• 제목/요약/키워드: LIghtweight Piezo-composite Curved Actuator

검색결과 6건 처리시간 0.019초

복합재료와 압전재료로 구성된 곡면형 작동기의 열변형 및 잔류응력 해석 (Thermal Deformation and Residual Stress Analysis of Lightweight Piezo-composite Curved Actuator)

  • 정재한;박기훈;박훈철;윤광준
    • 한국복합재료학회:학술대회논문집
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    • 한국복합재료학회 2001년도 춘계학술발표대회 논문집
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    • pp.126-129
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    • 2001
  • LIPCA (LIghtweight Piezo-composite Curved Actuator) is an actuator device which is lighter than other conventional piezoelectric ceramic type actuator. LIPCA is composed of a piezoelectric ceramic layer and fiber reinforced light composite layers, typically a PZT ceramic layer is sandwiched by a top fiber layer with low CTE (coefficient of thermal expansion) and base layers with high CTE. LIPCA has curved shape like a typical THUNDER (thin-layer composite unimorph feroelectric driver and sensor), but it is lighter an than THUNDER. Since the curved shape of LIPCA is from the thermal deformation during the manufacturing process of unsymmetrically laminated lay-up structure, an analysis for the thermal deformation and residual stresses induced during the manufacturing process is very important for an optimal design to increase the performance of LIPCA. To investigate the thermal deformation behavior and the induced residual stresses of LIPCA at room temperature, the curvatures of LIPCA were measured and compared with those predicted from the analysis using the classical lamination theory. A methodology is being studied to find an optimal stacking sequence and geometry of LIPCA to have larger specific actuating displacement and higher force. The residual stresses induced during the cooling process of the piezo-composite actuators have been calculated. A lay-up geometry for the PZT ceramic layer to have compression stress in the geometrical principal direction has been designed.

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곡면형 압전 복합재료 작동기 LIPCA 개발 (Development of Lightweight Piezo-composite Curved Actuator)

  • 박기훈;윤광준;박훈철
    • 한국항공우주학회지
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    • 제30권5호
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    • pp.94-100
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    • 2002
  • 본 논문은 곡면형 압전 복합재료 작동기 LIPCA의 개발 및 성능 실험에 관한 것이다. LIPCA는 압전 세라믹을 중심으로 상층부는 탄성계수가 크면서 열팽창계수가 낮은 섬유강화 복합재료층이 위치하며, 하층부는 탄성계수가 작으면서 열팽창계수가 큰 섬유강화 복합재료층이 위치한다. 작동기의 성능 검증을 위해 작동지그 및 전압 공급 장치 그리고 비접촉 레이저 센서로 이루어진 실험 시스템을 구성하였다. 성능 실험은 양단 단순지지상태에서 압전 재료의 전극에 $100\sim400V_{pp}$의 교류 전압을 1Hz로 가하였을 경우 작동기 중앙부에서 발생하는 수직방향의 변위를 측정하는 것으로 수행하였다. LIPCA와 THUNDER의 성능 검증 결과 LIPCA-C2는 THUNDER에 비해 34% 경량화 되었으며, 작동변위는 13% 향상되었다.

곡면형 비대칭 압전복합재료 작동기 LIPCA의 설계해석/제작/성능평가 (Design Analysis/Manufacturing /Performance Evaluation of Curved Unsymmetrical Piezoelectric Composite Actuator LIPCA)

  • 구남서;신석준;박훈철;윤광준
    • 대한기계학회논문집A
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    • 제25권10호
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    • pp.1514-1519
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    • 2001
  • This paper is concerned with design, manufacturing and performance test of LIPCA ( Lightweight Piezo- composite Curved Actuator) using a top carbon fiber composite layer with near -zero CTE(coefficient of thermal expansion), a middle PZT ceramic wafer and a bottom glass/epoxy layer with high CTE. The main point of this design is to replace the heavy metal layers of THUNDER by thigh tweight fiber reinforced plastic layers without losing capabilities to generate high force and large displacement. It is possible to save weight up to about 30% if we replace the metallic backing material by the light fiber composite layer. We can also have design flexibility by selecting the fiber direction and the size of prepreg layers. In addition to the lightweight advantage and design flexibility, the proposed device can be manufactured without adhesive layers when we use epoxy resin prepreg system. Glass/epoxy prepregs, a ceramic wafer with electrode surfaces, and a graphite/epoxy prepreg were simply stacked and cured at an elevated temperature (177 $^{circ}C$ after following an autoclave bagging process. It was found that the manufactured composite laminate device had a sufficient curvature after detached from a flat mold. The analysis method of the cure curvature of LIPCA using the classical lamination theory is presented. The predicted curvatures are fairly in agreement with the experimental ones. In order to investigate the merits of LIPCA, a performance test of both LIPCA and THUNDE$^{TM}$ were conducted under the same boundary conditions. From the experimental actuation tests, it was observed that the developed actuator could generate larger actuation displacement than THUNDERT$^{TM}$.

경량 압전복합재료 곡면형 작동기(LIPCA)의 작동성능 평가를 위한 유한요소 해석 (Finite Element Analysis for Actuating Performance Evaluation of LIghtweight Piezo-composite Curved Acutator)

  • 구남서
    • 대한기계학회논문집A
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    • 제25권11호
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    • pp.1881-1886
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    • 2001
  • A numerical method for actuating performance evaluation of LIPCA proposed using a finite element method. Fully coupled formulations for piezo-electric materials were introduced and 3-dimensional eight-node incompatible element was used. After verifying the developed code with typical examples, the center deflections of LIPCA were calculated and compared with the experimental result, which were in fairly agreement.

Design and Performance Evaluation of Mini-Lightweight Piezo-Composite Actuators

  • Tran, Anh Kim;Yoon, Kwang-Joon
    • Advanced Composite Materials
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    • 제18권4호
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    • pp.327-338
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    • 2009
  • In this paper, through an evaluation process conducted on several designs of mini-LIPCA (Lightweight Piezo-Composite curved Actuator), an optimal design of a mini-LIPCA has been proposed. Comparing with the LIPCA-C2, the design of the mini-LIPCA comes with reduced overall size and a thinner active layer. Since a variation in the number and lay-up of fiber composite layers may strongly affect the performance of the device, one is able to configure several designs of mini-LIPCA. The evaluation process is then followed in order to determine a configuration which characterizes the possibly optimal performance. That is, a design of a mini-LIPCA is said to be optimal if it is capable of producing a maximum out-of-plane displacement. The size of the LIPCA to be investigated was selected to be $10\;mm\;{\times}\;20\;mm$ in which the thickness of PZT plate is about 0.1 mm. The thickness of glass/epoxy and carbon/epoxy are about 0.09 mm and 0.1 mm, respectively. The evaluation process has been conducted thoroughly, i.e., analytical estimation, numerical approximation and the experimental measurement are all involved. Firstly, the design equation was used to calculate essential parameters of proposed lay-up configurations. Secondly, ANSYS, a commercial FEA package, was utilized to estimate displacement outputs of the actuators upon being excited. Finally, experimental measurements were able to verify the predicted results.

인공근육형 LIPCA를 이용한 물고기 모방 로봇의 설계, 제작 및 실험 (Mechanical Design Fabrication and Test of a Biomimetic Fish Robot Using LIPCA as an Artificial Muscle)

  • 허석;테디 위구나;구남서;박훈철
    • 대한기계학회논문집A
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    • 제31권1호
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    • pp.36-42
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    • 2007
  • This paper presents mechanical design, fabrication and test of a biomimetic fish robot actuated by a unimorph piezoceramic actuator, LIPCA(Lightweight Piezo-Composite curved Actuator.) We have designed a linkage mechanism that can convert bending motion of the LIPCA into the caudal fin movement. This linkage system consists of a rack-pinion system and four-bar linkage. Four types of artificial caudal fins that resemble caudal fin shapes of ostraciiform subcarangiform, carangiform, and thunniform fish, respectively, are attached to the posterior part of the robotic fish. The swimming test under 300 $V_{pp}$ input with 0.6 Hz to 1.2 Hz frequency was conducted to investigate effect of tail beat frequency and shape of caudal fin on the swimming speed of the robotic fish. At the frequency of 0.9 Hz, the maximum swimming speeds of 1.632 cm/s, 1.776 cm/s, 1.612 cm/s and 1.51 cm/s were reached for fish robots with ostraciiform, subcarangiform carangiform and thunniform caudal fins, respectively. The Strouhal number, which means the ratio between unsteady force and inertia force, or a measure of thrust efficiency, was calculated in order to examine thrust performance of the present biomimetic fish robot. The calculated Strouhal numbers show that the present robotic fish does not fall into the performance range of a fast swimming robot.