本研究為開發β型史特靈熱泵並建立熱力學理論模型以預測熱泵運作之特性，並藉由數值分析與實驗結果探討理論模型之準確性。理論模型將史特靈熱泵分成七個腔室為熱端水套、熱端汽缸、壓縮室、再生室、膨脹室、冷端汽缸、冷端水套，分別計算壓力、體積、溫度、質量等熱力性質之變化，同時考慮軸向熱傳、內部穿梭熱傳、內部泵氣熱傳、內部壓降熱傳之影響，並得到史特靈熱泵之放熱量、吸熱量、指示功、性能係數。
由熱力模型對各參數影響進行數值分析，包括壓力、轉速、幾何參數、填充氣體種類等，並藉由分析結果得到史特靈熱泵之設計方向，其中考慮到摩擦熱與機械損失之影響，加入熱力模型之理論值與實驗值比較並探討準確性及影響因素。

In this study, a prototype of Stirling heat pump is developed and the behavior is predicted by thermodynamic theoretical. Stirling heat pump is separated into seven chambers including hot water jacket, hot cylinder, compressor chamber, regenerator chamber, expansion chamber, cooling cylinder, and cooling water jacket. Thermodynamic properties such as pressure, volume, temperature, mass of gas and axial conduction heat transfer, shuttle heat transfer, pump heat transfer, and pressure heat transfer are calculated. Performance of Stirling heat pump including heat transfer rates, indicated power, and coefficient of performance are evaluated.
Thermodynamic theoretical parameters including filling pressure, rotational speed, geometry, and gas species are analyzed in order to determine the design direction of Stirling heat pump. By considering the heat friction loss and mechanical loss affects, theoretical model is compared with the experimental results in order to determine the accuracy and factor.

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