Spray characteristics of a pintle injector based on annular orifice area

Journal Pre-proof Spray characteristics of a pintle injector based on annular orifice area Suji Lee, Daehwan Kim, Jaye Koo, Youngbin Yoon PII:

S0094-5765(19)31385-2

DOI:

https://doi.org/10.1016/j.actaastro.2019.11.008

Reference:

AA 7753

To appear in:

Acta Astronautica

Received Date: 25 June 2019 Revised Date:

26 October 2019

Accepted Date: 2 November 2019

Please cite this article as: S. Lee, D. Kim, J. Koo, Y. Yoon, Spray characteristics of a pintle injector based on annular orifice area, Acta Astronautica, https://doi.org/10.1016/j.actaastro.2019.11.008. This is a PDF file of an article that has undergone enhancements after acceptance, such as the addition of a cover page and metadata, and formatting for readability, but it is not yet the definitive version of record. This version will undergo additional copyediting, typesetting and review before it is published in its final form, but we are providing this version to give early visibility of the article. Please note that, during the production process, errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. © 2019 Published by Elsevier Ltd on behalf of IAA.

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Spray characteristics of a pintle injector based on annular orifice area Suji Lee1, Daehwan Kim1, Jaye Koo2, and Youngbin Yoon3,* 1 Graduate Student, Department of Mechanical and Aerospace Engineering, Seoul National University, 1 Gwanakro, Gwanak-gu, Seoul, 08826, Republic of Korea 2 Professor, School of Aerospace and Mechanical Engineering, Korea Aerospace University, 76, Hanggongdaehakro, Deogyang-gu, Goyang-si, Gyeonggi-do, 10540, Republic of Korea 3 Professor, Department of Mechanical and Aerospace Engineering and the Institute of Advanced Aerospace Technology, Seoul National University, 1 Gwanak-ro, Gwanak-gu, Seoul, 08826, Republic of Korea * Address all correspondence to Youngbin Yoon, E-mail: [email protected].

13

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As interest in low-cost reusable launch vehicles and extraterrestrial exploration has

15

increased in recent years, soft-landing techniques have become important. A pintle injector

16

can help realize this because it is capable of thrust control. However, research on this topic is

17

very limited, and general optimization design procedures have not been completely

18

established. In particular, no studies have examined orifice adjustment for annular flow,

19

which is important in thrust control. In this study, a new design concept for a pintle injector

20

is presented specifically to improve spray uniformity in a 400 N class engine; this maintains

21

the concentricity of the pintle rod associated with the radial flow’s orifice size. The primary

22

focus here was on spray tests that were conducted to obtain the control range of the orifice

23

area for annular flow. Spray characteristics such as spray angle, spray uniformity, and

24

droplet size were analyzed, from which empirical correlations were derived. Finally, the

25

optimum control range for the annular flow’s orifice area was estimated from the

26

perspective of atomization performance. This can be of reference to develop an enhanced

27

thrust control system.

28 29

Keywords: Throttleable liquid rocket engine, Pintle injector, Annular orifice area, Spray characteristics

30 31 32 33 34 35 36 37 38 39 40 41 42 43

Nomenclature





, 


,  



∗ 















Cylinder cross-sectional area Annular flow’s outlet area Radial flow’s outlet area Blockage factor Characteristic velocity Thrust coefficient Combustion chamber diameter Circumferential length of each hole Pintle diameter Rocket thrust Gap distance Outlet height Momentum flux ratio

44



Distance until annular flow first collides with radial flow

45

N

New dimensionless number

46



Number of total holes/slot

47

O/F

Oxygen to fuel mass flow rate ratio

48

P

New parameter

49



Combustion chamber pressure

50 51 52 53

  

!

Patternation index Relative flow intensity Cylinder inner radius Cylinder outer radius

54

"#

Sauter mean diameter

55

SUI

Spray uniformity index

56

TMR

Total momentum ratio

57

We

Weber number

58 59

1. Introduction

60

requirement for commercial launch services. Consequently, interest in developing reusable launch vehicles has

61

quickly increased in countries around the world. Planetary exploration for future energy sources has also attracted

62

attention. Soft landing technology is a key factor in reusable launchers and extrasolar planet exploration. A

63

throttleable rocket engine is an important technology that can help accomplish this mission, so extensive research is

64

required.

With the recent growth of the private space rocket market, price competitiveness has become an important

65

There are several ways to control thrust, including changing the propellant’s type or composition and adjusting

66

the area of the nozzle throat or nozzle exit. However, these approaches are difficult to control due to physical

67

limitations and high heat flux concentrated in the nozzle throat. In contrast, controlling the propellant flow rate is

68

regarded as the simplest method. The relationship between rocket thrust and propellant flow rate is defined by Eq.

69

(1):

70

 $ %& ∙ ( )
 ∙ * +  ,

(1)

71

where , %&, ( ,
 ,  , and  are rocket thrust, propellant flow rate, nozzle exit velocity, exit area, exit pressure,

72

and free stream pressure, respectively. There are various ways to adjust flow rate, such as controlling differential

73

pressure or using a dual manifold, but the area control method is considered to be the most promising [1].

74 75

Fig. 1. Conceptual diagram of a pintle injector.

76 77

A pintle injector is a representative area control method and has the structure to control thrust. The propellant

78

flow rate is regulated by adjusting the injector orifice size using a specific moving device. Fig. 1 shows the basic

79

concept of the pintle injector, in which an area adjusting sleeve moves in the axial direction to control the propellant

80

orifice size. Fuel is injected in the axial direction of the combustion chamber in the form of annular flow along the

81

injector’s outer wall. The oxidizer flows into the pintle injector and forms a thin sheet in the radial direction through

82

the gap between the pintle and the sleeve. Propellants injected in the axial and radial directions collide with each

83

other at the end of the pintle, allowing mixing and atomization to proceed.

84

This pintle injector has several characteristics. First, it can control thrust and has consistent high performance

85

over a wide thrust range. Second, it is simple, allowing for cost and weight savings. For swirl or jet injectors

86

typically used in liquid rocket engines, multiple injectors are mounted on one plate. However, only one pintle

87

injector is required regardless of thrust, which can have a large range. Consequently, cost and weight can be reduced.

88

The third characteristic is combustion stability, as the pintle injector has recirculation zones around the injector.

89

Because the recirculation zone at the center of the combustion chamber acts as a deflector and mixer for unburned

90

droplets, it has a positive effect on combustion stability and performance [2, 3].

91

The pintle injector concept was first devised by TRW in the United Sates, and it was applied to the Apollo Lunar

92

Descent Engine (LMDE) in the 1960s. Since the early 2000s, pintle injector research has been carried out in industry

93

and academia. SpaceX applied the pintle injector used in the LMDE to the Merlin engine to develop a reusable

94

vehicle to reduce launch costs [4]. Northrop Grumman developed a TR202 prototype engine aimed at developing a

95

variable thrust rocket engine for future NASA take-offs and landings. The combustion characteristics were observed

96

through a 10:1 throttling level combustion test [5].

97

At Purdue University, a pintle injector for non-toxic bipropellants was developed and a combustion test was

98

performed. Several parameters related to the pintle injector design were chosen to investigate how they affect

99

combustion characteristics. In addition, as part of NASA’s Morpheus project, a pintle injector for the liquid

100

oxygen/liquid methane engine of a lunar lander was assembled and combustion tests were completed [6, 7]. At

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Minas Gerais Federal University in Brazil, various combinations were used to determine injection patterns of radial

102

and annular flows, and the basic spray conditions of a prototype injector for a 1 kN engine [8]. In Germany, effects

103

of pintle injector geometry on combustion and heat load were investigated. Four different pintle injector

104

configurations were fabricated and evaluated for performance [9]. At the Indian Institute of Space Science and

105

Technology, instability growth rate and droplet size were observed when radial and annular flows collided at

106

different momentum ratios [10]. At the University of Tokyo, a combustion chamber applied a pintle injector, and the

107

flame structure and combustion characteristics based on momentum ratios were identified [11, 12]. At China’s

108

National University of Defense Technology, a numerical analysis was performed to investigate effects of pintle

109

injector geometry on the combustion chamber’s internal combustion field. Specifically, combustion characteristics

110

based on characteristic length, pintle opening distance, and pintle length were observed [13]. In Korea, at Chungnam

111

National University, spray patterns and combustion performance were observed for various canted slit type pintle

112

injectors [14-16]. Finally, at Korea Aerospace University, spray characteristics under various conditions were

113

analyzed. In addition, recirculation zone and spray breakup simulations were carried out using a Lagrangian

114

approach to numerical analysis [17-19].

115

Although some recent research has been conducted on pintle injectors many questions and limitations remain.

116

Compared to conventional injectors used in liquid rocket engines, general design procedures for pintle injectors have

117

not been completely assessed. More data on the characteristics of the pintle injector are required, especially in

118

academia. In particular, research on injection area control is needed, but no research related to the orifice area of the

119

annular flow has been completed. The orifice range is important to maintain performance across the entire thrust

120

range.

121

In this study, a pintle injector was designed for 400 N class liquid oxygen/gas methane to obtain optimal design

122

data. A new design was adopted to improve uniformity, and spray characteristics were observed using water and air

123

as simulants with several measurement techniques. Experiments were conducted to obtain the annular flow’s orifice

124

area control range based on atomization performance. Correlations were obtained for spray angle and mean droplet

125

diameter.

126

2. Pintle injector design

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Table 1

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Specifications of a 400 N engine. Chamber pressure (MPa) Vacuum thrust (N) O/F Chamber diameter (mm) Throttling level (%) Mass flow rate of liquid oxygen (g/s) Mass flow rate of methane (g/s)

1 400 3.44 54 20 to 100 83.4 24.24

129 130

The target engine of the pintle injector is a 400 N class small thruster that uses liquid oxygen and gaseous

131

methane; Table 1 shows the specifications. The oxygen to fuel mass flow rate ratio (O/F) was set to 3.44, which is

132

typical for a methane engine. Radial flow and annular flow were set as liquid oxygen and gaseous methane,

133

respectively. The chamber diameter was calculated using Eq. (2), related to engine performance factors: .

 $ - ∙

134 135 136

/



0∙1 ∗ ∙12 ∙34

(2)

where  , ,  ∗ ,  , and  are combustion chamber diameter, relative flow intensity, characteristic velocity, thrust coefficient, and combustion chamber pressure, respectively.  ∗ (associated with combustion efficiency) and

137

 (associated with nozzle efficiency) were obtained using NASA CEA code [20]. The thrust control range was set

138

to 20–100%, to achieve 5:1 deep throttling.

139 140 141 142

Fig. 2. Combustor of the pintle injector [21]. Fig. 2 shows several parameters that can determine pintle injector geometry; there were three main design factors,

143

with the first being the ratio of chamber to pintle diameters ( / ). The diameter of the pintle injector was set at 11

144

mm, based on the recommended ratio of diameters 3 to 5 [21]. The second factor was skip distance, defined as the

145

ratio of distance (until the annular flow first collides with the radial flow) to pintle diameter ( / ); its

146

recommended value is one. Previous numerical results showed that combustion efficiency decreased when skip

147

distance was greater or less than one. When the skip distance equaled one, combustion efficiency was the highest

148

[13]. Therefore, skip distance was set to one, and  was determined to be 11 mm to the pintle diameter. The third

149

parameter was the blockage factor (BF), defined as the ratio of the circumferential length of the holes or slot at the

150

end of the pintle to the pintle circumference. The BF is presented using Eq. (3), and the meaning of each parameter

151

is shown in Fig. 3 [21, 22].

152

 $

67 ∙89 /8:

(3)

153

where  and  are number of total holes/slot and circumferential length of each hole, respectively. When BF

154

was less than one (i.e., the circumferential length of the holes is smaller than pintle circumference) there were

155

regions where annular and radial flow did not collide. To obtain a uniform spray pattern, a continuous slit type was

156

adopted. In this feature, the holes in Fig. 3 were in ring form and distributed in the pintle circumference direction

157

(Fig. 4). Ideally, the radial flow is uniformly sprayed on all pintle circumferences and forms a thin liquid sheet.

158

Because the BF equals one, all propellants participated in the mixing.

159

160 161

Fig. 3. Multi-hole type pintle geometry [22].

162

163 164

Fig. 4. New concept for maintaining concentricity of a pintle rod.

165 166

An important point in the design of a continuous slit-type injector is maintaining the concentricity of the pintle

167

rod. As shown in Fig. 4, the pintle rod is a moving part that moves axially in the combustion chamber and adjusts

168

the radial flow’s orifice area. If the pintle rod concentricity is not maintained, it will wobble inside the pintle and

169

eventually deteriorate the quality of the spray of the radial flow. This may be caused by the absence of a support for

170

concentricity of the pintle rod or the effect of the radial flow flowing into the pintle. Thus a new concept was applied

171

to maintain concentricity of the pintle rod. To support the concentricity of the pintle rod, a guide wall was enclosed

172

around the pintle rod, shown as red hatched lines in Fig. 4. This guide wall holds the pintle rod such that it does not

173

wobble inside the pintle. This guide wall also eliminates the effects of the flow inside the pintle by independently

174

separating the pintle rod from the inner passage of the radial flow.

175

The guide wall must be firmly fixed; this is achieved by placing several holes in the inlet area where the radial

176

flow enters the pintle, as shown in Section A-A in Fig. 4. In this area, the regions between the holes serve to connect

177

and support the guide wall with the outer wall. The radial flow is initially supplied into the multiple inlet holes, as

178

shown in Section A-A. It then passes through a cylinder region, as shown in Section B-B in Fig. 4, for mixing of the

179

fluids passing through each inlet hole. The cylinder region was placed before exiting the pintle outlet to form a

180

uniform distribution. After passing through the cylinder region, the radial flow through is distributed over the entire

181

circumference of the pintle as shown in Section C-C.

182

Fig. 5 (a) shows the final geometry of the pintle injector. It consisted of a pintle post (the core of the pintle

183

injector, with inner geometry as shown in Fig. 4), three manifolds to uniformly supply flows, pintle rod, and a

184

micrometer head (Mitutoyo MHN1-25MXN, resolution 0.001 mm) to adjust the radial flow’s orifice size. If the

185

geometry changed, each corresponding part could be independently replaced. Fig. 5 (b) shows the distribution plate

186

inserted between the middle and down manifold, which helped to uniformly distribute the annular flow. This plate

187

type was also used in a previous study to uniformly distribute propellant [8].

188 189 190 191 192 193 194 195

Fig. 5. Final geometry of the pintle injector; (a) whole view (b) section view.

196

3. Experimental setups and methods

197

3.1. Experimental conditions

198 199

Fig. 6. Control range with respect to throttling level.

200 201

Spray characteristics were observed at the minimum, mid-range, and maximum throttling levels of 20 60, and

202

100%, respectively. To achieve a deep throttling of 5:1, the differential pressure and the outlet height (H, related to

203

the outlet area of the radial flow) had to be adjusted simultaneously, a method widely used for thrust control. MIRA-

204

150A, a TRW binary propellant rocket engine, also used this mechanism. The injector’s moving part and the flow

205

control valve were mechanically linked to fulfill the desired throttling level [23]. Previous work showed that deep

206

throttling cannot be achieved under constant differential pressure. Therefore, it was necessary to consider

207

differential pressure control and area adjustable systems [24]. Fig. 6 shows the operating range of H according to

208

throttling levels as well as the corresponding mass flow rate and differential pressure. H was adjusted between 0.1

209

and 0.6 mm, a wide operation range that was accounted for when determining the minimum opening. The maximum

210

value of H was determined by considering the cylinder cross-sectional area (
 ) inside the pintle injector and the

211

radial flow’s outlet area (
,   ). These areas are expressed by Eq. (4), and each is shown in Fig. 7. If
,  

212

was larger than
 , the radial flow’s orifice size was fixed to
 even if H increased. In other words, the

213

variation of the H was meaningless in this range. Therefore, the maximum adjustment value of H was set to 0.6 mm,

214

to control H only for regions where
,   was less than
 .

215


 $ ;*!! +  ! , =
,   >
 @  > 0.6 %%
,   $ ; ∙ 

(4)

216

where  and ! are cylinder inner radius and cylinder outer radius, respectively. H was linearly controlled based

217

on throttling levels. H values at thrust levels of 20, 60, and 100% were 0.1, 0.35, and 0.6 mm, respectively. The

218

mass flow rates corresponding to each H were 16.6, 49.68, and 83.58 g/s, respectively. The differential pressure to

219

satisfy the mass flow rate of each thrust level was also adjusted with H, as shown in Fig. 6.

220 221

Fig. 7. Schematic of a pintle tip.

222 223

The gap distance (G) of the annular flow was related to the orifice size control (Fig. 2). To determine the range

224

of G, spray characteristics were observed at each thrust level. G ranges used are shown in Table 2. The outlet area of

225

the annular flow (
,  ) is shown in Eq. (5), and the maximum area was set to 185.519 %%! :
,  $ ; ∙ C ) D

226

(5)

227

In Table 2, a specific G range was chosen for each throttling level to obtain accurate empirical correlations for spray

228

angle and droplet size. The down manifold was manufactured for each G (i.e., G was changed by replacing the down

229

manifold).

230

Table 2

231

Range of gap distance (G).
,  (%%! ) 185.519 148.252 111.087 73.991 46.414 37.128 26.706 18.177 8.258

232 233

Gap distance G (mm) 3.95 3.3 2.6 1.835 1.21 0.986 0.725 0.503 0.234

234

3.2. Spray imaging

235

Backlight photography was used to obtain the spray image, as shown in Fig. 8. A stroboscope (SUGAWARA

236

MS-230DA model) with a flash duration of 6 μs was used as the backlight. To acquire spray images, a digital

237

camera (Canon EOS 7D, 5184 x 3456 pixels, spatial resolution 47μm/pixel) and a lens (Canon EF 24-70mm) were

238

used. The frozen image was obtained by setting the camera exposure time and flash frequency of the stroboscope to

239

1/30 sec and 30 Hz, respectively. To obtain spray images with the proper depth of field and brightness, the camera

240

was set to f/11 and ISO 1000.

241

For the cold test, water and air were used as simulants for liquid oxygen and methane, respectively. For the

242

liquid, a needle valve was mounted on the feed line to regulate differential pressure. A mass flow meter

243

(KOMETER KTM-800, accuracy ±0.5%) was used to monitor the liquid flow rate, and the gas feed line was

244

equipped with a mass flow controller (MKP TSC-150, accuracy ±0.2%) for flow control between the gas supply

245

system and the manifold. The gas flow rate was adjusted such that O/F was always maintained at 3.44, regardless of

246

thrust.

247 248 249

Fig. 8. Spray imaging apparatus. 3.3. Spray pattern

250

To analyze the degree of uniformity, the spray pattern perpendicular to the spray direction was measured using

251

the optical patternator. This technique has a high spatial resolution and rapid characterization but can contain error

252

sources such as multiple scattering and signal attenuation [25]; error correction were therefore applied. To remove

253

multiple scattering, a two-phase structured laser illumination planar imaging (SLIPI) technique was used. This

254

method extracted a single scattering signal using a modulated laser sheet [26]. The experimental setup consisted of a

255

high-speed dual head laser (Photonics Industries DM20-527DH), SLIPI optics module (LaVision), and CMOS high-

256

speed camera (Photron FASTCAM SA5, 1024 x 1024 pixels) with a lens (AF MICRO NIKKOR 105 mm). The

257

camera was set to f/5.6 with an image rate of 3 kHz, and 300 images were obtained for each experiment condition.

258

The modulated laser sheet position was 7 mm from the end of the pintle rod in the axial direction, taking into

259

consideration the diameter of the small combustion chamber and field of view. An example of the spray pattern

260

obtained through the experimental setup is shown in Fig. 9, an averaged image at a throttling level of 20% and G of

261

0.986 mm.

262 263

Fig. 9. Spray pattern from the optical patternator with SLIPI.

264 265

To deal with signal attenuation, a compensation method proposed by Abu-Gharbieh et al. (2000) was used. This

266

method was based on the Beer-Lambert law and compensated for each pixel by applying a compensating algorithm

267

in a discrete way, as shown in Eq. (6): UV

" N $ "  ∙ OPQRS ∙ ∑UWX "UN Y

268

(6)

269

where " N and "  are compensated and observed pixel intensity, respectively, and is a balance value that

270

minimizes the difference between the right and left image averages. The detailed process to develop Eq. (6) was

271

presented in a previous study [27].

272 273 274

275

3.4. Droplet size

276

Droplet size is an important index of injector atomization characteristics and affects combustion efficiency [27].

277

Especially for the pintle injector, it was necessary to maintain droplet size throughout the entire thrust range to

278

achieve a certain atomization efficiency. To observe droplet size, an experimental apparatus consisted of the high

279

speed camera used in the optical patternator, a long distance microscope (LaVision QM1) with a magnification lens

280

x2.0, and the stroboscope. The spatial resolution 4.59μm/pixel, and 200 images were taken per case. Droplet size

281

was measured at a point 20 mm from the pintle tip in the axial direction to the outline of the spray field.

282

283 284

Fig. 10. Image processing for droplet size measurement.

285 286

Fig. 10 shows the image processing procedure used to measure droplet size. The raw image taken by the camera

287

was recorded in grayscale, and the optimal threshold was calculated based on Otsu’s method. In the resulting binary

288

image, droplets were clearly visible apart from the background. The spray image contained background errors such

289

as dust on the detector. To eliminate these errors, a background image taken without spraying was also binarized and

290

then subtracted from the spray image. In the last step, droplets in the image boundary were excluded. Non-circular

291

droplets were removed based on the ratio of a minor axis length to a major axis length. This processing was

292

performed for each image and diameters were judged based on the ratio of the extracted from 200 images per

293

experimental case.

294

To analyze droplet size, the Sauter mean diameter (SMD) was used. The SMD, also called Z! , is expressed in

295

Eq. (7) as a ratio of volume to surface, and is a representative diameter that reflects evaporation rate and combustion

296

reaction [28]: ∑ 6[ ∙8[\

"# $ ∑

297

6[ ∙8[]

298

where  and  are the number of droplets and the middle diameter in size range ^, respectively.

299

4. Results and discussion

300

4.1. Spray structure

301 302 303

Fig. 11. Spray images with various throttling levels and gap distances.

(7)

304

Fig. 11 shows spray images for all experimental conditions. The breakup process was classified into two types: (i)

305

atomization immediately after collision of the radial and annular flows and (ii) droplets split from a liquid sheet after

306

collision. The second type was observed when the throttling level was 20% and the G was greater than 1.835 mm.

307

To set the criterion for dividing the two breakup mechanisms, momentum flux ratio (J) and Weber number (We) for

308

two-phase flow, defined as Eq. (8) and Eq. (9), respectively:. $

309 fO $

310

] _`[a ∙b`[a

] _cde ∙bcde

(8) ]

_cde ∙Cbcde Vb`[a D ∙ g`[a

(9)

311

where hi , h 0 , (i , ( 0 and j 0 are gas density, liquid density, gas velocity, liquid velocity, and liquid

312

surface tension, respectively. The characteristic length of the pintle injector was defined as H. Results confirmed that

313

the second breakup type occurred when J was greater than 6.4 and We was less than 4.13. In this region, there was a

314

specific breakup length and droplet size was relatively large. That is, atomization efficiency was relatively low, and

315

accounting for the small thruster, combustion efficiency can be adversely affected. This again illustrated that annular

316

flow orifice size control was important to optimum spray performance. To obtain optimum injector parameters,

317

spray characteristics were therefore analyzed except for this region.

318

For the first breakup type, the typical atomization process is shown in Fig. 12. After the thin liquid sheet in the

319

radial direction collided with the annular flow, a wave was generated by aerodynamic force, leading to the

320

disconnection of the liquid sheet. Furthermore, a liquid lump fell out of the end of the liquid sheet and then split into

321

smaller droplets.

322

323 324 325

Fig. 12. Atomization process.

326

To obtain the spray angle, 50 images were averaged for each case. The spray angle decreased with decreasing G

327

(Fig. 11), explained by total momentum ratio (TMR), which is closely related to the spray angle formation of the

328

pintle injector [21, 29]. TMR is defined in Eq. (10) and is expressed as the ratio of momentum of radial to annular

329

flows.

330

*m& ∙b,ndo[d`

k#l $ *m∙&b,

dppq`dn

(10)

331

At each throttling level, mass flow rates of the radial and annular flows were fixed. In addition, because H

332

associated with the radial flow orifice size was constant at each level, the radial flow momentum was fixed. As G

333

decreased, the annular flow’s orifice size also decreased while annular flow velocity increased. As a result, as G

334

decreased, annular flow momentum intensified and spray angle decreased.

335

336 337 338

Fig. 13. Relationship between spray angle and (a) total momentum ratio (rst) (b) the new dimensionless number, u = rst ∙ *v/w,.

339 340

Fig. 13 (a) shows that spray angle was proportional to TMR. When G was the same, the spray angles at all

341

throttling levels were nearly identical. From the perspective of TMR, it can be expressed as k#l ∝ y*V , under

342

conditions where G is the same in the entire throttling range. In other words, points with the same spray angle had

343

different TMRs. This is because H changes linearly with throttling level. Therefore, if the throttling level decreases

344

under the same G condition, TMR increases. For this characteristic, there was a gap (Fig. 13a) such that only the

345

correlation between the spray angle and TMR was expressed. Therefore, a new dimensionless number was defined to

346

represent spray angle tendency within the overall thrust range. Fig. 13 (b) shows spray angle tendency with a new

347

dimensionless number (N), defined by Eq. (11), which is the ratio of H to G in the TMR.

 $ k#l ∙ */,

348

(11)

349

For N, it can be expressed as  ∝ y*,. That is, if G is the same, the value of N is also constant

350

the throttling level. This allows the same spray angles to have one N and eliminates the gap that was observed

351

between the throttling levels in TMR and spray angle relationships. As a result, it can be expressed as one correlation

352

having a proportional relationship, such as the relationship between G and spray angle. The correlation between N

353

and spray angle (Fig. 13b) was defined as Eq. (12), with R2 = 0.98. This empirical equation will be used to predict

354

the spray angle in future spray conditions. "Qz{ z|}~O $ +177.83 ) 16007.17 

355

356

irrespective of

(12)

4.2. Spray uniformity

357

Using the error correction methods discussed in Section 3.3, spray uniformity was analyzed. Experiments were

358

conducted for regions with G greater than 0.986 mm. When the throttling level was 20%, the second breakup type

359

was excluded, as mentioned in Section 4.1. To determine uniformity degree, a Patternation Index (PI) and Spray

360

Uniformity Index (SUI) were defined by Eq. (13) and Eq. (14), respectively:

362



e†‡ …e

„ × 100

(13)

where | and  are the number of sectors and intensity of the image per sector, respectively, and "‰ $ Š ∑W *{ + {‹,! Œ

363 364

…e

*%, $ ∑W „ + ∑p

361



where { ≡ ∑p

…e

e†‡ …e /

and {‹ ≡

/!

(14)

∑p e†‡ e 

365

The PI and SUI represented spray symmetry, and circumferential uniformity and standard deviation of the spray

366

distribution [25, 30, 31]. Results of the spray uniformity analysis are shown in Fig. 14. PI, by definition, has a value

367

from zero to 200, and spray uniformity is higher with lower PI. PI and SUI averaged 20% and 0.26, respectively. In

368

addition, the standard deviations (σ) were 3.62% and 0.04 respectively. From the perspective of SUI, the standard

369

deviation appeared to be very small and this meant that the spray uniformity was almost constant irrespective of the

370

gap distance and the throttling level. When the spray uniformity associated with PI was expressed as a percentage,

371

and assuming that 100% was the ideal uniform distribution, the mean value of the spray uniformity from the PI data

372

was 90%. As an extension of this, the standard deviation of PI data was 1.81%. In this study, when the spray

373

uniformity was more than 90%, based on the average value of PI, and the standard deviation is within 5%, the

374

quality of the injector was considered suitable for experiments.

375 376

Fig. 14. Spray uniformity based on (a) Patternation Index (PI) and (b) Spray Uniformity Index (SUI).

377 378

4.3. Sauter mean diameter (SMD)

379

For the SMD analysis, J and We were selected. Fig. 15 shows SMD trend based on each dimensionless number,

380

and indicates that both were related to SMD. For the pintle injector, the first breakup was a vertical collision like a

381

jet in crossflow. At this time, liquid sheet breakup was caused by the transfer of gas momentum. In addition,

382

breakup was sustained by shear force due to the velocity difference between the radial and annular flows. Overall, it

383

seemed that complex mechanisms act on breakup.

384

385 386 387

Fig. 15. Relationship between SMD and: (a) momentum flux ratio () and (b) weber number (‘).

388

In Eq. (8), when G decreases, the velocity of gas (annular flow) increases, so that the momentum flux of the gas

389

corresponding to the denominator of J becomes relatively strong. Thus, J also decreases as G decreases. In other

390

words, it means that gas momentum transfer, which affects the liquid sheet, generally increased. Therefore, SMD

391

decreased proportionally as J decreased. For We, when G decreases at each throttling level, the velocity of gas

392

increases; thus, the force corresponding to the numerator of We becomes relatively strong from Eq. (9). Namely, it

393

indicates that relative velocity and the deforming force due to the shear force was intensified. Therefore, We and

394

SMD were inversely proportional to each other.

395

396

Fig. 16. Relationship between new parameter, ’= V“.”• ∙ ‘“.“– and —s˜.

397 398 399

To investigate which of the two dimensionless numbers had a greater impact on droplet formation, an empirical

400

correlation was derived. Fig. 16 shows the result, where Eq. (15) is the final correlation with R2 = 0.96. In Fig. 16,

401

the new parameter (P) on the x-axis is represented by VX.™Z ∙ fO X.Xš in Eq. (15).

402

"# $ +111.45 ~|*VX.™Z ∙ fO X.Xš , ) 490.12

403

Eq. (15) can also be expressed as Eq. (16), in which momentum transfer during the vertical collision of two flows

404

has a greater effect than the shear force in droplet formation. This was likely because the pintle injector created an

405

interaction between radial and annular flow. The correlation will be used to estimate the optimal G to obtain the

406

desired SMD.

407 408 409

"# $ 103.65 ~|*, + 5.57~| *fO, ) 490.12

(15)

(16)

410

4.4. Relationship between spray angle and SMD

411

412

Fig. 17. Relationship between spray angle and —s˜.

413 414 415

Fig. 17 shows the relationship between spray angle and SMD for G at each throttling level. Spray angle and SMD

416

had a linear relationship at each throttling level. When G was fixed, the spray angle was almost constant in the

417

whole thrust range. This is because, as described in Section 4.1, the spray angle changed according to G irrespective

418

of the throttling level. In addition, since G and the spray angle were proportional, the spray angle tended to increase

419

when G increased. On the other hand, SMD was different at each throttling level when G was fixed. For example,

420

when G was fixed at 0.986 mm, SMD at the 100, 60, and 20% throttling levels were 114.17, 227.12, and 493.20 μm,

421

respectively. This is because SMD was related not only to G but also to several factors associated with the throttling

422

level as shown in Eq. (16). When the throttling level was lowered under the fixed condition of G, SMD increased

423

with J increased and We decreased. This study focused on atomization performance, so the control range of G to

424

maintain constant SMD at all thrust levels was estimated and discussed in Section 4.5.

425

4.5. Variations in G and spray angle with SMD

426

The control range of G with constant SMD was obtained from an empirical equation (Section 4.3). In addition,

427

spray angle variation at the same time was estimated by Eq. (12). To analyze the resulting variations, three cases

428

(SMD = 100, 150, and 200 μm) were selected as examples based on ranges typically used in a liquid rocket engine

429

[32].

430

Fig. 18. Variation ranges (constant —s˜) of (a) gap distance and (b) spray angle.

431 432 433

Fig. 18 (a) shows the control range of G required to maintain the corresponding SMD. When SMD was constant,

434

the throttling level and G were linearly related. This indicated that the annular flow orifice area could be linearly

435

controlled based on throttling level. For radial flow, mass flow rate and H also had a linear relationship that

436

controlled outlet area. Therefore, the orifice sizes of radial and annular flows could be adjusted linearly for thrust

437

control. In addition, as the target SMD became smaller, the overall control range scale decreased. This is because G

438

must be further reduced in order to produce smaller droplets because the gas momentum flux and deforming force

439

must be stronger through increasing the gas velocity.

440

Fig. 18 (b) shows the variation range of the spray angle when G in the corresponding SMD was controlled (Fig.

441

18a). Spray angle also changed linearly with throttling level, and when the target SMD decreased, the change range

442

decreased. This is associated with the results in Fig. 18 (a), because the gas momentum was enhanced when G

443

became smaller as SMD decreased. Results of this study can help predict the G control range to maintain SMD and

444

spray angle variation. Furthermore, these data will be used to develop a control system for the radial and the annular

445

flows.

446

5. Conclusions

447

In this study, a pintle injector for a 400 N small liquid rocket engine was designed and research was conducted to

448

derive optimal design parameters. The developed pintle injector adopted the continuous slit type to achieve a

449

uniform spray pattern. In addition, the new design concept maintained the concentricity of the pintle rod. The

450

primary focus was the control range of the annular flow’s orifice area. For this, gap distance related to the annular

451

flow’s orifice area was selected as a representative parameter, various down manifolds were fabricated, and spray

452

characteristics were observed by replacing the down manifold at each thrust level. Spray angle was linearly related

453

to the total momentum ratio. As gap distance decreased under a fixed flow rate condition, the annular flow

454

momentum intensified due to the increased annular flow velocity, which in turn decreased the total momentum ratio

455

and narrowed spray angle. A new dimensionless number, which had a high correlation with spray angle throughout

456

the thrust range, was defined by introducing the ratio of outlet height associated with the radial flow’s outlet area to

457

gap distance in the total momentum ratio, and a correlation equation was subsequently developed. The Sauter mean

458

diameter was related to both momentum flux ratio and Weber number. It was also confirmed that momentum flux

459

ratio associated with momentum transfer had a greater effect on droplet formation. From the spray characteristics

460

results, the gap distance control range to maintain a constant Sauter mean diameter over the entire thrust range was

461

calculated based on atomization efficiency. Furthermore, the gap distance was linearly controlled by throttling level.

462

In the future, when spray characteristics are set for a target engine, these results will be of reference to estimate

463

the control range for the annular flow’s orifice size. The procedures and results of this study can be applied to a

464

linear control system for simultaneous control of the orifice sizes for radial and annular flows. Thus, an optimal

465

throttleable pintle injector with high atomization efficiency can be realized.

466

Acknowledgments

467

This work was supported by Advanced Research Center Program (NRF-2013R1A5A1073861) through the

468

National Research Foundation of Korea(NRF) grant funded by the Korea government(MSIP) contracted through

469

Advanced Space Propulsion Research Center at Seoul National University and by the National Research Foundation

470

of Korea(NRF) grant funded by the Korea government(MSIP) (2019M1A3A1A02076963).

471

References

472

[1] M. J. Casiano, J. R. Hulka, V. Yang, Liquid-propellant rocket engine throttling: a comprehensive review, J. Propul. Power,

473 474 475

26 (5) (2010) 897-923. [2] G. A., Dressler, J. M. Bauer, TRW pintle engine heritage and performance characteristics, 36th AIAA/ASME/SAE/ASEE Joint Propulsion Conference & Exhibit, Huntsville, AL, 2000.

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[3] D. T. Harrje, Liquid propellant rocket combustion instability, NASA, NASA-SP-194, 1972.

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[4] E. Seedhouse, SpaceX - making commercial spaceflight a reality, Springer, New York, 2013.

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[5] J. M. Gromski, A. N. Majamaki, S. G. Chianese, V. D. Weinstock, T. S. Kim, Northrop Grumman TR202 LOX/LH2 deep

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throttling engine technology project status," 46th AIAA/ASME/SAE/ASEE Joint Propulsion Conference & Exhibit, Nas

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hville, TN, 2010.

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[6] B. L. Austin, S. D. Heister, W. E. Anderson, Characterization of pintle engine performance for nontoxic hypergolic biprope llants, J. Propul. Power, 21 (4) (2005) 627-635. [7] M. J. Bedard, T. W. Feldman, A. Rettenmaier, W. Anderson, Student design/build/test of a throttleable LOX-LCH4 thrust chamber, 48th AIAA/SAE/ASEE Joint Propulsion Conference & Exhibit, Atlanta, Ga., 2012. [8] R. N. Rezende, A. Pimenta, V. C. Perez, Experiments with pintle injector design and development," 51th AIAA/SAE/ASE E Joint Propulsion Conference, Orlando, FL, 2015. [9] B. B. Vasques, O. J. Haidn, “Effect of pintle injector element geometry on combustion in a liquid oxygen/liquid methane rocket engine, 7th European Conference for Aeronautics and Aerospace Sciences, Milan, Italy, 2017. [10] S. Ninish, A. Vaidyanathan, K. Nandakumar, Spray characteristics of liquid-liquid pintle injector, Exp. Therm. Fluid Sci., 97 (2018) 324-340.

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[11] K. Sakaki, H. Kakudo, S. Nakaya, M. Tsue, H. Isochi, K. Suzuki, K. Makino, T. Hiraiwa, Optical measurements of ethanol/li

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quid oxygen rocket engine combustor with planar pintle injector, 51th AIAA/SAE/ASEE Joint Propulsion Conference,

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Orlando, FL, 2015.

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[12] K. Sakaki, T. Funahashi, S. Nakaya, M. Tsue, R. Kanai, K. Suzuki, T. Inagawa, T. Hiraiwa, Longitudinal combustion instabi lity of a pintle injector for a liquid rocket engine combustor, Combust. Flame, 194 (2018) 115-127. [13] X. Fang, C. Shen, Study on atomization and combustion characteristics of LOX/methane pintle injectors, Acta Astronaut. 136 (2017) 369-379. [14] H. Ryu, I. Yu, T. Kim, Y. Ko, S. Kim, H. Kim, Combustion performance of the canted slit type pintle injector rocket engine by blockage factor, Proceedings of the Korean Society of Propulsion Engineers Conference, Jeju, Korea, 2016. [15] I. Yu, S. Kim, Y. Ko, S. Kim, J. Lee, H. Kim, Combustion performance of a pintle injector rocket engine with canted slit shape by characteristic length and total momentum ratio, J. Korean Soc. Propuls. Eng., 21 (1) (2017) 36-43.

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[16] S. Kim, W. Kim, T. Kim, Y. Ko, S. Kim, H. Kim, Analysis on combustion phenomena by spray pattern of

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canted slit type pintle injector, Proceedings of the Korean Society of Propulsion Engineers Conference, Jeju,

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Korea, 2016.

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[17] M. Son, K. Yu, J. Koo, O. C. Kwon, J. S. Kim, Injection condition effects of a pintle injector for liquid rocket engines on atomization performances, J. ILASS-Korea, 20 (2) (2015) 114-120. [18] M. Son, K. Radhakrishnan, Y. Yoon, J. Koo, Numerical study on the combustion characteristics of a fuel-centered pintle i njector for methane rocket engines, Acta Astronaut. 135 (2017) 139-149. [19] K. Radhakrishnan, M. Son, K. Lee, J. Koo, Lagrangian approach to axisymmetric spray simulation of pintle injector for li quid rocket engines,” Atomization Spray., 28 (5) (2018) 443-458. [20] S. Gordon, B. J. McBride, Computer program for calculation of complex chemical equilibrium compositions and applications Ⅱ. users manual and program description, NASA Reference Publication 1311, E-8017-1, 1996. [21] N. Ashgriz, Handbook of Atomization and Sprays, Springer, New York, 2011.

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[22] S. Lee, J. Koo, Y. Yoon, Technology and developing trends of pintle injector for throttleable engine, J. Korean Soc. Propuls. Eng., 21 (4) (2017) 107-118. [23] R. J. Johnson, B. R. Boyd, T. H. Smith, Application of the Mira 150A variable-thrust engine to manned lunar flying systems, J. Spacecraft Rockets, 5 (7) (1968) 849-851. [24] S. Park, J. Nam, K. Lee, J. Koo, Y. Hwang, Prediction on throttling performance of a movable sleeve injector for deep throttling, J. Korean Society for Aeronautical and Space Sciences, 46 (6) (2018) 487-495. [25] Y. Yoon, H. Koh, D. Kim, T. Khil, Spray visualization using laser diagnostics, J. Korean Society of Visualization, 3 (2) (2005) 3-13. [26] M. Storch, Y. N. Mishra, M. Koegl, E. Kristensson, S. Will, L. Zigan, E. Berrocal, Two-phase SLIPI for instantaneous LIF and Mie imaging of transient fuel sprays, Opt. Lett., 41 (23) (2016) 5422-5425. [27] R. Abu-Gharbieh, J. L. Persson, M. Försth, A. Rosén, A. Karlström, T. Gustavsson, Compensation method for attenuated planar laser images of optically dense sprays, Appl. Optics, 39 (8) (2000) 1260-1267.

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[28] H. L. Arthur, Atomization and sprays, Hemisphere Publishing Corporation, New York, 1989.

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[29] S. Lee, J. Koo, Y. Yoon, Technology and developing trends of pintle injector for throttleable engine, J. Korean

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Soc. Propuls. Eng., 21 (4) (2017) 107-118.

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[30] R. W. Tate, Spray patternation, J. Ind. Eng. Chem., 52 (10) (1960) 49A-58A.

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[31] Y. Cao, The image analysis for optical Spray patternation, M.S. Thesis, Queen’s University, 2000.

531

[32] Х. В. Кесаев,Расчёт форсунок двигателя В.Д.Курпатенков, Publishing House MAI, Moscow, 1987.

Table 1 Specifications of a 400 N engine. Chamber pressure (MPa) Vacuum thrust (N) O/F Chamber diameter (mm) Throttling level (%) Mass flow rate of liquid oxygen (g/s) Mass flow rate of methane (g/s)

1 400 3.44 54 20 to 100 83.4 24.24

Table 2 Range of gap distance (G). ‫ܣ‬௘,௔௡௡௨௟௔௥ (݉݉ଶ ) 185.519 148.252 111.087 73.991 46.414 37.128 26.706 18.177 8.258

Gap distance G (mm) 3.95 3.3 2.6 1.835 1.21 0.986 0.725 0.503 0.234

Fig. 1. Conceptual diagram of a pintle injector.

Fig. 10. Image processing for droplet size measurement.

Fig. 11. Spray images with various throttling levels and gap distances.

Fig. 12. Atomization process.

Fig. 13. Relationship between spray angle and (a) total momentum ratio (
) (b) the new dimensionless number,  =
 ∙ / .

Fig. 14. Spray uniformity based on (a) Patternation Index (PI) and (b) Spray Uniformity Index (SUI).

Fig. 15. Relationship between SMD and: (a) momentum flux ratio (ࡶ) and (b) weber number (ࢃࢋ).

Fig. 16. Relationship between new parameter,
= . ∙ . and .

Fig. 17. Relationship between spray angle and ࡿࡹࡰ.

Fig. 18. Variation ranges (constant ࡿࡹࡰ) of (a) gap distance and (b) spray angle.

Fig. 2. Combustor of the pintle injector [21].

Fig. 3. Multi-hole type pintle geometry [22].

Fig. 4. New concept for maintaining concentricity of a pintle rod.

Fig. 5. Final geometry of the pintle injector; (a) whole view (b) section view.

Fig. 6. Control range with respect to throttling level.

Fig. 7. Schematic of a pintle tip.

Fig. 8. Spray imaging apparatus.

Fig. 9. Spray pattern from the optical patternator with SLIPI.

Highlights • • • • •

New design concept for a pintle injector was introduced to improve uniformity in a 400 N class liquid rocket engine Spray tests helped find the control range of the annular flow’s orifice area An appropriate correlation equation was developed for the parameters The control range was estimated using empirical correlations with respect to the degree of atomization A database for linear control system design was established

Declaration of interests ☒ The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper. ☐The authors declare the following financial interests/personal relationships which may be considered as potential competing interests: