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Related Concept Videos

Plastic Deformations01:19

Plastic Deformations

477
Plastic deformation represents a fundamental concept in materials science, which explains the irreversible change in the shape of a material when it experiences stress beyond its elastic capability. This phenomenon is important in structural engineering, especially in designing and analyzing cantilever beams—structures that are securely fixed at one end and bear loads at the opposite end. When these beams are subjected to loads within their elastic range, they will return to their...
477
Plastic Deformations01:14

Plastic Deformations

477
It is essential to understand how structural members behave under plastic deformation when the bending stress exceeds the material's yield strength. This state of deformation permanently alters the shape of the member, in contrast to the linear elastic behavior observed before yielding. The strain at any point in the member is expressed in terms of maximum strain. Notably, the neutral axis, which coincides with the centroid during elastic bending, shifts away from the centroid under plastic...
477
Temperature Dependent Deformation01:12

Temperature Dependent Deformation

415
In a nonhomogeneous rod made up of steel and brass, restrained at both ends and subjected to a temperature change, several steps are involved in calculating the stress and compressive load. Due to the problem's static indeterminacy, one end support is disconnected, allowing the rod to experience the temperature change freely. Next, an unknown force is applied at the free end, triggering deformations in the rod's steel and brass portions. These deformations are then calculated and added...
415
Deformations in a Symmetric Member in Bending01:18

Deformations in a Symmetric Member in Bending

528
When analyzing the deformation of a symmetric prismatic member subjected to bending by equal and opposite couples, it becomes clear that as the member bends, the originally straight lines on its wider faces curve into circular arcs, with a constant radius centered at a point known as Point C. This phenomenon helps to understand the stress and strain distribution within the member more clearly.
When the member is segmented into tiny cubic elements, it is observed that the primary stress...
528
Deformation of Member under Multiple Loadings01:11

Deformation of Member under Multiple Loadings

491
When a rod is made of different materials or has various cross-sections, it must be divided into parts that meet the necessary conditions for determining the deformation. These parts are each characterized by their internal force, cross-sectional area, length, and modulus of elasticity. These parameters are then used to compute the deformation of the entire rod.
In the case of a member with a variable cross-section, the strain is not constant but depends on the position. The deformation of an...
491
Deformation in a Circular Shaft01:10

Deformation in a Circular Shaft

936
One of the distinctive characteristics of circular shafts is their ability to maintain their cross-sectional integrity under torsion. In other words, each cross-section continues to exist as a flat, unaltered entity, simply rotating like a solid, rigid slab. To understand the distribution of shearing stress within such a shaft, consider a cylindrical section inside this circular shaft. This section has a length of L and a radius of R, with one end fixed. The radius of the cylindrical section is...
936

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Related Experiment Video

Updated: Feb 14, 2026

Flapping Soft Fin Deformation Modeling using Planar Laser-Induced Fluorescence Imaging
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Cardiac fluid dynamics meets deformation imaging.

Matteo Dal Ferro1, Davide Stolfo1, Valerio De Paris1

  • 1Cardiovascular Department, Azienda Ospedaliera Universitaria Integrata of Trieste, Trieste, Italy.

Cardiovascular Ultrasound
|February 21, 2018
PubMed
Summary
This summary is machine-generated.

Understanding cardiac function involves myocardial deformation to create blood flow. Recent advances link heart mechanics and intra-ventricular fluid dynamics, offering new clinical insights.

Keywords:
Cardiac fluid dynamicsDeformation imagingHemodynamic forcesIntraventricular pressure gradientSpeckle tracking

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Area of Science:

  • Cardiovascular Physiology and Biomechanics
  • Medical Imaging and Fluid Dynamics

Background:

  • Cardiac function relies on myocardial deformation to generate blood flow.
  • A strong relationship exists between cardiac function and intra-ventricular fluid dynamics.
  • Deformation imaging has advanced the understanding of cardiac mechanics.

Purpose of the Study:

  • To summarize recent advances in cardiac flow evaluations.
  • To highlight the relationship between cardiac flow and heart wall mechanics.
  • To discuss the clinical perspectives of integrating fluid dynamics and deformation imaging.

Main Methods:

  • Review of recent studies on cardiac flow and mechanics.
  • Assessment of heart wall mechanics using advanced deformation imaging techniques.
  • Integration of fluid dynamics principles with volumetric and deformation assessments.

Main Results:

  • Evidence of an intimate relationship between cardiac function and intra-ventricular fluid dynamics.
  • Deformation imaging provides insights into cardiac mechanics.
  • Fluid dynamics can enhance the understanding of cardiac mechanics beyond traditional assessments.

Conclusions:

  • Integrating cardiac flow dynamics with deformation imaging offers a deeper understanding of cardiac mechanics.
  • This emerging field holds promising clinical perspectives for cardiovascular assessment.
  • Combining fluid dynamics with volumetric and deformation data enhances knowledge of cardiac mechanics.