分布式光纤温度监测技术在压裂水平井产剖解释中的应用

doi:10.13809/j.cnki.cn32-1825/te.2021.04.010

Abstract

Abstract:

The distributed optical fiber temperature monitoring technology is gradually being used to monitor the downhole production of fractured horizontal wells. However, it is still a huge problem to interpret the production profile of fractured horizontal wells quantitatively based on DTS data in low permeability gas reservoirs. In view of this, this study established the method, first, the temperature data preprocessing, and then, on the basis of the principle of conservation of mass and energy conservation of horizontal wells in low permeability gas reservoir fracturing coupling temperature forward model, finally using a variety of traffic data of mathematical methods of inversion layers, forming a set of monitoring based on distributed optical fiber temperature measurement technology of horizontal wells in low permeability gas reservoir fracturing of output profile processing and interpretation methods.The actual data processing of fractured horizontal well 5 was carried out by using the established method.The results show that the forward temperature fitting curve is basically consistent with the original temperature curve, which indicates the rationality and accuracy of the forward model.In addition, the calculated absolute errors of daily gas production of the five wells were between 100 m³ and 1 712 m³, and the absolute errors of daily water production are between 0.7 m³ and 1.8 m³. The errors are small and meet the production requirements. All these provided technical support for the development of low permeability gas reservoirs.

Key words: distributed optical fiber, temperature monitoring technology, fracture, horizontal well, production profile control explain

CLC Number:

TE331

Xiaowei FENG,Yi ZHAO,Peng YANG, et al. Application of distributed optical fiber temperature monitoring technology in production and profile interpretation of fractured horizontal wells[J]. Petroleum Reservoir Evaluation and Development, 2021, 11(4): 542-549.

Figures/Tables 7

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Table 1

Table 2

References 32

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序号	顶深（m）	底深（m）	日产气量（m³）	日产水量（m³）	产气贡献（%）	产水贡献（%）
1	3 268.00	3 311.00	2 352.240	0	14.4	0
2	3 328.72	3 353.38	1 881.792	0	11.6	0
3	3 383.50	3 391.20	0	2.112	0	49.16
4	3 418.92	3 433.71	3 267.475	0	20.1	0
5	3 481.63	3 487.26	333.437	0	2.0	0
6	3 509.10	3 520.38	1 975.882	0	12.1	0
7	3 585.00	3 600.30	552.007	0	3.4	0
8	3 607.37	3 613.56	0	2.184	0	50.84
9	3 618.32	3 625.00	519.775	0	3.2	0
10	3 625.00	3 645.00	207.907	0	1.3	0
11	3 694.02	3 704.20	649.322	0	4.0	0
12	3 764.88	3 776.45	416.861	0	2.6	0
13	3 824.89	3 847.32	1 853.280	0	11.4	0
14	3 947.83	3 965.18	855.362	0	5.3	0
15	3 996.27	4 015.79	1 416.000	0	8.7	0
总计			16 281.341	4.296

井号	井口监测日产气（m³）	井口监测日产水（m³）	计算的日产气（m³）	计算的日产水（m³）	日产气相对误差（%）	日产水相对误差（%）
XX2井	32 000	12	30 288.235	10.275	5.349	14.375
XX3井	28 000	5	27 122.442	4.158	3.134	16.840
XX4井	20 000	6	19 900.995	4.911	0.495	18.150
XX5井	17 000	6	16 474.567	5.201	3.091	13.317

Application of distributed optical fiber temperature monitoring technology in production and profile interpretation of fractured horizontal wells

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