daisuke shimokuri

Last Updated :2025/04/03

Affiliations, Positions
Graduate School of Advanced Science and Engineering, Associate Professor
E-mail
crihiroshima-u.ac.jp
Other Contact Details
Japan
TEL : (+81)82-424-7647 FAX : (+81)82-424-7647

Basic Information

Academic Degrees

  • Doctor of Engineering, Hiroshima University
  • Master of Engineering, Hiroshima University

Research Fields

  • Engineering;Mechanical engineering;Thermal engineering

Educational Activity

Course in Charge

  1. 2025, Liberal Arts Education Program1, 2Term, Fuel, Combustion, and Contemporary Society
  2. 2025, Undergraduate Education, 3Term, Practice of Mechanics
  3. 2025, Undergraduate Education, First Semester, Experiments in Mechanical Engineering I
  4. 2025, Undergraduate Education, 1Term, Combustion Engineering Fundamentals
  5. 2025, Undergraduate Education, Year, Graduation Thesis
  6. 2025, Graduate Education (Master's Program) , 1Term, Special Exercises on Mechanical Engineering A
  7. 2025, Graduate Education (Master's Program) , 2Term, Special Exercises on Mechanical Engineering A
  8. 2025, Graduate Education (Master's Program) , 3Term, Special Exercises on Mechanical Engineering B
  9. 2025, Graduate Education (Master's Program) , 4Term, Special Exercises on Mechanical Engineering B
  10. 2025, Graduate Education (Master's Program) , Academic Year, Special Study on Mechanical Engineering
  11. 2025, Graduate Education (Master's Program) , 2Term, Combustion
  12. 2025, Graduate Education (Doctoral Program) , Academic Year, Special Study on Mechanical Engineering
  13. 2025, Graduate Education (Doctoral Program) , Academic Year, Special Study on Mechanical Engineering

Research Activities

Academic Papers

  1. Analysis of flame detection data from multiple-ion probes using feature extraction, JOURNAL OF THERMAL SCIENCE AND TECHNOLOGY, 17(3), 2022
    Link to Paper Search Results by DOI
  2. Development of Detailed Surface Reaction Mechanism of C2H4/C(3)H(6)Oxidation on Pt/Al(2)O(3)Monolith Catalyst Based on Gas Phase and Surface Species Analyses, COMBUSTION SCIENCE AND TECHNOLOGY, 194(7), 1458-1480, 20220519
    Link to Paper Search Results by DOI
  3. NOx emission characteristics and aerodynamic structure of a self-recirculation type burner for small boilers, PROCEEDINGS OF THE COMBUSTION INSTITUTE, 33, 2735-2742, 2011
    Link to Paper Search Results by DOI
  4. Flame propagation in a vortex flow within small-diameter tubes, PROCEEDINGS OF THE COMBUSTION INSTITUTE, 33, 3251-3258, 2011
    Link to Paper Search Results by DOI
  5. Flame Stabilization with a Tubular Flame, PROCEEDINGS OF THE COMBUSTION INSTITUTE, 30, 399-466, 20050101
  6. Flow Field in Swirl-Type Tubular Flame Burner, JSME International Journal= Series B, 48(4), 20051101
  7. Rapidly-Mixed Combustion in a Tubular Flame Burner, International symposium on combustion, 31, 20060401
  8. PIV Measurements on a 2-inch Tubular Flame Burner, Proceedings of the Sixth Asia-Pacific Conference on Combustion, 154-157, 20070501
  9. Flow Field of Turbulent Premixed Combustion in a Cyclone-Jet Combustor34, Journal of Thermal Science and Technology, 2(1), 90-101, 20070101
  10. An Experimental Study on the Flame Propagation Due to Vortex Bursting in a Small Diameter Tube, 76(764), 675-683, 20100401
  11. Flow field in swirl-type tubular flame burner, JSME INTERNATIONAL JOURNAL SERIES B-FLUIDS AND THERMAL ENGINEERING, 48(4), 830-838, 200511
    Link to Paper Search Results by DOI
  12. Further investigation on the enhancement of flame speed in vortex ring combustion, PROCEEDINGS OF THE COMBUSTION INSTITUTE, 34, 745-753, 2013
    Link to Paper Search Results by DOI
  13. Methane/oxygen combustion in a rapidly mixed type tubular flame burner, PROCEEDINGS OF THE COMBUSTION INSTITUTE, 34, 3369-3377, 2013
    Link to Paper Search Results by DOI
  14. Effects of inert gases on the vortex bursting in small diameter tubes, PROCEEDINGS OF THE COMBUSTION INSTITUTE, 34, 3403-3410, 2013
    Link to Paper Search Results by DOI
  15. Reexamination on methane/oxygen combustion in a rapidly mixed type tubular flame burner, COMBUSTION AND FLAME, 161(5), 1310-1325, 201405
    Link to Paper Search Results by DOI
  16. An experimental study on the high frequency oscillatory combustion in tubular flame burners, COMBUSTION AND FLAME, 161(8), 2025-2037, 201408
    Link to Paper Search Results by DOI
  17. Fundamental investigation on the Fuel-NOx emission of the oxy-fuel combustion with a tubular flame burner, PROCEEDINGS OF THE COMBUSTION INSTITUTE, 35, 3573-3580, 2015
    Link to Paper Search Results by DOI
  18. Effects of the Air - Fuel Injection Velocity Ratio on the Emission Characteristics of the Rapidly Mixed Tubular Flame, Journal of the combustion sciety of Japan, 57(179), 52-59, 2015
  19. An experimental study on a new heating technique with use of an inner hot gas region of tubular flames, Journal of the combustion society of Japan, 57(179), 71-81, 2015
  20. ★, Development of a small-scale power system with meso-scale vortex combustor and thermo-electric device, Journal of Micromechanics and Microengineering, 25, 104004-104011, 2015
    Link to Paper Search Results by DOI
  21. An Experimental Study on the Flame Structure Control in a Rapidly Mixed Type Tubular Flame Burner, Transactions of the Japane Society of Mechanical Engineering, 78(785), 185-193, 2012
    Link to Paper Search Results by DOI
  22. Further reduction in NOx Emission of Self-recirculation Type Burners by Cooling of the Recirculating Gas, Journal of the Combustion Society of Japan, 53(164), 104-110, 2011
  23. Flame behaviro in vortex flows, Journal of Gas Turbine Society of Japan, 44(2), 15-21, 20160301
  24. Development of a powerful miniature power system with a meso-scale vortex combustor, PROCEEDINGS OF THE COMBUSTION INSTITUTE, 36(3), 4253-4260, 2017
    Link to Paper Search Results by DOI
  25. An experimental study on the ignition ability of a laser-induced gaseous breakdown, COMBUSTION AND FLAME, 178, 1-6, 201704
    Link to Paper Search Results by DOI
  26. Comparative study of laser ignition and spark-plug ignition in high-speed flows, COMBUSTION AND FLAME, 191, 408-416, 201805
    Link to Paper Search Results by DOI
  27. Laser Measurement on Oxy-fuel Flame with Optically Accessible Tubular Flame Burner, Journal of Japanese Society for Experimental Mechanics, 17(3), 204-209, 201709
  28. Experimental study on self-acceleration in expanding spherical hydrogen-air flames, INTERNATIONAL JOURNAL OF HYDROGEN ENERGY, 43(27), 12556-12564, 20180705
    Link to Paper Search Results by DOI
  29. Tubular Flame Combustion for Nanoparticle Production, INDUSTRIAL & ENGINEERING CHEMISTRY RESEARCH, 58(17), 7193-7199, 20190501
    Link to Paper Search Results by DOI
  30. ★, Measurement and Numerical Simulation on the Ignition Delay Times of Nonane (C9H20) Isomers, Journal of the Combustion Society of Japan, 62(199), 64-73, 20200201
    Link to Paper Search Results by DOI
  31. Deflagration-to-detonation transition in laser-ignited explosive gas contained in a smooth-wall tube, COMBUSTION AND FLAME, 219, 275-282, 202009
    Link to Paper Search Results by DOI
  32. Measurements and simulations of ignition delay times and laminar flame speeds of nonane isomers, COMBUSTION AND FLAME, 227, 283-295, 202105
    Link to Paper Search Results by DOI
  33. Development of Surface Reaction Mechanisms of CO/O-2 on Pt and Rh for Three-Way Catalyst based on Gas Phase and Surface Species Analyses, COMBUSTION SCIENCE AND TECHNOLOGY, 193(12), 2137-2157, 20210910
    Link to Paper Search Results by DOI
  34. Direct spray combustion in a tubular flame burner toward fine particle synthesis, JOURNAL OF THERMAL SCIENCE AND TECHNOLOGY, 16(3), 2021
    Link to Paper Search Results by DOI
  35. Sinter-Necked, Mixed Nanoparticles of Metallic Tungsten and Tungsten Oxide Produced in Fuel-Rich Methane/Air Tubular Flames, JOURNAL OF CHEMICAL ENGINEERING OF JAPAN, 54(10), 557-565, 202110
    Link to Paper Search Results by DOI

Publications such as books

  1. 2014/04, Tubular Combustion, tubular flame, Momentum press, 2014, 04, Scholarly Book, Joint work, English, 1606503030, Chapter 7
    Amazon URL

Invited Lecture, Oral Presentation, Poster Presentation

  1. Development of Detailed Surface Reaction Database for TWC Based on Gas Phase and Surface Species Analyses, Daisuke SHIMOKURI, Hiroshi Murakami, Yuhei Matsumoto,Satoshi Hinokuma, Naoki Ishimoto, Daisuke Moriyama, Yusuke Kozai, Hitoshi Hongou, Hideaki Yokohata and Hiroyuki Takebayashi, The 9th international conference on modeling and diagnostics for advanced engine systems, 2017/07/30, Without Invitation, English, The Japan Society of Mechanical Engineers, Okayama, In this study, a detailed chemical kinetic database of NO/ CO/ O2 surface reaction on Rh/ Al2O3 has been constructed based on the measurements of gaseous / surface species. The gaseous species at the upstream and downstream of the monolithic catalyst were identified by FTIR, while the surface species on the powder catalyst were directly measured by FTIR. Based on those experimental results, detailed surface reaction kinetic database has been constructed. As the result of numerical simulation with 1-D code, it was confirmed that the gaseous conversion rates of NO and CO were quantitatively reproduced with the database.
    Related URL
  2. Autonomous Power System Using Small Scale Vortex Combustor, Daisuke SHIMOKURI, Power MEMS 2017, 2017/11/14, With Invitation, English, Power MEMS, KANAZAWA, Micro and meso scale combustors have attracted considerable attention as one of energy conversion media of liquid (or liquefied) hydrocarbon fuels which possess almost 100 times larger energy density than the conventional batteries. Then, in this decade, combustion characteristics in micro and meso scale channels have been extensively studied fundamentally and practically. Based on the obtained knowledge, micro combustion power systems aimed practical use have appeared. Currently, the miniature combustion power system using vortex combustor combined with thermos electric device (TED) is the most powerful system which output attained 18.1W and conversion efficiency 3.0% with 600W thermal input by propane air mixture. As a final step, prototype “autonomous” vortex combustion power system to charge the mobile electrical devices has developed. Using 250g butane cartridge, 10W output can be obtained over 5 hours with running all assisting devices such as micro blower for the combustion air or fans for cooling air of TED.

Awards

  1. 2009/05/26, The Young Investigator Prize, 6th Asia-Pacific Conference on Combustion, Conference Chair, For the paper:PIV Measurements on a 2-inch Tubular Flame Burner

External Funds

Acceptance Results of Competitive Funds

  1. 2011, 2012
  2. KAKENHI, Realization of a ultra low NOx burner with using continuously varying multi-step combustion and self-recirculation, 2011, 2012
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  3. KAKENHI, Fundamental study on thevortex bursting phenomena in small diameter tubes, 2011, 2012
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  4. 2012, 2013
  5. 2014, 2015
  6. 2014, 2015
  7. 2015, 2017
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  8. KAKENHI, 2015, 2017
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  9. KAKENHI(Grant-in-Aid for Scientific Research (B)), 2019, 2021

Social Activities

History as Committee Members

  1. JSME Thermal Engineering Division Secretary, 2019/04, 2020/03, The Japan Society of Mechanical Engineering
  2. Journal of the Combustion Society of Japan, Editorial Committee, 2015/04, 2018/03, Combustion Society of Japan
  3. Summer school of the combustion society of Japan, 2015/04, 2015/10, Combustion society of Japan