(3:2:3) Prerequisites: PETR 3304, 3306, 3308, IE 3301, GEOL 3302, 4324, MATH 3342, and 3350 with a C or higher; 2.5 GPA; department approval. Corequisites: PETR 4308, 4309. Economic, physical, analytical, and statistical evaluation of hydrocarbon-producing properties, emphasizing relative worth of investments based on engineering judgment, business strategy, and risk analysis using actual oil properties in team projects. (Design course) (Writing Intensive)
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3.00 Credits
(3:3:0) Prerequisites: PHYS 2401, MATH 2350 and CE 3302 or ME 3331 and CE 3305 or ME 3370 and PETR 3304, 3306, and 3402 with a C or higher, 2.5 GPA. departmental approval. Corequisites: PETR 4306, 4405, and 4407. Natural flow analysis¿reservoir performance (Inflow Performance Ratio), wellbore performance (Tubing Performance Ratio), surface flowline performance (Flow Performance Ratio). Artificial Lift Methods. Wellbore Stimulation/Acidizing, Hydraulic fracturing. (Design Course)
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0.00 - 3.00 Credits
(3:3:0)Prerequisite: PETR 3306 with a C or higher, 2.5 GPA, department approval. Corequisites: PETR 4303, 4405, and 4407. Introduction to EOR processes mechanisms, frontal advance theory and application, mechanisms of water-flooding and miscible processes and application to reservoir performance prediction.
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3.00 Credits
(3:3:0) Prerequisites: PETR 3304 and 3306, MATH 3342 and 3350, and PHYS 2401 with a C or higher, 2.5 GPA, department approval. Corequisites: PETR 4300 and 4309. Fundamental laws, anisotropic, coordinate systems and reservoir geometry, continuity and diffusivity equations, pressure-time-volume relationships. Basic theory of transient flow and testing, type curves, pressure derivative method, buildup, drawdown, interference and reservoir limit tests. Water influx, decline curves analysis, software and reservoir models. Unconventional gas reservoirs.
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