Multiphysics Analysis Used to Simulate Prototype of Military-Style Diesel Engine Cylinder Head

	Vishwas Bantanahal of Adiabatics, Inc. in Columbus, Indiana performed a multiphysics analysis of a cylinder head designed under an SBIR program contracted from TACOM.
	A solid model of the cylinder head was generated in Pro/ENGINEER.
	The ambient temperatures applied to the cylinder head ranged from 200ºF to 1,700ºF at the peak engine temperature. This illustration shows the areas to which temperatures and convection were applied as input for the heat transfer analysis.
	The ALGOR steady-state heat transfer analysis revealed high temperatures at the interface between the two exhaust ports.
	The ALGOR linear static stress analysis predicted thermal stresses well beyond the material’s yield point at the interface between the two exhaust ports, especially on the inner face (shown in the inset).

Diesel engines are being researched for use in military vehicles because of their competitive fuel economy and operating costs. Adiabatics, Inc. of Columbus, Indiana used multiphysics FEA software from Pittsburgh-based ALGOR, Inc. to study the thermal and structural behavior of a cylinder head for a diesel engine that would provide reduced heat rejection and increased power density while maintaining its superior fuel economy and lower operating cost. This work was part of an SBIR (Small Business Innovative Research) program contracted by Adiabatics, Inc. from TACOM (Tank-Automotive & Armaments Command) – a division of the U.S. Army.

Pushing for More Power

Diesel engines have better fuel economy and lower operating costs than the turbine engines typically used in tanks, which have a higher power density and higher fuel consumption. The proposed idea was to come up with a design modification of an existing diesel engine that would result in reduced heat rejection and increased power density (to approximately 1 HP/in³ of displacement).

In the prototype of the altered diesel engine, temperatures at certain portions of the stainless steel cylinder head were measured at 1,600ºF – almost twice the normal operating temperature of 800ºF – 900ºF. At these high temperatures, the cylinder head within the diesel engine was developing valve-insert and head-gasket combustion leaks, all due to local head distortion. Finite element analysis was necessary to evaluate the design and material used for the cylinder head and hence verify that the high temperatures were in fact causing the leaks.

Multiphysics Analysis of the Cylinder Head

Adiabatics, Inc. engineer Vishwas Bantanahal began with a Pro/ENGINEER solid model consisting of the cylinder head and six washers. He used ALGOR’s InCAD technology to capture the geometry and create a three-dimensional (3-D) finite element mesh. “ALGOR’s InCAD technology enabled me to easily and directly capture a CAD assembly and create a solid mesh of the assembly,” he said. “This direct CAD/CAE data exchange is much easier than other methods, such as using an intermediate universal file format.”

“Small holes and cuts were suppressed to prevent stress concentrations and to obtain a better understanding of the overall stress distribution in the model,” he said. “I also refined the mesh around the holes and fillets in the final model. Even though this was one of my initial projects with ALGOR software and taking into account that I already had considerable experience with other FEA software, I was impressed with how easy to use and effective ALGOR’s meshing and mesh refinement tools were.”

The model was set up for a steady-state heat transfer analysis. Stainless steel AISI 410 was the material used for the prototype cylinder head and steel was used for the washers. The washers were only modeled to obtain a uniform circular cross-sectional area for the application of the loads caused due to the tightening of the bolts.

The temperatures on the different surfaces of the cylinder head were determined using data obtained through previous cycle simulation tests for an intake air temperature of 600ºF. These temperatures along with the related convection coefficients were applied as input for the heat transfer analysis.

As expected, the heat transfer analysis revealed high temperatures on the walls of the exhaust port, ranging from 750ºF to almost 1,500ºF with the interface (bridge-like) region between the two exhaust valves reaching the highest temperatures.

The temperatures obtained from the steady-state heat transfer analysis were then applied to a linear static stress analysis where only thermal stresses were considered. “Through preliminary analyses, I discovered that other effects such as the mechanical loads caused by the tightening of the bolts on the cylinder head did not contribute much towards the stresses when compared to the high temperatures,” said Vishwas Bantanahal.

The highest stresses were found at the interface between the two exhaust ports where temperatures were also the highest. “The stresses across other regions of the cylinder head fell well below the yield point of the material,” points out Vishwas Bantanahal. “However, near the exhaust port region, stresses ranged from 85 KSI to over 200 KSI, which is well above the yield point of the material at the temperatures predicted by the heat transfer analysis. So, some local yielding could be expected.”

The linear static stress analysis confirmed the behavior that engineers saw in the initial prototype tests. “The highest thermal stresses coincided with the part of the cylinder head that had been leaking in the preliminary prototypes,” said Vishwas Bantanahal. “It was clear from these analyses that either the cylinder head or the operating parameters would need to be changed to ensure that the final design performs adequately.”

Although the linear static stress analysis predicted failure, Vishwas Bantanahal did not choose to do a nonlinear analysis. “Ideally, this part should stay well within the linear range. Once it has yielded, you would not want it to still be operating inside the engine,” he said.

The strength for most metals, such as stainless steel, drops considerably at temperatures greater than 1,400ºF. The most obvious way to increase the durability of the cylinder head is to choose a different material that has appreciable strength at very high temperatures (around 100-150 KSI at 1,600ºF – 1,800ºF). Another option would be to use a specialized thermal barrier coating (TBC), which is one of Adiabatics, Inc.’s specialties, to protect the head from wear and tear due to the thermal stresses. Research is currently in progress to make the cylinder head more durable while maintaining the operating parameters that reduce heat rejection and increase the diesel engine’s power density.