Help ?

IGMIN: あなたがここにいてくれて嬉しいです. お願いクリック '新しいクエリを作成してください' 当ウェブサイトへの初めてのご訪問で、さらに情報が必要な場合は.

すでに私たちのネットワークのメンバーで、すでに提出した質問に関する進展を追跡する必要がある場合は, クリック '私のクエリに連れて行ってください.'

科学、技術、工学、医学(STEM)分野に焦点を当てています | ISSN: 2995-8067  G o o g l e  Scholar

logo image

IgMin Research | マルチディシプリナリーオープンアクセスジャーナルは、科学、技術、工学、医学(STEM)の広範な分野における研究と知識の進展に貢献することを目的とした権威ある多分野のジャーナルです.

Abstract

要約 at IgMin Research

私たちの使命は、学際的な対話を促進し、広範な科学領域にわたる知識の進展を加速することです.

Engineering Group Research Article 記事ID: igmin118

Designing a Compact High-precision Positioner with Large Stroke Capability for Nanoindentation Devices

Sensors Mechanical EngineeringMaterials Engineering Affiliation

Affiliation

    Department of Civil and Mechanical Engineering, Purdue University, Fort Wayne, IN 46805, USA

要約

A new design of a fine positioner or high precision driven unit with a large positioning range is proposed for a custom-made in-situ indenter device equipped inside an SEM chamber. The design configuration of the proposed system is size-effective for the confined working area of the SEM chamber. The indentation depths can be precisely varied by controlling the fine positioner driven by a piezoelectric actuator. The main goal is to achieve very deep penetrations toward the bottom layers of tall or large-size scale specimens by single indentation, without the need for sequential indentations. Thus, the proposed design can eliminate the need for sequential adjustments of the specimen position with respect to the indenter tip as currently being practiced by the researchers. The specimen position adjustment after each indentation heavily depends on the coarse positioner and its accuracy level in a sub-millimeter regime which could result in position errors and unwanted lateral forces in the nanoindentation process. Therefore, the sequential indentations technique could lead to considerable variations in the outcomes of nanoindentation tests done on similar specimens. The proposed design will be realized to deploy in the Continuous Stiffness Measurement (CSM) techniques generally used to evaluate elastic properties as a function of continuous penetration depth with high-frequency loading and unloading cycles.

数字

参考文献

    1. Oliver DJ, Bradby JE, Williams JS, Swain MV, Munroe P, Journal of Applied Physics. 2009; 105:126101.
    2. Mohammad T, Salisbury SP. An improved stiffness model for piezo-actuated complementary clamp flexures International Journal of Mechatronics and Automation. 2012; 2:4.
    3. Mohammad T, Salisbury SP. Design and Assessment of a Z-Axis Precision Positioning Stage with Centimeter Range Based on a Piezoworm Motor, in IEEE/ASME Transactions on Mechatronics. 2015; 20:5; 2021-2030.
    4. Nowak JD, Malyska KA, Major RC, Warren OL, Michler J. Mater. Today. 2009; 12:44.
    5. Ghisleni R, Rzepiejewska-Malyska K, Philippe L, Schwaller P, Michler J. In situ SEM indentation experiments: instruments, methodology, and applications. Microsc Res Tech. 2009 Mar;72(3):242-9. doi: 10.1002/jemt.20677. PMID: 19140164.
    6. Li Y, Kim HI, Wei B, Kang J, Choi JB, Nam JD, Suhr J. Understanding the nanoscale local buckling behavior of vertically aligned MWCNT arrays with van der Waals interactions. Nanoscale. 2015 Sep 14;7(34):14299-304. doi: 10.1039/c5nr03581c. PMID: 26242771.
    7. Maschmann MR, Zhang Q, Wheeler R, Du F, Dai L, Baur J. In situ SEM observation of column-like and foam-like CNT array nanoindentation. ACS Appl Mater Interfaces. 2011 Mar;3(3):648-53. doi: 10.1021/am101262g. Epub 2011 Mar 2. PMID: 21366265.
    8. Maschmann MR, Zhang Q, Wheeler R, Du F, Dai L, Baur J. In situ SEM observation of column-like and foam-like CNT array nanoindentation. ACS Appl Mater Interfaces. 2011 Mar;3(3):648-53. doi: 10.1021/am101262g. Epub 2011 Mar 2. PMID: 21366265.
    9. Treacy MJ, Ebbesen TW, Gibson JM. Nature. 1996; 381:6584.
    10. Panzer MA, Zhang G, Mann D, Hu X, Pop E, Dai H. Heat Transfer. 2008; 130:5.
    11. Yaglioglu O, Hart J, Martens R, Slocum A. Rev. Sci. Instrum. 2006; 77:9.
    12. Shen ZL, Dodge MR, Kahn H, Ballarini R, Eppell SJ. Stress-strain experiments on individual collagen fibrils. Biophys J. 2008 Oct;95(8):3956-63. doi: 10.1529/biophysj.107.124602. Epub 2008 Jul 18. PMID: 18641067; PMCID: PMC2553131.
    13. Cao A, Dickrell PL, Sawyer WG, Ghasemi-Nejhad MN, Ajayan PM. Super-compressible foamlike carbon nanotube films. Science. 2005 Nov 25;310(5752):1307-10. doi: 10.1126/science.1118957. PMID: 16311330.
    14. APF710 actuator manual. https://www.thorlabs.com/drawings/a5af8e2a348979c1- E33CCEFE-CABF-3FDB-3F3B6B8FEC9B1420/APF710-Manual.pdf
    15. Svensson RB, Hassenkam T, Hansen P, Peter Magnusson S. Viscoelastic behavior of discrete human collagen fibrils. J Mech Behav Biomed Mater. 2010 Jan;3(1):112-5. doi: 10.1016/j.jmbbm.2009.01.005. Epub 2009 Feb 3. PMID: 19878908.
    16. Shen ZL, Dodge MR, Kahn H, Ballarini R, Eppell SJ. Stress-strain experiments on individual collagen fibrils. Biophys J. 2008 Oct;95(8):3956-63. doi: 10.1529/biophysj.107.124602. Epub 2008 Jul 18. PMID: 18641067; PMCID: PMC2553131.
    17. Maschmann MR, Zhang Q, Wheeler R, Du F, Dai L, Baur J. In situ SEM observation of column-like and foam-like CNT array nanoindentation. ACS Appl Mater Interfaces. 2011 Mar;3(3):648-53. doi: 10.1021/am101262g. Epub 2011 Mar 2. PMID: 21366265.
    18. Maschmann MR, Zhang Q, Wheeler R, Du F, Dai L, Baur J. In situ SEM observation of column-like and foam-like CNT array nanoindentation. ACS Appl Mater Interfaces. 2011 Mar;3(3):648-53. doi: 10.1021/am101262g. Epub 2011 Mar 2. PMID: 21366265.
    19. Tong T, Zhao Y, Delzeit L, Kashani A, Meyyappan M, Majumdar A. Height independent compressive modulus of vertically aligned carbon nanotube arrays. Nano Lett. 2008 Feb;8(2):511-5. doi: 10.1021/nl072709a. Epub 2008 Jan 12. PMID: 18189439.
    20. Ruoff RS, Tersoff J, Lorents DC, Subramoney S, Chan B, Nature. 1993; 367:6437.
    21. Bedewy M, Meshot E, Guo H, Verplogen E, Lu W. Phys. Chem. 2009; 111:16.
    22. Huang H, Zhao H, Mi J, Yang J, Wan S, Xu L, Ma Z. AIP Advances. 2012; 2:012104.
    23. Nalla RK, Stölken JS, Kinney JH, Ritchie RO. Fracture in human cortical bone: local fracture criteria and toughening mechanisms. J Biomech. 2005 Jul;38(7):1517-25. doi: 10.1016/j.jbiomech.2004.07.010. PMID: 15922763.
    24. Poissant J, Barthelat R. Exp. Mech. 2012; 52:9.
    25. Hulmes DJ, Wess TJ, Prockop DJ, Fratzl P. Radial packing, order, and disorder in collagen fibrils. Biophys J. 1995 May;68(5):1661-70. doi: 10.1016/S0006-3495(95)80391-7. PMID: 7612808; PMCID: PMC1282067.
    26. Huan Y, Liu D, Yang R, Zhang T. Measurement. 2010; 43:1090.

類似の記事

Screening for Sexually Transmitted Infections in Adolescents with Genitourinary Complaints: Is There a Still Role for Endocervical Gram Stains?
Subah Nanda, Amanda Schoonover, Jasman Kaur, Annie Vu, Erica Tavares, Angela Zamarripa, Christian Kolacki, Lindsey Ouellette and Jeffrey Jones
DOI10.61927/igmin251
Use of Augmented Reality as a Radiation-free Alternative in Pain Management Spinal Surgeries
Songyuan Lu, Jingwen Hui, Eric Lee, Darin Tsui, Farshad M Ahadian and Frank E Talke*
DOI10.61927/igmin236

ソーシャルアイコン

研究を公開する

私たちは、科学、技術、工学、医学に関する幅広い種類の記事を編集上の偏見なく公開しています。

提出する

見る 原稿のガイドライン 追加 論文処理料

IgMin 科目を探索する
グーグルスカラー
welcome Image

Google Scholarは2004年11月にベータ版が発表され、幅広い学術領域を航海する学術ナビゲーターとして機能します。それは査読付きジャーナル、書籍、会議論文、論文、博士論文、プレプリント、要約、技術報告書、裁判所の意見、特許をカバーしています。 IgMin の記事を検索