Your search keyword '"Deok Hwan Jeon"' showing total 7 results

1. Performance of a speed bump piezoelectric energy harvester for an automatic cellphone charging system

Author

Seong Do Hong, Jong Hyuk Eom, Jung Hwan Ahn, Jae Yong Cho, Sung Min Ko, Sang Bum Woo, Se Yeong Jeong, Wonseop Hwang, Jeong Pil Jhun, Tae Hyun Sung, Gyeong Ju Song, Kyung Bum Kim, Min Sik Woo, Deok Hwan Jeon, and Chan Ho Yang

Subjects

Computer science, business.industry, 020209 energy, Mechanical Engineering, Electric potential energy, Electrical engineering, Battery (vacuum tube), 02 engineering and technology, Building and Construction, Management, Monitoring, Policy and Law, law.invention, Power (physics), Speed bump, Capacitor, General Energy, 020401 chemical engineering, law, 0202 electrical engineering, electronic engineering, information engineering, Electricity, 0204 chemical engineering, business, Energy harvesting, Voltage

Abstract

We propose a piezoelectric energy harvesting technology installed in a roadway speed bump. We have installed a module that can charge mobile phones utilizing a speed bump piezoelectric harvester (SBPH), which is easy to apply to roads. A highly integrated module with 40 piezo-generators was fixed and installed at the center of the speed bump. When a medium-sized vehicle passed the module at a speed of 30 km/h, an output voltage of 144 Vmax, output current of 45.2 mAmax, and output power of 4086.08 mWmax (6.81 W/m2) were measured at a load resistance of 2 kΩ. When the vehicle passed over the SBPH nine times, it charged a capacitor (10,000 μF) to provide 6 V for about 200 s, and the charged electrical energy was enough to operate a cellphone. The self-controlled battery charging system via electricity generated by the piezoelectric module could be applied to a speed bump installed on an actual road.

Published

2019

2. Piezoelectric device operating as sensor and harvester to drive switching circuit in LED shoes

Author

Jae Yong Cho, Jung Hwan Ahn, Se Yeong Jeong, Tae Hyun Sung, Jae Chul Jeong, Gyeong Ju Song, Kyung Bum Kim, Deok Hwan Jeon, Seong Do Hong, and Wonseop Hwang

Subjects

Resistive touchscreen, Piezoelectric sensor, business.industry, Computer science, 020209 energy, Mechanical Engineering, Electrical engineering, Battery (vacuum tube), 02 engineering and technology, Building and Construction, Pollution, Piezoelectricity, Industrial and Manufacturing Engineering, General Energy, 020401 chemical engineering, 0202 electrical engineering, electronic engineering, information engineering, 0204 chemical engineering, Electrical and Electronic Engineering, business, Standby power, Energy harvesting, Mechanical energy, Civil and Structural Engineering, Electronic circuit

Abstract

The power generated by the designed piezoelectric energy harvester replaces the standby power that is constantly used in sensors and driving circuits in commercial LED shoes; the harvester thus reduces battery consumption. LED shoes incorporating a piezoelectric energy harvester are designed for night workers who work near roads. The piezoelectric energy harvester, composed of a piezoelectric device (PZT ceramic), which is inserted under the insoles of shoes, converts mechanical energy generated by motion of user into electrical energy. The designed harvester has an area of 6 × 4 mm and height of 3 mm (pressed state); it weighs 14 g. Because of its small size and light weight, device is suitable for real workers’ shoes. This piezoelectric energy harvester produces 800 μW at a resistive matching point of 400 kΩ; it is used as a sensor to control an LED switching circuit, allowing the LEDs to blink based on user movements. By applying the piezoelectric energy harvester to LED shoes, battery usage time can be doubled compared to LED shoes that are turned on continuously.

Published

2019

3. Watts-level road-compatible piezoelectric energy harvester for a self-powered temperature monitoring system on an actual roadway

Author

Tae Hee Lee, Gyeong Ju Song, Kyung Bum Kim, Jung Hun Kim, Wonseop Hwang, Deok Hwan Jeon, Seong Do Hong, Haimoon Cheong, Yewon Song, Chan Ho Yang, Jae Yong Cho, Ji-Young Choi, Tae Hyun Sung, Jung Hwan Ahn, and Jihoon Kim

Subjects

020209 energy, Mechanical Engineering, Electric potential energy, 02 engineering and technology, Building and Construction, Management, Monitoring, Policy and Law, Piezoelectricity, Automotive engineering, Power (physics), General Energy, 020401 chemical engineering, Range (aeronautics), 0202 electrical engineering, electronic engineering, information engineering, Environmental science, 0204 chemical engineering, Wireless sensor network, Energy harvesting, Voltage, Power density

Abstract

Piezoelectric energy harvesting technology can be used for a wide range of purposes through the design of road energy harvesting devices. For the roadway piezoelectric energy harvester (RPEH) developed here, a piezoelectric energy harvester (PEH) is fixed at both ends to increase the tolerable load and a module durable against harsh highway environments were developed using aluminum plates, steel plates, and polypropylene bars. A maximum voltage of 66 V, maximum current of 30.37 mA and maximum output power of 830 mW were measured with 2 mm of displacement at 15 Hz using the RPEH (50 cm × 20 cm) with 80 PEH units connected in parallel. On an actual high-speed road, measurements from a medium-sized vehicle which passes the RPEH at a speed of 90 km/h record an output voltage of 46.52 Vmax, output current of 93.04 mAmax, and power of 4.3 Wmax (power density: 43.0 W/m2) at a load resistance level of 0.5 kΩ. In an actual roadway environment, the electrical energy generated by the RPEH is sufficient to operate a temperature sensor and to transmit data wirelessly.

Published

2019

4. A multifunctional road-compatible piezoelectric energy harvester for autonomous driver-assist LED indicators with a self-monitoring system

Author

Jihoon Kim, Deok Hwan Jeon, Jae Yong Cho, Wonseop Hwang, Haimoon Cheong, Seong Do Hong, Sang Bum Woo, Chan Ho Yang, Ji-Young Choi, Jung Hwan Ahn, Tae Hee Lee, Kyung Bum Kim, Tae Hyun Sung, Gyeong Ju Song, and Chul Hee Ryu

Subjects

Maximum power principle, Computer science, 020209 energy, Mechanical Engineering, 02 engineering and technology, Building and Construction, Management, Monitoring, Policy and Law, Piezoelectricity, Automotive engineering, General Energy, 020401 chemical engineering, 0202 electrical engineering, electronic engineering, information engineering, Electric power, Vertical displacement, 0204 chemical engineering, Electrical impedance, Mechanical energy, Voltage, Leakage (electronics)

Abstract

The purpose of this research was to demonstrate a road-compatible piezoelectric energy harvester (RPEH) that uses the energy to power self-powered sensors and vehicle indicators. The demonstrated RPEH (20 × 50 × 10 cm3) with 80 piezoelectric devices can efficiently convert mechanical energy stemming from the small vertical displacement (1.45 mm) from vehicles into electrical power. The maximum voltage is 113.5 V, the maximum current is 25.71 mA, and the maximum power is 661 mW (6.61 W/m2) at an impedance resistance level of 0.9 kΩ under a z-axial load. The high-power RPEH was initially installed at a highway rest area. The measured output performances of the installed module on the actual roadway in the test setup area were a maximum voltage of 196 V and output power of 2080 mW (20.79 W/m2) at a vehicle speed of 30 km/h. Tests of the RPEH module demonstrate its ability to measure temperature, strain, and leakage values in real time and the generated energy provides sufficient power to illuminate LED indicators. It was also found that the z-axial loaded piezoelectric devices with a two-end fixed beam provide high output power with low levels of vertical displacement, making it highly efficient and durable for actual highway energy-harvesting applications.

Published

2019

5. Uniform stress distribution road piezoelectric generator with free-fixed-end type central strike mechanism

Author

Wonseop Hwang, Chul Hee Ryu, Jung Hwan Ahn, Jeong Hun Kim, Kyung-Bum Kim, Seong Do Hong, Yewon Song, Jae Yong Cho, Yooseob Song, Tae Hyun Sung, Jihoon Kim, Sang Bum Woo, Min Sik Woo, Deok Hwan Jeon, and Se Yeong Jeong

Subjects

Battery (electricity), business.industry, Mechanical Engineering, Building and Construction, Pollution, Piezoelectricity, Industrial and Manufacturing Engineering, Automotive engineering, Mechanism (engineering), General Energy, Black ice, Road surface, Environmental science, Wireless, Electrical and Electronic Engineering, business, Energy harvesting, Energy (signal processing), Civil and Structural Engineering

Abstract

A self-powered energy harvester for real roads to predict and detect black ice formation and pinpoint dangerous road sections was developed. An open-type piezoelectric device was developed for a high-efficiency module to achieve uniform stress distribution for enhanced energy harvesting performance by free-fixed-end type central strike mechanism. The output performance of the open-type device was 80% higher than that of the closed-type device. A uniform stress distribution road piezoelectric generator (URPG) with 120 open-type devices was installed on real roads. The URPG showed output power performance of up to 2.38 mW/cm3 when a vehicle passed once under the condition of being buried 2.5 cm below the road surface. The URPG can operate a wireless temperature sensor monitoring system for 83 s and charge a cellphone battery for 53 s. The developed self-powered energy harvesters can be used to reduce accidents caused by black ice on real roads.

Published

2022

6. A lever-type piezoelectric energy harvester with deformation-guiding mechanism for electric vehicle charging station on smart road

Author

Wonseop Hwang, Tae Hyun Sung, Chul Hee Ryu, Anuruddh Kumar, Hyoungjin Lee, Jeong Pil Jhun, Sinwoo Jeong, Cheulho Chang, Hansun Park, Se Yeong Jeong, Deok Hwan Jeon, Jae Yong Cho, and Jung Hwan Ahn

Subjects

business.product_category, Computer science, 020209 energy, Mechanical Engineering, 02 engineering and technology, Building and Construction, Pollution, Piezoelectricity, Industrial and Manufacturing Engineering, Automotive engineering, Energy storage, Power (physics), Vibration, Charging station, General Energy, Electricity generation, 020401 chemical engineering, Electric vehicle, 0202 electrical engineering, electronic engineering, information engineering, 0204 chemical engineering, Electrical and Electronic Engineering, business, Energy harvesting, Civil and Structural Engineering

Abstract

To meet the increasing demand for electric vehicles, this paper presents a novel concept to enhance the energy generation performance of piezoelectric energy harvesters used as charging stations on roads. A lever-type piezoelectric energy harvester with a deformation-guiding mechanism was designed and fabricated to overcome the existing limitations of low electrical output and low durability of piezoelectricity under extremely low road displacement conditions of 1 mm. The proposed harvester achieved a maximum output power of 60.3 mW at a load resistance of 50 kΩ under an input displacement of 1 mm. Thus, the module’s electrical performance was significantly higher than that obtained in previous similar studies. The proposed harvester had 467% higher output power than the previously proposed vibration type road energy harvester. For the energy storage test, a 0.08 F supercapacitor was charged up to 5.09 V (1 J) in 170 min. The results prove that the energy generated by the proposed harvester can be potentially used as a power source for electric vehicles on smart roads beyond the power supply of various sensor systems on the road.

Published

2021

7. Retraction notice to 'Enhanced flexible piezoelectric generating performance via high energy composite for wireless sensor network'[Energy 159 (2018) 196–202]

Author

Sahn Nahm, Seong Do Hong, Kyung Bum Kim, Tae Hyun Sung, Young Hun Jeong, Jae Yong Cho, Jung Hwan Ahn, and Deok Hwan Jeon

Subjects

High energy, Materials science, Notice, business.industry, Mechanical Engineering, Composite number, Electrical engineering, Building and Construction, Pollution, Piezoelectricity, Industrial and Manufacturing Engineering, General Energy, Electrical and Electronic Engineering, business, Wireless sensor network, Energy (signal processing), Civil and Structural Engineering

Published

2019