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Journal Articles
Article Type: Research Papers
J. Energy Resour. Technol. June 2023, 145(6): 062304.
Paper No: JERT-22-1766
Published Online: January 31, 2023
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in An Investigation of the Impact of Combustion Chamber Geometry on Turbulent Burning Speeds in a Thermodynamic Model
> Journal of Energy Resources Technology
Published Online: January 31, 2023
Fig. 1 Research engine and experimental setup More
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in An Investigation of the Impact of Combustion Chamber Geometry on Turbulent Burning Speeds in a Thermodynamic Model
> Journal of Energy Resources Technology
Published Online: January 31, 2023
Fig. 2 Produced combustion chamber geometries: cylindrical bowl (left), MR (center), and flat (right) More
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in An Investigation of the Impact of Combustion Chamber Geometry on Turbulent Burning Speeds in a Thermodynamic Model
> Journal of Energy Resources Technology
Published Online: January 31, 2023
Fig. 3 Schematic illustration of heat release rate calculation according to Rassweiler–Withrow approach More
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in An Investigation of the Impact of Combustion Chamber Geometry on Turbulent Burning Speeds in a Thermodynamic Model
> Journal of Energy Resources Technology
Published Online: January 31, 2023
Fig. 4 Schematic illustration of calculation sub-steps related to a thermodynamic model More
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in An Investigation of the Impact of Combustion Chamber Geometry on Turbulent Burning Speeds in a Thermodynamic Model
> Journal of Energy Resources Technology
Published Online: January 31, 2023
Fig. 5 Cylinder pressures related to different combustion chamber designs More
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in An Investigation of the Impact of Combustion Chamber Geometry on Turbulent Burning Speeds in a Thermodynamic Model
> Journal of Energy Resources Technology
Published Online: January 31, 2023
Fig. 6 Heat release rate in relation to different combustion chamber designs More
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in An Investigation of the Impact of Combustion Chamber Geometry on Turbulent Burning Speeds in a Thermodynamic Model
> Journal of Energy Resources Technology
Published Online: January 31, 2023
Fig. 7 Calculated flame front radius with the help of the thermodynamic model More
Image
in An Investigation of the Impact of Combustion Chamber Geometry on Turbulent Burning Speeds in a Thermodynamic Model
> Journal of Energy Resources Technology
Published Online: January 31, 2023
Fig. 8 Calculated flame propagation speeds in relation to different designs More
Image
in An Investigation of the Impact of Combustion Chamber Geometry on Turbulent Burning Speeds in a Thermodynamic Model
> Journal of Energy Resources Technology
Published Online: January 31, 2023
Fig. 9 Change in turbulent burning speed according to combustion chamber geometry More
Image
in An Investigation of the Impact of Combustion Chamber Geometry on Turbulent Burning Speeds in a Thermodynamic Model
> Journal of Energy Resources Technology
Published Online: January 31, 2023
Fig. 10 Change in turbulent burning speed as depending on flame radius More
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in An Investigation of the Impact of Combustion Chamber Geometry on Turbulent Burning Speeds in a Thermodynamic Model
> Journal of Energy Resources Technology
Published Online: January 31, 2023
Fig. 11 Impact of combustion chamber design on speed ratio ( S T / S L ) More
Journal Articles
Article Type: Research Papers
J. Energy Resour. Technol. June 2023, 145(6): 063202.
Paper No: JERT-22-1491
Published Online: January 31, 2023
Journal Articles
Accepted Manuscript
Article Type: Research Papers
J. Energy Resour. Technol.
Paper No: JERT-22-1567
Published Online: January 31, 2023
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in Numerical Study of Composite Percussive Drilling With Consideration of Heat Transfer Between Drilling Fluid and Bottom-Hole Rock in Geothermal Drilling
> Journal of Energy Resources Technology
Published Online: January 31, 2023
Fig. 1 Physical model More
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in Numerical Study of Composite Percussive Drilling With Consideration of Heat Transfer Between Drilling Fluid and Bottom-Hole Rock in Geothermal Drilling
> Journal of Energy Resources Technology
Published Online: January 31, 2023
Fig. 2 Rock stress distributions under the coupling action of axial percussion, torsional percussion, and heat transfer More
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in Numerical Study of Composite Percussive Drilling With Consideration of Heat Transfer Between Drilling Fluid and Bottom-Hole Rock in Geothermal Drilling
> Journal of Energy Resources Technology
Published Online: January 31, 2023
Fig. 3 ( a ) Relationship between axial force and time at various temperatures and ( b ) relationship between the bit torque and time at various temperatures More
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in Numerical Study of Composite Percussive Drilling With Consideration of Heat Transfer Between Drilling Fluid and Bottom-Hole Rock in Geothermal Drilling
> Journal of Energy Resources Technology
Published Online: January 31, 2023
Fig. 4 ( a ) Curves of the axial force versus penetration at various temperatures and ( b ) curves of the torque and the rotating angle at various temperatures More
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in Numerical Study of Composite Percussive Drilling With Consideration of Heat Transfer Between Drilling Fluid and Bottom-Hole Rock in Geothermal Drilling
> Journal of Energy Resources Technology
Published Online: January 31, 2023
Fig. 5 Effects of rock temperature on energy transferring efficiency under the composite percussion More
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in Numerical Study of Composite Percussive Drilling With Consideration of Heat Transfer Between Drilling Fluid and Bottom-Hole Rock in Geothermal Drilling
> Journal of Energy Resources Technology
Published Online: January 31, 2023
Fig. 6 Damage fragmentation characteristics of rocks at various temperatures More
