页岩气井泡沫排水采气技术应用研究——以平桥南区为例

doi:10.13809/j.cnki.cn32-1825/te.2020.05.013

Abstract

Abstract:

Foam drainage-gas recovery technology is the most common nowadays and is the most effective application technique. However, due to the certain difference in production conditions of different gas fields, the mode, type, and foam drainage system of foaming agents are different. At present, southern Pingqiao adopts the method of 24 h continuous injection which is commonly used in other gas fields. It works in some wells, but for other wells, this technology dose not works well. In order to form a set of foam drainage model suitable for shale gas wells in southern Pingqiao, combined with laboratory evaluation, field test and economic evaluation, it is proved that the foam drainage process can effectively carry out the bottom hole liquid accumulation and achieve a certain degree of production increase. But in the later stage, it is more focused on reducing the production decline of shale gas wells and ensuring the stable production of gas wells. The XHY-4M type liquid foaming agent is optimized for foaming. When the concentration of defoamer is 0.3 %, the concentration of defoamer is 5 % ~ 20 %, the ratio of defoamer and foaming dose is 1.2∶1, the ratio of water to gas in the well is greater than 0.5, and the overall foam drainage effect is better. Meanwhile, the foam drainage system is constantly adjusted and optimized, and the intermittent foam drainage system of “less injection and multiple times” is adopted, which is more applicable and the effect of economic evaluation is optimal. The results of this study have certain reference for the stable production of similar shale gas wells.

Key words: shale gas, southern Pingqiao, foam drainage-gas recovery technology, foaming agent, intermittence foam drainage system

CLC Number:

TE37

Jiaxin LI,Ningbo ZHANG,Chengxiang ZHOU. Application of foam drainage-gas recovery technology in shale gas wells: A case study of southern Pingqiao[J]. Reservoir Evaluation and Development, 2020, 10(5): 91-97.

Figures/Tables 16

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References 21

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药剂型号	药剂浓度/ %	起泡力/ mm	5 min泡高/ mm	泡沫密度/ （g·cm^-3）	携液率
XHY-4M	0.3	160	150	0.008 1	165
KD-06	0.3	125	110	0.011 0	120

药剂浓度/ %	起泡力/ mm	5 min泡高/ mm	泡沫含水率/ %	泡沫密度/ （g·cm^-3）	携液量/ mL
0.1	130	110	0.99	0.009 9	118
0.3	160	150	0.81	0.008 1	165
0.5	170	160	0.72	0.007 2	186
0.7	190	190	0.70	0.007 0	185
1.0	210	210	0.81	0.008 1	187

矿化度/（g·mL^-1）	携液率/%	备注
0.05	93	排空
0.10	92	排空
0.15	93	排空
0.20	91	排空
0.25	92	排空
0.30	92	排空

井号	ρ/（mg·L^-1）						pH	矿化度/（g·mL^-1）	水型
井号	Na⁺	K⁺	Ca²⁺	Mg²⁺	Cl^-	HCO₃^-	pH	矿化度/（g·mL^-1）	水型
A	4 306	195	68	416	10 589	793	7	0.02	氯化钙
B	9 686	404	54	445	20 854	442	6	0.03	氯化钙
C	17 988	422	53	478	26 543	458	6	0.05	氯化钙
D	7 551	308	54	438	16 619	717	6	0.03	氯化钙
E	16 102	445	57	1 207	26 284	676	8	0.04	氯化钙
平均值	11 126	355	57	597	20 178	617	7	0.03

井号	套压/MPa	油压/MPa	油套压差/MPa	产气量/ （10⁴ m³·d^-1）	产水量/（m³·d^-1）	水气比	泡排制度	泡排效果
A	4.7	1.1	3.6	2.3	8.5	3.7 ×10^-4	24 h加注	效果好
B	7.7	3.0	4.7	7.5	11.6	1.6 ×10^-4	24 h加注	效果好
C	4.3	3.4	0.9	4.2	13.1	3.1 ×10^-4	24 h加注	效果好
D	5.0	1.6	3.4	2.8	2.2	0.8 ×10^-4	24 h加注	效果好
E	3.0	1.4	1.6	6.7	7.0	1.0 ×10^-4	24 h加注	效果好
F	3.8	1.5	2.4	4.4	3.7	0.8 ×10^-4	24 h加注	效果好
G	3.2	1.1	2.1	4.9	11.9	2.4 ×10^-4	24 h加注	效果好
H	3.2	1.3	1.9	4.2	1.1	0.3 ×10^-4	24 h加注	效果不明显
I	3.9	2.6	1.3	4.8	1.5	0.3 ×10^-4	24 h加注	效果不明显
J	4.3	2.3	2.0	5.4	1.0	0.2 ×10^-4	24 h加注	效果不明显
K	2.9	1.3	1.6	2.7	1.3	0.5 ×10^-4	24 h加注	效果不明显
L	3.1	1.6	1.4	4.5	1.0	0.2 ×10^-4	24 h加注	效果不明显
M	3.1	1.4	1.7	5.5	2.2	0.4 ×10^-4	24 h加注	效果不明显

Application of foam drainage-gas recovery technology in shale gas wells: A case study of southern Pingqiao

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井号	完钻井深/m	人工井底/m	A点井深/m	A点垂深/m	B点垂深/m	AB 高差/m	油管下深/m
A	5 810	5 755	4 235	3 569	3 892	323	4 100
B	5 550	5 476	4 010	3 198	3 408	210	3 911

井号	泡排前				泡排后				对比
井号	压差/ MPa	产气量/ （10⁴ m³·d^-1）	产水量/ （m³·d^-1）	产量递减率/ %	压差/ MPa	产气量/ （10⁴ m³·d^-1）	产水量/ （m³·d^-1）	产量递减率/ %	压差降低/MPa	产量递减率/ %
A	3.7	2.3	8.5	25.1	1.2	3.5	7.5	12.0	2.5	13.1
B	4.7	7.5	11.6	43.7	1.4	8.6	18.5	16.1	3.3	27.6
平均值	4.2	4.9	10.1		1.3	6.1	13.0			20.4

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