基于综合规划的油气生产宏观作业综合优化方法

I. Ermolovich, A. Shamkov, I. Seleznev, Nikolay Nikolayevich Yelin, Andrey Vladimirovich Duryagin
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引用次数: 0

摘要

作为提高油气生产作业效率的主要工具之一,综合规划的任务是最相关的。由于高强度,今天所有的运营商都强调自动化综合规划过程的重要性。综合计划是指对各个部门负责的单独职能计划中所呈现的活动进行组合、排序和可能的组合,并及时更新活动的执行顺序。同时,功能计划是一组在其特殊性上统一起来的活动。功能计划的例子包括修井(TR)、修井(KR)、日常维护(PP)、研究、组织技术措施(OTM)、计划预防工作(PPR)、新井调试(VNS)。综合规划的目标是在现有限制条件下,以最有效的方式执行矿业公司的商业计划,实现经济效益。限制因素可以是多方面的,例如活动所需的专业人员和特殊设备的数量有限,需要在考虑到季节性和运输类型的情况下将资源转移到活动地点,在一项活动中有严格的作业顺序,由于无法在一个群集地点同时进行各种活动而产生的技术限制,对伴生气利用的限制。综合规划区分了规划的视野。一般来说,期限不超过一年,旨在评估公司商业计划的可行性,并证明资本和运营成本的合理性。年度计划必须考虑到目标(指定,分配到特定的井或油田)和未解决的(称为“虚拟”)活动,这些活动是基于过去一年的统计数据。月度计划和90天计划按月更新,比年度计划更详细和准确,只包含目标活动。月度计划从生产、预算和其他标准方面阐明商业计划的可行性。除了批准的年度、月度和90天计划外,还形成了一项运营(工作)计划,该计划每天或应要求更新。通常,业务计划是在两周的规划期内形成的。传统的综合规划方法有其缺点和改进的机会。传统综合规划方法的本质是,不同的作业服务,如地质服务、油井干预服务、管道维护服务、总动力工程师、总工程师等,每年和每月提交一份活动清单,纳入年度、月度(90天)生产计划,然后综合计划人员将所有活动结合起来,如果可能的话,将它们结合起来,尽可能接近目标。传统方法的主要缺点是形成一个综合计划的高强度,以及它的静态性质。事实上,批准的综合计划实际上不超过两天,因为油气田的生命通常是非常动态的——总是有计划外的活动,总是有工作人员的紧急情况,已经开始的工作人员的开始和结束日期的变化,等等。以上所有方面都表明,综合计划必须是动态的,必须不断更新(Repin et al., 2018)。本文提出的OIS UFAM集成调度解决方案为集成调度过程提供了广泛的自动化功能。
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Comprehensive Approach to Optimization of Macrooperations in Oil and Gas Production Based on Integrated Planning
The task of integrated planning, as one of the main tools to improve the operational efficiency of production activities of oil and gas production operators, is the most relevant. Due to the high intensity, today all operators emphasize the importance of automating the integrated planning process. An integrated plan means combining, ranking and possible combination, as well as timely updating the order of implementation of activities presented in separate functional plans, for which various services are responsible. At the same time, a functional plan is a group of activities united in its specificity. Examples of functional plans are well intervention (TR), well workover (KR), PP (routine maintenance), Research, OTM (organizational -technical measures), PPR (scheduled preventive work), VNS (commissioning of new wells). The goal of integrated planning is to execute the mining company's business plan in the most efficient way in terms of economic performance within the existing constraints. The constraints can be various aspects, such as the limited number of crews of the required specialization and special equipment for the activities, the need to move resources to the location of the activity taking into account the seasonality and types of transport, a strict sequence of operations within one activity, technological constraints associated with the inability to simultaneously conduct various activities at one cluster site, restrictions on the utilization of associated petroleum gas. Integrated planning distinguishes between planning horizons. As a rule, the horizon does not exceed one year and is designed to assess the feasibility of the company's business plan and justify capital and operating costs. Annual planning must take into account both targeted (named, assigned to a specific well or field site) and unaddressed (called "virtual") activities based on past year statistics. Monthly and 90-day plans are updated on a monthly basis and are more detailed and accurate than the annual plan, containing only targeted activities. Monthly planning clarifies the feasibility of the business plan in terms of production, budget and other criteria. In addition to the approved annual, monthly and 90-day plan, an operational (working) plan is formed, which is updated on a daily basis or upon request. As a rule, the operational plan is formed for a two-week planning horizon. The traditional integrated planning approach has its drawbacks and opportunities for improvement. The essence of the traditional approach of integrated planning is that different operational services, such as Geological Service, Well Intervention Service, Pipeline Maintenance Service, Chief Power Engineer, Chief Engineer, etc., annually and monthly submit a list of activities for inclusion in the annual, monthly (90-day) production program, after which the integrated planner combines all activities, combining them if possible, trying to achieve the targets as closely as possible, such as The main drawbacks of the traditional approach are the high intensity of forming an integrated plan, as well as its static nature. In fact, the approved integrated plan is actual no more than two days, as the life of oil and gas field is usually very dynamic - there are always unscheduled activities, there are always emergencies during crews, shifts in the start and end dates of already started crews, etc. All of the above aspects indicate that the integrated plan must be dynamic and must be constantly updated (Repin et al., 2018). The OIS UFAM integrated scheduling solution presented in this article provides extensive automation capabilities for the integrated scheduling process.
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