任何基于吸附的技术的边界温度都可以根据特劳顿的假设进行估算，即外推到无穷大压力（或类似于无限大温度）的等压线在一个点处相遇。在本文中，我们讨论了这一假设对许多热操作吸附装置的影响，这些装置适用于开发可再生能源，或更好地利用高或低水平热能。Trouton’s hypothesis不依赖于工作流体，因此对液体蒸汽和固体蒸汽系统都特别有用。我们举例说明了从特劳顿假说推导出的边界温度在重要过程中的应用，如制冰、炎热气候下的空间冷却、深度冻结和住宅热水生产。 边界温度有助于确定哪种吸附或太阳能加热技术更适合于特定的应用，或者它是否超出吸附系统的范围。引用:2016年年度会议，密苏里州圣路易斯，会议论文

The boundary temperatures for any sorption-based technology can be estimated on the basis of Trouton's hypothesis that isosteres, extrapolated to infinitepressure (or analogously to infinite temperature) meet at a single point. In this paper we discuss the consequences of this hypothesis for many sorptiondevices that are thermally operated, suitable for exploiting renewable energy resources, or making better use of high or low level thermal energy. Trouton'shypothesis is independent of the working fluids making it particularly useful to both liquid-vapor and solid-vapor systems. We exemplify the use of thederived boundary temperatures derived from Trouton's hypothesis to important processes such as ice making, space cooling in hot climates, deep freezing,and residential hot water production. The boundary temperatures help determine which sorption or solar heating technology may be better suited to servethe given application, or whether it is beyond the scope of sorption systems.