页岩凝析气受限空间相态及开发特征研究

doi:10.13809/j.cnki.cn32-1825/te.2024.03.004

Abstract

Abstract:

The exploration of Well-Fuye-10 in the Dongyuemiao section has provided valuable characteristic parameters of typical continental shale, revealing a reservoir with well-developed mesopores and macropores and significant heterogeneity. The predominant pore sizes are around 10 nm. Notably, deviations in the critical parameters of the confined fluids alter the condensate gas properties within these nanopores, differentiating them from conventional laboratory results. This study combines indoor phase state experiments, critical parameter migration calculations, and numerical simulations of confined fluids to analyze the phase state characteristics and extraction properties of shale condensate gas. The findings elucidate the phase state transformation and extraction dynamics of the condensate gas. Adjustments in the calculations for condensate gas phase characteristics to account for critical parameter offsets indicate that as pore radius decreases, there is a corresponding reduction in critical temperature and pressure of the system components. This results in a contraction of the phase diagram towards the lower left, a decrease in dew point pressure, reduced gas phase viscosity, an increase in deviation factor, and a gradual decrease in retrograde condensate saturation. Additionally, a mechanism model was employed to assess the impact of critical parameter shifts on depletion extraction effectiveness. Results demonstrate that while the recovery rate of natural gas remains relatively unchanged, the recovery rate of condensate oil shows a significant increase, rising by 9.93% as the pore radius decreases to 10 nm. These insights offer pivotal guidance for the development of shale condensate gas reservoirs, particularly in managing the unique phase behavior and optimizing recovery strategies.

Key words: shale condensate gas, continental shale, confined space, phase change, critical parameter offset, development characteristic

CLC Number:

TE372

Yong TANG,Kun CHEN,Xiaohu HU, et al. Phase behavior and development characteristics of shale condensate gas in confined space[J]. Petroleum Reservoir Evaluation and Development, 2024, 14(3): 343-351.

Figures/Tables 12

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组分	闪蒸气摩尔分数	闪蒸油摩尔分数	井流物摩尔分数	井流物质量分数
CO₂	0.198 8	0	0.185 6	0.283 0
N₂	0.424 7	0	0.396 6	0.384 8
C₁	81.870 9	0	76.436 9	42.473 5
C₂	10.468 5	0.299 0	9.793 6	10.202 0
C₃	3.855 6	0.334 5	3.621 9	5.533 4
iC₄	0.806 1	0.218 2	0.767 1	1.544 5
nC₄	1.132 4	0.541 2	1.093 1	2.200 9
iC₅	0.606 6	1.119 4	0.640 6	1.601 2
nC₅	0.428 8	1.143 4	0.476 2	1.190 2
C₆	0.207 6	5.586 2	0.564 6	1.682 0
C₇	0	10.915 3	0.724 5	2.409 4
C₈	0	16.185 7	1.074 3	3.982 1
C₉	0	11.875 3	0.788 2	3.303 9
C₁₀	0	9.700 6	0.643 8	2.988 8
C₁₁₊	0	42.081 4	2.793 0	20.220 4

孔隙半径/nm	临界温度/K
孔隙半径/nm	N₂—C₁	CO₂—C₃	iC₄—nC₄	iC₅—nC₅	C₆—C₉	C₁₀₊
非受限	196.98	50.87	144.89	191.15	240.45	446.48
100	196.25	322.61	415.89	461.74	510.56	713.73
40	195.14	320.49	412.67	457.92	506.04	704.93
30	194.53	319.31	410.89	455.8	503.53	700.06
20	193.31	316.97	407.34	451.58	498.54	690.39
10	189.68	310.01	396.78	439.05	483.73	661.82
5	182.52	296.33	376.13	414.57	454.84	606.65
2	161.97	257.33	317.82	345.76	374.05	457.08

孔隙半径/nm	临界压力/MPa
孔隙半径/nm	N₂—C₁	CO₂—C₃	iC₄—nC₄	iC₅—nC₅	C₆—C₉	C₁₀₊
非受限	4.59	4.73	3.74	3.38	3.05	1.59
100	4.58	4.71	3.72	3.36	3.03	1.58
40	4.55	4.68	3.69	3.33	3.01	1.55
30	4.54	4.66	3.67	3.32	2.99	1.55
20	4.51	4.63	3.64	3.29	2.96	1.53
10	4.42	4.53	3.55	3.20	2.87	1.46
5	4.26	4.33	3.36	3.02	2.70	1.34
2	3.78	3.76	2.84	2.52	2.22	1.01

孔隙半径/nm	天然气采收率/%	凝析油采收率/%
非受限	83.05	12.11
100	83.01	13.07
40	82.99	14.55
30	82.97	15.09
10	82.79	22.04

Phase behavior and development characteristics of shale condensate gas in confined space

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