BEGIN:VCALENDAR VERSION:2.0 METHOD:PUBLISH PRODID:-//Tendenci - The Open Source AMS for Associations//Tendenci Codeba se MIMEDIR//EN BEGIN:VEVENT DESCRIPTION:--- This iCal file does *NOT* confirm registration.\r\nEvent d etails subject to change. ---\r\nhttps://www.spegcs.org/events/6586/\r\n\r \nEvent Title: Fundamentals of Simulating Naturally Fractured Reservoirs\r \nStart Date / Time: Jan 13, 2023 08:00 AM US/Central\r\nLocation: Liberty Conference Room\r\nSpeaker: Ibrahim Elsayed\r\nGoogle\r\nhttp://maps.goog le.com/maps?q=960+Memorial+City+Way,Houston,TX,77024\r\n\r\nForecast\nhttp ://www.weather.com/weather/monthly/77024\r\n\r\nThis training is designed for reservoir engineers and geoscientists involved in the evaluation and m anagement of naturally fractured reservoirs. In particular, it is intended for energy professionals who perform activities related to understanding fractured reservoir behavior and who use numerical simulation models for h istory matching and prediction. Several methods exist for modeling natural ly fractured reservoir dynamic behavior. The method used depends on the ob jective of the numerical simulation. The dual porosity concept is commonly used in hydrology and the oil and gas industry to represent flow in fract ured media. In this training, you will learn about the background, concept s, and assumptions of the dual porosity model for simulating a naturally f ractured reservoir. The principles of fracture modeling encourage a multi- disciplinary collaborative approach when you model and simulate fractured reservoirs. The training will begin by introducing the fundamentals of fra ctured reservoirs to establish a baseline of basic information and termino logies. We will then discuss the oil recovery mechanisms unique to fractur ed reservoirs such as viscous displacement, spontaneous imbibition, and gr avity drainage. We will close by exploring the critical interactions betwe en fractures and rock during gas or water injection is critical when you e stimate recoveries. Throughout this class, simple element models will be u sed to demonstrate key concepts that can then be implemented with differen t software packages.\r\n \r\n --- This iCal file does *NOT* confirm regist ration.Event details subject to change. ---\r\n\r\n--- By Tendenci - The O pen Source AMS for Associations ---\r\n UID:uid6586@spegcs.org SUMMARY:Fundamentals of Simulating Naturally Fractured Reservoirs DTSTART:20230113T140000Z DTEND:20230113T180000Z CLASS:PUBLIC PRIORITY:5 DTSTAMP:20240329T154038Z TRANSP:OPAQUE SEQUENCE:0 LOCATION:Liberty Conference Room X-ALT-DESC;FMTTYPE=text/html:
This training is designed for reservoir en gineers and geoscientists involved in the evaluation and management of nat urally fractured reservoirs. In particular, it is intended for energy prof essionals who perform activities related to understanding fractured reserv oir behavior and who use numerical simulation models for history matching and prediction. Several methods exist for modeling naturally fractured res ervoir dynamic behavior. The method used depends on the objective of the n umerical simulation. The dual porosity concept is commonly used in hydrolo gy and the oil and gas industry to represent flow in fractured media. In t his training, you will learn about the background, concepts, and assumptio ns of the dual porosity model for simulating a naturally fractured reservo ir. The principles of fracture modeling encourage a multi-disciplinary col laborative approach when you model and simulate fractured reservoirs. The training will begin by introducing the fundamentals of fractured reservoir s to establish a baseline of basic information and terminologies. We will then discuss the oil recovery mechanisms unique to fractured reservoirs su ch as viscous displacement, spontaneous imbibition, and gravity drainage. We will close by exploring the critical interactions between fractures and rock during gas or water injection is critical when you estimate recoveri es. Throughout this class, simple element models will be used to demonstra te key concepts that can then be implemented with different software packa ges.
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