• 제목/요약/키워드: The vibration power generation system

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The Research of Vibration Power Generation with Two Degree of Freedom Using Ocean Wave (파도를 이용한 2자유도 파력진동발전시스템에 대한 연구)

  • Han, Ki-Bong;Lee, Hyoung-Woo
    • Journal of Advanced Marine Engineering and Technology
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    • v.35 no.8
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    • pp.1028-1034
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    • 2011
  • This paper have been studied that ocean wave power vibration generation system with two D.O.F.(degree of freedom) consists of buoy and vibration generation system with two D.O.F. for using efficiency of ocean wave energy. It selected main frequencies ${\omega}_1$, ${\omega}_2$ in frequency with ocean wave and it fitted them to the natural frequencies of vibration system with two D.O.F. in the vibrational power generation system. Then each the relative velocity of between the winding coil and the permanent magnet is faster than the velocity of ocean wave up and down motion by resonance phenomenon. Also the ocean wave power generation with two D.O.F. obtained the more electric energy then the ocean wave power generation with one D.O.F. by coupling effect for two D.O.F. vibration system. Therefore ocean wave power vibration generation system with two degree of freedom that is proposed in this paper has merits which not only using more energy in the ocean wave but also obtaining more electronic energy.

The Research of the Hybrid Power Generation using Ocean Wave (파력을 이용한 하이브리드 발전에 대한 연구)

  • Han, Ki-Bong;Lee, Hyoung-Woo
    • Journal of Advanced Marine Engineering and Technology
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    • v.35 no.6
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    • pp.861-866
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    • 2011
  • This paper described the hybrid power generation using ocean wave that consists of linear power generation system and vibrational power generation system. The linear power generation system is made up of the winding coil, the permanent magnet and it is performed stable generation regardless of the wave frequency using directly the ocean wave velocity. And the vibration power generation system consists of the winding coil, the permanent magnet and spring. When the vibration system natural frequency in the vibrational power generation system is tuned to the ocean wave frequency, the relative velocity of between the winding coil and the permanent magnet is faster than the velocity of ocean wave up and down motion, then we can obtain more the electric power. Therefore, in this paper, the proposed hybrid power generation using ocean wave have merits that obtaining the more electric energy in resonance frequency and carrying out stable generation even over the range of resonance frequency.

System Analysis and Design for Vibration-Based Power Generation using Piezoelectric Materials (압전 재료를 이용한 진동에너지 변환 전력발생 시스템 해석 및 설계)

  • Keum, Myoung-Hun;Kim, Kyung-Ho;Lee, Seung-Yep;Ko, Byoung-Sik
    • Transactions of the Korean Society of Mechanical Engineers A
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    • v.28 no.6
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    • pp.717-725
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    • 2004
  • A power generation systems are proposed to convert ambient mechanical vibration into electrical energy using cantilever-type piezoelectric materials. The vibration-based power device can be used for self-powered systems without batteries. This paper presents the theoretical analysis for the coupled equations of piezoelectric and structural motions and investigates the dynamic characteristics of the self-power system using transfer function method. The theoretical model is verified by the finite element analysis of the resonance frequency, the dynamic response of the structure and the sensor sensibility. Experimental results measured using a prototype system agree with the theoretical predictions. The system is shown to produce 34.5 ㎼ in average. Finally, we perform the optimal design for system variables to maximize output power.

System Analysis and Design for a Vibration Converted Power Generator using Piezo Materials (압전 재료를 이용한 진동에너지 변환 전력발생 시스템 해석 및 설계)

  • 금명훈;이승엽;고병식;김경호
    • Proceedings of the Korean Society for Noise and Vibration Engineering Conference
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    • 2003.11a
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    • pp.1059-1066
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    • 2003
  • A power generation system are proposed to convert ambient mechanical vibration into electrical energy using cantilever-type piezoelectric materials. The vibration-based power device can be used for self-powered systems without batteries. This paper presents the theoretical analysis for the coupled equations of piezoelectric and structural motions and investigates the dynamic characteristics of the self-power system using transfer function method. The theoretical model is verified by the finite element analysis of the resonance frequency, the dynamic response of the structure and the sensor sensibility. Experimental results measured using a prototype system agrees with the theoretical predictions. The system is shown to produce 2.53㎼ in average. Finally, we perform the optimal design for system variables to maximize output power.

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A Basic Experimental Study on Vibration Power Generation Using Bridge Vibration (교량의 진동을 이용한 진동력 발전 기초실험연구)

  • Jo, Byung-Wan;Lee, Yun-Sung;Kim, Yung-Ji;Yoon, Kwang-Won
    • International Journal of Highway Engineering
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    • v.12 no.4
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    • pp.121-129
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    • 2010
  • Through this paper, we studied on the basic concept of vibration-induced power generation for urban infrastructures. Since the travelling of automobiles on the bridge cause vibration, it is possible to convert the vibration energy into green-electric energy by utilizing magnetic induction technology. In this paper we define the concept of green-bridge vibration power generation system which contains the concept of magnetic induction technology and propose a vibration power generation device for converting the bridge vibration energy into the electric energy. Also, an experiment was held by applying the vibration power generator on a real bridge. The results showed the applicability and effectiveness of the vibration power generator.

Analysis of Energy Conversion Efficiency in Micro Power Generation using Vibrating Piezoelectric Cantilever (압전빔의 진동을 이용한 마이크로 동력원의 에너지 변환 해석)

  • Lee, Heon-Ju;Chang, Young-Soo;Lee, Yoon-Pyo
    • Proceedings of the KSME Conference
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    • 2007.05b
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    • pp.3365-3370
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    • 2007
  • We developed micro power generation system using piezoelectric materials. In our system, the ambient vibrating energy is converting to electric energy by deflection of piezoelectric beams. The system consists of energy generating parts, converting enhancement parts, electric regulation and charging parts, and interface with small-energy-consuming mobile devices. The geometry of piezoelectric beams, the source of vibrating energy, and the electric load of target application determine the characteristics of generating electric power, such as impedance, voltage, current and power density. Therefore, we made a model for analysis of generating power with given information such as piezoelectric materials, geometry, vibration type, and mass. With this model, we can calculate capacitance of piezoelectric beams, generating voltage, current, and power. To obtain maximum energy transfer efficiency, we approached this study in the view of material, electrical, and mechanical engineering

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The research of vibration power generation to make effective use of ocean wave energy (파도에너지를 효율적으로 이용하기위한 파력진동발전기에 대한 연구)

  • Lee, Hong-Chan;Lee, Jae-Ho;Han, Ki-Bong
    • Proceedings of the Korean Society of Marine Engineers Conference
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    • 2011.10a
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    • pp.75-75
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    • 2011
  • This paper has been studied that ocean wave vibration power generator is composed of buoy and vibration generator to make effective use of ocean wave energy. We designed buoy to can occur resonance for dominant frequency with ocean wave. And then we fitted the natural frequency of vibration system with vibration power generator to buoy's natural frequency. And we can show that the amplitude of ocean wave up and down motion is decreased, on the other hand, the displacement of vibration system with vibration power generator is increased. Therefore, ocean wave vibration power generator which is proposed in this paper has merits not only securing its stability from surroundings but also producing more electronic power by using ocean wave energy.

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Electrically Induced Damping Characteristics and a Relevant Requirement for the Maximum Power Generation in Piezoelectric Vibration Energy Harvesters (압전 진동 에너지 수확 장치의 전기 유발 감쇠 특성 및 최대 전력 발생 조건)

  • Kim, Jae Eun
    • Transactions of the Korean Society for Noise and Vibration Engineering
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    • v.25 no.6
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    • pp.406-413
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    • 2015
  • The piezoelectric coupling in piezoelectric vibration energy harvesters with load resistance induces electrical damping as well as increase in the system stiffness. Starting from analytically deriving the explicit relations through governing equations in the frequency domain, this work identifies the characteristics of the electrically induced damping mechanism and shows that the electrically induced damping serves as a structural hysteretic damping on condition that a piezoelectric vibration energy harvester is excited at its short-circuit resonant frequency and its load resistor is optimally impedance- matched at the same time. Finally, it is analytically verified that the equivalence of a mechanical and an electrically induced damping ratio is required for the maximum power generation at a load resistor, which was claimed in some literature.

Study on vibration characteristics of low pressure turbine hood resonance in a 500MW thermal power plant (500MW 화력발전소 저압터빈 Hood 공진 특성에 관한 연구)

  • Cho, Cheul-Whan;Cho, Seong-Tae;Koo, Jae-Raeyang;Kim, Hyoung-Suk
    • Journal of Power System Engineering
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    • v.17 no.3
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    • pp.23-27
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    • 2013
  • In this research paper, we study on how to decrease the high vibration of turbine hood casings which are main facilities of power generation industry. Cause of Standard coal-fired power 500MW facilities turbine hoods' high vibration is that Natural frequency of hood casing designed in near domain frequency, when they are making hoods. We investigate to reduce high vibration at hood casing. We use FEM method to found how to avoid resonance, and test to confirm that our FEM result. We Finally attach minium mass plate at hood casing to avoid resonance and high vibration reduce lower $100{\mu}m$.