一种新型化学环燃烧结构的实验研究

M. Yazdanpanah, A. Hoteit, Ann Forret, A. Delebarre, T. Gauthier
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引用次数: 18

摘要

化学循环燃烧(CLC)是一种很有前途的新型燃烧技术,它以最小的能量损失实现二氧化碳的固有分离。氧载体用于连续地将氧气从空气反应堆转移到燃料反应堆,在燃料反应堆中氧气被输送到燃料。因此,防止了空气和燃料之间的直接接触。产生的烟气富含二氧化碳,没有N2稀释。然后,被还原的氧载体被运回空气反应器进行再氧化,从而形成一个化学循环。各种CLC配置已经开发出来并在实验室规模上进行了测试。然而,需要更多的研究来实现可行的CLC过程。在需要解决的不同问题中,控制两个反应器之间的固体循环速率对于实现适当的氧传递速率和固体氧化度的影响是最重要的。此外,最小化燃料和空气反应堆之间的气体泄漏是另一个需要考虑的重要问题。提出了一种新的中程流化床结构,其中反应在两个相互连接的鼓泡流化床中进行。固体循环速率控制是通过使用气动非机械阀(l -阀)独立于反应器中的气体流速来实现的。此外,在输送固体时,采用环密封将气体泄漏降至最低。本文介绍了10kwth等效冷样机运行的实验结果。研究了操作变量对固体循环速率、两层间气体泄漏和各工艺要素压力平衡的影响。结果表明,该系统具有稳定的固体循环、有效的固体流量控制和良好的气密性。
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Experimental Investigations on a Novel Chemical Looping Combustion Configuration
Chemical Looping Combustion (CLC) is a promising novel combustion technology involving inherent separation of carbon dioxide with minimum energy penalty. An oxygen carrier is employed to continuously transfer oxygen from the air reactor to the fuel reactor where the oxygen is delivered to the fuel. Consequently, direct contact between the air and fuel is prevented. The resulting flue gas is CO2 -rich, without N2 dilution. The reduced oxygen carrier is then transported back to the air reactor for re-oxidation purposes, hence forming a chemical loop.Various CLC configurations have already been developed and tested on laboratory scales. However, more investigations are required to achieve feasible CLC processes. Among the different points to address, control of the solid circulation rate between the two reactors is of the highest importance regarding its effect on achievement of an appropriate oxygen transfer rate and solid oxidation degrees. Moreover, minimization of gas leakage between the fuel and air reactors is another important issue to be considered. A novel CLC configuration is proposed where reactions are carried out in two interconnected bubbling fluidized beds. Solid circulation rate control is achieved independently of gas flow rate in the reactors through use of pneumatic non-mechanical valves (L-valves). Moreover, loopseals are employed to minimize gas leakage while transferring solids.Experimental results from operation of a 10 kWth equivalent cold prototype are presented in this paper. The effect of operating variables on the solid circulation rate, gas leakage between the two beds and the pressure balance on all of the process elements is studied. The results demonstrate stable solid circulation with efficient control of the solid flow rate and effective gas tightness of the system.
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