The researchers
developed a novel self-powered device that is driven by respiration, allowing
them to be integrated with gas masks
As
technology progresses, devices are getting smaller, low-cost, and more
efficient. The advent of Internet of Things (IoT) has made researchers explore
ways to make sensors more compact and portable. In a new study, researchers
from Chung-Ang University, Korea have developed a device that is operable via breathing
and can, therefore, be integrated into gas masks. This device is capable of
powering LEDs and Bluetooth trackers, and can monitor breathing patterns and
chemical warfare agents.
Image title: The IVF-TENG system integrated into a gas mask to serve
as a versatile sensor-based detection system.
Image caption: In a new study, Chung-Ang University researchers design
a high-power and high output triboelectric nanogenerator (TENG)-based sensor
that can be powered by breathing. The researchers integrated this device into a
gas mask to create a self-powered hybrid sensor that detects breathing patterns
and harmful chemicals.
Image credit: Prof. Sangmin Lee from Chung-Ang University, Korea
License type: CC BY-NC
Image link: https://onlinelibrary.wiley.com/doi/abs/10.1002/aenm.202201001
With the
onset of the Internet of Things (IoT) era, devices have learned to communicate
and exchange data. This is achieved through sensors installed in physical
objects, machines, and equipment. The sensors can detect changes in events.
However, the need for continuous energy supply to these sensors poses a
challenge. Batteries are bulky, expensive, and not environmentally friendly.
Additionally, they need to be constantly replaced or recharged.
Consequently,
there is a demand for sustainable and renewable energy sources to replace
batteries. The triboelectric nanogenerator (TENG) is one such device. Put
simply, TENGs convert mechanical energy into electrical energy. Their high
energy efficiency, compatibility with readily available materials, and low cost
make them a promising candidate for powering sensors.
Despite
such advantages, however, current TENGs are limited by a low output current. But
increasing the output current would require larger equipment, making it
impossible to be used in small devices. Is there a way around this trade-off?
Fortunately,
a research team led by Associate Professor Sangmin Lee from Chung-Ang
University in Korea, has now addressed this issue. “Our lab is interested in high-power TENG design and TENG-based
self-powered sensors. We sought to address the limitation of current TENGs so
that they could be used to realize portable power sources in practice,” says
Dr. Lee, explaining his motivation behind the study, which was published online on May 31, 2022 in Advanced Energy Materials. The study will be featured on the front cover of the
upcoming issue.
The team developed
a novel device in their study called “inhalation-driven vertical flutter TENG”
(IVF-TENG) which exhibits an amplified current output. "Respiration acts as a continuous mechanical input and can be used
to operate TENGs. Film-flutter TENGs are such respiration-driven devices that
can generate a continuous electrical output from an extremely small respiration
input by exploiting the flutter phenomenon arising from airflow-induced
vibrations,” explains Dr. Lee.
The
IVF-TENG is composed of an aluminium (Al) inlet electrode, an aeroelastic
dielectric sheet (polyimide), and an Al outlet electrode. The aeroelastic sheet
has four segments with four slits and is subjected to vertical flutter behavior
caused by airflow. This makes the proposed IVF-TENG different from existing
TENGs.
The team
investigated the electrical and mechanical mechanisms of IVF-TENG. They found
that IVF-TENG generated a continuous, high-frequency electrical voltage (17 V)
and a closed-circuit current of 1.84 μA during inhalation, and an electrostatic
discharge voltage of 456 V and closed-circuit output current of 288 mA at the
beginning and end of every inspiratory cycle.
They further demonstrated that IVF-TENG can continuously power 130 LEDs in series and 140 LEDs in parallel in every inhalation. Additionally, it could charge a 660 capacitor to, in turn, power a Bluetooth tracker and provide its signal to a smartphone. These properties demonstrated the potential for IVF-TENG’s application in portable electronics and wireless data transmission.
Furthermore,
the researchers integrated IVF-TENG into a gas mask and demonstrated its
ability to monitor the breathing pattern of the user by observing the output
response waveform. Moreover, it could detect chemical warfare agents like
cyanogen chloride, sarin, and dimethyl methylphosphonate (DMMP), showing its
potential for use during emergencies. “Since
gas masks are extensively used in emergencies like fire and chemical gas
exposure, we focused on applying TENG to a gas mask. We believe that IVF-TENG
can be used as a self-powered sensor in such scenarios,” Dr. Lee speculates.
Indeed,
their invention could make TENGs reinvent gas masks as a self-powered hybrid
sensing system in the near future!
Reference
Authors
Title of original paper
Journal |
Deokjae Heo1, Myunghwan Song1,
Seh-Hoon Chung1, Kyunghwan Cha1, Youna Kim2,
Jihoon Chung2, Patrick T.J. Hwang3, Jaeheon Lee4,
Heesoo Jung4, Youngho Jin4, Jinkee Hong2,*,
Min-Kun Kim4,*, and Sangmin Lee1,*
Inhalation-Driven Vertical Flutter
Triboelectric Nanogenerator with Amplified Output as a
Gas-Mask-Integrated Self-Powered Multifunctional System
Advanced Energy Materials
|
|
|
DOI
Affiliations |
1School of Mechanical Engineering, Chung-Ang
University 2Department of Chemical & Biomolecular
Engineering, College of Engineering, Yonsei University 3Department of Biomedical Engineering, The University
of Alabama at Birmingham 4Agency for Defense Development, Chem-Bio
Technology Center |
*Corresponding authors’ email: |
Your Press Release Source
Chung-Ang University
About Chung-Ang University
Chung-Ang University is a private
comprehensive research university located in Seoul, South Korea. It was started
as a kindergarten in 191 and attained university status in 1953. It is fully
accredited by the Ministry of Education of Korea. Chung-Ang University conducts
research activities under the slogan of “Justice and Truth.” Its new vision for
completing 100 years is “The Global Creative Leader.” Chung-Ang University
offers undergraduate, postgraduate, and doctoral programs, which encompass a
law school, management program, and medical school; it has 16 undergraduate and
graduate schools each. Chung-Ang University’s culture and arts programs are
considered the best in Korea.
Website: https://neweng.cau.ac.kr/index.do
About Associate Professor Sangmin Lee
Dr. Sangmin Lee received his Ph.D. in Mechanical Engineering from
Pohang University of Science and Technology (POSTECH) in 2011. He teaches at
Chung-Ang University where he is an Associate Professor in the School of
Mechanical Engineering. His group researches in the field of energy harvesting
based on electrostatic potential, piezoelectric/triboelectric nanogenerators,
and hybrid cells. His research interests also lie in surface wetting control
including superhydrophobicity/superhydrophilicity based on micro and
nanofabrications, and mechanical characterization of micro and nanostructures
surfaces.
Read more about Prof. Lee here: https://scholarworks.bwise.kr/cau/researcher-profile?ep=919