石油工程 (Petroleum Engineering)

石油工程(Petroleum Engineering) 林再興教授授課教師：謝秉志助理教授(雲平大樓東棟27813) 2010 年 9月 ~ 2011 年 1月

Chapter 1 Introduction (前言) What is pe·tro·le·um (pə-trō'lē-əm)? • Oil from rock • Petroleum may be in gaseous, liquid, and solid hydrocarbons that occurs naturally beneath the earth's surface. • Oil being a thick, flammable, yellow-to-black hydrocarbons mixture. • Could be separated into fractions including natural gas, gasoline, naphtha(揮發油), kerosene(煤油), fuel and lubricating oils, paraffin wax(石臘), and asphalt(瀝青) and is used as raw material for a wide variety of derivative products.

石油的分子結構 石油是碳氫化合物。碳-- C，氫-- H。烷烴 (石蠟烴)、環烷烴、烯烴及芳香烴，其分子結構均不相同。甲烷即是含有一個碳原子，乙烷含兩個碳原子，丙烷含三個碳原子，依此類推。烯烴類有一組雙鍵結構 (請比較異丁烷與異丁烯)，芳香烴為六隅體結構等。

Petroleum(石油) and Energy(能源) • 能源 (Energy Sources)是什麼? 具有可以使用之熱能(heat) 或功率(power)的物質或資源。例如，石油、煤，及太陽能等。

能源的分類 • 傳統能源或非再生能源(Non-renewable Energy) 這類資源的循環時間極長 – 用完之後，難以在短期內補充，會”耗盡”。包括：石油、天然氣、煤及核能。 • 再生能源(Renewable Energy) 資源可以快速循環或補充 – “不會用完”，”不會枯竭耗” ，包括：太陽能、風力能、潮汐能、水力能、波浪能、地熱能及生質能等。

傳統能源 (Non-renewable Energy) • 化石燃料能(Fossil Fuel Energy) －石油、天然氣、煤炭 • 核能(Nuclear Energy) －鈾(Uranium)

再生能源(Renewable Energy)種類 • 太陽能(Solar Power) • 風力能(Wind Power)

再生能源(Renewable Energy)種類 • 潮汐能(Tidal Power)

再生能源(Renewable Energy)種類 • 水力能(Hydro-electric Power) • 波浪能(Wave Power)

再生能源(Renewable Energy)種類 • 地熱能(Geothermal Energy) 生質能(Biomass Energy)

人類如何使用能源?

世界消費能源總量之中各類能源所佔比例 Source: EIA, Annual Energy Review, 2002

^BP Statistical review of world energy June 2006 (XLS). British Petroleum (June 2006). Retrieved on 2007-04-03. ^ abcdefghijk

石油能源 • 石油及天然氣是動、植物之殘骸在地層中，於適當地層溫度及壓力條件下所分解之碳氫化合物而形成。 • 1970年代的二次全球能源危機是因石油供應短缺所造成，又稱為石油能源危機。 • 1990年代波斯灣戰爭也是因為石油而引起。 • 2008 oil price up to 150 USD/bbl • 石油價格的升降，直接影響全球經濟。 • 預測石油短缺即將來臨︰四十年?

天然氣能源 • 天然氣是一種氣態的碳氫化合物 (註：石油是液態碳氫化合物)。 • 天然氣的燃燒效率高，而且乾淨。 • 液化天然氣 (簡稱 LNG) 是把礦區產出的天然氣冷凍至零下 162°C，成為一種無色、無臭的液體，體積也縮減為氣態時的六百分之一左右，以便於儲存及越洋運送。

石油分類 • 物理性質 -- relative weight (API gravity) ; viscosity -- "light", "intermediate" or "heavy" -- impurity --"sweet," which means it contains relatively little sulfur, or -- "sour," which means it contains substantial amounts of sulfur and requires more refining in order to meet current product specifications • 化學性質石油的分子結構 • 產地 by the location of its origin (e.g., "West Texas Intermediate, WTI" or "Brent") • 市場商品產地(&物理性質)

API Gravity API <=> American Petroleum Institute API = 10o (SG=1) => water API < 20o(SG>0.96) => heavy oil 30o < API < 40o(0.89>SG>0.84) => intermediate oil (light to medium) 40o < API (SG<0.84) => light oil API > 45o(SG<0.84) => volatile oil API ~ 60o ~ 70o(0.76-0.72) => condensate liquid

The world reference Crude (oil) • Brent Crude, comprising 15 oils from fields in the Brent and Ninian systems in the East Shetland Basin of the North Sea. The oil is landed at Sullom Voe terminal in the Shetlands. Oil production from Europe, Africa and Middle Eastern oil flowing West tends to be priced off the price of this oil, which forms a benchmark. • West Texas Intermediate (WTI) for North American oil. • Dubai, used as benchmark for Middle East oil flowing to the Asia-Pacific region. • Tapis (from Malaysia, used as a reference for light Far East oil) • Minas (from Indonesia, used as a reference for heavy Far East oil) • The OPEC basket used to be the average price of the following blends: • Arab Light Saudi Arabia • Bonny LightNigeria • Fateh Dubai • IsthmusMexico (non-OPEC) • Minas Indonesia • Saharan Blend Algeria • Tia Juana Light Venezuela • OPEC attempts to keep the price of the Opec Basket between upper and lower limits, by increasing and decreasing production. This makes the measure important for market analysts.

What is a "barrel" of oil? • 1 barrel = 0.158987 cubic meters1 barrel = 34.99089 Imperial gallons1 barrel = 42 U.S. gallons1 barrel = 158.987146 liters • Now-a-days, oil volumes are measured in cubic meters or "cubes" as they are referred to in the "oil patch" • 1 cubic meter = 6.28994 barrels1 cubic meter = 1,000 liters • 1 barrel = 158.987146 liters • Brent Crude is one of the major classifications of oil consisting of Brent Crude, Brent Sweet Light Crude ... per barrel is about $3 less than WTI, and $3 more than OPEC Basket. Brent Crude has an API gravity of around 38. ...

Chart of crude oil prices since 1861 Crude oil prices 1861 - 2008 US dollar per barrel World events

Chart of Rotterdam & Gulf Coast product prices Rotterdam product prices US dollar per barrel US Gulf Coast production prices US dollar per barrel Source: Platts

Proved oil reserves Proved reserves at end 2008 Thousand million barrels

Distribution of proved oil reserves Distribution of proved oil reserves in 1988, 1998 and 2008 Percentage

SEPTEMBER 17, 2009

Crude Oil, Gasoline and Natural Gas FuturesNYMEX Prices for September 15, 2008 Graphs: Oil & Gas Spot and Futures prices

Crude Oil, Gasoline and Natural Gas FuturesNYMEX Prices for September 18, 2007

Major fields in Petroleum Engineering • Drilling Engineering • Production Engineering • Reservoir Engineering

Major topics covered in this course (petroleum engineering) • Petroleum geology and reservoir • Petroleum Prospecting • Drilling engineering • Reservoir engineering • Formation evaluation • Production engineering

References Textbook 2– chapter 1 Textbook 2 Archer, J. S., and Wall, C.G., Petroleum Engineering—principles and practice, Graham & Trotman, MD, 1986. Textbook 4– chapter 1 Textbook 4 Hyne,N.J., Petroleum Geology, Exploration, Drilling and Production, Penn Well Co., Tulsa, Oklahoma, 2001.

What is Petroleum Engineering • Petroleum Engineering is a creative technology • The function of petroleum engineering • to provide a basis for the design and implementation of techniques to recover commercial quantities of natural petroleum. • Broadly based technology of petroleum engineering • Engineering; geology; mathematics; physics; chemistry; economics; geostatics.

The design of petroleum techniques • The design of petroleum techniques is based on • observation of production performance, • a representation of reservoir inferred from very limited sampling. • With the passage of time and cumulative production, more information on the nature of the reservoir can be accumulated and the production methods can modified.

Uncertainty of Design • Thus petroleum engineering can represent an exercise in the application of uncertainty to design. • The terminology of the subject contains varying degrees of confidence in representation of the in-place and recoverable resource base. • We will discuss the representation of “proven” quantities of hydrocarbon in terms of availability of information and the existence of technology to exploit recovery on commercially attractive terms.

Costs of production • In the current climate of deeper reservoir exploration and increased exploitation of offshore reservoirs in the world’s sedimentary basins (Fig. 1.1), costs of production are significant. For example, in terms of pre-tax cost of oil production from a 2000 m ss onshore well compared with a 3000 m ss offshore well, a ratio of 1:10 might be expected. • Current exploration in maturing hydrocarbon provinces is centered on more subtle trapping mechanisms than structural highs and on smaller accumulations.

Enhanced Oil Recovery (EOR) and Improved Hydrocarbon Recovery (IHR) • The further recovery of hydrocarbons from reservoirs approaching the end of conventional development process requires the cost-effective application of enhanced (EOR) or improved hydrocarbon recovery (IHR) process. • The exploitation of heavy oil (API gravity less than 20o API) and of gas condensate and volatile oil reservoirs (API gravity greater than 45o API) requires special petroleum engineering effort, particularly in high-pressure or offshore reservoirs.

Developments in the recovery of hydrocarbon from oil sands and oil shales require that petroleum engineering methods are combined with the technologies of mining engineers and chemical engineers.

Text Books • Textbook 1 Fundamentals of Petroleum, Petroleum Extension Service, The University of Texas at Austin, Austin, Texas,1979. • Textbook 2 Archer, J. S., and Wall, C.G., Petroleum Engineering—principles and practice, Graham & Trotman, MD, 1986. • TextBook 3 Donohue, D.A.T., and Lang K.R.,A First Course in Petroleum Technology, International Human Resources Development Corporation, Houston,1986. • Textbook 4 Hyne,N.J., Petroleum Geology, Exploration, Drilling and Production, Penn Well Co., Tulsa, Oklahoma, 2001. • Textbook 5 Devereux, S., Drilling Technology, Penn Well Co., Tulsa, Oklahoma, 1999.

Text Books • 林國安等人，石油探採 (第一冊) – 石油地質，，中國石油股份有限公司訓練教材叢書，中油訓練所，嘉義市， 2003。 • 林國安等人，石油探採 (第二冊) – 地球物理探勘，，中國石油股份有限公司訓練教材叢書，中油訓練所，嘉義市， 2003 。 • 林國安等人，石油探採 (第三冊)– 油井鑽鑿，中國石油股份有限公司訓練教材叢書，中油訓練所，嘉義市， 2003 。 • 林國安等人，石油探採 (第四冊) – 油氣生產，中國石油股份有限公司訓練教材叢書，中油訓練所，嘉義市， 2003 。

石油工程講授大綱 1. 前言 (Introduction) Textbook 2– chapter 1 Textbook 4– chapter 1 2. 石油地質及儲油層 (Petroleum Geology and Reservoir) Textbook 1– chapter 1 Textbook 2– chapter 2 Textbook 3– chapter 4.1; 4.2 3.石油探勘 (Petroleum Prospecting) Textbook 1– chapter 2 SPE Energy Education 4.鑽井工程 (Drilling Engineering) Textbook 1– chapter 4 Textbook 2– chapter 3 SPE Energy Education Textbook 3– chapter 1

石油工程講授大綱 5.地層評估 (Formation Evaluation) Textbook 4– chapter 19 6.油層工程 (Reservoir Engineering) Textbook 2– chapter 4; 5; 8; 12 7.生產工程 (Production Engineering) Textbook 1– chapter 5 Textbook 3– chapter 3 SPE Energy Education

References • Web sites • 台灣中油股份有限公司-石油教室 Classroom (http://www.cpc.com.tw/big5/content/index.asp?pno=108) • 石油能源暨地下儲氣工程研究實驗室 (http://www.ncku.edu.tw/~source/home/LAB4328B/Lab_index2.html)

台灣中油股份有限公司-石油教室 Classroom

石油能源暨地下儲氣工程研究實驗室

石油工程 (Petroleum Engineering)