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Mechanical Characteristics of Steel01:18

Mechanical Characteristics of Steel

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The mechanical characteristics of steel are assessed through various tests that evaluate its strength, toughness, and flexibility. These tests include tension, torsion, impact, bending, and hardness assessments, each providing crucial information about steel's suitability for specific applications.
The tension test is fundamental for determining tensile strength. In this test, a steel specimen is stretched using a gripping device until it breaks. The data collected during this test are used...
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Engineering by Cuts: How Kirigami Principle Enables Unique Mechanical Properties and Functionalities.

Jiayue Tao1, Hesameddin Khosravi1, Vishrut Deshpande2

  • 1Department of Mechanical Engineering, Clemson University, 224 Fluor Daniel Building, 216 South Palmetto Boulevard, Clemson, SC, 29631, USA.

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Kirigami, the art of paper cutting, engineers advanced materials with unique mechanical properties like shape morphing and super-stretchability. This review surveys kirigami

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Area of Science:

  • Materials Science and Engineering
  • Mechanical Engineering
  • Applied Physics

Background:

  • Kirigami, an ancient art, is now a framework for engineering multi-functional materials.
  • Slit cutting of sheet materials enables unique mechanical behaviors.
  • Kirigami platforms integrate electronic and responsive components for advanced applications.

Purpose of the Study:

  • To provide a comprehensive survey of recent advances in kirigami-based engineering.
  • To detail unique mechanical properties induced by kirigami cutting.
  • To explore underlying physical principles and applications of kirigami structures.

Main Methods:

  • Review of academic literature on kirigami.
  • Analysis of design methodologies and mechanics modeling.
  • Exploration of advanced fabrication techniques and material science integration.

Main Results:

  • Kirigami cutting imparts desirable mechanical properties (shape morphing, auxetics, super-stretchability, buckling, multistability) to sheet materials.
  • Kirigami structures serve as versatile platforms for embedding electronic and responsive components.
  • Significant research activity highlights the potential of kirigami in metamaterials, sensors, and soft robotics.

Conclusions:

  • Kirigami engineering offers a promising discipline for developing next-generation materials and devices.
  • Synergies between design, mechanics, fabrication, and material science are crucial for advancing kirigami.
  • Continued research will mature kirigami-based engineering for diverse applications.