Читать книгу Acoustic and Vibrational Enhanced Oil Recovery - George V. Chilingar - Страница 13

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Introduction

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Physical fundamentals of vibration and acoustic actions on the reservoir for improving the oil yield and increasing the development tempo of depleted and water-encroached oil fields are presented in this book. It is shown that the area of most efficient application is reservoirs with crudes characterized by a high water content and heterogeneity, low permeability, high shaliness, etc. The developed techniques are ecologically neutral and do not cause damage to the well-designed elements. The book may be useful to students, scientists, and engineering-technical personnel engaged in geophysics and development of petroleum fields.

The book is devoted to the theoretical and applied aspects of physics of the porous media saturated with oil, gas, and (or) water. A special attention is devoted to the hydro- and thermodynamic phenomena emerging in such media upon spreading within them of elastic waves with frequencies between infrasound and ultrasound. For expert analysis of the reviewed phenomena, the authors expended years of painstaking work (creating theoretical models and conducting specialized physical experiments on the reservoir models in the in situ conditions). In the 1970s to 1990s, the authors designed a complicated special equipment for the laboratory and field experiments and then conducted experimental and industrial testing. Beginning in 1990s, the interest increased in the vibration and acoustic technologies to an increasing oil-gas production in Russia, USA, France, Brazil, and China. The authors believe that the results achieved will be useful first of all for specialists designing new methods of improving well productivity. A useful information, however, will be found here also by geophysicists creating new technologies of rock diagnostics and of seismic and acoustic identification of commercial hydrocarbon accumulations.

Having read the book, the reader will get the idea of major aspects in theory and practice of vibration and acoustic effect on the porous media. It is important that the reviewed technologies are nondamaging to the environment. The authors believe that the book will initiate a burst of interest not only in the hydraulics and flow physics in the field of vibration but also in the nonlinear geophysics. The most important is the synergetic physicochemical effects forming the foundation of seismo-geochemistry and the study of the Earth’s gas respiration in the process of its oscillatory motions.

Research presented in this book was initiated partly because of the recorded dependence of the rate of oil production on earthquake occurrences in seismically active areas (Surguchev et al., 1975 [33]). It was noticed that several days after the occurrence of an earthquake with the epicenter located in the vicinity of the oil-producing oil field, the rate of oil production increased and remained higher than the pre-earthquake level for a considerable period of time. It was also noticed in the soil remediation studies (e.g., Sadeghi et al., 1992 [28]) that sonic energy applied to the contaminated soil increases the rate of hydrocarbon removal and decreases the percentage of residual hydrocarbons. Modern world oil and gas-producing industry is dominated by the application of artificial methods of affecting oil reservoirs. The application of diverse action systems and methods enabled an implementation of the intensive oil fields’ development at high oil production tempo. The major accrual in the oil reserves in the future is anticipated in the areas of ever more complex geologic and geographic environment, significantly distant from the areas of oil consumption.

Thus, developing novel efficient enhanced oil recovery technology [e.g., Electrical Enhanced Oil Recovery (EEOR)] is imperative. At present, after a field development is ended, more than half of oil reserves remain subsurface. This means that, currently, the fields with residual oil reserves of over 0.5 BT (billion tons) are written off annually. If such amount of the oil loss is maintained, then a stable increase of oil production cannot be guaranteed for an extended period of time due to limited oil reserves.

The following major reasons may be identified for a decreased oil yield:

 – The operation of capillary forces preventing oil displacement from smaller pores of a micro-nonuniform porous medium;

 – Unfavorable interrelation between the mobilities of the displaced and displacing liquids;

 – Geological heterogeneity of the productive reservoir.

Almost 90% of oil in Russia, for example, is recovered from the fields which experienced poor sweep efficiency during the waterflooding.

Another important trend is development of the techniques improving interrelation of the mobilities between the oil and water. For the application of one or another action method on the oil and gas reservoirs, it is important to know where exactly the oil is remaining after flooding. Due to a low sweep efficiency by water, the non-recovered oil in the flooding process, will constitute 60% to 90% of the entire reserve. About 10% to 40% of the oil is not recovered due to a low sweep efficiency by waterflooding.

In the development of low-viscosity oil fields with productive reservoirs of moderate heterogeneity, the major cause of incomplete oil recovery is associated with the capillary forces. Oil recovery improving methods in such fields must be the elimination (total or partial) of capillary forces causing the problem.

If a field under development is characterized by a strong geological heterogeneity of productive reservoirs, then the oil yield improving methods should first of all include increase in the sweep efficiency by the water in waterflooding.

At the development of high-viscosity oil fields, a substantial fraction of non-recovered oil is associated with unfavorable mobility ratio. That is why the means of increasing the oil yield must be directed first of all to increasing viscosity of the displacing fluid and decreasing viscosity of the displaced oil.

Most of the known methods of increasing the oil yield includes the means of eliminating, in part or in full, the manifestation of one of the three aforementioned major causes of lowering efficiency of oil displacement from the productive reservoirs. However, the application of these means in the late development stages gives disappointing results. One of the major causes of the low efficiency of the methods is that they ignore natural tendency of hydrocarbon fluids to move when subjected to the action of gravity and capillary forces. This explains the attention of petroleum engineers and geologists to vibration and acoustic technologies capable of taking these tendencies into account.

Various options are created of base technologies and technical solutions for industrial implementation. Depending on technology and the applied technical means, vibration and acoustic methods may be used for the solution of the following tasks:

 – Increasing the productivity of producing wells in which the application of conventional methods turned out impossible or of low efficiency;

 – Increasing the oil and gas yield from the water-flooded low-productivity reservoirs;

 – Increasing sweep efficiency during waterflooding.

Vibration technologies of increasing well productivity are most popular as a result of their relative simplicity and low cost. They are based on various techniques of passing the energy from the borehole vibration source to the reservoir by way of the borehole fluid. Due to a strong fading of vibrations in a liquid, this way of the energy transfer results in vibrations fading already at 1 m from the borehole walls. However, this is quite sufficient for efficient cleaning up of the borehole walls and the bottomhole zone from dirt and colmatage matter (formation damage). Vibration eliminates the blocking effect of residual gas, oil and water phases. Vibration initiates the fluid filtration in low-permeability zones. In low-permeability reservoirs, on achieving sufficiently strong pressure impulses, even a hydrofracking of the reservoir is possible. In the territory of the former Soviet Union (FSU), the application of action methods to bottomhole zones resulted in the production of over 20 million tons of oil.

One can expand the vibrations to greater distances from the vibration source. The effective encompassment of the productive reservoir around the initiating borehole may reach 12 km2. The number of wells simultaneously encompassed by the action is 25 to 50 (depending on the development grid).

The development technique of increasing the reservoir’s oil-gas yield, created by the authors, is the unique “vibro-seismic” method. It is cyclical areal action in the reservoir by the low-frequency vibrations in the frequency range corresponding to the reservoir resonance. The annual oil production from the test areas as a result of vibro-seismic action increased more than 60%. The effect lasted for 6 to 18 months and longer. An increase of the productive reservoir encompassment by the thickness was 30% to 35% and more. In some cases, the wells which produced earlier by a rod-operated plunger pump switched to a durable gushing regime with almost tenfold increase in the production rate. The action efficiency was defined not only by an increase of the total production but also by a decrease of water cut. In some wells, the water cut was decreased by 30% to 40%. As a result of applying this technique, more than 500 thousand tons of oil were produced.

Figure 1.1 shows the dependence of water cut in wells located at three different oil fields in Northern Caucasus several days after an earthquake. The earthquake epicenter was located at a distance of 130 to 170 km from the producing wells. In all three cases, a decrease in water cut and a respective increase in oil production was recorded in about a week after the earthquake. Nevertheless, on the average, decrease in the water cut was about 40% for all three wells for a considerable period of time. This and other similar facts led to extensive laboratory and field studies of artificial vibro-seismic enhancement of oil production. Theoretical and experimental aspects of this phenomenon and the mechanism of enhanced oil recovery due to the presence of elastic waves generated by surface-based vibrators have been studied during the last 40 years by Surguchev et al. (1984) [34], Simkin and Surguchev (1991) [31], Simkin (1992) [30], and Kouznetsov and Simkin (1994) [21].

Figure 1.1 Decrease in the water cut in three wells after an earthquake: 1 = Makhachkalinskoe field, 170 km from the earthquake epicenter; 2 = Shamkal-Bulakskoe field, 130 km from the epicenter; 3 = Novo-Groznenskoe field, 130 km from the epicenter. All fields are located in the northern Caucasus.

In 1987, at one of Professor George V. Chilingar’s Petroleum Engineering Classes at the University of Southern California, his star student from Iran, K. Majid Sadeghi gave a lecture on his research on vibrational dewatering of contaminated muds. Professor Chilingar asked Sadeghi: “Now that we can dewater muds, can we use this technology to increase the production of oil from the oil sands? Sadeghi answered: “Absolutely.”

Acoustic and Vibrational Enhanced Oil Recovery

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