Abstract
To understand the effect of internal leakage on the torque field and characteristics of a torque converter (TC), a transient analysis was performed on the internal flow of a TC and the pressure pulsation characteristics of monitoring points in the convection channel. It was found that dividing the leakage area of the TC into a separate watershed improved simulation accuracy by 4%. When there was a leakage area, there were distinct collision, mixing, and assimilation stages between the leakage flow and the main flow. These phenomena caused energy loss that was highest at low speed ratios. However, the leakage flow always accounted for 12% of the main flow regardless of the speed ratio. At the same time, the leakage flow had a larger influence on pressure pulsation inside the TC and especially the low frequency band was more substantial. This shows that the leakage area has a large influence on the TC performance, energy loss, and flow state. Analysis of the leakage area showed that reducing the leakage area helps to improve powertrain performance and fuel economy.
Highlights
A torque converter (TC) is mainly composed of a pump, turbine, and stator
When the TC leakage area was divided into separate areas, the simulation accuracy was improved by 4%
According to the conservation of mass: /QSP/ = /QP-T/ + /QT-S/ and Qleak = /QS-P/, and regardless of how the main flow changed, the leakage flow always accounted for about 12% of the main flow
Summary
A torque converter (TC) is mainly composed of a pump, turbine, and stator. The working fluid is a hydraulic transmission oil. As the turbine speed increased, the dynamic and static interference between the turbine and the stator strengthened, which increased the impact of the leaked fluid on the main flow, resulting in a lowfrequency broadband at point A.
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