有缆智能分层采油技术研究与现场试验

doi:10.13809/j.cnki.cn32-1825/te.2025.04.018

摘要/Abstract

摘要：

江苏油田复杂小断块油藏以水驱分层注水开发为主，目前采用智能分注来提升注采对应水平以提高采收率。由于采出井分层控制水平低，分层注水受效关系、受效程度认识不清，采油井层间干扰，单层突进，含水率上升快等问题突出，为注采协同缓解高含水期层间与平面矛盾，减少无效水循环，控制采油井含水率上升，研发了有缆智能分层采油技术。通过筛选适应井下高温、高压、腐蚀及结垢环境的流量、含水率、压力、温度传感器，选用可靠的分层流量调节开关及控制技术，合理设计组件空间布局及分层配产器整体机械结构，选用不同的双向传输电缆及连接技术，开发配产器控制电路及地面集成控制系统，优化配套井下分层采油管柱，降低工具及实施成本，实现了井下分层生产参数的实时连续监测及对分层配产器的无线远程调控。现场开展了单层轮采、分层配产、耦合调整试验，证实了试验前油藏动态分析结论，验证了智能分层采油工具及管柱性能，实现注采耦合联动、增油控水和分层测调，试验井含水率下降38.8%。该技术的应用可为油藏精细地质分析与挖潜提供依据，大大提高了油田采油智能化水平。

关键词: 采油井, 分层采油, 分层配产器, 管柱优化, 注采耦合

Abstract:

The complex small fault block oilfields in Jiangsu are mainly developed through waterflooding with stratified injection. Currently, intelligent stratified injection is applied to improve injection-production coordination and enhance recovery efficiency. Due to the low level of stratified control in production wells and the unclear understanding of the relationship and degree of effectiveness of stratified water injection, issues such as interlayer interference in production wells, single-layer water breakthrough, and rapid water cut increases are prominent. To achieve injection-production coordination, alleviate interlayer and areal contradictions during the high water cut period, reduce ineffective water cycling, and control the rise in water cut of production wells, a cabled intelligent stratified oil production technology was developed. Flow rate, water cut, pressure, and temperature sensors suitable for the high-temperature, high-pressure, corrosive, and scaling-prone downhole environment were selected. Reliable stratified flow control devices and control technologies were adopted, and the spatial layout of components and overall mechanical structure of the stratified production allocator were optimally designed. Different bidirectional transmission cables and connection technologies were selected, the control circuits of the production allocator and a ground-integrated control system were developed, and the supporting downhole stratified oil production strings were optimized. Tool and implementation costs were reduced, enabling real-time continuous monitoring of downhole stratified production parameters and wireless remote control of the stratified production allocator. Field tests, including alternating single-layer production, stratified production allocation, and coupled adjustment, were conducted. The tests confirmed the conclusions of pre-test reservoir dynamic analysis and verified the performance of the intelligent stratified oil production tools and strings. Injection-production coupling, enhanced oil production, water cut control, and stratified measurement and adjustment were achieved, with the water cut of the test well reduced by 38.8%. The application of this technology can provide a basis for fine geological analysis and potential exploration of oil reservoirs, significantly enhancing the intelligent level of oilfield production.

Key words: production well, stratified oil production, stratified production allocator, string optimization, injection-production coupling

中图分类号:

TE355

邓吉彬,康玉阳,严卫杰, 等. 有缆智能分层采油技术研究与现场试验[J]. 油气藏评价与开发, 2025, 15(4): 679-685.

DENG Jibin,KANG Yuyang,YAN Weijie, et al. Research and field testing of cabled intelligent stratified oil production technology[J]. Petroleum Reservoir Evaluation and Development, 2025, 15(4): 679-685.

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采油管柱类型	传输连接方式	分层数	封隔方式	泵类型	作业需求	实施成本	优点	缺点
湿对接分体管柱	湿连接	≥2	过电缆封隔器	常规泵	两趟管柱	较高	检泵便捷，下部管柱可复用	可能漏电，斜井易撞击、磨损
无线对接分体管柱	无线对接	≥2	过电缆封隔器	常规泵	两趟管柱	高	检泵便捷，下部管柱可复用	斜井易撞击、磨损
插管式分体管柱	密封连接器	2	插管桥塞	常规泵	两趟管柱	低	工艺简单，不易漏电，适应性较广	需要改造下层配产器，多层不适用
一体式管柱	密封连接器	≥2	过电缆封隔器	杆式泵、改进管式泵固定阀	一趟管柱	较低	安全性高，适应性广	检泵繁琐，下部管柱不可复用

时间	开采层	日产液量/m³	含水率/%	上层内压/MPa	上层外压/MPa	下层内压/MPa	下层外压/MPa	上层开度/%	下层开度/%
措施前	多层合采	13.2	90.0
2024年3月	单采下层	11.0	95.0	6.95	4.91	7.37	7.42	0	100
2024年3月	单采上层	2.0	47.7	2.61	2.64	2.94	9.89	100	5
2024年4月	分层配产	4.0	80.0	2.50	2.52	2.97	9.77	100	42
2024年5月	分层配产	1.7	42.0	2.36	2.38	2.88	11.29	100	25
2024年7月	分层配产	2.8	51.2	2.45	2.49	2.53	9.38	100	30