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摘要? 疏松砂巖儲(chǔ)層在改造及注水施工中表現(xiàn)出與致密儲(chǔ)層壓裂迥異的力學(xué)變形特征,，亟需特定的力學(xué)機(jī)理解釋其宏微觀變形行為,，從而為現(xiàn)場(chǎng)施工提供理論指導(dǎo),。針對(duì)疏松砂巖質(zhì)地松軟,、塑性強(qiáng),、滲透率高的巖土力學(xué) 性質(zhì)，本文引入土力學(xué)的理念,，介紹微壓裂這一儲(chǔ)層改造與增注技術(shù),，深入分析該類儲(chǔ)層在微壓裂過(guò)程中的擴(kuò) 容及微裂縫起裂機(jī)理。在理清微壓裂力學(xué)機(jī)理的基礎(chǔ)上,，總結(jié)歸納已有的儲(chǔ)層微壓裂效果評(píng)價(jià)方法,，包括室內(nèi) 實(shí)驗(yàn)、解析分析和數(shù)值計(jì)算方法,，闡明各類方法的必要性和優(yōu)缺點(diǎn),。基于力學(xué)機(jī)理和計(jì)算方法,，討論了微壓裂技術(shù)在超稠油儲(chǔ)層改造,、井筒解堵和人工干預(yù)地應(yīng)力場(chǎng)中的應(yīng)用方法和工程案例。最后,，以超稠油儲(chǔ)層改造為例,，提出微壓裂效果自動(dòng)化評(píng)價(jià)技術(shù),。研究發(fā)現(xiàn)微壓裂為綜合孔隙彈性、塑性和斷裂多種力學(xué)變形的復(fù)雜力學(xué) 機(jī)制,，在不同的應(yīng)用場(chǎng)合實(shí)現(xiàn)的功能各異,，但普遍體現(xiàn)為擴(kuò)容至微裂縫起裂這一過(guò)程的局部至全部特征；分析微壓裂作用效果應(yīng)當(dāng)考慮多尺度效應(yīng),，結(jié)合多類數(shù)值計(jì)算方法開(kāi)展實(shí)際工程案例評(píng)價(jià),。超稠油儲(chǔ)層微壓裂改造以井周產(chǎn)生微裂縫、井間儲(chǔ)層發(fā)生孔隙擴(kuò)容為主,，加強(qiáng)井間熱對(duì)流效應(yīng),，加速井間連通。微壓裂應(yīng)用于井筒解堵時(shí)提供了反洗沖砂,、井周擴(kuò)容與造微裂縫恢復(fù)流體通道的作用,，從而延長(zhǎng)解堵效果。此外,，微壓裂亦可應(yīng)用于致密儲(chǔ)層,，通過(guò)人工干預(yù)井周、井間,、段簇間有效地應(yīng)力場(chǎng),，使其利于預(yù)期造縫目標(biāo)。未來(lái)的技術(shù)攻關(guān)應(yīng)集中在完善自動(dòng)化,、進(jìn)而發(fā)展智能化的微壓裂技術(shù),，逐步取代人工決策及控制。

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關(guān)鍵詞 ：疏松砂巖；微壓裂,；擴(kuò)容,；裂縫；解堵,；地應(yīng)力,；智能

Abstract：

Unconsolidated sandstone formations display specific mechanical deformation behavior in their stimulation or injection, which is distinct from that of tight formations upon hydraulic fracturing. In this regard, the mechanical mechanisms must be

revealed to interpret the macro and micro-scale deformation, therefore providing theoretical guidance for field practices. Given the characteristics of an unconsolidated sandstone formation such as soft texture, great plasticity, and high permeability, this article brings in soil mechanics to introduce the formation stimulation and injection augmentation technique known as microfracturing, then delves into the dilation and microfracture initiation mechanisms during microfracturing in such a type of formation. Based on the microfracturing mechanisms, assessment methods of microfracturing efficiency, including laboratory experiments, analytical solu tions, and numerical approaches, are discussed, and summarized on their necessity as well as advantages and disadvantages. Based on the mechanical mechanisms and the calculation methods, the applications of microfracturing in the stimulation of ultra-heavy oil formation, plugging-removal in wellbores and artificial interference of the geostress field, are discussed with respect to the detailed approaches and successful case studies. Finally, the automatic evaluation technique of microfracturing efficiency is proposed using ultra-heavy oil formation stimulation as an example. It is found that microfracturing is a complex mechanism that combines the theories and techniques of poroelasticity, plasticity, and fracture mechanics. It demonstrates various functionalities in different engineering scenarios, but generally shows a series of features of the process from dilation to microfracture initiation. It is believed that the analysis of its stimulation efficiency in realistic practices must consider multiscale effects and use multiple numerical approaches. Microfracturing in an ultra-heavy oil formation is mainly characterized by the microfracture generation surrounding the wellbores and the porosity dilation in between the dual wells, which lead to an enhanced effect of thermal convection and subse quently a fast interwell hydraulic communication. Microfracturing in the plug removal of a wellbore results in a back flush of the sand grains, interwell porosity dilation and flow recovery through microfractures, which would extend the efficiency of the removal attempt. Moreover, microfracturing can also provide a means of artificial geostress field interference for the near wellbore, interwell, and inter-stage or inter-cluster regions, which favorites the predesigned fracturing goal. Future investigation shall be dedicated to improving the automatic implementation of the microfracturing technique, and to further developing an intelligent decision making and control approach when applying the technique, eventually reducing the need for man-made work efforts.

Key words： unconsolidated sandstone; microfracturing; dilation; fracture; plugging removal; geostress; intelligence

收稿日期: 2021-06-30 ????

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基金資助:國(guó)家自然基金重大項(xiàng)目“天然氣水合物儲(chǔ)層力學(xué)特征及多場(chǎng)耦合工程響應(yīng)機(jī)制”( 編號(hào)：51991362) 資助

通訊作者: [email protected]

引用本文: ??

林伯韜. 疏松砂巖儲(chǔ)層微壓裂機(jī)理與應(yīng)用技術(shù)研究. 石油科學(xué)通報(bào), 2021, 02: 209-227 LIN Botao. Microfracturing mechanisms and techniques in unconsolidated sandstone formations. Petroleum Science Bulletin, 2021, 02: 209-227.

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