摘要
为优化直喷天然气发动机的喷射策略,在一台六缸电控直喷天然气发动机上,用试验方法研究了引燃柴油量及柴油/天然气喷射间隔对发动机HC、CO和NO_x排放的影响。试验结果表明:喷射间隔一定时,HC排放随引燃柴油喷射量的增加而降低;在引燃柴油喷射量为4.0 mg时,HC排放随喷射间隔的增加而增加;引燃柴油喷射量在6.0~11.5 mg范围内,HC排放在喷射间隔从0.5 ms变化到1.1 ms时,变化较小;喷射间隔增加到1.4 ms时,HC排放升高趋势明显。CO排放随引燃柴油喷射量的变化规律为先降低后升高;在不同的柴油喷射量下增加喷射间隔,CO排放均降低。NO_x排放随引燃柴油喷射量的增加先降低后升高;在喷射间隔为0.5 ms时,NO_x排放相对较小,在喷射间隔为1.4 ms时,NO_x排放最高。增加引燃柴油喷射量有利于HC的减排,对CO排放的影响较小,但会导致NO_x排放的恶化;增加喷射间隔会促使HC和NO_x排放的升高,但CO排放有所降低。
Adjustment of injection strategy has been considered as an effective and reliable way for the emission control of directly injected natural gas engines. However, the system investigation on the effects of pilot diesel quantity and injection separation is scarce. In order to achieve better emission characteristics by optimizing the injection strategy of directly injected natural gas engine, experimental investigation was conducted on a 6-cylinder pilot-ignited natural gas engine to study the effects of diesel injection quantity(DIQ) and separation between diesel and natural gas injection(SDN). The test engine was modified from a diesel engine with bore diameter of 126 mm, stroke of 155 mm and compression ratio of 17. The design of cylinder head was redesigned to adapt to the installation of the dual fuel injector, which had two concentric needles and two electronically controlled solenoid valves. An integrated pressure regulating module was added to controlthe injection pressure of diesel and natural gas. The supply system of natural gas, including compressor and buffer tank, was also added to provide compressed pipeline natural gas. Besides, the control module of natural gas injection was integrated into the original electronic controlled unit to realize the accurate control of both diesel and natural gas injection. In the experiment process, the intake temperature was fixed at 22° CA and the intake air pressure was maintained at 101 k Pa while the diesel rail pressure was adjusted to 18 MPa. To prevent natural gas leaking into diesel, the rail pressure of natural gas was slightly lower than that of diesel(17.5 MPa). The tested operating condition was at engine speed of 1 275 r/min with brake specific effective pressure of 0.54 Mpa, which was a typical operating point of European steady state cycle. To evaluate the effects of diesel injection quantity(DIQ) and separation between diesel and natural gas injection(SDN), the injection timing of natural gas was kept constant at 8° BTDC while diesel injection quantity was varied from 4.0 to 11.5 mg under four different injection separations(0.5 ms, 0.8 ms, 1.1 ms and 1.4 ms). The natural gas pulse width was adjusted in accordance with the diesel injection quantity to maintain the fixed engine brake specific power. The emissions were measured by a Horiba MEXA 7 200 exhaust gas analyzer. CO emissions were tested by nondispersive infrared technology.HC emissions were tested by flame ionization detector. NO_x emissions were tested by chemiluminescent detector(CLD).The emissions of each operating point were collected after 5 minutes of steady operation and all the emissions were recorded three times to obtain the averaged values for further analysis. The experimental results showed that HC emissions decreased with the increase of diesel injection quantity at the same injection separation and increased with increasing injection separation at the diesel injection quantity of 4.0 mg; in the diesel injection quantity range of 6.0 ~11.5 mg. HC emissions changed slightly when the injection separation varied from 0.5 ms to 1.1ms, however, when injection separation extended to1.4 ms, the rising trend of HC emissions became more obvious. CO emissions exhibited a first decrease then increase trend with the increase of diesel injection quantity, and the minimum value occurred at the diesel injection quantity of 6.0 mg or8.5 mg; a decrease with the increase of injection separation at all diesel injection quantities can also be observed. NO_x emissions firstly declined and then rise with the increasing diesel injection quantity; additionally, at the injection separation of 0.5 ms, NO_x emissions were relatively lower while reached the peak value at the injection separation of 1.4 ms. It can be concluded that the increase of diesel injection quantity has beneficial effects on HC emissions and negative effects on NO_x emissions while exerts little influence on CO emissions; the extension of injection separation results in higher HC and NO_x emissions as well as reduced CO emissions.
出处
《农业工程学报》
EI
CAS
CSCD
北大核心
2016年第6期95-100,共6页
Transactions of the Chinese Society of Agricultural Engineering
基金
国家高技术船舶科研项目(2060303)
关键词
发动机
柴油机
燃油喷射
引燃柴油量
喷射间隔
天然气发动机
排放性
engines
diesel engines
fuel injection
diesel injection quantity
injection separation
natural gas engine
emission characteristics
