影视先锋中文字幕_国产精品久久久久电影_亚洲在线日韩_欧美精品在线免费观看

油氣儲運網

標題: 關于破乳的英文論文 Characterization and Rheology of Water-in-Oil Emulsion from [打印本頁]
作者: helloshigy    時間: 2013-1-12 16:18
標題: 關于破乳的英文論文 Characterization and Rheology of Water-in-Oil Emulsion from
Figures…………………………………………………………………………...vi
List of Tables………………………………………………………………………….....x
CHAPTER 1: INTRODUCTION................................................................................ 1
1.1 Importance of Deepwater Fields.............................................................. 1
1.2 Problem Statement.................................................................................. 4
1.3 Objectives................................................................................................ 6
CHAPTER 2: THEORETICAL BACKGROUND.................................................... 8
2.1 Basic Principles of Emulsions.................................................................. 8
2.2 Emulsions Properties............................................................................. 10
2.2.1 Morphology of Emulsion ................................................................. 10
2.2.2 Phase Inversion .............................................................................. 11
2.2.3 Drop size distribution ...................................................................... 14
2.3 Emulsions Rheology and Shear Viscosity ............................................. 18
2.3.1 Models at constant temperature ..................................................... 19
2.3.2 Models with variation of temperature .............................................. 20
2.4 Emulsion Stability .................................................................................. 22
2.4.1 Sedimentation and Creaming ......................................................... 23
2.4.2 Aggregation .................................................................................... 24
2.4.3 Coalescence ................................................................................... 28
2.5 Demulsification ...................................................................................... 29
2.5.1 Effect of surface-active materials.................................................... 31
2.5.2 Chemical Demulsifier Efficiency...................................................... 32
v
CHAPTER 3: CHARACTERIZATION OF EMULSIONS BY NMR...................... 38
3.1 Introduction ........................................................................................ 39
3.2 Fundamentals .................................................................................... 39
3. CPMG Pulsed Sequence ................................................................... 40
3.4 PGSE and PGSTE Pulsed Sequences .............................................. 44
3.5 T1 weighted 1-D Profile Measurement................................................ 50
CHAPTER 4: EXPERIMENTAL PROCEDURES............................................... 53
4.1 Materials................................................................................................ 53
4.2 NMR Measurements.............................................................................. 54
4.3 Demulsifier Selection............................................................................. 55
4.4 Viscosity Measurements........................................................................ 57
4.5 Accuracy and Reproducibility ................................................................ 60
CHAPTER 5: RESULTS AND DISCUSSION..................................................... 62
5.1 Interfacial Tension Measurements ........................................................ 62
5.2 Emulsion Characterization by NMR....................................................... 62
5.2.1 T2 Distribution from CPMG Measurements..................................... 64
5.2.2 Drop size distribution from restricted diffusion measurement ......... 69
5.2.3 1-D T1 weighted profile measurement ............................................ 78
5.3 Emulsion Rheology ............................................................................... 86
5.3.1 Effect of temperature and shear rate .............................................. 87
5.3.2 Effect of water cut ........................................................................... 90
5.4 Demulsifier Performance and Selection ................................................ 91
5.4.1 Bottle testing ................................................................................... 92
5.4.2 Viscosity reduction and optimum dosage........................................ 94
5.4.3 Effect of mixing order ...................................................................... 99
CHAPTER 6: CONCLUSIONS AND FUTURE WORK..................................... 101
6.1 Conclusions......................................................................................... 101
6.2 Suggested Future Work....................................................................... 102
REFERENCES. ................................................................................................ 108




Reducing such a high viscosity requires better understanding of emulsion
properties. Separation topsides can also be an issue; emulsions can be very
stable depending on the properties of the oil and may not easily break under
gravity. Therefore, the use of chemicals that work as demulsifiers is commonly
employed. Injecting the chemical subsea, either at the manifold or at the tree,
can obtain great benefits as it will reduce pressure drop in pipelines and/or
enhance the emulsion separation and handling.
Hence, it is important for the industry to find an efficient way of testing and
evaluating these chemicals in the lab before applying them in the field. An
efficient testing method will lead to an optimization and potential reduction of the
quantity of the chemical needed for this purpose, resulting in monetary and most
important, environmental benefits. So far, mainly bottle testing has been
employed to conduct such measurements. The use of nuclear magnetic
resonance (NMR) method will help in characterizing an emulsion and evaluating
chemicals’ effectiveness to break/invert it. This study focuses on characterizing
of water-in-oil emulsions, that formed in deepwater production, by nuclear
magnetic resonance (NMR) and studying their rheological behavior at different
operation temperatures with and without demulsifiers present.
6
1.3 Objectives
The main objective of the project is to study and characterize emulsion
stability for deepwater oil fields and evaluate chemicals’ effectiveness to
break/invert such emulsions in order to reduce their viscosity. This study will,
specifically, focus on the viscosity of the emulsions created at different
temperatures and their tendency to separate with and without the injection of
commercial de-emulsifiers. In addition to the bottle testing, the identification of
the separation is conducted with the use of NMR technique that can obtain quick
information on phase distribution of the emulsion under study. Furthermore, the
use of viscosity measurement is also applied to determine the rheological
behavior at different operating conditions. Transporting emulsion as water-in oil
type, oil continuous, increase the viscosity and, therefore, could have cost impact
associated with high pumping requirements. Inverting this type of emulsion into
oil-in-water will decrease the viscosity as the continuous phase will change to
water and consequently help reducing the cost of pumping. This study could help
in identifying whether it is more cost effective for crude oils of moderate viscosity
to add a demulsifier to produce coalescence and hence separate/invert emulsion
without depending on only conventional bottle testing or sampling.
In this thesis, Chapter 2 presents an overview of the theoretical
background and summarizes the basic knowledge on emulsions. These include
the emulsion properties, stability, rheology and the demulsification mechanisms
used to destabilize emulsion.
7
Chapter 3 illustrates the use of low-field nuclear magnetic resonance,
NMR, and MRI techniques and how they can be effectively utilized to estimate
and characterize the emulsion properties.
After that, Chapter 4 is devoted to explain the experimental procedures and
the materials used in this work. The procedures of executing the NMR
experiment and emulsion preparation method are also described.
The results obtained from this work along with detailed discussion are then
described in Chapter 5. Finally, Chapter 6 highlights the conclusions obtained
from this work and proposes some possible future ideas that can be applied in
the extension of this work.
.
8
CHAPTER 2
THEORETICAL BACKGROUND
2.1. Basic Principles of Emulsions
Emulsions can be found in almost every part of the petroleum production
and recovery process and can be encountered at many stages during drilling,
producing, transporting and processing of crude oil. Emulsion can be defined as
a dispersion of a liquid within another liquid. The stability is conferred by the
presence of agents at the interfaces that may delay the spontaneous tendency of
the liquids to separate. Such agents are most commonly molecules with polar
and non-polar chemical groups in their structure usually referred to as
surfactants- or finely divided solids. The dispersed phase is commonly present in
an emulsion in the form of spherical drops [3].
Phase separation in emulsions is imposed by thermodynamics because as
the oil and water form two continuous phases while they separate, the interfacial
area and therefore the free energy of the dispersion are reduced. As a
consequence, the characteristics of the emulsion (drop size distribution, mean
drop size and other properties) cannot remain unchanged in time. Therefore, the
stability of an emulsion refers to the ability of the dispersion to preserve its
properties within a given timeframe [3]. Most of the petroleum emulsions that will
be encountered in practice contain oil, water and emulsifying agents and exist in
9
a metastable state that has high potential barrier to prevent coalescence of the
particles.
An emulsion can be classified according to different criteria. In the classic
type of emulsion, the two immiscible liquids involved are water and oil. As should
be clear from the foregoing discussion, either of these two liquids can be defined
as the disperse phase. The disperse phase is sometimes referred to as internal
phase, and the continuous phase as the external phase. Depending on which
one is the disperse phase, emulsions of quite different physical characteristics
are usually obtained [4]. The following types of emulsions are now readily
distinguished in principle:

5 [thesis]Characterization and Rheology of Water-in-Oil Emulsion from.pdf (4.56 MB, 下載次數: 1, 售價: 3 金幣)



歡迎光臨 油氣儲運網 (http://m.secauo.com/) Powered by Discuz! X3.4
影视先锋中文字幕_国产精品久久久久电影_亚洲在线日韩_欧美精品在线免费观看 






国产高清不卡一区二区|
国产a精品视频|
亚洲国产综合91精品麻豆|
午夜av一区二区|
美女网站一区二区|
不卡高清视频专区|
欧美日韩综合色|
精品福利av导航|
亚洲欧美在线另类|
另类成人小视频在线|
99精品一区二区|
欧美一区二区成人6969|
国产欧美综合在线观看第十页|
国产精品久久久久三级|
日本 国产 欧美色综合|
成人国产一区二区三区精品|
久久日一线二线三线suv|
精品国产sm最大网站免费看|
久久精品免费看|
日韩免费看的电影|
亚洲综合无码一区二区|
国产美女娇喘av呻吟久久|
欧美日韩一区三区四区|
亚洲综合免费观看高清完整版
|
自拍偷在线精品自拍偷无码专区|
亚洲不卡av一区二区三区|
成人高清视频在线|
国产精品嫩草久久久久|
精品在线免费观看|
欧美精品在线一区二区|
欧美亚洲国产一区在线观看网站|
欧洲一区二区三区免费视频|
国产精品美日韩|
色94色欧美sute亚洲13|
国产精品久久久久久久久免费相片|
成人v精品蜜桃久久一区|
亚洲精品中文在线|
97久久人人超碰|
亚洲6080在线|
欧美极品xxx|
国产黄色精品视频|
亚洲欧洲国产日本综合|
欧美日韩日本视频|
激情久久久久久久久久久久久久久久|
91麻豆精品国产91久久久资源速度|
亚洲综合激情另类小说区|
欧美二区乱c少妇|
国产精品一品二品|
国产无一区二区|
国产成人精品www牛牛影视|
亚洲欧美色一区|
日本韩国欧美三级|
精品伊人久久久久7777人|
日韩美女久久久|
在线观看91精品国产麻豆|
成人av电影免费在线播放|
亚洲成人一区二区在线观看|
久久久亚洲午夜电影|
欧美日韩视频在线观看一区二区三区|
精品亚洲国内自在自线福利|
一区二区欧美在线观看|
在线成人高清不卡|
jizz一区二区|
亚洲6080在线|
自拍偷在线精品自拍偷无码专区|
日韩一级片网址|
处破女av一区二区|
亚洲视频一区二区在线观看|
欧美成人a视频|
国产传媒日韩欧美成人|
日韩av中文在线观看|
精品国产一区a|
欧美嫩在线观看|
国产精品综合一区二区|
天堂在线一区二区|
精品成人佐山爱一区二区|
欧美专区日韩专区|
不卡的av中国片|
国产成人h网站|
激情综合五月天|
日本不卡中文字幕|
亚洲二区在线视频|
亚洲影视在线观看|
亚洲毛片av在线|
最新国产の精品合集bt伙计|
久久久精品欧美丰满|
日韩你懂的电影在线观看|
欧美日韩一二三区|
91福利在线看|
在线观看区一区二|
91福利视频在线|
在线观看免费一区|
在线观看中文字幕不卡|
色综合久久久久网|
精品一区二区三区的国产在线播放
|
亚洲国产日韩综合久久精品|
亚洲美女屁股眼交|
一区二区三区av电影|
亚洲欧美激情插
|
亚洲视频在线一区观看|
中文字幕在线不卡视频|
欧美韩国日本不卡|
亚洲婷婷在线视频|
亚洲精选在线视频|
亚洲午夜免费电影|
午夜久久电影网|
免费国产亚洲视频|
国产高清在线观看免费不卡|
国产精品资源在线看|
成人美女视频在线观看18|
97久久超碰国产精品电影|
91丝袜呻吟高潮美腿白嫩在线观看|
精品一区免费av|
国产精品一线二线三线|
成人午夜电影网站|
91蜜桃在线免费视频|
日本久久电影网|
777色狠狠一区二区三区|
精品盗摄一区二区三区|
中文字幕巨乱亚洲|
亚洲国产wwwccc36天堂|
免费观看一级欧美片|
国产福利电影一区二区三区|
91香蕉视频污|
日韩午夜激情视频|
国产精品色眯眯|
日韩在线播放一区二区|
国产精品996|
欧美日韩一区国产|
久久久久久久久久久99999|
亚洲精品国产精品乱码不99|
毛片av中文字幕一区二区|
9i看片成人免费高清|
777午夜精品视频在线播放|
久久综合九色欧美综合狠狠|
一区二区三国产精华液|
极品瑜伽女神91|
欧亚一区二区三区|
久久美女艺术照精彩视频福利播放
|
亚洲精品伦理在线|
久久精品国产亚洲高清剧情介绍|
白白色亚洲国产精品|
91精品国产全国免费观看|
国产精品国产馆在线真实露脸|
日韩黄色免费电影|
91小视频在线观看|
久久久精品日韩欧美|
日韩vs国产vs欧美|
91免费国产在线|
国产情人综合久久777777|
免费的国产精品|
欧美在线看片a免费观看|
国产女人18毛片水真多成人如厕|
日韩国产欧美三级|
欧洲中文字幕精品|
国产精品乱子久久久久|
国产一区二区在线电影|
欧美精品在线视频|
一区二区日韩电影|
色综合视频一区二区三区高清|
26uuu国产一区二区三区|
日韩黄色片在线观看|
欧美中文字幕一区二区三区|
中文字幕中文字幕在线一区|
国产九色精品成人porny
|
国产精品888|
精品国产乱码久久久久久蜜臀
|
欧美日韩国产123区|
亚洲免费在线电影|
不卡影院免费观看|
国产精品第四页|
成人黄色综合网站|
国产精品素人一区二区|
国产成人免费高清|
久久久久久97三级|
国产美女视频一区|
国产视频911|
成人免费看视频|
国产精品三级久久久久三级|
大桥未久av一区二区三区中文|
国产欧美一区在线|
成人午夜在线视频|
亚洲天堂久久久久久久|
91女人视频在线观看|
亚洲激情在线激情|
欧美性色欧美a在线播放|
亚洲www啪成人一区二区麻豆
|
欧美老年两性高潮|
全国精品久久少妇|
精品久久久久久久久久久院品网
|
日韩影视精彩在线|
欧美一级搡bbbb搡bbbb|
肉丝袜脚交视频一区二区|
日韩一区二区三区四区|
精品一区二区三区欧美|
国产亚洲欧美一区在线观看|
zzijzzij亚洲日本少妇熟睡|
一区二区视频在线|
欧美夫妻性生活|
国产综合一区二区|