Scientists Show How to Store Liquid Fuels in Polymeric Gels to Prevent Explosions and Fires

2022/05/11
  • Research

Researchers from Shibaura Institute of Technology and Tokyo Institute of Technology in Japan investigate a new safer way to transport and store fuels
Liquid fuels with high energy density, though used worldwide, are dangerous to transport and store owing to their volatility, which produces explosive gas mixtures. To address this problem, researchers from Shibaura Institute of Technology and Tokyo Institute of Technology, Japan, recently investigated the possibility of storing liquid fuel within polymeric gel networks, preventing their fast evaporation, and demonstrating good combustion performance. Their work paves the way for safer transport and storage of liquid fuels. 

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Title:Storage of ethanol inside a polymeric gel sphere (top) andthe combustion state of the polymeric gel storage (bottom).
Caption:Researchers from SIT Japan showed in a new study that chemically cross-linked polymeric gel networks can trap highly volatile liquid fuel molecules, such as ethanol, through physical interactions, thereby greatly reducing their evaporation rate and risks of fire accidents.

Credit:Naoki Hosoya from SIT, Japan.
Usage restrictions:Under a Creative Commons license CC BY-NC-ND 4.0. You are free to share the material. Attribution is required. You may not use the material for commercial purposes. You cannot distribute any derivative works or adaptations of the original work.


Liquid fuels with high energy density are essential in many applications where chemical energy is converted into controlled motion, such as in rockets, gas turbines, boilers, and certain vehicle engines. Besides their combustion characteristics and performance, it is also important to guarantee the safety and stability of these fuels when in use as well as during transport and storage. 
 
One common hazard when dealing with liquid fuels is that they can evaporate quickly if given space, producing clouds of highly flammable gases. As one might expect, this can lead to catastrophic explosions or fire accidents. To tackle this problem, researchers have considered the use of gelled fuels, or fuels turned into thick gel-like substances from cold temperatures. Unfortunately, there are many aspects to optimize and hurdles to overcome before gelled fuels can go beyond the research phase. 
 
Luckily, a team of researchers led by Prof. Naoki Hosoya from Shibaura Institute of Technology (SIT) and Prof. Shingo Maeda from Tokyo Institute of Technology (Tokyo Tech), Japan, recently investigated a more compelling solution to the safety problem of liquid fuels, namely storing them inside polymeric gel networks. In their study, the team analyzed the performance, advantages, and limitations of storing ethanol, a common liquid fuel, within a chemically cross-linked poly(N-isopropylacrylamide) (PNIPPAm) gel. This paper was made available online on April 21, 2022 and published in Volume 444 of the Chemical Engineering Journal on September 15, 2022.
 
First, they checked whether trapping ethanol molecules within the long and chemically intertwined PNIPAAm polymer chains helped reduce its evaporation rate. To test this, the researchers created small spheres of PNIPAAm gel loaded with ethanol and placed them on an electronic scale to record how mass changed as ethanol vaporized. They also performed this experiment with an equivalent puddle of ethanol, with roughly the same surface area and mass as the gel sphere.
 
They found that storing ethanol within the polymer gel completely suppressed the fuel’s tendency to rapidly vaporize. This is likely due to how ethanol molecules are “trapped” in the gel, as Prof. Hosoya explains: “The polymeric gel contains innumerable three-dimensional polymer chains that are chemically cross-linked in a strong way. These chains bind the ethanol molecules through various physical interactions, limiting its evaporation in the process.” Interestingly, the loaded gel does not behave like a wet towel. Whereas a wet towel would release its liquid if wrung, the polymeric gel did not let out ethanol easily under external forces.
 
With the problem of evaporation solved, the team moved on to examine the actual combustion characteristics of the ethanol in the polymeric gel network to see if they burnt efficiently. They ignited ethanol-loaded gel spheres of various sizes and observed the changes in their mass and shape profiles in real time. Based on this, they determined that the burning of the loaded PNIPAAm gel spheres consisted of two phases: a phase dominated by pure ethanol burning, followed by a second phase dominated by the burning of the PNIPAAm polymer itself.
 
Through a subsequent theoretical analysis of these results, the team came to an important conclusion: the first and main combustion phase of the loaded PNIPAAm gel spheres follows a constant droplet temperature model, also known as the “d2law.” What this means is that the burning of the ethanol-loaded gel can be described by the same model used for liquid fuel droplets, hinting that their combustion performances should be similar.
 
Overall, this study is a stepping stone towards new ways to safely transport and store liquid fuels inside polymer gels, which could save many lives. “Polymeric gel storage could prevent explosions and fire accidents by drastically reducing the evaporation of fuels and, in turn, the formation of flammable gaseous mixtures, which can readily happen following a leak in a storage facility,” explains Prof. Hosoya. “Much work still remains to be done on this front, such as checking the stability and performance of polymeric gels at different temperature, pressure, and humidity conditions, as well as developing simpler fabrication procedures and better ways to use these fuel-loaded gels in real engines.”
 
Let us hope the research progresses quickly to create safer work environments in the near future.

Reference

Title of original paper: Chemically cross-linked gel storage for fuel to realize evaporation suppression
Authors:
Naoki Hosoya, Kazuki Nishiguchi, Hiroyasu Saito, and Shingo Maedaa
Journal: Chemical Engineering Journal
DOI: 10.1016/j.cej.2022.136506
Affiliations:
Department of Engineering Science and Mechanics, Shibaura Institute of Technology
a Department of Mechanical Engineering, Tokyo Institute of Technology

Funding Information

N/A


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