琼东南盆地深水东区Y8-1含气构造天然气来源及侧向运聚模式

张迎朝; 甘军; 徐新德; 梁刚; 李兴

doi:10.3799/dqkx.2019.159

琼东南盆地深水东区Y8-1含气构造天然气来源及侧向运聚模式

doi: 10.3799/dqkx.2019.159

中海石油(中国)有限公司湛江分公司, 广东湛江 524057

基金项目:

国家“十三五”科技重大专项《琼东南盆地深水区大中型气田勘探关键技术》 2016ZX05026-002

详细信息

作者简介:
张迎朝(1971-), 男, 教授级高级工程师, 主要从事南海油气勘探、科研工作

中图分类号: P624
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出版历程
- 收稿日期: 2019-02-03
- 刊出日期: 2019-08-15

The Source and Natural Gas Lateral Migration Accumulation Model of Y8-1 Gas Bearing Structure, East Deep Water in the Qiongdongnan Basin

Zhanjiang Branch of China National Offshore Oil Corporation Ltd., Zhanjiang 524057, China

摘要

摘要: 综合钻井天然气地球化学、地震资料，分析了琼东南盆地深水东区Y8-1构造天然气成因、来源及侧向运聚模式.天然气轻烃C6、C7组成分析表明，Y8-1构造天然气既有别于松东凹陷北坡的油型气，也不同于深水L17-2气田的煤型气.根据天然气乙烷、丙烷碳同位素特征，判断Y8-1构造天然气具有煤型气和油型气混合成因特征.选择盆地东部典型煤型气、油型气作为端元，计算得到Y8-1构造天然气中煤型气占53.3%、油型气占46.7%，分别来源于松南-宝岛凹陷下渐新统崖城组陆源海相烃源岩、始新统湖相烃源岩，两套烃源岩均具备生成成熟-高成熟天然气的地质条件.松南-宝岛凹陷中烃源岩生成的天然气沿断裂、构造脊、砂岩层侧向长距离运移，在Y8-1崖城组、花岗岩基岩圈闭中聚集成藏.
- 天然气成因 /
- 轻烃 /
- 碳 /
- 混源气 /
- 深水东区 /
- 琼东南盆地
Abstract: Based on the geochemical analyses of natural gases and seismic exploration data,the genesis,sources and lateral migration accumulation of Y8-1 bearing structure were comprehensively analyzed in the East deep water of the Qiongdong Basin. The analyses of C6,C7 light hydrocarbons show that the natural gas of the Y8-1 bearing structure is different from oil-type gas in the northern slope of Songdong sag,and coal-type gas of L17-2 gas field in the deepwater as well. According to the ethane and the propane carbon isotope,the natural gas in the Y8-1 bearing structurehas the mixing characteristics of coal-type gas and oil-type gas. The typical coal-type gas and the oil-type gas in the east Qiongdongnan Basin are selected to be end elements,the natural gas ethane carbon isotope of the Y8-1 bearing structure is calculated as coal-type gas for 53.3% and oil-type gas for 46.7% in the natural gas. The Y8-1 mixing source gas derived from the terrestrial marine source rock of Lower Oligocene Yacheng formation and Eocene lacustrine source rock in Songnan-Baodao sag respectively,and both sets of source rocks have geological conditions for the formation of mature-high mature natural gas. The natural gas generated from the source rocks in the Songnan,Baodao sags migrates along the tectonic ridges,faults,and sandstone carriers for a long distance,thenaccumulatedin the Yacheng formation and granite basement traps in the Songnan low-uplift,East deep water of the Qiongdong Basin.
- genesis of the natural gas /
- light hydrocarbon /
- carbon /
- mixing source gas /
- east deep water /
- Qiongdongnan Basin

HTML全文

图 1 琼东南盆地构造区划示意图

Fig. 1. The structure division sketch map in the Qiongdongnan Basin

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图 2 琼东南盆地及邻区天然气乙烷碳同位素（δ¹³C₂）和丙烷碳同位素（δ¹³C₃）相互关系

Fig. 2. Correlation between ethane carbon isotope(δ¹³C₂) and propane carbon isotope(δ¹³C₃)of the varied natural gases in the Qiongdongnan Basin and adjacent basins

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图 3 琼东南盆地天然气轻烃石蜡指数-庚烷值关系

Fig. 3. Relationship between paraffin index and heptane value of natural gas light hydrocarbon in Qiongdongnan Basin

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图 4 松南-宝岛凹陷-Y8-1典型剖面5.5 Ma以来构造发育史

Fig. 4. Structural development history since the typical 5.5 Ma of Songnan-Baodao sag across Y8-1

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图 5 （a）过Y8-1含气构造地震剖面；（b）Y8-1天然气侧向运聚模式

Fig. 5. (a)The seismic section crossing Y8-1;(b)Lateral migration-accumulation mode of Y8-1

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表 1 琼东南盆地东部天然气组分、干燥系数与碳同位素特征

Table 1. Natural gas composition, dry coefficient and carbon isotope characteristics, East Qiongdongnan basin

区带	井号	井段（m）	测试层号	天然气组分(%)				干燥系数	碳同位素δ¹³C(‰)
区带	井号	井段（m）	测试层号	C₁	C_2~5	N₂	CO₂	C₁/C_1~5	C₁	C₂	C₃	C₄	CO₂
松东凹陷北坡带	SF24-1-1	2 122.5	MDT	74.30	9.80	6.77	7.81	0.88	-47.06	-30.92	-29.96	-28.64	-7.61
宝岛凹陷北坡带	BF13-1-1	1 573.0 ~1 580.0	DST	86.14	10.24	2.46	0.72	0.89	-48.65	-30.53	-31.15	-27.82	-25.54
	BF13-3-1	1 740.0	MDT	84.70	11.40	2.80	0.61	0.88	-48.91	-27.45	-27.93	-27.84
	BF13-3S-1	1 967.5	MDT	82.48	8.09	6.67	1.18	0.91	-45.53	-30.39	-29.84	-28.09	-29.33
	BF19-2-3	3 911.0	MDT	79.70	8.29	6.28	1.19	0.91	-35.98	-30.39	-28.57	-27.41	-6.23
	BF19-2-3	3 934.5	MDT	72.93	3.73	3.84	18.72	0.95	-35.17	-30.67	-28.60	-27.30	-4.26
松南低凸起	Y8-1-1	2 880.5	MDT	89.90	2.97	6.11	0.59	0.97	-45.44	-27.64	-27.80		-7.82
松南低凸起	Y8-1-1	2 895.6	MDT	89.77	2.99	6.13	0.69	0.97	-45.59	-27.83	-27.88		-8.03
松涛凸起	SF34-3-1	2 301.8	MDT	93.92	4.50	0.43	0.65	0.95	-46.55	-27.57	-27.50		-16.70
松涛凸起	SF34-3-1	2 311.6	MDT	92.70	5.42	0.39	0.72	0.94	-46.54	-25.59	-26.22		-16.22
注：SF24-1-1:下中新统三亚组; BF13-1-1:中中新统梅山组; BF13-3-1:中中新统梅山组; BF13-3S-1:中中新统梅山组; BF19-2-3:上渐新统陵水组Ⅰ气组和上渐新统陵水组Ⅱ气组; Y8-1-1:下渐新统崖城组; SF34-3-1:下中新统三亚组

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表 2 琼东南盆地东区、北部湾盆地天然气轻烃C₆和C₇系列分析数据表

Table 2. The C₆ and C₇ light hydrocarbon series of the east Qiongdongnan Basin and the Beibu Gulf Basin

井名	井深(m)	采样方式	C₆系列(%)				C₇系列(%)
井名	井深(m)	采样方式	正构烷烃	异构烷烃	环烷烃	芳香烃	正构烷烃	异构烷烃	环烷烃	芳香烃
SF24-1-1	2 122.5	FMT	21.72	41.95	34.08	2.25	15.52	31.90	49.14	3.45
BF13-1-1	1 573.0~1 580.0	DST	23.08	47.12	29.81	0	13.64	31.82	54.55	0
BF13-1-1	1 577.3	MDT	20.75	48.11	31.13	0	12.00	30.00	58.00	0
BF13-3-1	1 740.0	MDT	25.00	56.43	18.57	0	14.63	43.90	41.46	0
BF13-3S-1	1 967.5	MDT	21.19	41.53	36.44	0.85	13.21	26.42	58.49	1.89
BF19-2-3	3 911.0	MDT	15.15	36.36	39.39	9.09	16.67	33.33	33.33	16.67
BF19-2-3	3 934.5	MDT	9.09	18.18	27.27	45.45	6.25	6.25	31.25	56.25
Y8-1-1	2 880.5	MDT	12.82	46.15	30.77	10.26	11.43	31.43	48.57	8.57
Y8-1-1	2 895.6	MDT	13.33	44.44	28.89	13.33	12.50	32.50	45.00	10.00
L17-2-1	3 306.0	MDT	13.98	34.41	25.81	25.81	13.73	21.57	43.14	21.57
L18-1-1	2 819.9~2 846.7	DST	13.11	40.98	22.95	22.95	11.11	27.78	44.44	16.67
SF34-3-1	2 301.8	MDT	20.11	42.93	35.87	1.09	17.30	23.24	58.38	1.08
SF34-3-1	2 311.6	MDT	20.00	42.95	36.07	0.98	16.08	24.71	57.65	1.57
WZ1	2 137.5~2 265.8	DST3	29.53	42.13	27.95	0.39	19.63	23.36	56.07	0.93
WZ2	2 351.0~2 357.0	DST2	28.89	53.33	17.04	0.74	20.00	34.29	45.71	0
WZ3	2 459.0~2 473.5	DST2	28.85	48.72	18.59	3.85	20.45	31.82	43.18	4.55

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表 3 琼东南盆地主要含气构造天然气C₇轻烃组成

Table 3. The Composition of C₇ light hydrocarbon series of natural gas in Qiongdongnan basin

井名	深度(m)	地层	天然气C₇轻烃组成			甲基环己烷指数(%)	成因类型
井名	深度(m)	地层	甲基环己烷(MCH)(%)	正庚烷（nC₇）(%)	二甲基环戊烷(ΣDMCP)(%)	甲基环己烷指数(%)	成因类型
SF24-1-1	2 122.5	下中新统三亚组	42.60	24.00	33.30	42.60	油型气
BF13-1-1	1 573.0~1 580.0	中中新统梅山组	40.00	20.00	40.00	40.00	油型气
BF13-1-1	1 577.3	中中新统梅山组	40.00	17.10	42.90	40.00	油型气
BF13-3-1	1 740.0	中中新统梅山组	30.40	26.00	43.60	30.40	油型气
BF13-3S-1	1 967.5	下中新统三亚组	42.10	18.40	39.50	42.10	油型气
BF13-3S-1	1 967.5	下中新统三亚组	45.80	18.80	35.40	45.80	油型气
BF19-2-3	3 911.0	上渐新统陵水组二段Ⅰ气组	50.00	10.00	40.00	50.00	煤型气
	3 934.5	上渐新统陵水组二段Ⅱ气组	50.00	16.70	33.30	50.00	煤型气
			57.10	14.30	28.60	57.10	煤型气
			60.00	20.00	20.00	60.00	煤型气
L17-2-1	3 306.0	上中新统黄流组	48.30	24.10	27.60	48.30	煤型气
L17-2-2	3 331.3	上中新统黄流组	50.00	21.40	28.60	50.00	煤型气
L18-1-1	2 819.9~2 846.7	莺二段T29A气组	40.00	20.00	40.00	40.00	油型气
Y8-1-1	2 880.5	下渐新统崖城组	47.60	19.10	33.30	47.60	油型气
Y8-1-1	2 895.6	下渐新统崖城组	43.50	21.70	34.80	43.50	油型气
WZ1	2 137.5~2 265.8	流-段	33.30	25.90	40.70	33.30	油型气
WZ2	2 351.0~2 357.0	涠三段	34.80	30.40	34.80	34.80	油型气
WZ3	2 459.0~2 473.5	涠三段	35.71	32.14	32.14	35.71	油型气
注：甲基环己烷指数=MCH/(MCH+nC₇+ΣDMCP)×100%

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表 4 Y8-1含气构造天然气混源比例计算表

Table 4. The calculation table of mixed source ratios of the natural gas in Y8-1 gas bearing structure

天然气组分	Y8-1气藏天然气碳同位素(‰)	湖相气端元：S24气藏			陆源浅海相气端元：L17气田			混源气藏天然气碳同位素(‰)
天然气组分	Y8-1气藏天然气碳同位素(‰)	天然气组分含量m（%）	天然气碳同位素n (‰)	混合比例f_h（%）	天然气组分含量x（%）	天然气碳同位素y (‰)	混合比例f_q（%）	计算考虑天然气组分A	计算未考虑天然气组分B
乙烷	-27.74	4.45	-30.92	46.7	4.4	-24.93	53.3	-27.74	-27.73
丙烷	-28.84	3.36	-29.96	40.8	1.1	-23.38	59.2	-27.84	-26.06
注：丙烷同位素倒转偏轻，计算结果仅供参考，A=(m×n×f_h+x×y×f_q)/(m×f_h+x×f_q), B=n×f_h+y×f_q

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