A well designed adsorbent bed is very important to an adsorption refrigeration system.
吸附床是吸附式制冷系统的核心部件。
In the adsorption refrigeration system, three enhanced heat transfer models of tube adsorbent bed are designed.
介绍了吸附式制冷系统中吸附床的三种强化传热模型结构设计方案。
The numerical simulation of adsorbent bed has adopted one-dimensional uniform pressure field model along the circumference.
吸附床的数学模拟采用沿吸附床周向的一维均匀压力场模型。
The model and results are helpful to reveal heat and mass transfer characters of the adsorbent bed and to provide theoretical basis for optimal design of this system.
该数学模型和计算结果有助于深入认识吸附床的传热传质特性,以期能为吸附床的具体设计提供理论依据。
The heat transfer process in an adsorbent bed for natural gas storage is analyzed. Its simple models are developed and their theoretical solutions obtained are discussed.
分析了天然气吸附床的传热过程,建立了简化的吸附床内传热模型,讨论了传热模型的分析解。
Adsorbent bed is the core component of adsorption refrigeration system, its heat and mass transfer performance has a direct influence on the refrigerating capacity of the system.
吸附床是吸附式制冷系统的核心部件,其传热传质性能的好坏直接影响到系统的制冷量。
The separation process demonstrated the integration advantage of expanded bed adsorption and the excellent properties of the novel mixed-mode expanded bed adsorbent.
该分离过程充分体现了扩张床吸附的集成化优势和新型混合模式扩张床吸附剂的优良性能。
A regenerable adsorbent and catalyst substrate that is amenable to in-flight maintenance and addresses issues associated with pellet bed size attrition is emerging as a viable improvement solution.
底一可再生吸附剂及催化剂物,适合进行空中维护并解决与相关的问题球团矿床大小磨损正在形成作为一种可行的改善解决方案。
A regenerable adsorbent and catalyst substrate that is amenable to in-flight maintenance and addresses issues associated with pellet bed size attrition is emerging as a viable improvement solution.
底一可再生吸附剂及催化剂物,适合进行空中维护并解决与相关的问题球团矿床大小磨损正在形成作为一种可行的改善解决方案。
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