TY - JOUR Y1 - 2016/// SN - 01487191 PB - SAE International UR - https://www.scopus.com/inward/record.uri?eid=2-s2.0-85072355837&doi=10.4271%2f2016-01-0647&partnerID=40&md5=39eab8fbfbec3cfa2dafc525668f64c0 JF - SAE Technical Papers A1 - Osman, A. A1 - Muhammad Yusof, M.K.A. A1 - Rafi, M. AV - none N2 - Additional fuel consumption reduction during the NEDC test cycle and real life driving can be effectively achieved by quickly raising the temperatures of the powertrain's parts, oils and coolant closer to the optimal operating temperatures. In particular, the engine cooling system today must play a bigger role in the overall thermal management of the powertrain's fluids and metals during warm-up, idle and severe operating conditions. In responding to these additional requirements, the previously proposed cost effective split cooling system has been further evolved to expedite the powertrain's warming up process without compromising the overall heat rejection performance during severe operating conditions. In achieving these warming and cooling functions, the coolant flow rate in the cylinder head is almost stagnant when the single thermostat is closed and at its maximum when the thermostat is fully opened. In this context, the constantly flowing engine oil above the cylinder head's water jacket can be warmed up and cooled by these differing coolant flow rates and temperatures. Unlike other conventional split cooling circuits, the coolant flow rate in the cylinder block is constantly flowing thus allowing heat transfers to take place between the recirculated coolant to the cabin heater and CVT oil heat exchanger. In speeding up the warming up process involving the CVT oil, additional heat is obtained from the exhaust gas via the turbocharger housing with reversible coolant flow. During the vehicle testing and development, the test vehicles were subjected to various tests and the temperatures of various powertrain fluids and metals were measured at various locations and compared with the baseline. From the tests conducted, the proposed cooling system significantly enhanced the thermal management efficiency and effectiveness of the vehicles while reducing the cost and complexity of the overall cooling system. Copyright © 2016 SAE International. N1 - cited By 5; Conference of SAE 2016 World Congress and Exhibition ; Conference Date: 12 April 2016 Through 14 April 2016; Conference Code:121606 KW - Automobile cooling systems; Coolants; Cooling; Cost effectiveness; Fuel oils; Heat exchangers; Powertrains; Temperature control; Thermoelectric equipment; Thermostats; Variable speed transmissions; Waste heat KW - Coolant flow rates; Cooling function; Engine cooling systems; Exhaust heat recovery; Fuel consumption reduction; Management efficiency; Operating condition; Operating temperature KW - Cylinder heads TI - Vehicle Testing and Development Involving a Simplified Split Cooling with Integrated Exhaust Heat Recovery and Reuse ID - scholars7287 ER -