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Shinnosuke Nishiki Laboratory
Shinnosuke Nishiki Laboratory

錦慎之助

In our laboratory, we are conducting research on numerical simulation of thermal fluid using a large-scale computer. The research themes can be broadly divided into (1) numerical simulation of fire and safety using FDS (Fire Dynamics Simulator), and (2) direct numerical calculation (DNS) and modeling of turbulent premixed combustion.
In my graduation research, I will use FDS for numerical simulation and visualization. Research themes include (1) tunnel fires and evacuation, (2) fire whirls, and (3) highly accurate prediction of the flow of hydrogen and carbon monoxide.
We aim for research that can contribute to the realization of a safe and secure society.

Basic Information

Faculty name/Affiliation Shinnosuke Nishiki / Department of Information and Electronic Engineering, Faculty of Science and Engineering
Specialized Fields Computational science, social / safety system, mechanical engineering (combustion / fluid)
Research theme Numerical simulation of fire and safety by FDS, DNS and modeling of turbulent premixed combustion
Research keywords Numerical simulation, tunnel fire, diffusion of leaked gas, combustion, social safety
Faculty introduction URL https://www3.med.teikyo-u.ac.jp/profile/ja.fc65721f8b5853ad.html

Our Research

Numerical simulation of tunnel fire and evacuation

Numerical simulation of tunnel fire and evacuation

In a car tunnel fire, it is difficult to evacuate due to poor visibility due to smoke. In addition, the effects of toxic gases such as carbon monoxide on the human body must be considered as an evacuation measure. If simulations including water spraying and evacuation by sprinklers can be performed accurately and the site of a tunnel fire can be reproduced on a computer, safety measures can be taken at the design stage and large-scale experiments (expensive). It is possible to reduce the number of times. We aim to improve safety by improving the simulation accuracy of tunnel fires.

Fire whirl

Fire whirl

It is said that a large-scale fire whirl occurred in the Great Kanto Earthquake, killing about 40,000 people. There is also information that a fire whirl was witnessed in the Great East Japan Earthquake. In the near future, there is a concern that a fire whirl will occur in an earthquake directly beneath the Tokyo metropolitan area, which is feared to occur. Expected. We are aiming to clarify the mechanism of fire whirl generation that has not yet been elucidated so that we can contribute to disaster mitigation.

Prediction of hydrogen leakage diffusion behavior

Prediction of hydrogen leakage diffusion behavior

In order to prevent global warming, it is required to control carbon dioxide emissions. Fuel cell vehicles that use hydrogen as fuel have been put into practical use and are expected to become widespread in the future. However, on the other hand, hydrogen may have the image of "explosion" and "danger". Hydrogen is a very light gas that diffuses quickly, and even if a small amount leaks from the fuel tank, the risk of explosion is low if it can be quickly discharged to a large space. We simulated a hydrogen leak experiment with an opening in a closed space simulating a small garage with FDS, and showed that the hydrogen concentration time history can be reproduced with great accuracy. Applying this know-how, we are conducting research to reproduce the leakage behavior of gases such as hydrogen and carbon monoxide under various conditions.

Introducing the FacultyThis section introduces details about the research and the passionate thoughts around the research.

錦慎之助講師の紹介

Discover the fascinating and untold stories behind the cutting-edge research being conducted by our esteemed professors. Get an in-depth look at the motivations and passions driving their work, and learn how their findings are making a real impact on society. Don't miss the opportunity to gain a deeper understanding of the amazing work being done right here at our laboratory!

Introduction of Shinnosuke Nishiki

Papers and Conferences Presentation

Paper presentation

Title Journal title Laboratory Contents
Dissipation and dilatation rates in premixed turbulent flames Physics of Fluids 33, 035112 (2021); https://doi.org/10.1063/5.0039101 Nishiki Laboratory detail

Title Journal title Laboratory Contents
Influence of Thermal Expansion on Potential and Rotational Components of Turbulent Velocity Field Within and Upstream of Premixed Flame Brush Flow, Turbulence and Combustion (2020). Https://doi.org/10.1007/s10494-020-00131-3 Nishiki Laboratory detail

Conference presentation

Title Society name Laboratory Contents
Numerical simulation of leaked hydrogen conduct considering the effect of ventilation by FDS Japan Society of Mechanical Engineers 2020 Annual Meeting Nishiki Laboratory detail
Blood flow simulation in shunt vessels during hemodialysis using computational fluid dynamics The 30th Japanese Society of Clinical Engineering Nishiki Laboratory detail
VR visualization of tunnel fire simulation by FDS 58th Combustion Symposium Nishiki Laboratory detail
Flame propagation over a methane hydrate surface 58th Combustion Symposium Nishiki Laboratory detail
Fire simulation in Todoroki Cavern by FDS 34th Computational Fluid Dynamics Symposium Nishiki Laboratory detail
Application of Helmholtz-Hodge decomposition and conditioned structure functions to exploring influence of premixed combustion on turbulence upstream of the flame 38th International Symposium on Combustion Nishiki Laboratory detail
Solenoidal and potential velocity fields in weakly turbulent premixed flames 38th International Symposium on Combustion Nishiki Laboratory detail

Title Society name Laboratory Contents
Simulation of fire whirl in a wide area of fire spread by FDS 57th Combustion Symposium Nishiki Laboratory detail