Two-phase Flow

Two phase particle lden jet

The two-phase flow research group aims to improve our current understanding of the interaction between particles (or droplets) and the surrounding fluid through the collaborative use of detailed experimental measurements, advanced numerical simulations and rigorous data analysis.

The development on an enhanced understanding of particle-laden flows is particular relevant as it holds the promise for improvements in a range of industrial applications, including energy generation, mineral processing and pollutant/contaminant dispersion systems.

The two-phase research group is continually looking for potential industrial/research collaborators, as well as potential PhD. students, both locally and globally. If you would like to discuss potential collaboration, please do not hesitate to contact us.

  • Background

    Two-phase flows, and in particular particle-laden flows, are used widely in industry, especially in the field of thermal energy technologies. The distributions of the particles in these systems is not only complex, which makes them difficult to predict reliably, but also has a significant impact on the performance of these reactors (Smith et al. 1998; Smith et al. 2002). New understanding is needed to develop reliable engineering tools to enable them to be optimised.

    2 phase clustered jet

    Important applications include the:

    • design of particle receivers for solar thermal technologies;
    • combustors of pulverised fuel technologies for coal and/or biomass;
    • processing of minerals, such as alumina and cement.

    The research challenge

    All two-phase flow reactors typically transport materials in suspension, with a wide range of particle sizes from sub-microns to sub millimetres under conditions termed 鈥渢wo-way-coupling鈥 in which the flow influences the distribution of particles and the particles influence the flow. Furthermore, the particles tend to 鈥渃luster鈥 in regions of the flow that are related to the underling three-dimensional turbulent structure of the flow (Lau & Nathan 2017), such as in regions of high strain and low vorticity.

    These characteristics make the flows highly complex and computationally intensive to predict, which means that practical design tools must employ models with simplifying assumptions. This, in turn, requires detailed understanding, together with reliable and detailed measurements for the development and validation of computational models. This is best obtained by the combination of multi-dimensional laser diagnostic measurements and computational fluid dynamics modelling.

    What we're doing

    The two-phase research group is actively involved in the fundamental research of multi-phase flows and in the development of innovative technologies in collaboration with partners.

    2 phase cement kiln

    Cement kiln

    • particle-laden turbulent jets issuing from various industrial burner nozzles, including precessing and co-annular jets (Birzer et al. 2009; Birzer et al. 2011; Birzer et al. 2012);
    • the distribution of velocity and orientation of fibrous particles in both a settling flow and a turbulent jet (Qi et al. 2012; Qi et al. 2013; Qi et al. 2014; Qi et al. 2015);
    • well-characterised, particle-laden turbulent jets issuing from a long, round pipe in a co-flow (Lau & Nathan 2013; Lau & Nathan 2014; Lau & Nathan 2016; Lau & Nathan 2017);
    • the flow field within particle-laden, directly irradiated solar vortex reactors (Chinnici et al. 2015, 2017);
    • heat transfer of radiatively heated particles in conditions relevant to concentrated solar thermal systems.

    International collaboration

    The CET is also actively engaged with other researchers globally to develop computational models. This includes:

    • RANS modelling of a densely-seeded pipe and jet flows (Kartushinsky et al. 2010)
    • the development of sub-grid models for Large-Eddy Simulation of particle-laden jets (Jebakumar et al. 2015)
    • .
  • People

    Academic and research staff

    Dr Timothy Lau

    Dr Timothy Lau
    Research Associate

    Expertise:
    Particle-laden flows, fluid mechanics, turbulence, laser diagnostics.

    Professor Gus Nathan

    Professor Gus Nathan
    Professor

    Expertise:
    Two-phase flows, combustion technology, concentrated solar systems.

    Dr Maziar Arjomandi

    Dr Maziar Arjomandi
    Lecturer

    Expertise:
    Fluid mechanics, heat transfer, hybrid technology development.

    Dr Alfonso Chinnici

    Dr Alfonso Chinnici
    Research Associate

    Expertise:
    Computational fluid dynamics, solar thermal systems.

    Dr Woei Saw

    Dr Woei Saw
    Research Associate

    Expertise:
    Solar thermal systems, hybrid technology development.

    Dr Zhao Tian

    Dr Zhao Tian
    Lecturer

    Expertise:
    Computational fluid dynamics, solar hybrid systems.

  • Partners & collaborators

    The two-phase research group actively collaborates with researchers from across the globe. Current collaborators include:

    • , Tallin 最新糖心Vlog of Technology, Estonia;
    • Professor John Abraham, Purdue 最新糖心Vlog, USA;
    • , 最新糖心Vlog of New South Wales, 最新糖心Vlog;
    • Dr Jim Hinkely, CSIRO;
    • , ETH Zurich;
    • , ANU;
    • , Sandia National Laboratories.

    This work is supported by:

    • The 最新糖心Vlogn Research Council, through the ARC Discovery and Linkage grants schemes;
    • ARENA, through its 最新糖心Vlog-USA collaborations program and through the 最新糖心Vlogn Solar Thermal Research Initiative.
  • Facilities & equipment

    The research facilities for the study of multi-phase flows include a dedicated and globally-unique laser-laboratory with a wind tunnel, laser diagnostic facilities and particle handling equipment. Key facilities include:

    Two phase optical train

    Optical train

    • Specialised two-phase flow facilities including particle handling and extraction systems;
    • Wind and water tunnels for flow visualisation and fluid mechanics;
    • A range of scientific lasers, including pulsed Nd:YAG lasers, a CO2 laser, and a specialised laser developed for the heating of particles;
    • Hot-wire anemometry, including post-processing of velocity measurements to obtain derived quantities of turbulence;
    • Simultaneous diagnostics, able to couple measurements of temperature, velocity, particle concentration;
    • Specialised optics and detectors, such as Intensified CCD cameras and high-speed visualisation;
    • Expertise in most current laser techniques, including:
    • Particle Image Velocimetry (PIV)
    • Laser Doppler Velocimetry (LDV)
    • Planar Nephelometry
    • Laser Sheet Drop-sizing (LSD)
    • Planar Laser Induced Fluorescence (PLIF)
    • Two-colour Phosphor Thermometry
    • In-house image processing, post-processing and data analysis, including capability to extract derived quantities, such as particle cluster dimensions, from planar measurements.

    These facilities have been established with the support of the 最新糖心Vlogn Research Council.

  • Expertise

    The CET has expertise in the following multi-phase fields:

    Cement kiln

    Cement kiln

    • Detailed investigation of turbulent particle-laden jets issuing from well characterised jets under conditions of relevance to industrial nozzles used in kilns, furnaces, burners, solar receivers etc. (Lau & Nathan 2013; Lau & Nathan 2014; Lau & Nathan 2016a; Lau & Nathan 2016b);
    • Flows utilising fibrous particles, of relevance to applications involving biomass听 combustion and gasification (Qi et al. 2012; Qi et al. 2013; Qi et al. 2014; Qi et al. 2015);
    • Air pollution control, including the听 mitigation of fine particulate emission;
    • Development of practical devices for application in kilns, boilers and furnaces, notably the patented Precessing Jet technology, which听 is commercially available as the Gyrotherm庐 kiln burner (Nathan & Manias 1995; Nathan et al. 2006)
    • Development of novel particle receivers for the solar thermal energy technologies ();
    • Development and validation of Computational Fluid Dynamics models of particle-laden flows (Jebakumar et al. 2015).
  • Research projects

    A Fundamental Study of Well-Characterised Particle-Laden Jets

    A long-term programme within the two-phase research group involves the fundamental study of a well-characterised particle-laden turbulent jet issuing from a long, round pipe (see Figure 1).

    Figure 1: Typical experimental arrangement for current measurements in particle-laden jets (from Birzer et al. 2011)

    Figure 1: Typical experimental arrangement for current measurements in particle-laden jets (from Birzer et al. 2011)

    This experiment was carefully designed to provide well-defined and well-characterised in-flow and boundary conditions to make the experiment well suited to the validation of numerical models as well as to provide new understanding in their own right.听 For this reason, systematic measurements are performed with a range of mono-dispersed distributions of particles, different pipe dimensions and different flow velocities using measurements with high spatial resolution.

    A fundamental study of well-characterised particle-laden jets.

    Characterisation of particle clusters within a turbulent flow

    One key phenomenon in turbulent two-phase flows is the instantaneous preferential concentration, or clustering, of particles within the flow. This phenomenon is of high relevance as it not only affects the mean and instantaneous two-phase flow, but may also significantly impact chemical reactions and thermal performance in reacting flows. However, the current state of understanding of particle clustering is limited, in large part due to the difficulty in identifying and analysing these clusters. This project involves the detailed study of these clusters within a particle-laden turbulent jet.

    The first part of the project is the development of a robust and consistent method to identify and characterise particle clusters. The two-phase research group has developed a novel method to accomplish this by utilising planar measurements of particle concentration (planar nephelometry) in combination with sophisticated image processing techniques (Lau & Nathan 2017).

    Characterisation of particle clusters within a turbulent flow.

    The study of the flow and heat transfer within a particle-laden solar vortex reactor

    Figure 3: Example of a solar vortex generator (from Hirsch & Steinfeld, International Journal of Hydrogen Energy, 2004).

    Figure 3: Example of a solar vortex generator (from Hirsch & Steinfeld, International Journal of Hydrogen Energy, 2004).

    Concentrated solar thermal (CST) systems are gaining popularity in industrial processes due to their low emissions, high efficiencies, their ability to generate the high temperatures necessary for efficient plant operation, as well as their potential to hybridise with existing conventional thermal plants. While there are a range of different types of CST reactors in existence, one recently proposed configuration utilises solid particles to improve solar radiation absorption (see Figure 3). However, the performance of this configuration is currently limited due to our poor understanding of the two-phase flow within the reactor, and in particular, the phenomenon of particle deposition onto the window of the device, which reduces thermal performance.

    This project seeks to develop and optimise the design of solar vortex reactors, with a particular aim of understanding the particle-laden flow within the reactor and reducing particle deposition on the window. This project will involve the study of a range of different configurations of solar vortex reactors through the use of cutting-edge experimental measurements and computational fluid dynamics modelling.

  • Research data

    Particle-laden turbulent pipe jet in uniform co-flow

    Detailed experiments were conducted on a mono-disperse, particle-laden turbulent jet issuing from a long, vertically mounted pipe, into a weak co-flow. Simultaneous planar measurements of the particle-phase concentration and velocity, as well as measurements of the single-phase (un-laden) jet were conducted whereby the Stokes number was systematically varied from SkD = 0.3 to 22.4.

    Schematic diagram of particle-laden turbulent pipe jet in weak co-flow.

    Schematic diagram of particle-laden turbulent pipe jet in weak co-flow.

    2 phase data summary

    Summary of the data provided

    Particle-laden Turbulent Jet (Mean Flow) Lau & Nathan 2014

    Key experimental parameters

    • Pipe diameter, D = 12.7mm
    • Pipe length, L = 2080mm
    • Jet Reynolds number, ReD = 10K and 20K
    • Jet-to-co-flow velocity ratio = 12.0
    • Particle diameter, dp = 10, 20 and 40 micron
    • Particle mass loading, 桅 = 0.4
    • Particle density, 蟻p = 1200 kg/m3
    • Particle Stokes number, SkD = 0.3, 1.4 and 11.2

    Key data provided

    Simultaneous measurements of particle concentration and particle velocity (mean and r.m.s.) at the pipe exit and along the centreline.

    (Lau, T. C. W., & Nathan, G. J. (2014). The influence of Stokes number on the velocity and concentration distributions in particle-laden jets. Journal of Fluid Mechanics 757, 432-457)

    Full data set, downloadable spreadsheet

    Particle-laden Turbulent Jet (Mean and R.M.S.) Lau & Nathan 2016

    Key experimental parameters

    Pipe diameter, D = 12.7mm
    Pipe length, L = 2080mm
    Jet Reynolds number, ReD = 10K, 20K and 40K
    Jet-to-co-flow velocity ratio = 12.0
    Particle diameter, dp = 10, 20 and 40 micron
    Particle mass loading, 桅 = 0.4
    Particle density, 蟻p = 1200 kg/m3
    Particle Stokes number, SkD = 0.3, 1.4, 2.8, 5.6, 11.2 and 22.4

    Key data provided

    Comprehensive dataset consisting of simultaneous measurements of particle concentration and particle velocity (mean and r.m.s.) at the pipe exit, along the centreline and at two axial stations x/D = 10 & x/D = 30

    (Lau, T. C. W., & Nathan, G. J. (2016). The effect of Stokes number on particle velocity and concentration distributions in a well-characterised, turbulent, co-flowing two-phase jet. Journal of Fluid Mechanics, 809, 72-110)
    Full data set, downloadable spreadsheet

    If you require further information please see the Contact us section.

  • List of publications

    Listed below are the recent publications arising out of the two-phase research group.

    Direct links to the published articles (via digital object identifiers, DOIs), or where available, accepted versions of manuscripts, can be found by clicking the hyperlinks below.

    Journal articles

    1. Lau, T. C. W.; Nathan, G. J. (in press); The e铿ect of Stokes number on particle velocity and concentration distributions in a well-characterised, turbulent, co-铿俹wing two-phase jet Journal of Fluid Mechanics
    2. Lau, T. C. W.; Nathan, G. J. (2016a); Int. J. Multiphase Flow, doi:
    3. Cheong, M.; Birzer, C.; Lau, T. C. W.;听
      s听Experimental Techniques, 2015; 1-9
    4. Qi, G.; Nathan, G. J.; Lau, T. C. W.听
      听Powder Technology, 2015; 276:10-17
    5. Jebakumar, A. S.; Premnath, K. N.; 听Abraham, J.;
      听Computers & Fluids, 2015.
    6. Lau, T. C. W.; Nathan, G. J.
      听Journal of Fluid Mechanics, 2014; 757:435-457
    7. Qi, G. Q.; Nathan, G. J.; Kelso, R. M.; Powder Technology, 2014; 257:192-197
    8. Qi, G. Q.; Nathan, G. J.; Kelso, R. M.; Powder Technology, 2013; 235:550-555
    9. Birzer C. H.; Kalt, P. A. M.; Nathan, G. J.
      听International Journal of Multiphase Flow, 2012; 41:13-22
    10. Qi, G. Q.; Nathan, G. J.; Kelso, R. M.; Powder Technology, 2012; 229:261-269
    11. Birzer C. H.; Kalt, P. A. M.; Nathan, G. J. Experiments in Fluids, 2011; 51:641-656
    12. Birzer C. H.; Kalt, P. A. M.; Nathan, G. J. 听International Journal of Multiphase Flow, 2011; 37:394-402
    13. Kartushinsky, A.; Michaelides, E. E.; Rudi, Y.; Nathan, G. J.; modelling of a particular turbulent round jet听Chemical Engineering Science, 2010; 65:3384-3393
    14. Foreman, R. J.; Nathan, G. J.; 听International Journal of Multiphase Flow, 2009; 35:96-100
    15. Birzer C. H.; Kalt, P. A. M.; Nathan, G. J. 听International Journal of Multiphase Flow, 2009; 35:288-296
    16. Kalt, P. A. M.; Nathan, G. J. 听Applied Optics, 2007; 46: 7227-7236
    17. Kalt, P. A. M.; Birzer C. H.; Nathan, G. J. 听Applied Optics, 2007; 46: 5823-5834
    18. Nathan, G. J.; Mi, J.; Alwahabi, Z.; Newbold, G. R. J; Nobes, D. S. 听Progress in Energy and Combustion Science, 2006; 32: 496-538
    19. Smith, N.L.; Nathan, G.J.; Zhang, D.K.; Nobes, D.S.; 听29th Symposium (International) on Combustion, 2002
    20. Smith, N. L., Megalos, N. P., Nathan, G. J., Zhang, D. K., & Smart, J. P.; Fuel, 1998, 77: 1013-1016
    21. Nathan, G. J; Manias, C. G.; 听Combustion Emission Control, 1995; 309-312

    Conference papers

    1. Lau, T. C. W.; Nathan, G. J.; Proceedings of the 7th 最新糖心Vlogn Conference on Laser Diagnostics in Fluid Mechanics and Combustion, Melbourne, 最新糖心Vlog, 9-11 Dec 2015
    2. Chinnici, A., Xue, Y., Lau, T. C. W., Arjomandi, M., Nathan, G. J.; Proceedings of the 7th 最新糖心Vlogn Conference on Laser Diagnostics in Fluid Mechanics and Combustion, Melbourne, 最新糖心Vlog, 9-11 Dec 2015
    3. Saridakis, I. J.; Lau, T. C. W., Djenidi, L.; Nathan, G. J. 听Proceedings of the 19th Australasian Fluid Mechanics Conference, 8-11 December 2014, Melbourne
    4. Nathan, G. J.; Alwahabi, Z.; Dally, B. B.; Medwell, P. R.; Arjomandi, M.; Sun, Z. W.; Lau, T. C. W.; Van Eyk, P. 听Optical Instrumentation for Energy and Environmental Applications, E2 2014. Optical Society of America (OSA). 25 Nov 2014
    5. Lau, T. C. W.; Nathan, G. J.; Proceedings of the 4th International Conference on Jets, Wakes and Separated Flows, Nagoya, Japan, 17-21 Sep 2013
    6. Cheong, M.; Birzer, C. H.; Lau, T. C. W. 听Proceedings: the 7th Australasian Congress on Applied Mechanics (ACAM 7), 9-12 December 2012, Adelaide: pp.808-816
    7. Cheong, M.; Birzer, C. H.; Lau, T.听C. W. 听Proceedings of the 18th Australasian Fluid Mechanics Conference, 3-7 Dec 2012, Lauceston, Tasmania, 最新糖心Vlog / P. A. Brandner and B. W. Pearce (eds.), 4 p.
    8. Birzer C. H.; Kalt, P. A. M.; Nathan, G. J. 听The 最新糖心Vlogn Combustion Symposium, 2011, The 最新糖心Vlog of Newcastle
    9. Birzer C. H.; Kalt, P. A. M.; Nathan, G. J. 听The 最新糖心Vlogn Conference on Laser Diagnostics in Fluid Mechanics and Combustion, 2011, The 最新糖心Vlog of New South Wales
    10. Birzer C. H.; Kalt, P. A. M.; Nathan, G. J. 听Proceedings of the 17th Australasian Fluid Mechanics Conference, 2010, Auckland
    11. Birzer C. H.; Kalt, P. A. M.; Nathan, G. J. 听The 最新糖心Vlogn Combustion Symposium, 2009, Brisbane
    12. Birzer C. H.; Kalt, P. A. M.; Nathan, G. J. 听11th International Conference in Multiphase Flows in Industrial, 2008, Palermo, Italy
    13. Birzer C. H.; Kalt, P. A. M.; Nathan, G. J. 听Fifth 最新糖心Vlogn Conference on Laser Diagnostics in Fluid Mechanics and Combustion, 2008, The 最新糖心Vlog of Western 最新糖心Vlog
    14. Birzer C. H.; Kalt, P. A. M.; Nathan, G. J.; Smith, N. L. 听Fifth Asia-Pacific Conference on Combustion, 2005, The 最新糖心Vlog of Adelaide
    15. Birzer C. H.; Kalt, P. A. M.; Smith, N. L.; Nathan, G. J. 听Fourth 最新糖心Vlogn Conference on Laser Diagnostics in Fluid Mechanics and Combustion, 2005, The 最新糖心Vlog of Adelaide
    16. Birzer C. H.; Kalt, P. A. M.; Nathan, G. J.; Smith, N. L. 听5th Australasian Fluid Mechanics Conference, 2004, The 最新糖心Vlog of Sydney
    17. Nathan, G.J.; Smith, N.L.; Mullinger, P.J.; Smart, J.P.; 听5th International Conference on Industrial Furnaces and Boilers (INFUB), 11-14 April 2000, Portugal
    18. Smith, N.L.; Megalos, N.P.; Nathan, G.J.; Zhang, D.K.; Smart, J.P.; 听27th Symposium (International) on Combustion, 1998
  • Contact us

    For enquiries regarding data

    Dr. Timothy Lau
    Centre for Energy Technology
    School of Mechanical Engineering,
    The 最新糖心Vlog of Adelaide
    SA 5005 最新糖心Vlog
    timothy.lau@adelaide.edu.au
    Phone: +61 8313 3960

    For enquiries regarding collaborative work

    Prof. Graham 鈥楪us鈥 Nathan
    Centre for Energy Technology
    School of Mechanical Engineering,
    The 最新糖心Vlog of Adelaide
    SA 5005 最新糖心Vlog
    graham.nathan@adelaide.edu.au
    Phone: +61 8313 5822