Diesel engine efficiency increase is impossible without studying heat transfer in the combustion chamber. The heat transfer determines the fuel efficiency and engine eco friendliness. At present, pressure sensors are the only means for the engine working process monitoring and control. An indicator diagram, though, does not characterize the heat transfer process in combustion chamber by the simple and intelligible way. The article suggests employing heterogeneous gradient heat flux sensors for non-stationary heat flux registration on firedeck of a swirl-chamber diesel engine. The sensors operation principle is based on transversal Seebeck effect. Heterogeneous gradient heat flux sensors allow perform direct measuring of the thermal flux density. The sensors are midget, possess good heat stability, and their time constant allows registering heat flux changes per cycle without distortion. A probe and three different zones of the firedeck are instrumented with gradient heat flux sensors. The article studied the effect of the fuel injection timing advance angle on the heat flux on the firedeck. Spatial variation of peak value of heat flux was observed. The observed spatial variation is mainly driven by imbalance of fuel-air mixture in combustion chamber. However, the heat flux density reaches its maximum simultaneously in all points under study. Maximum of the heat flux density at the injection timing angle deviation from the optimal value shifts from the upper dead point in the “delay” direction, the indicator diagram maximum herewith do not possess this property.
The suggested technique allows control the engine by the position of maximum heat flux density.
F. van der Graaf. Heat Flux Sensors / chapter 8 of Volume 4: “Thermal Sensors” of the multivolume work “Sensors, a Сomprehensive Series”, Göpel. – Ed., 1990.
Gerachhenko O.А. Osnovy teplometrii [Basics of heat flux measurement]. Kiev: Nauko vadumka, 1971. 92 p.In Russ
Kavtaradze R.Z. Lokal’nyj teploobmen v porshnevyh dvigatelyah: Ucheb. posobie dlya vuzov [Local heat transfer in piston engines: Tutorial for high schools]. Moscow: Publishing house MSTU N.E. Bauman, 2001. 592 p.In Russ.
Salvatore P. Heat flux measurement device: Designing an experimental system for determining the effectiveness of thermal barrier coating inside a combustion chamber. Master thesis. 2015. http://www.diva-portal.org/smash/record.jsf?pid=diva2%3A913691&dswid=-1777
Ivaschenko N.A., Neuburg L.R., Kavtaradze R.Z., Aliev I.N. Reshenie obratnyh vneshnih nestacionarnyh zadach teploprovodnosti na poverhnostyah kamery sgoraniya DVS [Solving inverse time-dependent external heat conduction problems for combustion chamber surfaces of internal combustion engine]. Vestnik MGTU im N.E. Baumana. Seriya “Mashinostroenie” – Bulletin of Bauman Moscow State Technical University. Series “Mechanical Engineering”, 2016, no.1 (106). DOI: 10.18698/0236-3941-2016-1-68-79. In Russ.
Mityakov A., Mityakov V., Sapozhnikov S., Gusakov A., Bashkatov A., Seroshtanov V., Babich A. Hydrodynamics and heat transfer of yawed circular cylinder. International Journal of Heat and Mass Transfer, 2017, vol. 115, pp. 333–339. https://doi.org/10.1016/j.ijheatmasstransfer.2017.07.055.
Mityakov V.Y., Sapozhnikov S.Z., Zainullina E.R., Babich A.Y., Milto O.A., Kalmykov K.S. Gradient heat flux measurement while researching of saturated water steam condensation. Journal of Physics: Conference Series, 2017, vol. 891(1), 012128. https://doi.org/10.1088/1742-6596/891/1/012128.
Mityakov V.Y., Grekov M.A., Gusakov A.A., Sapozhnikov S.Z., Seroshtanov V.V., Bashkatov A.V., Kalmykov K.S. Comprehensive study of flow and heat transfer at the surface of circular cooling fin. Journal of Physics: Conference Series, 2017, vol. 891(1), 012095. https://doi.org/10.1088/1742-6596/891/1/012095.
Sapozhnikov S.Z., Mityakov YU.V., Mityakov A.V. Osnovy gradientnoj teplometrii [Basics of gradient heat flux measurement]. St. Petersburg: Publishing house of Peter the Great St.Petersburg Polytechnic University, 2012. 203 p. In Russ.
Broekaert S., Demuynck J., De Cuyper T., De Paepe M., Verhelst S. Heat transfer in premixed spark ignition engines. Part I: Identification of the factors influencing heat transfer. Energy, 2016, vol. 116, pp. 380–391.
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