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- 1. Introduction and Review
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Abstract Underbalanced tubing conveyed perofration (TCP) attained higher production and assured safety when applied with sucker-rod pump installation in wells in three different Egyptian oil fields. The TCP allowed more efficient operation because it does not require killing the well after perforation to run the downhole pump and sucker rod. The overbalanced perforation eliminates the risks of damaging the producing formation beyond the perforations. The compared performance of wells using underbalanced TCP with that of other wells using tubing gun technique, casing gun technique eveals that the underbalanced TCP prevailed successful in all cases. 1. Introduction and Review Many thousands of depleted wells all over the world use sucker rod pump systems as artificial lift method. Application of conventional perforating techniques for sucker rod pumping system may cause formation damage for the well to be killed after perforation to run the downhole pump and the sucker rod. Since underbalanced perforating has been proven to provide much more production than either balanced or overbalanced perforating, it is recommended for application instead of sucker rod or along with them. The major goal of any well completion is to obtain maximum oil production. The used perforating techniques and tools 1-5 have been proven to have a tremendous importance on determining the resulting production rate. It is always required to have such a program that would minimize the perforation/formation damage and maximize the well deliverability, hopefully reducing the total number of storage wells required. Naguib et al 1 reviewed and evaluated different artificial lift methods in Egyptian oil fields. Fig. 1 shows the locations of these fields. The study indicated that Egyptian natural producing wells represent 15 %, while gas lifted wells are 24 %, and the pumped wells are 61 %. The relationship between the well borehole pressure and the formation pressure at the time of perforation can be classified into (a) overbalanced, (b) balanced, or (c) underbalanced. Underbalanced perforating is perforating that is performed when the reservoir pressure (P r ) is higher than the downhole wellbore pressure (P wf ) Then, the underbalanced pressure (P u ) = P r – P wf . In a consolidated formation, the jet perforating process causes a severe compaction surrounding mass as the penetrating an ultra-high speed “bullet” advances. Without further cleaning, the debris and compaction may form a definite permeability block to the extent that an open channel may not exist. This problem has not been appreciated for a long time. The resulting low flow rate may be considered adequate or incorrectly assumed to be the maximum flow potential, or the flow rate may be assumed coming from only a few well perforations. The general recommendation to overcome perforation damage has been to perforate with sufficiently high differential pressure toward the wellbore in order to flush out debris and compaction. 2 SPE 114793 Brieger and Stovall 1 showed that many field- operating crews believe erroneously that such an ideal perforation occurs under typical downhole conditions. Their study showed that laboratory tests using limited differential pressure indicated that much higher energy is required to dislodge the zone of low permeability resulting from perforation, crushed rock where lining jet gun perforation channels. On the other hand, field tests indicate that the tubing conveyed perforating technique (also called Vannsystem) has high back-surge pressure, which may provide enough energy to produce almost ideal perforations and provide very positive results. Colle 2 developed a completion technique for overcoming formation damage. Basically, this technique suggested overcoming the formation damage of cementing, drilling, and perforating by perforating with deep penetrating shaped charges and immediately back-surging with maximum differential pressure to the wellbore. The sole objective of the production engineers is to have well perforations producing at minimum flow resistance at the reservoir/perforated-system interface. Bell et al 3 showed that this could be achieved by (a) establishing well conditions enhancing cleanup of the perforations, and (b) choosing perforators and techniques providing the best flow performance. They 3 also concluded that natural completions are always more productive when perforation is achieved under reverse pressure. The perforating equipment and techniques have a very important bearing on the determination of the resulting production. Bell 4 indicated that the best perforating techniques depend on the type of well completion. Furthermore, for a specific completion method, choices of techniques and equipment are constrained by the well configuration, fluid type of wellbore pressure, formation characteristics, and damage conditions. Bell also stated two main steps for obtaining minimum resistance to flow at the reservoir/perforated system interface: (a) establishing well conditions that enhance cleanup of the perforations, and (b) choosing perforators and techniques for best flow performance. It is imperative for the completion engineer to perforate a well such that the completion pressure loss is low, the production rate is high, the operation is safe, and the cost is low. Crawford 5 developed and presented a set of equations for a systematic estimation of a desirable downhole design guidelines for (1) the minimum underbalanced pressure necessary to provide clean perforations, (2) the maximum underbalanced pressure that can be tolerated without causing sand production, and (3) recommended underbalanced pressure. Yüklə 201,87 Kb. Dostları ilə paylaş:
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