Search Results

Reducing loss torque in automatic transmissions (ATs) is a key factor in improving fuel economy. A promising approach is to reduce the viscosity of the Automatic Transmission Fluid (ATF) so as to minimize churning loss. Aisin AW and JXTG Nippon Oil & Energy Corporation have developed a super low viscosity ATF, called “AW-2”, which has approximately 50% lower kinematic viscosity at 40 °C compared to the conventional ATF “AW-1”. It is generally understood that if the viscosity of an ATF is too low, it can have a negative impact on the fatigue life of components such as gears and bearings, and possibly lead to increased wear or seizure. AW-2 was designed to solve these problems via the application of two key technologies. The first is a high performance base oil with a low traction coefficient, which translates to low viscosity under high pressure conditions.

A precise control system for a molten ferrous alloy temperature above 1700 K after the completion of induction melting has been developed in order to produce high quality casting parts for automobiles. In this system, the molten ferrous alloy temperature is measured just one time by a disposable thermocouple after the melting. The system predicts the temperature transition after the measurement using an original thermal model, and adjusts the supplied electric power to the furnace automatically according to the predicted temperature. Using this thermal model, the system has attained control deviations within ±5K under the following temperature controls, and contributed to the quality control of casting parts and the energy-saving during furnace operations. Casting temperature for a cast-steel of 1813 K in a 300 kg capacity high-frequency induction furnace on the “Toyota Vacuum Casting Process”.

We have developed a simple and lower cost mixed air flow fan with guide vanes on the blade surfaces for use in automotive engine cooling. Through investigation of the fan performance and flow visualization, the axial and radial flow produced by this fan proved to be most suitable and efficient for engine cooling. The improved efficiency and increased air flow provided by this fan contribute to reduction of specific noise level and power consumption as compared to conventional fans. It is moreover possible to reduce the size and dimensions of the fan while maintaining its cooling performance. It is also useful for eliminating heat dwelling and high temperature problems from the exhaust pipe and carburetor in the engine room.