Characteristics of and main factors controlling the karst shoal reservoir of the lower Cambrian Longwangmiao Formation in the Anyue gas field, central Sichuan Basin, China

doi:10.13745/j.esf.sf.2020.5.22

Abstract

Abstract:

The Lower Cambrian Longwangmiao Formation gas reservoir in the Moxi Block of the Anyue gas field is the largest complete carbonate gas reservoir discovered in China so far. The gas reservoir, developed in the eastern end of the paleo-uplift in the central Sichuan Basin, has a proven gas-bearing area of 805 km² and proven gas geological reserves of 4403.8×10⁸ m³. Its high efficiency development is of strategic significance for ensuring natural gas supply in the Sichuan-Chongqing area. Reservoir development in the Longwangmiao Formation shows strong heterogeneity, and the gas well productivity varies greatly across the reservoir. For gas reservoir development and deployment, it is very important to study both macroscopic and microscopic characteristics of the reservoir and evaluate the heterogeneity of the reservoir storage space. Based on core, imaging log and cast slice data as well as CT scan, nuclear magnetic resonance, mercury injection, etc., we conducted a systematic study on the stratigraphic sequence division, correlation, karst pattern, reservoir characteristics and main controlling factors of the Lower Cambrian Longwangmiao Formation in the Anyue gas field of the central Sichuan Basin. Results show that there are three types of reservoir storage spaces in the Longwangmiao Formation: millimeter-sized dissolved vugs, solution pores, and intergrain/intercrystal pores. Reservoir of the Longwangmiao Formation is mainly developed in sand-clastic dolomite, featuring small to medium-sized dissolved vugs or solution pores, with medium-low porosity and medium-high permeability. Porosity of the full diameter samples from the Longwangmiao Formation was between 2%-18.48%, averaging at 4.81%, and the full diameter permeability ranged between 0.01-78.5 mD, averaging at 3.91 mD. Due to fracture and cavity, reservoir permeability acquired at different measurement scales varied greatly. The log interpreted permeability ranged between 0.1-10 mD, which was slightly higher than the core tested permeability; whereas well tested permeability ranged between 3.24-925 mD, about 1-2 orders of magnitude higher than the core tested permeability. The Moxi area developed four stages of shaols in the vertical and two main shoals with one trench in the horizontal directions, while the second and third stage shaols distribute most extensively. The Longwangmiao Formation experienced three stages of reservoir dissolution, namely the pene-sedimentary, supergene reformation and burial stages. In the pene-sedimentary stage, frequent short time exposures and leaching and dissolution of meteoric fresh water resulted in the formation of early micropores as well as solution pinholes in shoal carbonate deposits. Caledonian period karstification was the key factor for the formation of the vuggy reservoir of the Longwangmiao Formation. Along the vast karst slope, bed-parallel dissolved vugs and pores were well developed, with the karst vuggy reservoirs superimposing vertically and compacting laterally. The favorable spatial allocation of the bed-parallel dissolved vugs and the high-steep structure fissures resulted in the formation of the apparently homogeneous fractured vuggy reservoir. High-quality reservoir is mainly distributed in the MX11- MX8 and MX10-MX12-MX9 well fields, with a reservoir thickness of 40-50 m.

Key words: Anyue gas field, Longwangmiao Formation, shoal, reservoir space, karst pattern, reservoir characteristics, main controlling factors

CLC Number:

P618.130.21

ZHANG Manlang, GUO Zhenhua, ZHANG Lin, FU Jing, ZHENG Guoqiang, XIE Wuren, Ma Shiyu. Characteristics of and main factors controlling the karst shoal reservoir of the lower Cambrian Longwangmiao Formation in the Anyue gas field, central Sichuan Basin, China[J]. Earth Science Frontiers, 2021, 28(1): 235-248.

Figures/Tables 13

References 38

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对比项	准同生期岩溶	表生期岩溶	埋藏期岩溶
形成时期	龙王庙组沉积期或略晚	加里东期	海西期和印支期
岩溶机制	受海退影响,颗粒滩暴露,遭受大气淡水改造	古隆起抬升,龙王庙组遭受风化剥蚀、淋滤改造。风化壳岩溶具有垂向分带特点	筇竹寺组生烃,含有机酸的地层水沿断层进入龙王庙组储层,对早期缝洞进一步改造
岩石学特征	泥粉晶云岩、含砂屑泥晶云岩、砂屑云岩等遭受溶蚀。不稳定的文石、高镁方解石被溶解,溶蚀作用具组构选择性^[18]	中粗粒残余砂屑云岩和中—细晶云岩遭受溶蚀。发育岩溶角砾岩、溶沟、溶缝。溶洞中充填渗流沙,蓝灰色泥岩、碳质泥岩、陆源石英及黄铁矿	不受岩石类型限制,主要与烃源断裂和早期的孔洞发育有关。溶蚀孔洞中常见沥青充填,并见鞍状白云石、自生石英、萤石、天青石及方铅矿、闪锌矿等热液矿物充填^[15]
孔洞发育特征	发育针状溶孔及微孔,主要为粒内溶孔、铸模孔及粒间溶孔。准同生期岩溶为基质孔隙型、溶蚀孔隙型储层形成奠定了基础	发育大中溶孔和中小溶洞,溶洞为粒(晶)间溶孔及裂缝进一步溶蚀扩大而形成。在岩溶斜坡顺层溶蚀孔洞大面积发育。表生期岩溶是龙王庙组高效储层形成的关键因素	粒(晶)间溶孔再次遭受溶蚀形成较大的孔洞,构造缝溶蚀扩大,晚期胶结物发生溶蚀。由于溶蚀作用与充填作用伴生,埋藏期岩溶对储层孔隙的总体贡献较小
地球化学特征	泥粉晶白云岩的碳、氧同位素接近或略低于同期海相碳酸盐岩基线,δ¹³C为-0.77‰,δ¹⁸O为-7.24‰,Sr/Ba为1.01,古盐度Z值122	溶洞充填晶粒云岩的碳、氧同位素和锶含量较低,δ¹³C为-2.20‰,δ¹⁸O为-10.87‰,Sr/Ba为0.42,古盐度Z值117,为淡水成因。而围岩为海水渗透回流成因白云岩^[15]	δ¹³C、δ¹⁸O小于同期海相碳酸盐岩基线。早寒武世海相碳酸盐岩的δ¹³C为-0.4‰~-0.1‰,δ¹⁸O为-6.2‰~-4.7‰

对比项	准同生期岩溶	表生期岩溶	埋藏期岩溶
形成时期	龙王庙组沉积期或略晚	加里东期	海西期和印支期
岩溶机制	受海退影响,颗粒滩暴露,遭受大气淡水改造	古隆起抬升,龙王庙组遭受风化剥蚀、淋滤改造。风化壳岩溶具有垂向分带特点	筇竹寺组生烃,含有机酸的地层水沿断层进入龙王庙组储层,对早期缝洞进一步改造
岩石学特征	泥粉晶云岩、含砂屑泥晶云岩、砂屑云岩等遭受溶蚀。不稳定的文石、高镁方解石被溶解,溶蚀作用具组构选择性^[18]	中粗粒残余砂屑云岩和中—细晶云岩遭受溶蚀。发育岩溶角砾岩、溶沟、溶缝。溶洞中充填渗流沙,蓝灰色泥岩、碳质泥岩、陆源石英及黄铁矿	不受岩石类型限制,主要与烃源断裂和早期的孔洞发育有关。溶蚀孔洞中常见沥青充填,并见鞍状白云石、自生石英、萤石、天青石及方铅矿、闪锌矿等热液矿物充填^[15]
孔洞发育特征	发育针状溶孔及微孔,主要为粒内溶孔、铸模孔及粒间溶孔。准同生期岩溶为基质孔隙型、溶蚀孔隙型储层形成奠定了基础	发育大中溶孔和中小溶洞,溶洞为粒(晶)间溶孔及裂缝进一步溶蚀扩大而形成。在岩溶斜坡顺层溶蚀孔洞大面积发育。表生期岩溶是龙王庙组高效储层形成的关键因素	粒(晶)间溶孔再次遭受溶蚀形成较大的孔洞,构造缝溶蚀扩大,晚期胶结物发生溶蚀。由于溶蚀作用与充填作用伴生,埋藏期岩溶对储层孔隙的总体贡献较小
地球化学特征	泥粉晶白云岩的碳、氧同位素接近或略低于同期海相碳酸盐岩基线,δ¹³C为-0.77‰,δ¹⁸O为-7.24‰,Sr/Ba为1.01,古盐度Z值122	溶洞充填晶粒云岩的碳、氧同位素和锶含量较低,δ¹³C为-2.20‰,δ¹⁸O为-10.87‰,Sr/Ba为0.42,古盐度Z值117,为淡水成因。而围岩为海水渗透回流成因白云岩^[15]	δ¹³C、δ¹⁸O小于同期海相碳酸盐岩基线。早寒武世海相碳酸盐岩的δ¹³C为-0.4‰~-0.1‰,δ¹⁸O为-6.2‰~-4.7‰