Fractal-Generated Turbulence in Opposed Jet Flows

Geipel, Philipp; Goh, Kok Hin Henry; Lindstedt, R.P.

doi:10.1007/s10494-010-9288-x

Cited by 44 publications

(72 citation statements)

References 36 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The opposed jet configuration (Geipel et al 2010, Goh et al 2013b) was slightly modified (see Fig. 3) to accommodate seeding of the lower nozzle (LN) by a combination of a flame stabilising mesh (FSM) and a flash back arrestor (FBA).…”

Section: Opposed Jet Geometrymentioning

confidence: 99%

“…4) was installed 50 mm upstream the UN exit, featuring a BR of 65% with maximum and minimum bar widths of 2 mm and 0.5 mm (t r = 4). The CFG provides increased multiscale turbulence (Goh et al 2013b, Geipel et al 2010, Goh et al 2013a, Goh et al 2014) compared to conventional perforated plates. Premixed CH 4 -air mixtures with U b,U N = 11.0 ms −1 at T U N = 320 K were injected through the UN at varying equivalence ratio (Φ = 0.20, 0.40, 0.60 and 0.80).…”

Section: Opposed Jet Geometrymentioning

confidence: 99%

“…In summary, the current contribution builds on earlier studies of isothermal and combusting flows in the opposed jet geometry (Geipel et al 2010, Goh et al 2013a, Goh et al 2014, Goh et al 2015 to cover lean premixed flames burning against hot combustion products (Goh et al 2013b). Past studies are extended through the use of fractal grid generated turbulence to quantify the transition from a conventional turbulent flame in the flamelet regime of combustion to a distributed mode using a multi-fluid description.…”

Section: Introductionmentioning

confidence: 98%

“…Despite the use of fractal based analysis techniques, the potential advantages of using fractal grids to generate turbulence in geometries suitable for systematic investigations of turbulent flames is comparatively recent. Geipel et al (2010) systematically investigated the use of fractal cross grids an opposed jet geometry. The study was conducted using Particle Image Velocimetry (PIV) and hot wire anemometry (HWA) to generate velocity statistics and energy spectra in order to assess the potential of such grids.…”

Section: Introductionmentioning

confidence: 99%

“…The opposed jet geometry has been extensively utilised to investigate -laminar as well as turbulent -non-premixed, partial premixed, and premixed combustion and, more recently, combustion regime transitions for aviation fuels (Goh et al 2013b). The configuration has notable advantages for combustion studies (Mastorakos et al 1995, Geyer et al 2005, Geipel et al 2010): (i) excellent optical access for laser-based diagnostic measurements, (ii) accurate experimental control of boundary conditions, (iii) aerodynamic flame stabilisation, rather than via pilot flames, leading to flame dynamics and extinction being related to the inherent aerothermochemistry of the combustion process; and (iv) individual control of variables affecting the chemical and turbulent time-scale. The last two points identify the facility as ideal for investigations of combustion regime transitions.…”

Section: Introductionmentioning

confidence: 99%

See 4 more Smart Citations

Fractal Grid Generated Turbulence—A Bridge to Practical Combustion Applications

Hampp

Lindstedt

2016

Fractal Flow Design: How to Design Bespoke Turbulence and Why

View full text Add to dashboard Cite

Abstract.Practical applications typically feature high turbulent Reynolds numbers and, increasingly, low Damköhler numbers leading to distributed combustion. Such conditions are difficult to achieve on a laboratory scale that permits detailed experimental investigations. The aerodynamically stabilised turbulent opposed jet flame configuration is a case point -an exceptionally flexible canonical geometry traditionally featuring low turbulence levels. Fractal grids can be used to increase the turbulent Reynolds number, without any negative impact on other parameters, and to remove the classical problem of a relatively low ratio of turbulent to bulk strain. The use of fractal grids to ameliorate such problems is exemplified for fuel lean combustion with combustion regime transitions achieved through the stabilisation of turbulent premixed flames against hot combustion products. An analysis is presented in the context of a multi-fluid formalism that extends the customary bimodal pdf approach to include multiple fluid states. The approach is quantified via simultaneous OH-PLIF and PIV, permitting the identification of five separate states (reactant, combustion product, mixing, mildly reacting and flamelet fluids). The sensitivity of the distribution between the fluid states to threshold values is also evaluated. The work suggests that a consistent treatment of the delineating thresholds is necessary when comparing different types of simulations (e.g. DNS) and experiments for reacting fluids with multiple states. The use of fractal grids in a flame driven shock tube provides a further example and is shown to generate turbulent Re numbers of the order 10 5 for flows with Mach numbers approaching unity. The conditions are of relevance to flame stabilisation in hypersonics and are analysed through OH-PLIF and high speed PIV with optimal fractal grids selected on the basis of maximum flame acceleration.

show abstract

Section: Opposed Jet Geometrymentioning

confidence: 99%

Section: Opposed Jet Geometrymentioning

confidence: 99%

Section: Introductionmentioning

confidence: 98%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Fractal Grid Generated Turbulence—A Bridge to Practical Combustion Applications

Hampp

Lindstedt

2016

Fractal Flow Design: How to Design Bespoke Turbulence and Why

View full text Add to dashboard Cite

show abstract

Flow Field Topology of Impinging Jets with Fractal Inserts

Cafiero

Discetti

Astarita

2016

Springer Proceedings in Physics

View full text Add to dashboard Cite

An experimental investigation of the flow field features of a round air jet equipped with a fractal (FG) and a regular (RG) grid insert impinging on a flat surface is carried out by means of 2D-2C Particle Image Velocimetry (PIV). The results are compared to those for a round jet without any grid (JWT). The test Reynolds number is set to 10,000. The average flow fields and the turbulent kinetic energy distributions are presented. In particular, the effect of the presence of the fractal grid on the turbulence intensity distribution and on the planar component of the Reynolds stress is analyzed. Some differences between the location of the maximum of the turbulence intensity profile and the data reported in the literature are found. A possible interaction process between the wakes of the grids and the growing shear layer of the jet might be responsible of this discrepancy. A comparison between the flow field and the heat transfer results obtained by the authors in a previous work is also carried out. What is underlined is that both an higher turbulence level and a much stronger axial velocity cause an increment in the heat transfer rate.

show abstract

Quantification of External Enthalpy Controlled Combustion at Unity Damköhler Number

Hampp

Lindstedt

2018

Energy for Propulsion

View full text Add to dashboard Cite

Fractal-Generated Turbulence in Opposed Jet Flows

Cited by 44 publications

References 36 publications

Fractal Grid Generated Turbulence—A Bridge to Practical Combustion Applications

Fractal Grid Generated Turbulence—A Bridge to Practical Combustion Applications

Flow Field Topology of Impinging Jets with Fractal Inserts

Quantification of External Enthalpy Controlled Combustion at Unity Damköhler Number

Contact Info

Product

Resources

About