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"Paving"

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"Paving"

Development and Evaluation of Rack Type Piezoelectric Harvester for Smart Street Lamps Control
Chang-il Kim, Young-hun Jeong, Woon Ik Park, Jeong-ho Cho, Yong-ho Jang, Beom-jin Choi, Shin-seo Park, Jong-hoo Paik
J Electr Electron Mater 2016;29(11):696-701.   Published online November 1, 2016
In this study, to increase output of road piezoelectric energy harvester, it was made into rack type in which many piezoelectric materials can be installed and load transfer device of the leverage type to transfer vehicle load was made. By paving it in the road, the output characteristics depending on vehicle load and speed were evaluated. Changing vehicle load, harvester output characteristics depending on speed changes were evaluated at the interval of 10 km/h from 10 km/h to 100 km/h. Also, by making a wireless switch and sending wireless signal with output of rack type harvester, whether to receive it was evaluated by distance. It was checked that all switches work up to front-to-back 100 m from harvester.
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Development and Evaluation of the Bender Type Piezoelectric Energy Harvester According to Installation Methods and Vehicle Weight
Chang Il Kim, Young Hun Jeong, Ji Sun Yun, Jeong Ho Cho, Jong Hoo Paik, Yong Ho Jang, Beom Jin Choi, Shin Seo Park, Young Bong Cho
J Electr Electron Mater 2016;29(5):274-278.   Published online May 1, 2016
A road energy harvester was designed and fabricated to convert mechanical energy from the vehicle load to electrical energy. The road energy harvester is composed of 20 piezoelectric materials. This study attempted to evaluate output depending on pavement materials when paving road piezoelectric energy harvester in the road. Harvester is the bender type and is the method of supporting the both ends of piezoelectric material and applying the load in the middle part. Harvester was paved in the type paved with asphalt, type paved with cement and in the exposed type not covering the top of harvester. The output characteristics were compared and evaluated depending on changes in vehicle load and vehicle speed changes. As vehicles, truck (11.9 ton), SUV(1.6 ton) and sedan (1.5 ton) were used and the output characteristics when driving at the interval of 10 km/h from 10 km/h to 100 km/h were evaluated.
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Development and Evaluation of the Road Energy Harvester According to Piezoelectric Cantilever Structure and Vehicle Load Transfer Mechanism
Chang Ii Kim, Kyung Bum Kim, Young Hun Jeong, Young Jin Lee, Jeong Ho Cho, Jong Hoo Paik, In Seok Kang, Moo Yong Lee, Beom Jin Choi, Shin Seo Park
J Electr Electron Mater 2012;25(10):773-778.   Published online October 1, 2012
A road energy harvester was designed and fabricated to convert mechanical energy from the vehicle load to electrical energy. The road energy harvester is composed of 16 piezoelectric cantilevers. We fabricated prototypes using a vehicle load transfer mechanism. Applying a vehicle load transfer mechanism rather than directly installing energy harvesters under roads decreases the area of road construction and allows more energy harvesters to be installed on the side of the road. The power generation amount with respect to the vehicular velocity change was assessed by installing the vehicle load transfer mechanism form and underground form. The energy harvester installed in the underground form generated power of 4.52mJ at the vehicular velocity of 50 km/h. Also, power generation of the energy harvester installed in the vehicle load transfer mechanism form was 48.65mJ at the vehicular velocity of 50 km/h.
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Development and Evaluation of the Road Energy Harvester Using Piezoelectric Cantilevers
Chang Il Kim, Kyung Bum Kim, Jong Hac Jeon, Young Hun Jeong, Jeong Ho Cho, Jong Hoo Paik, In Seok Kang, Moo Yong Lee, Beom Jin Choi, Young Bong Cho
J Electr Electron Mater 2012;25(7):511-515.   Published online July 1, 2012
A road energy harvester was designed and fabricated to convert mechanical energy from the vehicle load to electrical energy. The road energy harvester is composed of 24 piezoelectric cantilevers and a vehicle load transfer mechanism. Applying a vehicle load transfer mechanism rather than directly installing energy harvesters under roads decreases the area of road construction and allows more energy harvesters to be installed on the side of the road. The power generation amount with respect to the vehicular velocity change was assessed by installing the vehicle load transfer mechanism and the energy harvester in the form of speed bumps and underground. The energy harvester installed in a speed bump form generated power of 7.61 ㎽at the vehicular velocity of 20 km/h. Also, power generation of the energy harvester installed in the underground form was 63.9 ㎽at the vehicular velocity of 28 km/h. Although the number of piezoelectric cantilevers was reduced by 1/3 to 24 in comparison to the previous research results with 72 piezoelectric cantilevers, similar power generation characteristic value was obtained within the vehicular velocity of 20 km/h by altering the vehicle load transfer mechanism and cantilever vibration method.
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