The reduction of Earth-to-orbit launch costs in conjunction with an increase in launcher reliability and operational Efficiency is the key demands on future space transportation systems, like single-stage-to-orbit vehicles (SSTO). The realization of these vehicles strongly depends on the performance of the engines, which should deliver high performance with low system complexity. Performance data for rocket engines are practically always lower than the theoretically attainable values because of imperfections in the mixing, combustion, and expansion of the propellants. The main part of the project addresses different nozzle concepts with improvements in performance as compared to conventional nozzles achieved by Different Mach numbers, thus, by minimizing losses caused by over- or under expansion. The design of different nozzle shapes and flow simulation is done in gambit and fluent software’s respectively for various parameter

Akolkar, Vedant

Bhawarker, Yogesh, Mr.

Daware, Digambar, Mr.

Katdare, Prakash

Padalwar, Pallavi

Yadav, Krishna

English

Interscience Research Network

Graduate Research in Engineering and Technology (GRET) Volume 1 Issue 7 Rockets and Missiles Technologies. Article 16 June 2022 Two Dimensional CFD Analysis on Different Rocket Nozzles Yogesh Bhawarker Mr. Department of Aerospace Engineering, Sandip University, SOET, NASHIK, MH, yogeshbhawarker@gmail.com Digambar Daware Mr. Department of Aerospace Engineering Sandip University, digambardaware7@gmail.com Krishna Yadav Department of Aerospace Engineering Sandip University, krishnayadav8433@gmail.com Vedant Akolkar Department of Aerospace Engineering Sandip University, vedantakolkar9511@gmail.com Pallavi Padalwar Department of Aerospace Engineering Sandip University, padalwarpallavi@gmail.com See next page for additional authors Follow this and additional works at: https://www.interscience.in/gret  Part of the Aerodynamics and Fluid Mechanics Commons, Propulsion and Power Commons, and the Space Vehicles Commons Recommended Citation Bhawarker, Yogesh Mr.; Daware, Digambar Mr.; Yadav, Krishna; Akolkar, Vedant; Padalwar, Pallavi; and Katdare, Prakash (2022) "Two Dimensional CFD Analysis on Different Rocket Nozzles," Graduate Research in Engineering and Technology (GRET): Vol. 1: Iss. 7, Article 16. DOI: 10.47893/GRET.2022.1120 Available at: https://www.interscience.in/gret/vol1/iss7/16 This Article is brought to you for free and open access by the Interscience Journals at Interscience Research Network. It has been accepted for inclusion in Graduate Research in Engineering and Technology (GRET) by an authorized editor of Interscience Research Network. For more information, please contact sritampatnaik@gmail.com. Two Dimensional CFD Analysis on Different Rocket Nozzles Authors Yogesh Bhawarker Mr., Digambar Daware Mr., Krishna Yadav, Vedant Akolkar, Pallavi Padalwar, and Prakash Katdare This article is available in Graduate Research in Engineering and Technology (GRET): https://www.interscience.in/gret/vol1/iss7/16 Graduate Research in Engineering and Technology (GRET): An International Journal ISSN 2320 – 6632, Volume-1, Issue-7 61  Two Dimensional CFD Analysis on Different Rocket Nozzles  Yogesh Bhawarker1, Digambar Daware1, Krishna Yadav2, Vedant Akolkar2, Pallavi Padalwar3, Prakash Katdare4   1,2,3Department of Aerospace Engineering, Sandip University, Nashik India 4Department of Mechanical Engineering, Sagar Institute of Research and Technology, Bhopal India Corresponding Author : yogesh.bhawarker@gmail.com      Abstract— The reduction of Earth-to-orbit launch costs in conjunction with an increase in launcher reliability and operational Efficiency is the key demands on future space transportation systems, like single-stage-to-orbit vehicles (SSTO). The realization of these vehicles strongly depends on the performance of the engines, which should deliver high performance with low system complexity.  Performance data for rocket engines are practically always lower than the theoretically attainable values because of imperfections in the mixing, combustion, and expansion of the propellants.  The main part of the project addresses different nozzle concepts with improvements in performance as compared to conventional nozzles achieved by Different Mach numbers, thus, by minimizing losses caused by over- or under expansion.  The design of different nozzle shapes and flow simulation is done in gambit and fluent software’s respectively for various parameters Keywords- CD- Nozzle, Bell shaped Nozzle, pressure, density, velocity. I.  INTRODUCTION A  nozzle  is  a  device  designed  to  control  the  direction  or characteristics  of  a  fluid  flow  (especially  to  increase  velocity) as  it  exits  (or  enters)  an  enclosed  chamber.  A  nozzle  is  often  a pipe  or  tube  of  varying  cross  sectional  area  and  it  can  be  used to  direct  or  modify  the  flow  of  a  fluid  (liquid  or  gas).  Nozzles are  frequently  used  to  control  the  rate  of  flow,  speed, direction,  mass,  shape,  and/or  the  pressure  of  the  stream  that emerges  from  them.  A  jet  exhaust  produces  a  net  thrust  from the  energy  obtained  from  combusting  fuel  which  is  added  to the  inducted  air.  This  hot  air  is  passed  through  a  high  speed nozzle,  a  propelling  nozzle  which  enormously  increases  its kinetic  energy.  The  goal  of  nozzle  is  to  increase  the  kinetic energy  of  the  flowing  medium  at  the  expense  of  its  pressure and  internal  energy.  Nozzles  can  be  described  as  convergent (narrowing  down  from  a  wide  diameter  to  a  smaller  diameter in  the  direction  of  the  flow)  or  divergent  (expanding  from  a smaller  diameter  to  a  larger  one).  A  de  Laval  nozzle  has  a convergent  section  followed  by  a  divergent  section  and  is often  called  a  convergent-divergent  nozzle  ("con-di  nozzle"). Convergent nozzles accelerate subsonic fluids.  If  the  nozzle pressure  ratio  is  high  enough  the  flow  will  reach  sonic velocity  at  the  narrowest  point  (i.e.  the nozzle  throat).  In this situation, the nozzle is said to be choked. II. NOZZLES BASIC REVIEW  A  rocket  nozzle  includes  three  main  elements:  a  converging section,  a  throat,  and  a  diverging  section.  The combustion exhaust gas first enters the converging section.  The  gas  moves at  subsonic  speeds  through  this  area,  accelerating  as  the  cross sectional  area  decreases.  In  order  to  reach  supersonic  speeds, the  gas  must  first  pass  through  an  area  of  minimum  cross sectional  area  called  the  throat.  From  here,  the  supersonic  gas expands  through  the  converging  section  and  then  out  of  the nozzle.  Supersonic flow accelerates as it expands. The following are the features of nozzle, • Nozzle produces thrust.  •  Convert  thermal  energy  of  hot  chamber  gases  into       kinetic energy  and  direct  that  energy  along  nozzle  axis.  •  Exhaust  gases  from  combustion  are  pushed  into  throat region  of  nozzle.  •  Throat  is  smaller  cross-sectional  area  than  rest  of  engine; here  gases  are  compressed  to  high  pressure.  •  Nozzle  gradually  increases  in  cross-sectional  area  allowing gases  to  expand  and  push against  walls  creating  thrust. •  Mathematically,  ultimate  purpose  of  nozzle  is  to  expand gases  as  efficiently  as  possible  so  as  to  maximize  exit velocity. EXPANSION AREA RATIO  Most important parameter in nozzle design is expansion area ratio, e. Fixing other variables (primarily chamber pressure) → only one ratio that optimizes performance for a given altitude (or ambient pressure). However, we have to keep in mind that rocket does not travel at only one altitude, so we should know trajectory to select Graduate Research in Engineering and Technology (GRET): An International Journal ISSN 2320 – 6632, Volume-1, Issue-7 62  expansion ratio that maximizes performance over a range of ambient pressures. Thus variable expansion ratio nozzles are preferred for space travel.  III. WHY NOZZLES ARE USED?  Nozzles are frequently used to control the rate of flow, speed, direction, mass, shape, and/or the pressure of the stream that emerges from them. A jet exhaust produces a net thrust from the energy obtained from combusting fuel which is added to the inducted air. This hot air is passed through a high speed nozzle, a propelling nozzle which enormously increases its kinetic energy. The goal of nozzle is to increase the kinetic energy of the flowing medium at the expense of its pressure and internal energy. Convergent nozzles accelerate subsonic fluids. If the nozzle pressure ratio is high enough the flow will reach sonic velocity at the narrowest point (i.e. the nozzle throat).Convergent nozzles accelerate subsonic fluids. If the nozzle pressure ratio is high enough the flow will reach sonic velocity at the narrowest point (i.e. the nozzle throat).  IV. WORKING OF ROCKET A rocket engine, or simply "rocket", is a jet engine that uses only stored propellant mass for forming its high speed propulsive jet. Rocket engines are reaction engines and obtain thrust in accordance with Newton's third law. Since, they need no external material to form their jet, rocket engines can be used for spacecraft propulsion as well as terrestrial uses, such as missiles. Most rocket engines are internal combustion engines, although non-combusting forms also exist. Rocket engines as a group have the highest exhaust velocities, are by far the lightest, but are the least propellant efficient of all types of jet engines. Rocket technology can combine high thrust (mega Newton’s), very high exhaust speeds (around 10 times the speed of sound in air at sea level) and very high thrust/weight ratios (>100) simultaneously as well as being able to operate outside the atmosphere, and while permitting the use of low pressure and hence lightweight tanks and structure. V. TYPES OF NOZZLES Types of nozzles are several types. They could be based on either speed or shape.  A. Based  on  speed The  basic  types  of  nozzles  can  be  differentiated  as  • Spray nozzles  • Ramjet nozzles  B.  Based  on  shape The  basic  types  of  nozzles  can  be  differentiated  as  • Conical  • Bell  • Annular  CONICAL NOZZLES:  •  Used  in  early  rocket  applications  because  of  simplicity  and ease  of  construction  •  Cone  gets  its  name  from  the  fact  that  the  walls  diverge  at  a constant  angle  •  A small  angle  produces  greater  thrust,  because  it  maximizes the  axial  component  of  exit  velocity  and  produces  a  high specific  impulse  •  Penalty  is  longer  and  heavier  nozzle  that  is  more  complex  to build  •  At  the  other  extreme,  size  and  weight  are  minimized  by  a large  nozzle  wall  angle –  Large  angles  reduce  performance  at  low altitude  because high  ambient  pressure causes  overexpansion  and  flow  separation  • Primary Metric of Characterization:  Divergence Loss  VI. HOW NOZZLES ARE DESIGNED? A rocket engine uses a nozzle to accelerate hot exhaust to produce thrust as described by Newton's third law of motion. The amount of thrust produced by the engine depends on the mass flow rate through the engine, the exit velocity of the flow, and the pressure at the exit of the engine. The value of these three flow variables are all determined by the rocket nozzle design. A nozzle is a relatively simple device, just a specially shaped tube through which hot gases flow. Rockets typically use a fixed convergent section followed by a fixed divergent section for the design of the nozzle. This nozzle configuration is called a convergent-divergent, or CD, nozzle. In a CD rocket nozzle, the hot exhaust leaves the combustion chamber and converges down to the minimum area, or throat, of the nozzle. The throat size is chosen to choke the flow and set the mass flow rate through the system. The flow in the throat is sonic which means the Mach number is equal to one in the throat. Downstream of the throat, the geometry diverges and the flow is isentropically expanded to a supersonic Mach number that depends on the area ratio of the exit to the throat. The expansion of a supersonic flow causes the static pressure and temperature to decrease from the throat to the exit, so the amount of the expansion also determines the exit pressure and temperature. The exit temperature determines the exit speed of sound, which determines the exit velocity. The exit velocity, pressure, and mass flow through the nozzle determine the amount of thrust produced by the nozzle. VII. DIFFERENT TYPES OF SOFTWARE USED We use variety of software to make our work easy, fast and accurate. The software required will be on two categories. They are designing and analysis. Recently we have many types of software for designing. We mainly use three types of software. They are   • CATIA  • Gambit  • ANSYS  VIII. DIMENSIONS AND BOUNDARY CONDITIONS ASSUMED CD Nozzle dimensions and boundary conditions Inlet diameter = 69cm Graduate Research in Engineering and Technology (GRET): An International Journal ISSN 2320 – 6632, Volume-1, Issue-7 63  Exit diameter = 82cm Inlet pressure = 210000 Pa Temperature =   300 K  Bell Nozzle dimensions and boundary conditions Inlet diameter = 48cm Exit diameter = 68 cm  Inlet pressure = 210000 Pa Total temperature = 300K  Double bell Nozzle dimensions and boundary conditions Inlet diameter = 48 cm Exit diameter = 91 cm Inlet pressure = 210000 Pa Total temperature = 300K  Expandable Nozzle dimensions and  boundary conditions Inlet diameter = 69 cm Exit diameter = 100 cm Inlet pressure = 210000 Pa Total temperature = 300 K  APPLYING  BOUNDARY  CONDITIONS   Applying  boundary  conditions  indicate  that  we  need  to  give boundary  conditions  to  each  and  every  face.  For  example,  the inlet  has  to  be  given  certain  conditions  like  inlet  pressure  and inlet  temperature.  Likewise  we  need  to  give  wall  boundary conditions  to  the  top  surface.  Similarly axis condition should be given to  the axis.  IX. THE CFD RESULTS  The  CFD  analysis  of  a  rocket  engine  nozzle  has  been conducted  to  understand  the  phenomena  of  subsonic  flow through  it  at  various  divergent  angles.  A  two  -dimensional axisymmetric  model  is  used  for  the  analysis  and  the  governing equations  were  solved  using  the  finite-volume  method  in ANSYS  FLUENT®  software.  The  variations  in  the parameters  like  the  Mach  number,  static  pressure,  turbulent intensity  are  being  analyzed.  The  phenomena  of  oblique shock  are  visualized  and  the  travel  of  shock  with  divergence angle  is  visualized.  Computational Fluid Dynamics (CFD) is an engineering tool that assists experimentation. Its scope is not limited to fluid dynamics; CFD could be applied to any process which involves transport phenomena with it. To solve an engineering problem we can make use of various methods like the analytical method, experimental methods using prototypes. The analytical method is very complicated and difficult. The experimental methods are very costly. If  any errors in the design were detected during the prototype testing,  another  prototype  is  to  be  made  clarifying  all  the errors  and  again  tested. This is a time-consuming as well as a cost consuming process. Flow instabilities might be created inside the nozzle due to the formation if shocks which reduce the exit Mach number as well as thrust of the engine. This could be eliminated by varying the divergent angle. Here analysis has been conducted on nozzles with divergent angles and thus change in the external diameter 32, 34, 40, 44, 50, 55. Experimentation using the prototypes  of  each  divergent angle  is  a  costly  as  well  as  a  time  consuming  process.  CFD proves to be an efficient tool to overcome these limitations. Here in this work the trend of various flow parameters are also analyzed.    CD  NOZZLE  RESULTS:  Density  Pressure   Velocity      BELL SHAPED NOZZLE RESULT   Graduate Research in Engineering and Technology (GRET): An International Journal ISSN 2320 – 6632, Volume-1, Issue-7 64  Density    Pressure    Velocity  Temperature    CONCLUSION  Because  of  greater  value  for  exit  velocity,  we  can  conclude that  convergent  divergent  nozzle  can  show  better performance  than  bell  nozzle,  dual  bell  nozzle  and expandable  nozzles.  Although  benefits  in  performance  were indicated  in  most  of  the  available  publications,  not  many  of these  nozzle  concepts  has  yet  been  used  in  existing  rocket launchers.  It  is  shown  that  significant  performance  gains results  from  the  adaptation  of  the  exhaust  flow  to  the  ambient pressure.  All  of  the  advanced  nozzle  concepts  have  been  to the  subject  of  analytical  work  and  gave  much  satisfactory results,  but  Convergent  divergent  nozzle  stands  as  best  among the  nozzles  we  analyzed.     REFERENCES  1. Deepak, D, Cornelio, Jodel AQ, Abraham, M Midhun, Prasad, U Shiva, Journal Article: Numerical Analysis of The Effect of Nozzle Geometry on Flow Parameters in Abrasive Water Jet Machines. Pertanika Journal of Science & Technology,V 25,2, 0128-7680, 2017.  2. Mandapudi, Snigdha, Chaganti, Satya Sandeep, Gorle, Swathi, CFD Simulation Of Flow Past Wing Body Junction: A 3-D Approach, International Journal of Mechanical and Production Engineering Research and Development,Volume 7,Issue 4, pp 341-350, 2017, Transstellar Journal Publications and Research Consultancy Private Limited. 3. Prasad, U Shiva, B Ramamohan pai, Yogeesha Pai, Govardhan, D, Praveen, B Design and analysis of two throat wind tunnel, International Journal of Mechanical and Production Engineering Research and Development, V 7, Issue  4,pp 381-388, 2017, Transstellar Journal Publications and Research Consultancy Private Limited  4. www.wikipedia.com/propelling_nozzle  5. www.wikipedia.com/fluid_mechanics 6. www.aerospaceweb.org 

Two Dimensional CFD Analysis on Different Rocket Nozzles

https://www.interscience.in/cgi/viewcontent.cgi?article=1120&context=gret

Two Dimensional CFD Analysis on Different Rocket Nozzles

Abstract

Similar works

Full text

Available Versions

Interscience Research Network