Calculation Methods and Influencing Factors of Gas Field Decline Rate

doi:10.7657/XJPG20250510

Abstract

Abstract:

Accurate evaluation of performance decline is crucial for efficient development of gas fields and ensuring stable energy supply. Production decline rate and productivity decline rate are two commonly used parameters for presenting performance decline in gas fields from different perspectives, but their definitions are different. In order to understand the physical meanings of production decline rate and productivity decline rate and clarify their inherent relationship and influencing factors, the calculation method of gas field decline rate was analyzed, and the influencing factors were identified. The results indicate that, for exponential decline, the productivity decline rate are consistent with the production decline rate, while for hyperbolic decline, the productivity decline rate is always greater than the production decline rate, and the difference between the two decline rates increases with the increase of decline index and initial decline rate, and the two rates gradually tend to be consistent with each other with the extension of production time. The concept of gas field exploitation intensity was introduced to eliminate the fluctuations in production decline rate caused by downstream gas consumption changes. A new method of production/productivity prediction was proposed. Specifically, an exponential decline model is used at the early stage of decline, and a harmonic decline model is used at the mid to late stage of decline; then, the average of the two model results is taken as the lower limit, and the result obtained from the harmonic decline model as the upper limit. The research results are of great significance to accurately analyze the decline behaviors of gas fields and scientifically formulate development plans.

Key words: gas field, decline rate calculation, production decline rate, productivity decline rate, exploitation intensity, exponential decline model, harmonic decline model

CLC Number:

TE355

FAN Youhong, LIU Zhijun, PEI Ze, REN Chaofeng. Calculation Methods and Influencing Factors of Gas Field Decline Rate[J]. Xinjiang Petroleum Geology, 2025, 46(5): 600-605.

Figures/Tables 8

Table 1.

Fig. 1.

Table 2.

Fig. 2.

Table 3.

Fig. 3.

Table 4.

Table 5.

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时间/ 年	年度产量/ 10⁴ m³	年末产能/ 10⁴ m³	产量递减率/%	产能递减率/%
1	9 206	900
2	6 423	628	30.2	30.2
3	4 481	438	30.2	30.2
4	3 126	306	30.2	30.2
5	2 181	213	30.2	30.2
6	1 522	149	30.2	30.2
7	1 062	104	30.2	30.2
8	741	72	30.2	30.2
9	517	51	30.2	30.2
10	361	35	30.2	30.2

年度	年度生产时间/d	实际产量/10⁸ m³	产量递减率/%	开采强度/（天·年^-1）	校正产量/10⁸ m³	校正产量递减率/%
2019年度	287.2	33.7		327.4	34.0
2020年度	319.5	29.2	13.4	343.8	28.0	17.6
2021年度	290.3	23.3	20.2	325.8	23.6	15.7
2022年度	272.0	21.3	8.6	330.4	21.3	9.7
2023年度	306.2	19.9	6.6	336.0	19.5	8.5

年度	年产气量/ 10⁸ m³	指数递减预测产量/10⁸ m³	调和递减预测产量/10⁸ m³	2类递减预测产量平均值/10⁸ m³	预测产量/ 10⁸ m³	产量递减率/ %
2019年度	33.7	33.7	33.7	33.7	33.7
2020年度	29.2	27.9	29.3	28.6	28.9	14.1
2021年度	23.3	23.0	25.9	24.5	25.2	12.9
2022年度	21.3	19.1	23.2	21.1	22.2	11.9
2023年度	19.9	15.8	21.1	18.4	19.7	11.1
2024年度		13.0	19.3	16.1	17.7	10.3
2025年度		10.8	17.7	14.3	16.0	9.6
2026年度		8.9	16.4	12.7	14.6	9.0
2027年度		7.4	15.3	11.3	13.3	8.4
2028年度		6.1	14.3	10.2	12.3	7.9
2029年度		5.0	13.5	9.3	11.4	7.4

年度	年末产能/ 10⁴ m³	指数递减预测产能/ 10⁴ m³	调和递减预测产能/ 10⁴ m³	2类递减预测产能平均值/10⁴ m³	预测产能/ 10⁴ m³	产能递减率/ %
2019年度	988	988	988	988	988
2020年度	763	762	852	809	829	16.0
2021年度	679	587	749	668	708	14.6
2022年度	660	453	668	560	614	13.3
2023年度	573	349	602	476	539	12.2
2024年度		269	549	409	479	11.2
2025年度		207	504	356	430	10.2
2026年度		160	466	313	390	9.4
2027年度		123	433	278	356	8.6
2028年度		95	405	250	327	8.0
2029年度		73	380	227	303	7.4

年度	预测年度产量/10⁸ m³		预测年末产能/10⁴ m³
年度	本文方法	衰竭曲线法	本文方法	衰竭曲线法
2024年度	17.7	17.6	479	503
2025年度	16.0	15.8	430	450
2026年度	14.6	14.3	390	404
2027年度	13.3	13.0	356	365
2028年度	12.3	11.8	327	332
2029年度	11.4	10.8	303	303