Citations (13)
Keep up to date with the latest research on this topic with citation updates for this article.
Read on this site (5)
Aldélio Bueno Caldeira. (2016) Ignition and combustion of a gaseous fuel pocket array in an oxidizing environment. Numerical Heat Transfer, Part A: Applications 70:9, pages 1009-1020.
Read now
Read now
Richard Mathie, ChristosN. Markides & AlexanderJ. White. (2014) A Framework for the Analysis of Thermal Losses in Reciprocating Compressors and Expanders. Heat Transfer Engineering 35:16-17, pages 1435-1449.
Read now
Read now
Tien-Mo Shih, Chandrasekhar Thamire, Chao-Ho Sung & An-Lu Ren. (2010) Literature Survey of Numerical Heat Transfer (2000–2009): Part I. Numerical Heat Transfer, Part A: Applications 57:3-4, pages 159-296.
Read now
Read now
Egel Urip, Ka
Heng Liew & S. L. Yang. (2007) Modeling IC Engine Conjugate Heat Transfer Using the KIVA Code. Numerical Heat Transfer, Part A: Applications 52:1, pages 1-23.
Read now
Read now
Giedrius Garbinčius, Vilius Bartulis, Robertas Pečeliūnas & Saugirdas Pukalskas. (2005) The influence of coolant scale deposit inside the internal combustion engine on the piston and cylinder deformations. Transport 20:3, pages 123-128.
Read now
Read now
Articles from other publishers (8)
Aly I. Taleb, Christoph Barfuß, Paul Sapin, Alex J. White, Drazen Fabris & Christos N. Markides. (2022) Simulation of thermally induced thermodynamic losses in reciprocating compressors and expanders: Influence of real-gas effects. Applied Thermal Engineering 217, pages 118738.
Crossref
Crossref
Victor Irizar & Casper Schousboe Andreasen. (2017) Hydraulic pitch control system for wind turbines: Advanced modeling and verification of an hydraulic accumulator. Simulation Modelling Practice and Theory 79, pages 1-22.
Crossref
Crossref
S. Tanov, J. Salvador-Iborra, Ö. Andersson, P. Olmeda & A. García. (2017) Influence of the number of injections on piston heat rejection under low temperature combustion conditions in an optical compression-ignition engine. Energy Conversion and Management 153, pages 335-345.
Crossref
Crossref
Hari Subramaniam Bhaskaran, Paul Ro, Joong-Kyoo Park & Kishore Ranganath Ramakrishnan. (2017) Analysis of a Novel Technique for Temperature Rise Abatement in Liquid Piston Compressors–External Gas Injection. Journal of Thermal Science and Engineering Applications 9:2.
Crossref
Crossref
Caroline Willich, Christos N. Markides & Alexander J. White. (2017) An investigation of heat transfer losses in reciprocating devices. Applied Thermal Engineering 111, pages 903-913.
Crossref
Crossref
Ibrahim A. Sultan & Azfar Kalim. (2011) Improving reciprocating compressor performance using a hybrid two‐level optimisation approach. Engineering Computations 28:5, pages 616-636.
Crossref
Crossref
J. F. Carneiro & F Gomes de Almeida. (2007) Heat transfer evaluation of industrial pneumatic cylinders. Proceedings of the Institution of Mechanical Engineers, Part I: Journal of Systems and Control Engineering 221:1, pages 119-128.
Crossref
Crossref
R.J. Goldstein, E.R.G. Eckert, W.E. Ibele, S.V. Patankar, T.W. Simon, T.H. Kuehn, P.J. Strykowski, K.K. Tamma, A. Bar-Cohen, J.V.R. Heberlein, J.H. Davidson, J. Bischof, F.A. Kulacki, U. Kortshagen & S. Garrick. (2002) Heat transfer – a review of 2000 literature. International Journal of Heat and Mass Transfer 45:14, pages 2853-2957.
Crossref
Crossref