607 Effect of Injection Pressure on Droplets Dispersion near Diesel Injector Nozzle

2015 ◽  
Vol 2015.68 (0) ◽  
pp. 223-224
Author(s):  
Sho MATSUDA ◽  
Noritsune KAWAHARADA ◽  
Daisaku SAKAGUCHI ◽  
Hironobu UEKI ◽  
Masahiro ISHIDA
Keyword(s):  
Injection Pressure ◽  
Injector Nozzle

scholarly journals Analysis of Fuel Injection Pressure Effect on Diesel Engine Combustion Opacity Value

2020 ◽  
Vol 1 (1) ◽  
pp. 1-5
Author(s):  
Andi Firdaus Sudarma ◽  
Hadi Pranoto ◽  
Mardani A. Sera ◽  
Amiruddin Aziz
Keyword(s):  
Fuel Injection ◽  
Engine Performance ◽  
Injection Pressure ◽  
Fuel Spray ◽  
Idle Speed ◽  
Injector Nozzle ◽  
Engine Combustion ◽  
Nozzle Pressure ◽  
Smoke Opacity ◽  
Fuel Injection Pressure

The use of diesel engines for vehicle applications has expanded for decades. However, it produces black smoke in the form of particulate matter contains fine and invisible particles during operation. The popular method for measuring the smoke opacity is by using a smoke meter for its simplicity and less costly. Fuel injection pressure is one of the parameters that affect the emission significantly, and the proper nozzle adjustment can reduce the density of exhaust gases and improve the engine performance. The purpose of this study is to determine the optimum fuel spray pressure that produces the lowest opacity value and analyse the effect of fuel spray pressure on the opacity value at a different engine speed. The present experiment uses the Hyundai D4BB engine, and the pressure variations were implemented on the injector nozzle at 125, 130, and 135 kg/cm2. The engine was also tested with various engine idle speed, i.e., 1000, 1500, 2000, and 2500 rpm. It has been found that the optimum distance of fuel spraying is 147.679 mm with injector nozzle pressure 130 kg/cm2, and the value of opacity is 9.51%.

scholarly journals Study on the Common Rail Type Injector Nozzle Design Based on the Nozzle Flow Model

2020 ◽  
Vol 10 (2) ◽  
pp. 549
Author(s):  
Sang-Wook Han ◽  
Yun-Sub Shin ◽  
Hyun-Chul Kim ◽  
Gee-Soo Lee
Keyword(s):  
Flow Model ◽  
Injection Pressure ◽  
Common Rail ◽  
Injection System ◽  
Nozzle Flow ◽  
Flow Area ◽  
Common Rail Injection System ◽  
Injection Duration ◽  
Injector Nozzle ◽  
Cavitation Region

In this paper, a nozzle flow model was used to design an injector nozzle and obtain initial spray conditions for the dimethyl ether (DME) common rail-injection system. In order to deliver the same amount of energy as that provided by diesel at a low injection pressure of 50 MPa, the injector for DME needs nozzle holes with larger diameters and a higher SAC volume for the same injection duration. In addition, the needle lift and needle seat diameter should be increased to maintain a minimum flow area ratio. Although the vapour pressure and maximum injection pressure of DME are lower than those of diesel, the nozzle in a DME system showed higher discharge coefficients and effective nozzle exit diameters for the same injection duration owing to low kinematic viscosity. However, because the maximum injection pressure in DME is lower than that with diesel, and the length of the cavitation region is narrower.

scholarly journals Sensitivity Analysis of Fuel Injection Characteristics of GDI Injector to Injector Nozzle Diameter

Energies ◽  
2019 ◽  
Vol 12 (3) ◽  
pp. 434 ◽  
Author(s):  
Xinhai Li ◽  
Yong Cheng ◽  
Shaobo Ji ◽  
Xue Yang ◽  
Lu Wang
Keyword(s):  
Cfd Simulation ◽  
Fuel Injection ◽  
Injection Pressure ◽  
Nozzle Diameter ◽  
Gasoline Direct Injection ◽  
Small Range ◽  
Fuel Mass ◽  
Single Hole ◽  
Injector Nozzle ◽  
The Difference

The accuracy of a nozzle diameter directly affects the difference of the injection characteristics between the holes and productions of a GDI (gasoline direct injection) injector. In order to reduce the difference and guarantee uniform injection characteristics, this paper carried out a CFD simulation of the effect of nozzle diameter which fluctuated in a small range on single-cycle fuel mass. The sensitivity of the fuel injection quantity to the injector nozzle diameter was obtained. The results showed that the liquid phase ratio at the nozzle outlet decreased and the velocity of the outlet increased with the increase of the nozzle diameter. When fluctuating in a small range of nozzle diameters, the sensitivity of the single-hole fuel mass to the nozzle diameter remained constant. The increase of the injection pressure lead to the increase of the sensitivity coefficient of the single-hole fuel mass to the nozzle diameter. The development of cavitation in the nozzle and the deviation of the fuel jet from the axis were aggravated with the increase of the injection pressure. However, the fluctuation in a small range of nozzles had little effect on the near-nozzle flow.

Effects of Injector Nozzle Inclusion Angle on Extending the Lower Load Limit of Gasoline Compression Ignition Using 87 AKI Gasoline

2014 ◽  
Author(s):  
Christopher P. Kolodziej ◽  
Stephen A. Ciatti
Keyword(s):  
Injection Pressure ◽  
Premixed Combustion ◽  
Injection Timing ◽  
Compression Ignition ◽  
Effective Pressure ◽  
Advantages And Disadvantages ◽  
Injector Nozzle ◽  
Brake Mean Effective Pressure ◽  
Low Load ◽  
Ignition Propensity

Gasoline Compression Ignition (GCI) is a promising single-fuel advanced combustion concept for increased efficiency and reduced emissions in comparison with current conventional combustion modes. Gasoline fuels are advantageous in premixed combustion concepts because of their increased volatility and reduced reactivity compared to diesel. These qualities help reduce emissions of particulate matter (PM) and oxides of nitrogen (NOx), while making combustion phasing (and therefore combustion noise reduction) easier to manage. One of the challenges of using a gasoline with an anti-knock index (AKI) of 87 in a premixed combustion concept is being able to achieve stable low load operation. (Note that AKI is equivalent to (RON + MON)/2.) With such small injection quantities of a relatively more volatile and less reactive fuel than diesel, the injection timing of minimum load fueling needs to be early enough to allow the auto-ignition chemistry enough time, but late enough to keep the fuel from over-mixing and losing ignition propensity. The objective of this study was to investigate the advantages and disadvantages of reducing the injector nozzles’ inclusion angle from 148° to 120° on the combustion and emissions performance of GCI at 850 RPM and low load. To assess these effects, minimum fueling injection timing sweeps were performed with a 3% coefficient of variance of indicated mean effective pressure with each injector nozzle angle at 500 and 250 bar injection pressure. The results from these experiments revealed that both reduced injector nozzle angle and reduced injection pressure increased ignition propensity and allowed for reduced fueling and stable low load extension to 1 bar brake mean effective pressure using 87 AKI gasoline without any external boosting or heating. Combustion characteristics (such as noise) and emissions are discussed.

scholarly journals Effects of injection parameters, boost, and swirl ratio on gasoline compression ignition operation at idle and low-load conditions

2016 ◽  
Vol 18 (8) ◽  
pp. 824-836 ◽  
Author(s):  
Janardhan Kodavasal ◽  
Christopher P Kolodziej ◽  
Stephen A Ciatti ◽  
Sibendu Som
Keyword(s):  
Load Condition ◽  
Injection Pressure ◽  
Operating Conditions ◽  
Compression Ignition ◽  
Swirl Ratio ◽  
Injector Nozzle ◽  
Low Load ◽  
Dynamics Simulations ◽  
Compression Ignition Combustion ◽  
Injection Pressures

In this work, we study the effects of injector nozzle inclusion angle, injection pressure, boost, and swirl ratio on gasoline compression ignition combustion. Closed-cycle computational fluid dynamics simulations using a 1/7th sector mesh representing a single cylinder of a four-cylinder 1.9 L diesel engine, operated in gasoline compression ignition mode with 87 anti-knock index (AKI) gasoline, were performed. Two different operating conditions were studied—the first is representative of idle operation (4 mg fuel/cylinder/cycle, 850 r/min), and the second is representative of a low-load condition (10 mg fuel/cylinder/cycle, 1500 r/min). The mixture preparation and reaction space from the simulations were analyzed to gain insights into the effects of injection pressure, nozzle inclusion angle, boost, and swirl ratio on achieving stable low-load to idle gasoline compression ignition operation. It was found that narrower nozzle inclusion angles allow for more reactivity or propensity to ignition (determined qualitatively by computing constant volume ignition delays) and are suitable over a wider range of injection timings. Under idle conditions, it was found that lower injection pressures helped to reduce overmixing of the fuel, resulting in greater reactivity and ignitability (ease with which ignition can be achieved) of the gasoline. However, under the low-load condition, lower injection pressures did not increase ignitability, and it is hypothesized that this is because of reduced chemical residence time resulting from longer injection durations. Reduced swirl was found to maintain higher in-cylinder temperatures through compression, resulting in better ignitability. It was found that boosting the charge also helped to increase reactivity and advanced ignition timing.

Effect of Diesel Nozzle Geometry on Internal Cavitating Flow

2010 ◽  
Vol 97-101 ◽  
pp. 2925-2928 ◽  
Author(s):  
Zhi Xia He ◽  
Qing Mu Mu ◽  
Qian Wang ◽  
Jian Ping Yuan
Keyword(s):  
Flow Model ◽  
Injection Pressure ◽  
Cavitating Flow ◽  
Nozzle Geometry ◽  
Curvature Radius ◽  
Turning Angle ◽  
Injector Nozzle ◽  
Diesel Nozzle ◽  
Multi Phase ◽  
Better Than

The presence of cavitation and turbulence in a diesel injector nozzle has significant effect on the subsequent spray characteristics. However, the mechanism of the cavitating flow and its effect on the subsequent spray is unclear. The initiation, development and collapse of the cavity are strongly influenced not only by the injection pressure and back pressure but also by the nozzle geometry. The numerical simulation of cavitating flow in nozzle holes of a vertical multi-hole injector with mixture multi-phase cavitating flow model was carried out. The effects of sac geometry, hole entrance curvature radius and hole inclination angle on the cavitating flow in nozzle holes were investigated. It is finally concluded that the performance of IMPROVED nozzle is better than that of STD nozzle and VCO nozzle and small inlet turning angle of the orifice can enhance the atomization of the spray.

Numerical and Experimental Investigations of Cavitating Flow in a Vertical Multi-Hole Injector Nozzle

2010 ◽  
Author(s):  
Zhixia He ◽  
Jing Bai ◽  
Qian Wang ◽  
Qingmu Mu ◽  
Yunlong Huang
Keyword(s):  
Numerical Simulation ◽  
Numerical Models ◽  
Three Dimensional ◽  
Injection Pressure ◽  
Cavitating Flow ◽  
Critical Conditions ◽  
Experimental Investigations ◽  
Nozzle Flow ◽  
Cavitation Inception ◽  
Injector Nozzle

The presence of cavitation and turbulence in a diesel injector nozzle has significant effect on the subsequent spray characteristics. However, the mechanism of the cavitating flow and its effect on the subsequent spray is unclear because of the complexities of the nozzle flow, such as the cavitation phenomena and turbulence. A flow visualization experiment system with a transparent scaled-up vertical multi-hole injector nozzle tip was setup for getting the experimental data to make a comparison to validate the calculated results from the three dimensional numerical simulation of cavitating flow in the nozzle with mixture multi-phase cavitating flow model and good qualitative agreement was seen between the two sets of data. The critical conditions for cavitation inception were derived as well as the relationship between the discharge coefficient and non-dimensional cavitation parameter. After wards, the testified numerical models were used to analyze the effects of injection pressure, back pressure, cavitation parameter, Reynolds number, injector needle lift and needle eccentricity on the cavitating flow inside the nozzle. Combined with visual experimental results, numerical simulation results can clearly reveal the three-dimensional nature of the nozzle flow and the location and shape of the cavitation induced vapor distribution, which can help understand the nozzle flow better and eventually put forward the optimization ideas of diesel injectors.

An Experimental Investigation of Cavitating Flow in Diesel Injector Nozzle under Different Back Pressures

2014 ◽  
Vol 960-961 ◽  
pp. 1446-1449
Author(s):  
Xi Cheng Tao ◽  
Zhi Xia He ◽  
Peng Zhao ◽  
Wen Jun Zhong ◽  
Gen Miao Guo
Keyword(s):  
Pressure Difference ◽  
Injection Pressure ◽  
Internal Flow ◽  
Experimental System ◽  
Cavitating Flow ◽  
Back Pressure ◽  
Mean Velocity ◽  
Cavitation Inception ◽  
Flow Losses ◽  
Injector Nozzle

A study was carried out on the influence of different back pressures on internal flow of diesel injector nozzles. For this study, a flow visualization experimental system equipped with a pressurized chamber was setup. Experimental results show that, with the injection pressure remain constant and increase back pressure leading to the cavitation area diminished gradually and even disappeared. With a same pressure difference, higher back pressure test condition promoted the outlet mean velocity and inhibited the occurrence of cavitation inception, which demanded a larger pressure difference to make it happen. Moreover, it also resulted in a relatively large flow losses to the single phase flow compared to the cavitating flow.

Sign in / Sign up

Export Citation Format

Share Document