Creating Optimal Power Supply for Extensive Onshore Oil Fields

W. Baerthlein, D. Audring
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Abstract

It becomes evident today's Oil&Gas projects in average have higher electrical power demand than years back. In most cases technical decisions are to simply increase current to compensate power needs. Design ratings for operating and short-circuit currents of medium-voltage switchgear on generator voltage level are limiting grid design. This is the case especially for power islands. Stepping up generator voltage can be a perfect solution in particular for power grids feeding extended oil fields. Installing step-up transformers for each generator unit and working with a network voltage up to 33 kV or higher sometimes creates disposition to believe that this is a more expensive solution. A load-flow and short-circuit calculation for the main substation is required to properly size the switchgear and the other distribution equipment derived from planned grid arrangement and oil field process specific operation modes. It has also to be considered expected power supply quality, reliability and availability. A cost comparison will be based on total cost of ownership between the solution with main substation on generator voltage level of 11 kV and the solutions with step-up transformers up to 22 or up to 33 kV. This comparison will also include the additional heat losses of overhead lines or cables to and between the wellpads for a year of operation. When using higher voltages, there should be no limitation with respect to grid design and grid operation. Generally, the voltage level has to be adequate for the supply purpose. A network should be designed to avoid use of current limiters. With proper voltage level selection the bus sectionalizers can remain in NC position. It is possible that generator units are operated that loss of one set can be compensated to avoid any interruption of power supply. Power generation can be increased when feeding via transformers to higher voltage levels of switchgear. The Power Plant Switchgear will require only a reduced short-circuit level and lower design currents for busbars and feeders to achieve optimized grid design. Unit transformers between generators and switchgear will prevent any negative influence of ground faults from the grid to the generators. Also with respect to heat losses, maintenance, grid availability and reliability as well as aging the advantages are clearly on the higher voltage level. The required power grid will be assessed based on different voltage levels. The optimized solution for the oil field will be discussed in detail. Solution approach with higher voltage levels and optimized grid design will have reserves to deliver additional electrical power for extensions and also for operation in depletion mode. There are now oil fields which do not allow bridging distances between wellpads by means of overhead lines but by underground cabling because of environmental conditions. Considering this aspect in cost comparison between different grid designs and voltage levels the advantage for higher voltage levels with optimized grid design will be even clearer.
为广阔的陆上油田创造最佳电源
很明显,今天的油气项目的平均电力需求比几年前要高。在大多数情况下,技术决策是简单地增加电流来补偿电力需求。中压开关柜在发电机电压水平上的工作电流和短路电流的设计额定值是电网设计的限制。对于权力岛来说尤其如此。提高发电机电压可以是一个完美的解决方案,特别是为扩展油田供电的电网。为每个发电机组安装升压变压器,并在高达33千伏或更高的网络电压下工作,有时会使人倾向于认为这是一个更昂贵的解决方案。根据规划的电网布置和油田工艺的具体运行方式,需要对主变电所进行负荷流和短路计算,以适当地确定开关柜和其他配电设备的尺寸。它还必须考虑预期的电源质量,可靠性和可用性。成本比较将基于11千伏发电机电压水平的主变电站和22或33千伏升压变压器的解决方案之间的总拥有成本。这种比较还将包括一年作业中架空管线或电缆与井台之间的额外热损失。当使用较高电压时,不应限制电网设计和电网运行。一般来说,电压水平必须满足供电的需要。网络的设计应避免使用电流限制器。通过适当的电压电平选择,母线分段器可以保持在NC位置。在发电机组运行时,有可能补偿一台机组的损失,以避免供电中断。当通过变压器馈电到开关设备的更高电压水平时,发电量可以增加。电厂开关柜将只需要减少短路水平和母线和馈线的更低设计电流,以实现优化的电网设计。发电机和开关柜之间的单元变压器将防止电网对发电机接地故障的任何负面影响。此外,在热损失、维护、电网可用性和可靠性以及老化方面,优势明显体现在更高的电压水平上。所需的电网将根据不同的电压水平进行评估。对油田的优化方案进行了详细的讨论。采用更高的电压水平和优化的电网设计的解决方案将为扩展和耗尽模式的运行提供额外的电力储备。由于环境条件的原因,现在有些油田不允许通过架空线路来桥接井台之间的距离,而是使用地下电缆。考虑到这一点,在不同电网设计和电压水平之间的成本比较中,优化电网设计的更高电压水平的优势将更加明显。
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