@misc{8023,
  abstract     = {{The effect of jet Reynolds number, jet exit angle, the nozzle to surface distance, jet to jet spacing on the heat transfer, and pressure force performance from multiple impinging round jets on a moving curved surface have been numerically evaluated. Two correlations are developed and validated for the average Nu number and the pressure force coefficient and the agreement between the CFD and correlations was reasonable. The surface motion effect becomes more pronounced on the Nu number distribution for low jet Re number, high jet to jet spacing, large jet to surface distance, and angled jets. The pressure force coefficient is highly dependent on the jet to surface distance and jet angle but relatively insensitive to jet Re number and jet to jet spacing. }},
  author       = {{Chitsazan, Ali and Klepp, Georg Heinrich and Glasmacher, Birgit}},
  booktitle    = {{Frontiers in heat and mass transfer : FHMT ; an international journal }},
  issn         = {{2151-8629}},
  keywords     = {{Angled jets, Heat transfer, Pressure force, Surface motion, Curvature, Correlation}},
  number       = {{1}},
  publisher    = {{Global Digital Centra}},
  title        = {{{CORRELATION DEVELOPMENT FOR JET IMPINGEMENT HEAT TRANSFER AND FORCE ON A MOVING CURVED SURFACE}}},
  doi          = {{10.5098/hmt.18.16}},
  volume       = {{18}},
  year         = {{2022}},
}

@misc{8024,
  abstract     = {{For the optimization of the impinging round jet, the pressure force coefficient and drying energy consumption on the moving curved surface are set as the objective functions to be minimized simultaneously. SHERPA search algorithm is used to search for the optimal point from multiple objective tradeoff study (Pareto Front) method. It is found that the pressure force coefficient on the impingement surface is highly dependent on the jet to surface distance and jet angle, while the drying energy consumption is highly dependent on the jet to jet spacing. Generally, the best design study during the multi-objective optimization is found at the maximum jet to surface distance, jet to jet spacing and surface velocity, and also minimum inlet velocity and jet angle. }},
  author       = {{Chitsazan, Ali and Klepp, Georg Heinrich and Chitsazan, Mohammad Esmaeil and Glasmacher, Birgit}},
  booktitle    = {{Frontiers in heat and mass transfer : FHMT ; an international journal }},
  issn         = {{2151-8629}},
  keywords     = {{Multiple jets, Heat transfer, Pressure force, Energy consumption, Optimization}},
  publisher    = {{Global Digital Centra}},
  title        = {{{MULTI-OBJECTIVE OPTIMIZATION OF DRYING ENERGY CONSUMPTION AND JET IMPINGEMENT FORCE ON A MOVING CURVED SURFACE}}},
  doi          = {{10.5098/hmt.18.17}},
  volume       = {{18}},
  year         = {{2022}},
}

@misc{8026,
  abstract     = {{The effect of jet arrangement, jet Re number, jet exit angle (θ), the nozzle-to-surface distance (H/d), jet-to-jet spacing (S/d) on the heat transfer, and pressure force performance from multiple impinging round jets on a moving flat surface have been numerically evaluated. There is a minor difference between in-line and staggered arrangements on a moving flat surface. The averaged Nusselt number on a moving flat surface reduces with an increase in the relative velocity (VR). The surface motion effects become more pronounced on the local Nu distribution at low Re, small S/d, large H/d, and angled jets for a moving flat surface. The pressure force coefficient on a moving flat surface is highly dependent on the H/d and θ but relatively insensitive to the VR, Re, and S/d within the range examined. Two correlations are developed and validated for the average Nu and force coefficient and the agreement between the CFD and correlation is found to be reasonable.}},
  author       = {{Chitsazan, Ali and Klepp, Georg Heinrich and Glasmacher, Birgit}},
  booktitle    = {{International Journal of Heat and Technology}},
  issn         = {{0392-8764}},
  keywords     = {{multiple jet, heat transfer, pressure force, surface motion, angled jet, jet arrangement}},
  number       = {{1}},
  pages        = {{137--144}},
  publisher    = {{Pitagora}},
  title        = {{{Effect of Surface Motion on Heat Transfer and Pressure Force from Multiple Impinging Jets– A Numerical Study}}},
  doi          = {{10.18280/ijht.400116}},
  volume       = {{40}},
  year         = {{2022}},
}

@inproceedings{6317,
  abstract     = {{The electrical-thermal behavior of an electrical connector is determined by heat generation due to Joule heating and heat absorption by conduction, convection and radiation. Heat flow from the connector to the wire is an important heat absorption mechanism for most electrical connectors. The temperature difference between the connector and the wire at infinity is proportional to the axial heat flow induced into the wire. The purpose of this study is to dimension the electrical resistance of a connector for power distribution by the heat flow into the wire. The heat flow is used as a design factor in order to define the maximum power loss for wires with different cross-section areas. With this approach the maximum acceptable electrical resistance for connectors with different sizes can be estimated in the early stages of the design process.}},
  author       = {{Blauth, Michael and Berger, Frank and Song, Jian}},
  booktitle    = {{60th IEEE Holm Conference on Electrical Contacts}},
  isbn         = {{978-1-4799-6069-9 }},
  keywords     = {{Wires, Connectors, Temperature measurement, Resistance, Heat transfer, Resistance heating}},
  location     = {{New Orleans, LA, USA }},
  pages        = {{192 -- 199}},
  publisher    = {{IEEE}},
  title        = {{{Influence of the Electrical Resistance and Wire Size on the Current Carrying Capacity of Connectors}}},
  doi          = {{10.1109/HOLM.2014.7031043}},
  year         = {{2014}},
}