Compared with front engine vehicle, the windward side’s flow field in cooling model of rear engine bus is complicated and it can’t be calculated by means of 1D model. For this problem, this paper has used Star-CCM to build a 3D simulation model of cooling system, engine compartment and complete vehicle. Then, it had a 1D/3D coupling calculation on cooling system with Kuli software. It could be helpful in the optimization design of the flow field of rear engine compartment and optimization match of cooling system.
The engine cabin is a hemi-closure space and there are cooling system, engine and inlet and exhaust system, transmission, air conditioning, hydraulic equipment and other system in it. The layout structure is very compact. There are many components such as intake grid, condenser, intercooler, radiator, wind guide cover, fan and exhaust path on the cooling path of engine cabin. The study on the airflow in vehicle mainly includes the study on the flow resistance of engine cabin, heat dissipation and aerodynamics of the outside of vehicle. The “air-side” in the thermal management system is the airflow of the engine cabin and the study on the airflow is to research the air flow and heat transfer among the components including engine in the cabin. It aims to reduce the hot air recirculation, decrease the airflow resistance of engine cabin and provide enough air for cooling system and other components which need to be cooled [
The Moffat in Ford used the “union simulation” technique, with the Flowmaster and UH3D software, to study on the transient characteristics of the vehicle thermal management system. By comparison with the results of tests, the simulation precision of this method is checked. It could be over 95% [
Thus, more and more car companies and research institutions are using CAE technology to study the airflow and heat transfer of engine cabin or inside and outside of vehicle, with accurately and effectively using CAE technology. It can save a lot of time and costs.
One-dimensional and three-dimensional coupling calculation is to calculate the inside and outside flow field of vehicle with three-dimensional software at first. And then, it calculated the one-dimensional system performance with boundary conditions, which was obtained in three-dimensional calculation that made the results more refined more accurate than original single boundary conditions.
For rear engine buses, the cooling air enters the engine cabin from the side grille, with the cooling fan’s suction effect. The radiator surface has a more complex flow field, which the velocity distribution in it is very uneven. Using one-dimensional model to calculate makes the results have a large deviation. So we need to use the 1D/3D coupling simulation method to make the calculation results more accurate.
There are lots of complicated components in engine cabin of bus, not only includes the engine body, the parts cooling system, but also air-conditioning compressor, air cleaner, the gear pulley system and a variety of different materials, pipes, lines and so on. If all the components in the engine compartment need simulation calculation, not only the size of the actual geometry of the model will be not available, but also will increases the difficulty of meshing, and the computer hardware and software requirements will be very high. Thus only the geometries of large parts in the cabin are retained in the calculation, and the pipes and lines have been simplified.
The assembly of the various components was finished in CATIA, and final assembly model shown in
A closed computational domain was established to calculate the bus model shown in
Meanwhile, ensure the accuracy of computing, using the local mesh refinement approach, which solute the difficult of coarse mesh could not identify the smaller size barrier. The total number of the final mesh is about 5 million shown in
The pressure on bus body side and top surface was smaller and more evenly distributed. But the pressure on bus rounded edge was significantly reduced. That pointed out resistance was reduced at right angles to the bus edge.
In the cooling fan suction, the air through grille on the left is much more than grille on the right. It means that, even at high speed, the suction fan is still the main source of cooling air to rear engine bus.
One-dimensional vehicle thermal management simulation model was established based on the air side and the coolant side of real vehicle. The specific model was shown in
Because this study model is a rear engine compartment bus, its air side model could not simply be calculated according to the one-dimensional simulation of the front of the engine compartment vehicle. For the inhomogeneity of wind speed on the cooling module surface, the only calculation method was three-dimensional and one- dimensional co-simulation method.
The contours chart of wind speed distribution on the cooling module surface with Star-CCM at speed 90 km/h of the bus was shown in
Importing the wind speed distribution matrix shown in
The calculated and measured value of water temperature have a certain error, because the calculation model ignores some secondary factors like the effect of heat transfer of the surface of the cooling water pipes, but the results are in an acceptable error range. The error of the one-dimensional model in Kuli, radiator calculation program and experimental is small, and they all have the same trend, thus we can ensure the accuracy of the calculation model.
Because the flow field of the rear engine cabin of the passenger car is much more complicated than the front’s, the error is very lager if using the 1D model directly like we did in front engine cabin to simulate the cooling system. The Studies show that only the one-dimensional and three-dimensional coupling calculation method could make the results of the calculation of rear engine bus cooling system more accurate and it is much more suitable for engineering development and application.