Improvements on High Temperature Lithium Oxyhalide Primary Battery for Downhole Tools Power Applications

Wu Bi, Jiaxiang Ren, Pengyu Cheng, Xu Wang, Timothy R. Dunne, Lei Zhao
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Abstract

Commercial lithium oxyhalide batteries have a very flat voltage curve. It is challenging to determine a battery's remaining capacity during and after powering downhole drilling tools. It is wasteful and environmentally hazardous to dispose of lightly used battery packs. Through innovations in battery cell design and electrolyte formulation, laboratory cells showed multiple voltage plateaus allowing easy estimation of remaining capacity at room temperature. Prototyped DD-size batteries validated the unique feature at high temperatures. If the batteries are used in downhole drilling and measurement tools, non-productive time may be shortened, and costs reduced over time. Small coin cells were assembled in an inert argon gas filled glovebox. The assembled coin cell, lithium metal foil disk, carbon electrode, and other cell components were weighted to determine electrolyte weight accurately. Carbon black electrodes were prepared by coating carbon black paste on nickel foam substrate. After overnight air drying, coated nickel foam was hot pressed to 1 mm thickness at 230 °C. DD-size cells were prototyped at a battery vendor with selected cell configurations. Performance of coin cells and prototyped DD-size cells were measured during constant current discharge tests. Discharge voltage curves of baseline coin cells mimicking commercial battery products were flat at 3.4 until sudden voltage crash at the end of discharge. Coin cells OP-33 and OP-36, with the improved design and electrolyte formula, showed two main voltage plateaus. The higher voltage plateau was around 3.85-3.60 V, and the lower voltage plateau was around 3.50-3.40 V. The sharp voltage transition from 3.60 V to 3.50 V was easy for a user or a battery management system to detect. Capacity percentage in the higher voltage plateau and the lower voltage plateau depends on the energy active chemical compositions of electrolyte. A cell design and electrolyte formulation were selected to prototype scaled-up DD-size cells. Three repeating DD-size cells were discharged at 150 °C. The overall sloping voltage curves and the obvious voltage transition between two discharge stages around 3.5 V can greatly facilitate battery capacity estimation. As of today, there is no commercial high temperature lithium oxyhalide primary battery with such a unique feature of staged and sloping battery voltage shape for capacity estimation. Compared to capacity estimation by charge counting method utilized in some battery monitoring chips, capacity estimation based on voltage change is much simpler, more accurate, and consumes less battery energy without needs of frequent current measurement and charge calculation. Any previously lightly discharged battery pack can be easily determined whether further usage is possible for the next downhole tools power application, which saves cost and reduces battery waste.
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井下工具动力用高温氧化卤化锂一次电池的改进
商用氧化卤化锂电池具有非常平坦的电压曲线。在为井下钻井工具供电期间和之后,确定电池的剩余容量是一项挑战。处理少量使用过的电池组既浪费又对环境有害。通过电池设计和电解质配方的创新,实验室电池显示出多个电压平台,可以轻松估计室温下的剩余容量。dd大小的原型电池在高温下验证了这种独特的特性。如果将电池用于井下钻井和测量工具,则可以缩短非生产时间,并随着时间的推移降低成本。小型硬币电池组装在充满惰性氩气的手套箱中。对组装好的硬币电池、锂金属箔片、碳电极和其他电池组件进行称重,以准确确定电解质的重量。在泡沫镍基体上涂覆炭黑浆料制备炭黑电极。经过一夜风干后,涂覆的泡沫镍在230℃下热压至1mm厚度。dd大小的电池在电池供应商处按选定的电池配置进行原型设计。在恒流放电测试中测量了硬币电池和原型dd尺寸电池的性能。模拟商业电池产品的基准硬币电池的放电电压曲线在3.4时是平坦的,直到放电结束时电压突然崩溃。硬币电池OP-33和OP-36,经过改进的设计和电解质配方,出现了两个主要的电压平台。较高电压平台在3.85-3.60 V左右,较低电压平台在3.50-3.40 V左右。从3.60 V到3.50 V的急剧电压转换很容易被用户或电池管理系统检测到。在高电压平台和低电压平台上的容量百分比取决于电解质的能量活性化学成分。选择了一种电池设计和电解质配方来原型放大dd尺寸的电池。三个重复dd大小的电池在150°C下放电。整体倾斜的电压曲线和3.5 V左右两个放电阶段之间明显的电压过渡,极大地方便了电池容量的估计。到目前为止,市面上还没有一种高温氧化卤化锂原电池具有如此独特的分段和倾斜电池电压形状,用于容量估计。与一些电池监测芯片采用的充电计数方法相比,基于电压变化的容量估计更简单、更准确,并且不需要频繁测量电流和计算充电,消耗电池能量更少。任何先前轻度放电的电池组都可以很容易地确定是否可以在下一次井下工具动力应用中进一步使用,从而节省成本并减少电池浪费。
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