Abstract
Clutch fill control in clutch-to-clutch transmissions influences shift quality considerably. An oncoming clutch should be applied synchronously with the release of an offgoing clutch to shift gear smoothly; therefore, the gap between the piston and clutch plates should be eliminated when the torque capacity is near zero at the end of the clutch fill phase. Open-loop control is typically implemented for the clutch fill because of the cost of pressure sensor. Low control precision causes underfill or overfill to occur, deteriorating shift quality. In this paper, a mathematical model of an electrohydraulic clutch shift control system is presented. Special dynamic characteristic parameters for optimal clutch fill control are subsequently proposed. An automatic method for predicting initial fill control parameters is proposed to eliminate distinct discrepancies among transmissions caused by manufacturing or assembling errors. To prevent underfill and overfill, a fuzzy adaptive control method is proposed, in which clutch fill control parameters are adjusted self-adaptively and continually. Road vehicle test results proved that applying the fuzzy adaptive method ensures the consistency of shift quality even after the transmission’s status is changed.
Highlights
Automatic transmissions are used to transfer the power of an engine smoothly and effectively to vehicle wheels at optimal transmission ratios according to performance requirements and economic demand
To optimize the engagement of clutches, clutch fill is usually formulated as an optimization problem
Openloop clutch pressure control was proposed as a solution by means of dynamic programming algorithm for cost reasons [6]
Summary
Automatic transmissions are used to transfer the power of an engine smoothly and effectively to vehicle wheels at optimal transmission ratios according to performance requirements and economic demand. Openloop clutch pressure control was proposed as a solution by means of dynamic programming algorithm for cost reasons [6] This control method requires precision tracking of the input pressure. Building an open-loop clutch pressure control model for clutch fill phase based on the dynamic pressure characteristics of electrohydraulic clutch control systems is necessary to satisfy the requirements of clutch fill time and maximal fluid flow. Lubrication (1) Flow control valve (2) Solenoid valve (3) Shift valve (4) Oil duct (5) Pressure-regulating valve (6) Pump (7) Filter (8) Tank (9) Solenoid valve (10) Control value (11) Disc spring (12) Piston (13) Clutch friction disc
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