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Three-Dimensional Force System01:30

Three-Dimensional Force System

In mechanical engineering, a three-dimensional force system is a system of forces acting in three dimensions, with forces applied along the x, y, and z coordinate axes. The three-dimensional force system is an important concept in mechanical engineering, as it allows engineers to understand and analyze the behavior of objects and structures in three dimensions. By understanding the forces acting on a system, engineers can design more efficient and effective mechanical systems that can withstand...
Three-Dimensional Force System:Problem Solving01:30

Three-Dimensional Force System:Problem Solving

A three-dimensional force system refers to a scenario in which three forces act simultaneously in three different directions. This type of problem is commonly encountered in physics and engineering, where it is necessary to calculate the resultant force on the system, which can then be used to predict or analyze the behavior of the object or structure under consideration.
To solve a three-dimensional force system, first resolve each force into its respective scalar components. Do this using...
Stress on an Oblique Plane01:16

Stress on an Oblique Plane

Understanding stress on an oblique plane under axial loading is pivotal in material mechanics. This analysis offers insight into a material's durability and strength, which is crucial for civil engineering and structural design. Axial loading refers to force application along the material's central axis, causing compression or elongation and leading to normal stress. Normal stress occurs when a force acts perpendicularly to the material's area, resulting in compressive or tensile stress. When...
Deformations in a Transverse Cross Section01:21

Deformations in a Transverse Cross Section

When a material is subjected to uniaxial stress, it elongates or contracts in the direction of the applied force, and also undergoes changes in the perpendicular directions. This behavior is crucial for understanding how materials behave under stress and is governed by mechanical properties such as Poisson's ratio v, which measures the ratio of transverse strain to axial strain.
As the material stretches, it expands or contracts in orthogonal directions to the load. This phenomenon varies...
Plastic Deformations of Members with a Single Plane of Symmetry01:21

Plastic Deformations of Members with a Single Plane of Symmetry

When a structural member undergoes plastic deformation due to bending, it is crucial to understand the position of the neutral axis and the stress distribution. This member, characterized by a single plane of symmetry, exhibits a uniform stress distribution, with negative stress above the neutral axis and positive stress below. Notably, the neutral axis does not align with the centroid of the cross-section. This misalignment is typical in cases where the cross-section is not rectangular or...
Three-Dimensional Analysis of Strain01:29

Three-Dimensional Analysis of Strain

Three-dimensional strain analysis is crucial for understanding how materials deform under stress, particularly in elastic, homogeneous materials. This method employs principal stress axes to simplify complex stress states into more understandable forms. Subjected to stress, a small cubic element within a material either expands or contracts along these axes, transforming into a rectangular parallelepiped. This transformation effectively illustrates the material's deformation. The principal...

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Printing Thermoresponsive Reverse Molds for the Creation of Patterned Two-component Hydrogels for 3D Cell Culture
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Printing Thermoresponsive Reverse Molds for the Creation of Patterned Two-component Hydrogels for 3D Cell Culture

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ソフトマターの3次元印刷

Ryan L Truby1,2, Jennifer A Lewis1,2

  • 1John A. Paulson School of Engineering and Applied Sciences, Harvard University, Cambridge, Massachusetts 02138, USA.

Nature
|December 16, 2016
PubMed
まとめ
この要約は機械生成です。

光とインクベースの3Dプリントは,調整可能な性質を持つ迅速で費用対効果の高い柔らかい物質の製造を可能にします. この高度なアディティブ製造は ソフトロボティクスやセンサーなどの分野で 革新を促しています

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科学分野:

  • 材料科学
  • 製造エンジニアリング
  • ロボット

背景:

  • 伝統的な製造は高価なツールとマスクに依存しています
  • アディティブ・マニュファクチャリングは 迅速なプロトタイピングと製造を可能にします
  • 先進的な応用には 調整可能な性質を持つ柔らかい物質が不可欠です

研究 の 目的:

  • 光とインクによる3Dプリントの 可能性を強調するためです
  • 柔らかい物質の 添加物製造の可能性を紹介する
  • 3Dプリントによって可能になったイノベーションを 示すためにです

主な方法:

  • 光とインクベースの3D印刷技術を使用します.
  • プログラム可能な構成とアーキテクチャを持つ製造材料
  • 調節可能な機械的,電気的,機能的特性を探求する.

主要な成果:

  • 複雑な材料の迅速な,ツールレスな製造を証明した.
  • 材料の性質と構造を正確に制御できる
  • 生物学的にインスパイアされた複合材料 形状変形システム ソフトセンサ ロボット工学

結論:

  • 3Dプリントは 柔らかい物質の製造に革命を起こします
  • アディティブ・マニュファクチャリングは 様々な科学技術分野におけるイノベーションを促進します
  • この技術は以前は不可能だった 材料や装置の作成を可能にします