摘要
To study the economic advantages of hydrogen internal combustion engine, an experimen- tal study was carried out using a 2.0 L port fuel-injected (PFI) hydrogen internal combustion engine. Influences of fuel-air equivalence ratio φ, speed, and ignition advance angle on heat efficiency were determined. Test results showed that indicated thermal efficiency ( ITE ) firstly increased with fuel- air equivalence ratio, achieved the maximum value of 40. 4% ( φ = 0.3 ), and then decreased when was more than 0. 3. ITE increased as speed rises. Mechanical efficiency increased as fuel-air equiva- lence ratio increased, whereas mechanical efficiency decreased as speed increased, with maximum mechanical efficiency reaching 90%. Brake thermal efficiency (BTE) was influenced by ITE and me- chanical efficiency, at the maximum value of 35% (φ =0.5, 2 000 r/min). The optimal ignition ad- vance angle of each condition resulting in the maximum BTE was also studied. With increasing fuel- air equivalence ratio, the optimal ignition angle became closer to the top dead center ( TDC ). The test results and the conclusions exhibited a guiding role on hydrogen internal combustion engine opti- mization.
To study the economic advantages of hydrogen internal combustion engine, an experimen- tal study was carried out using a 2.0 L port fuel-injected (PFI) hydrogen internal combustion engine. Influences of fuel-air equivalence ratio φ, speed, and ignition advance angle on heat efficiency were determined. Test results showed that indicated thermal efficiency ( ITE ) firstly increased with fuel- air equivalence ratio, achieved the maximum value of 40. 4% ( φ = 0.3 ), and then decreased when was more than 0. 3. ITE increased as speed rises. Mechanical efficiency increased as fuel-air equiva- lence ratio increased, whereas mechanical efficiency decreased as speed increased, with maximum mechanical efficiency reaching 90%. Brake thermal efficiency (BTE) was influenced by ITE and me- chanical efficiency, at the maximum value of 35% (φ =0.5, 2 000 r/min). The optimal ignition ad- vance angle of each condition resulting in the maximum BTE was also studied. With increasing fuel- air equivalence ratio, the optimal ignition angle became closer to the top dead center ( TDC ). The test results and the conclusions exhibited a guiding role on hydrogen internal combustion engine opti- mization.
基金
Supported by the National Natural Science Foundation of China(51276019)
