Adair, R., Qvale, E., Pearson, J., Instantaneous heat transfer to the cylinder wall in reciprocating compressors. Proceedings of International Compressor Engineering Conference, 1972, 521–526.
Afjei, T., Suter, P., Favrat, D., Experimental analysis of an inverter-driven scroll compressor with liquid injection. Proceedings of the 1992 Compressor Engineering Conference at Purdue University, 1992.
Beard, J.E., Kinematic Analysis of Gerotor Type Pumps, Engines, and Compressors, 1985, Purdue University Ph.D. thesis.
Behnel, S., Bradshaw, R., Citro, C., Dalcin, L., Seljebotn, D., Smith, K., Cython: the best of both worlds. Comput. Sci. Eng. 13 (2011), 31–39, 10.1109/MCSE.2010.118.
Bell, I., Theoretical and Experimental Analysis of Liquid Flooded Compression in Scroll Compressors, 2011, Purdue University Ph.D. thesis. http://docs.lib.purdue.edu/herrick/2/.
Bell, I.H., Groll, E.A., Braun, J.E., Horton, W.T., A computationally efficient hybrid leakage model for positive displacement compressors and expanders. Int. J. Refrig., 2013, 10.1016/j.ijrefrig.2013.01.005.
Bell, I.H., Lemort, V., Groll, E.A., Braun, J.E., King, G.B., Horton, W.T., Liquid flooded compression and expansion in scroll machines – part II: experimental testing and model validation. Int. J. Refrig. 35 (2012), 1890–1900, 10.1016/j.ijrefrig.2012.07.008.
Bell, I.H., Wronski, J., Quoilin, S., Lemort, V., Pure and pseudo-pure fluid thermophysical property evaluation and the open-source thermophysical property library CoolProp. Ind. Eng. Chem. Res. 53 (2014), 2498–2508, 10.1021/ie4033999.
Bianchi, G., Cipollone, R., Friction power modeling and measurements in sliding vane rotary compressors. Appl. Therm. 84 (2015), 276–285.
Bianchi, G., Kennedy, S., Zaher, O., Tassou, S. A., Miller, J., & Jouhara, H. (2018). Numerical Modeling of a Two-Phase twin-screw Expander for Trilateral Flash Cycle applications. Int. J. Refrig. 88, 248–259.
Blevins, R.D., Formulas for Natural Frequency and Mode Shape. 1979, van Nostrand Reinhold Company.
Bradshaw, C., A Miniature-Scale Linear Compressor for Electronics Cooling, 2012, Purdue University Ph.D. thesis.
Bradshaw, C.R., Groll, E.A., A comprehensive model of a novel rotating spool compressor. Int. J. Refrig. 36 (2013), 1974–1981.
Bradshaw, C.R., Groll, E.A., Garimella, S.V., A comprehensive model of a miniature-scale linear compressor for electronics cooling. Int. J. Refrig. 34 (2011), 63–73, 10.1016/j.ijrefrig.2010.09.016.
Bradshaw, C.R., Kemp, G., Orosz, J., Groll, E.A., Development of a loss Pareto for a rotating spool compressor using high-speed pressure measurements and friction analysis. Appl. Therm. Eng. 99 (2016), 392–401.
Brent, R., An algorithm with guaranteed convergence for finding a zero of a function. Comput. J. 14 (1971), 422–425.
Cash, J., Karp, A.H., A variable order Runge–Kutta method for initial value problems with rapidly varying right-hand sides. ACM Trans. Math. Softw. 16 (1990), 201–222.
Chapman, S.J., Electric Machinery Fundamentals. 2005, McGraw Hill.
Chen, Y., Halm, N., Groll, E., Braun, J., Mathematical modeling of scroll compressor. Part I – compression process modeling. Int. J. Refrig. 25 (2002), 731–750.
Chen, Y., Halm, N., Groll, E., Braun, J., Mathematical modeling of scroll compressor. Part II – overall scroll compressor modeling. Int. J. Refrig. 25 (2002), 751–764.
Fransesconi, M., & Antonelli, M. (2017). A Numerical Model for the Prediction of the Fluid Dynamic and Mechanical Losses of a Wankel-type Expansion Device. Appl. Energy 205, 225–235.
Galindo, J., Dolz, V., Royo-Pascual, L., Haller, R., & Melis, J. (2016). Modeling and Experimental Validation of a Volumetric Expander Suitable for Waste Heat Recovery from and Automotive Internal Combustion Engine Using an Organic Rankine Cycle with Ethanol. Energies, 9, 1–18.
Gnielinski, V., Neue gleichungen für den wärme-und den stoffübergang in turbulent durchströmten rohren und kanälen. Forsch. Ing. 41 (1975), 8–16.
Hamrock, B.J., Schmid, S.R., Jacobson, B.O., Fundamentals of Fluid Film Lubrication. 2004, CRC Press.
Hu, J., Yang, L., Shao, L.L., Zhang, C.L., Generic network model of reciprocating compressor. Int. J. Refrig. 45 (2014), 107–119.
Ishii, N., Bird, K., Sano, K., Oono, M., Iwamura, S., Otokura, T., Refrigerant leakage flow evaluation for scroll compressors. Proceedings of the 1996 Compressor Conference at Purdue University, 1996.
Jovane, M., Modeling and Analysis of a Novel Rotary Compressor, 2007, Purdue University Ph.D. thesis.
Kakaç, S., Shah, R.K., Aung, W., Handbook of Single-phase Convective Heat Transfer. 1987, Wiley, New York.
Kim, H., Roh, C.G., Kim, J.K., Shin, J.M., Hwang, Y., & Lee, J. K. (2009). An Experimental and Numerical Study on Dynamic Characteristic of Linear Compressor in Refrigeration System. Int. J. Refrig. 32, 1536–1543.
Kim, J.H., Analysis of a Bowtie Compressor with Novel Capacity Modulation, 2005, Purdue University Ph.D. thesis.
Krishna, A., Analysis of a Rotatring Spool Expander for Organic Rankine Cycle Applications, 2015, Purdue University Ph.D. thesis.
Lemmon, E., Pseudo-pure fluid equations of state for the refrigerant blends R-410a, R-404a, R-507a, and R-407c. Int. J. Thermophys. 24 (2003), 991–1006.
Lemmon, E.W., Bell, I.H., Huber, M.L., McLinden, M.O., NIST Standard Reference Database 23: Reference Fluid Thermodynamic and Transport Properties-REFPROP. 2016, National Institute of Standards and Technology Version 9.1.1.
Lemort, V., Contribution to the Characterization of Scroll Machines in Compressor and Expander Modes, 2008, University of Liège Ph.D. thesis.
Lemort, V., Bell, I., Groll, E., Braun, J.E., Analysis of liquid-flooded expansion using a scroll expander. Proceedings of the 19th Compressor Engineering Conference at Purdue University, 2008.
Link, R., Deschamps, C.J., Numerical modeling of startup and shutdown transients in reciprocating compressors. Int. J. Refrig. 34 (2011), 1398–1414.
Liu, R., Zhou, Z., Heat transfer between gas and cylinder wall of refrigerating reciprocating compressor. Proceedings of the International Compressor Engineering Conference, 1984, 110–115.
Liu, Y., Hung, C., Chang, Y., Design optimization of scroll compressor applied for frictional losses evaluation. Int. J. Refrig. 33 (2010), 615–624, 10.1016/j.ijrefrig.2009.12.015.
Mathison, M.M., Braun, J.E., Groll, E.A., Modeling of a two-stage rotary compressor. HVAC&R Res. 14 (2008), 719–748.
Mathison, M.M., Braun, J.E., Groll, E.A., Modeling of a novel spool compressor with multiple vapor injection ports. Int. J. Refrig. 36 (2013), 1982–1997.
Nikolov, A., Brummer, A., Investigating a small oil-flooded twin-screw expander for waste-heat utilisation in organic rankine cycle systems. Energies 10 (2017), 1–27.
Okada, K., Kuyama, K., Motion of rolling piston in rotary compressor. Proceedings of International Compressor Engineering Conference at Purdue University, 1982.
Ooi, K., Wong, T., A computer simulation of a rotary compressor for household refrigerators. Appl. Therm. Eng. 17 (1997), 65–78.
Oudkerk, J.F., Contribution to the Characterization of Piston Expanders for their use in Small-Scale Power Production Systems, 2016, University of Liège Ph.D. thesis.
Pan, X., Wang, M., Xing, Z., & Shulin, P., (2018). Structural Study on a Swing Compressor with no Valves for Air Conditioning Systems. Int. J. Refrig. 88, 300–306.
Papes, I., Degroote, J., Vierendels, J., Development of a thermodynamic loworder model for a twin-screw expander with emphasis on pulsations in the inlet pipe. Appl. Therm. Eng. 103 (2016), 909–919.
Pérez, F., Granger, B.E., IPython: a system for interactive scientific computing. Comput. Sci. Eng. 9 (2007), 21–29, 10.1109/MCSE.2007.53.
Raimondi, A., Boyd, J., A solution for the finite journal bearing and its application to analysis and design: I. A S L E Trans. 1 (1958), 159–174, 10.1080/05698195808972328.
Raimondi, A., Boyd, J., A solution for the finite journal bearing and its application to analysis and design: II. A S L E Trans. 1 (1958), 175–193, 10.1080/05698195808972329.
Raimondi, A., Boyd, J., A solution for the finite journal bearing and its application to analysis and design: III. A S L E Trans. 1 (1958), 194–209, 10.1080/05698195808972330.
Sathe, A.A., Miniature-scale Diaphragm Compressor for Electronics Cooling, 2008, Purdue University Ph.D. thesis.
Schiffmann, J., Small-scale and oil-free turbocompressor for refrigeration applications. Proceedings of International Compressor Engineering Conference, 2014.
Shung, J. B., & Pennock, G. R. (1994). Geometry for Trochoidal-Type Machines with Conjugate Envelope. Mech. Mach. Theor. 29, 25–42.
Singh, P.J., A digital reciprocating compressor simulation program including suction and discharge piping. Proceedings of International Compressor Engineering Conference at Purdue, 1984.
Soedel, W., Design and Mechanics of Compressor Valves. 1984, Ray W. Herrick Laboratories, School of Mechanical Engineering, Purdue University.
Soedel, W., Sound and Vibrations of Positive Displacement Compressors. 2007, CRC Press Taylor & Francis Group.
Stosic, N., Smith, I.K., Kovacevic, A., Mujic, E., Review of mathematical models in performance calculation of screw compressors. Int. J. Fluid Mach. Syst. 4 (2011), 271–288.
Suefuji, K., Nakayama, S., Practical method for analysis and estimation of reciprocating hermetic compressor performance. Proceedings of International Compressor Engineering Conference at Purdue University, 1980.
Suefuji, K., Shiibayashi, M., Tojo, K., Performance analysis of hermetic scroll compressors. Proceedings of the 1992 International Compressor Engineering Conference at Purdue University, 1992.
Tan, K., Ooi, K., Heat transfer in compression chamber of a Revolving Vane (RV) compressor. Appl. Therm. Eng. 31 (2011), 1519–1526.
Tian, C., Dou, C., Yang, X., & Li, X. (2004). A Mathematical Model of Variable Displacement Wobble Plate Compressor for Automotive Air Conditioning System. Appl. Therm. Eng. 24, 2467–2486.
Tojo, K., Ikegawa, M., Maeda, N., Machida, S., Shiibayashi, M., Uchikawa, N., Computer modeling of scroll compressor with self adjusting back-pressure mechanism. Proceedings of the 1986 International Compressor Engineering Conference at Purdue University, 1986.
Wang, Z., Shen, Y., Wang, Z., Wang, J., Jiang, W., Li, Q., Theoretical research and optimization analysis for the injection process of the single screw refrigeration compressor. Int. J. Refrig. 88 (2018), 91–101.
Wronski, J., Design and Modelling of Small Scale Low Temperature Power Cycles, 2015, Technical University of Denmark Ph.D. thesis.
Wu, Y.R., Tran, V.T., Dynamic response prediction of a twin-screw compressor with gas-induced cyclic loads based on multi-body dynamics. Int. J. Refrig. 65 (2016), 111–128.
Yanagisawa, T., Shimizu, T., Friction losses in rolling piston type rotary compressors. III. Int. J. Refrig. 8 (1985), 159–165, 10.1016/0140-7007(85)90156-2.
Yang, B., Bradshaw, C.R., Groll, E.A., Modeling of a semi-hermetic CO2 reciprocating compressor including lubrication submodels for piston rings and bearings. Int. J. Refrig. 36 (2013), 1925–1936.
Yang, B., Kurtulus, O., Groll, E.A., Modeling of an oil-free carbon dioxide compressor using Sanderson-Rocker arm motion (S-RAM) mechanism. IOP Conf. Ser.: Mater. Sci. Eng., 2015 pp. 90.
Yang, X., Dong, C., Qu, Z., Design and dynamic analysis of a novel double-swing vane compressor for electric vehicle air conditioning systems. Int. J. Refrig. 76 (2017), 52–62.
Yap, K.S., Ooi, K.T., Chakraborty, A., Analysis of the novel cross vane expander-compressor: mathematical modelling and experimental study. Energy 145 (2018), 626–637.
Zaytsev, D., Development of Wet Compressor for Application in Compression-Resorption Heat Pumps, 2003, Technical University Delft Ph.D. thesis.
Zhang, Y., Wang, W., Effect of leakage and friction on the miniaturization of a Wankel compressor. Front. Energy 5 (2011), 83–92.
Zhao, L., Li, M., Ma, Y., Liu, Z., Zhang, Z., Simulation analysis of a two-rolling piston expander replacing a throttling valve in a refrigeration and heat pump system. Appl. Therm. Eng. 66 (2014), 383–394.
Ziviani, D., Theoretical and Experimental Characterization of Single-Screw Expanders for ORC Applications, 2017, Ghent University Ph.D. thesis.
Ziviani, D., Bell, I.H., Zhang, X., Lemort, V., De Paepe, M., Braun, J.E., Groll, E.A., PDSim: Demonstrating the capabilities of an open-source simulation framework for positive displacement compressors and expanders. Int. J. Refrig., 2019, 10.1016/j.ijrefrig.2019.10.015.
Ziviani, D., Groll, E., Modeling and analysis of an open-drive Z-compressor. IOP Conf. Ser.: Mater. Sci. Eng., 2017 pp. 232.