The effect of nozzle geometry over internal flow and spray formation for three different fuels

Payri, Raúl; Viera, Juan P.; Gopalakrishnan, Vishrawas; Szymkowicz, Patrick G.

doi:10.1016/j.fuel.2016.06.041

Cited by 70 publications

(84 citation statements)

References 64 publications

(118 reference statements)

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…Research has also focused on elucidating the relationship between nozzle shape and cavitation, whose presence can significantly perturb fuel spray characteristics such as the discharge coefficient, outlet velocity, spray angle, and atomization behavior [3]. A converging diameter profile and a sufficiently rounded hole inlet corner were found to decrease or eliminate geometric cavitation in comparison to a sharp-cornered, cylindrical geometry [4,5]. In addition, local asymmetries at the hole inlet have been shown to generate correspondingly asymmetric cavitation, forming at the location where the fuel flow experiences the largest change in direction [5].…”

mentioning

confidence: 99%

A study on the relationship between internal nozzle geometry and injected mass distribution of eight ECN Spray G nozzles.

Matusik¹,

Duke²,

Sovis³

et al. 2017

Proceedings ILASS–Europe 2017. 28th Conference on Liquid Atomization and Spray Systems

Self Cite

View full text Add to dashboard Cite

Gasoline direct injection (GDI) nozzles are manufactured to meet geometric specifications with length scales on the order of a few hundred microns. The machining tolerances of these nominal dimensions are not always known due to the difficulty in accurately measuring such small length scales in a nonintrusive fashion. To gain insight into the variability of the machined dimensions as well as any effects that this variability may have on the fuel spray behavior, a series of measurements of the internal geometry and fuel mass distribution were performed on a set of eight nominally duplicate GDI "Spray G" nozzles provided by the Engine Combustion Network. The key dimensions of each of the eight nozzle holes were measured with micron resolution using full spectrum x-ray tomographic imaging at the 7-BM beamline of the Advanced Photon Source at Argonne National Laboratory. Fuel density distributions at 2 mm downstream of the nozzle tips were obtained by performing x-ray radiography measurements for many lines of sight. The density measurements reveal nozzle-to-nozzle as well as hole-to-hole density variations. The combination of high-resolution geometry and fuel distribution datasets allows spray phenomena to be linked to specific geometric characteristics of the nozzle, such as variability in the hole lengths and counterbore diameters, and the hole inlet corner radii. This analysis provides important insight into which geometrical characteristics of the nozzles may have the greatest importance in the development of the injected sprays, and to what degree these geometric variations might account for the total spray variability. The goal of this work is then to further the understanding of the relationship between internal nozzle geometry and fuel injection, provide input to improve computational models, and ultimately aid in optimizing injector design for higher fuel efficiency and lower emissions engines. KeywordsGDI, nozzle geometry, fuel spray density, fuel injector, DISI, Spray G, ECN, gasoline IntroductionTo fully realize the benefits of a gasoline direct injection (GDI) engine, precise control over the amount of injected fuel and the fuel-to-air mixing ratio is necessary. Any variations to the fuel spray distribution can affect the combustion process, and by extension the fuel efficiency and emissions levels. Modern multi-hole GDI nozzles generally feature a relatively complex step-hole geometry in which each hole might require knowledge of at least nine dimensions to accurately model. Due to the importance of the injection process on the output metrics of a GDI engine, a subset of internal combustion engine research has been dedicated to investigating the effects of nozzle geometry on the corresponding fuel spray distribution. X-ray spray tomography measurements of three six-hole GDI nozzles with varying hole patterns explored the effects of geometric asymmetries on the spray structure [1]. The authors found that the emitted fuel spray distribution varied between jet-like, hollow-coned, or crescent-shap...

show abstract

mentioning

confidence: 99%

A study on the relationship between internal nozzle geometry and injected mass distribution of eight ECN Spray G nozzles.

Matusik¹,

Duke²,

Sovis³

et al. 2017

Proceedings ILASS–Europe 2017. 28th Conference on Liquid Atomization and Spray Systems

Self Cite

View full text Add to dashboard Cite

show abstract

“…ディーゼル機関において熱効率の向上や排気物質の低減のため，燃料噴霧特性の詳細な理解に基づく燃焼の適切な制御が求められている．燃料噴霧の基礎的な情報として，噴霧先端到達距離や噴霧角等の噴霧形状については多くの研究成果が報告されている．燃料噴霧は時間的な非定常性が強く，空間的にも不均一であることから，噴霧内部における噴霧液滴を評価する必要がある．噴霧下流の燃料噴霧については，噴霧液滴が十分に拡散し，比較的計測が容易であることから，PDPA (Wang et al, 2016a)や PIV (Zama et al, 2012)により計測された液滴の速度分布や粒径分布が報告されている．噴孔近傍の噴霧については液滴が非常に密集しているため比較的計測が容易ではないものの，Crua らは長距離顕微鏡を用いて噴孔近傍の噴霧外縁部の噴霧液滴の速度および粒径分布を計測している (Crua et al, 2015)．また Moon らは X 線位相コントラスト法 (XPCI: X-ray Phase Contrast Imaging) を用い *1 正員，長崎大学工学研究科（〒852-8521 長崎県長崎市文教町 1-14） *2 いすゞ自動車（株）（〒252-0881 神奈川県藤沢市土棚 8） *3 （株）いすゞ中央研究所 E-mail of corresponding author: komada@nagasaki-u.ac.jp ることで，噴孔近傍噴霧のラインオブサイト特性に基づく画像を取得しており，その画像を解析することで噴霧の速度分布や粒径分布を計測している (Moon et al, 2014)．燃料噴霧は下流に向かって広がり拡散することから噴霧の分散過程が重要であり，噴霧角から分散を評価した結果が報告されている (Payri et al, 2016) (Naber and Siebers, 1996)．また，Wang らは微小な時間に噴射された燃料の質量と噴霧画像における噴霧断面積の増加量の間のつりあいから噴霧質量の分散を評価している (Wang et al, 2016b Fig. 1 Fuel spray measurement system.…”

Section: まえがきunclassified

Dispersion of spray droplets near diesel fuel injector nozzle

Komada

Kawaharada

Udagawa

et al. 2017

Transactions of the JSME (In Japanese)

View full text Add to dashboard Cite

A laser 2-focus velocimeter (L2F) was used for measurements of velocity, size and number density of droplets in diesel sprays injected into the atmosphere by using 8-hole injector nozzle. The diameter of the nozzle orifice was 0.112mm. The injection pressure was set at 65MPa. The droplets dispersion model which can estimate the number density by using the spray width and the droplet velocity was proposed. It was shown that the velocity of droplets at the spray center region was higher than the one at spray periphery region in the middle period of injection duration. The size of droplets at the spray center region was larger than the one at the spray periphery region. The number density of droplets was high at the region between the spray center and the spray periphery. The number density estimated by the droplets dispersion model was nearly same as the one evaluated by L2F measurement at the spray center region in the middle period of injection duration. It is understood that the number density was decided by the dispersion due to the changes of the spray width and the spray velocity at the center region in the middle period of injection duration.

show abstract

“…Therefore, richer surrogates containing aromatics and other species that are important components in diesel fuels must also be represented in the surrogate selected for this study. In the present paper, three surrogate fuels are employed, n-heptane as the classical diesel substitute, ndodecane that has been widely accepted as a diesel substitute in recent years and it was decided as reference fuel for the ECN [20,29] and finally a multi-component diesel surrogate consisting of n-tetradecane (0.5), n-decane (0.25) and a-methylnaphthalene (0.25) is utilized [30,31]. Numbers in parentheses represent mass fractions.…”

Section: Introductionmentioning

confidence: 99%

“…The study follows up on three previous works which analyze the effect of nozzle geometry over the liquid iso-thermal non-evaporative spray formation [32], the effect of nozzle geometry combined with different fuels on the hydraulic performance and liquid isothermal non-evaporative spray formation [30], and the same nozzles and fuels on evaporative conditions [31]. In this work, all experiments were also performed for the same nozzle geometries (cylindrical and conical convergent) and fuel types.…”

Section: Introductionmentioning

confidence: 99%

The effect of nozzle geometry over ignition delay and flame lift-off of reacting direct-injection sprays for three different fuels

Payri

Viera

Gopalakrishnan

et al. 2017

Fuel

Self Cite

View full text Add to dashboard Cite

h i g h l i g h t sSimultaneous Schlieren and OH * chemiluminescence visualizations are carried out with different techniques. The effect of nozzle geometry is analyzed for three different fuels along a wide test matrix in reactive conditions. Analysis of spray tip penetration, lift-off length and ignition delay. A total of 162 different test conditions are evaluated in the high temperature/high pressure test rig. The experimental database will be published and available for model validation. a b s t r a c tThe influence of internal nozzle flow characteristics over ignition delay, and flame lift-off of reacting direct-injection sprays is studied experimentally for three fuels using two different nozzle geometries. This is a continuation of previous work by the authors, where, evaporative and non-evaporative, isothermal spray developments were studied experimentally for the same nozzle geometries and fuels. Current study reports the ignition delay through Schlieren technique, and flame lift-off length through OH * chemiluminescence visualization. The nozzle geometries consist of a conical nozzle and a cylindrical nozzle with 8.6% larger outlet diameter when compared to the conical nozzle. The three fuels considered are n-heptane, n-dodecane and a three-component surrogate to better represent the physical and chemical properties of diesel fuel. Reacting spray is found to penetrate faster than non-reacting spray due to combustion induced acceleration after ignition. Higher oxygen concentration, and ambient temperature enhance the reactivity leading to higher spray tip penetration. Injection pressure does not affect the reactivity significantly and hence, influences spray penetration through momentum-similar to a non-reacting spray. Both ignition delay and lift-off length are found to be shortest and longest for n-dodecane and n-heptane, respectively, while the surrogate fuel falls in-between the two pure component fuels. Both ignition delay and lift-off length are found to decrease with increase in oxygen concentration, ambient temperature, and density. The cylindrical nozzle, in spite of shorter lift-off length is found to have longer ignition delay, when compared to the conical nozzle. This could be due to better atomization leading to larger spread angle and evaporative cooling from the cylindrical nozzle compared to a conical nozzle. The longer ignition delay also leads to leaner equivalence ratios at the time of ignition.

show abstract

The effect of nozzle geometry over internal flow and spray formation for three different fuels

Cited by 70 publications

References 64 publications

A study on the relationship between internal nozzle geometry and injected mass distribution of eight ECN Spray G nozzles.

A study on the relationship between internal nozzle geometry and injected mass distribution of eight ECN Spray G nozzles.

Dispersion of spray droplets near diesel fuel injector nozzle

The effect of nozzle geometry over ignition delay and flame lift-off of reacting direct-injection sprays for three different fuels

Contact Info

Product

Resources

About