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Fatigue Strength of Concrete01:22

Fatigue Strength of Concrete

305
Fatigue, in the context of materials science and engineering, refers to the weakening or failure of a material caused by repeatedly applied loads, even if these loads are below the strength limit of the material. Fatigue strength in concrete is a critical property that influences its durability and longevity. Concrete can fail in two ways due to fatigue. Static fatigue or creep rupture occurs under a constant load or one that increases slowly. The other failure mode is due to cyclical or...
305
Fatigue01:21

Fatigue

263
Fatigue occurs when materials rupture under repeated or fluctuating loads, even at stress levels far below their static breaking strength. It typically results in brittle failure, even for ductile materials. It is a critical consideration in designing machines and structural components subjected to repetitive or varying loads. The nature of these loadings can range from fluctuating loads like unbalanced pump impellers causing vibrations to repeatedly bending a thin steel rod wire back and forth...
263
Non-destructive Tests for Concrete Strength01:12

Non-destructive Tests for Concrete Strength

203
The rebound hammer test, also known as the Schmidt hammer test, is a non-destructive technique for evaluating the hardness of concrete and, indirectly, the strength of concrete. It operates on the principle that the rebound of a spring-driven mass from a concrete surface correlates to the surface's hardness. The device comprises a mass within a tubular housing, a spring mechanism, and a plunger that strikes the concrete. Upon release, the energy imparted to the mass by the spring causes it...
203
Measurement of Air Content in Concrete01:23

Measurement of Air Content in Concrete

301
Air content measurement in concrete is critical for ensuring structural integrity and durability of concrete structures, especially in environments prone to severe weather conditions. Accurate air content analysis optimizes concrete's resistance to freeze-thaw cycles and enhances its workability and strength. Several methods are standardized under ASTM guidelines to measure the air content in fresh concrete, each suitable for different concrete types and conditions.
The pressure method,...
301
Tensile Strength Considerations of Concrete01:16

Tensile Strength Considerations of Concrete

212
Considering the tensile strength of concrete involves recognizing that the theoretical strength of cement paste can be up to a thousand times higher than what is observed in practical applications. This significant discrepancy is largely attributed to the presence of microscopic cracks within the concrete. These cracks tend to amplify stress at their tips when a load is applied, a phenomenon explained by Griffith's theory of brittle fracture.
The dimensions and shape of a concrete specimen...
212
Abrasion Resistance of Concrete01:23

Abrasion Resistance of Concrete

246
Abrasion resistance is an essential characteristic of concrete that determines its durability and longevity under various wear conditions. Concrete surfaces are vulnerable to different types of abrasion. For instance, surfaces may wear down due to the constant movement of vehicles or be eroded by solids carried in water, as seen in concrete canal linings. Specific tests are conducted to measure the abrasion resistance of concrete.
One such test is the revolving disc test, where three plates...
246

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Updated: Sep 26, 2025

Measuring the Motor Aspect of Cancer-Related Fatigue using a Handheld Dynamometer
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Fatigue Measurements in an Existing Highway Concrete Bridge.

Harald Schuler1, Martin Müller1

  • 1School of Architecture, Civil Engineering and Geomatics, FHNW University of Applied Sciences and Arts Northwestern Switzerland, Hofackerstrasse 30, 4132 Muttenz, Switzerland.

Sensors (Basel, Switzerland)
|April 23, 2022
PubMed
Summary
This summary is machine-generated.

Accurately assessing bridge structural safety requires understanding actual fatigue loads. This study measures fatigue effects on a bridge, separating long-term and short-term impacts from truck traffic.

Keywords:
bridge monitoringfatigue loadsmaintenancetruck passage

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Area of Science:

  • Civil Engineering
  • Structural Engineering
  • Materials Science

Background:

  • Accurate assessment of bridge structural safety is crucial, especially when loads change or increase.
  • Understanding actual fatigue effects is key to reliable structural integrity evaluations.
  • Existing methods may not fully capture real-world fatigue loading conditions.

Purpose of the Study:

  • To measure and record actual fatigue loads at a critical point on an existing bridge.
  • To differentiate between long-term and short-term fatigue effects.
  • To count load amplitudes from individual truck passages.

Main Methods:

  • Field measurement and data recording of fatigue loads on a bridge.
  • Signal processing techniques to separate long-term and short-term effects.
  • Amplitude counting algorithms to analyze truck-induced loads.

Main Results:

  • Successful measurement and recording of actual fatigue loads were achieved.
  • Effective separation of long-term environmental effects from short-term traffic loads.
  • Quantification of load amplitudes from passing trucks.

Conclusions:

  • Direct measurement provides critical data for accurate bridge fatigue assessment.
  • Distinguishing load types is essential for understanding cumulative fatigue damage.
  • Challenges in field measurements necessitate robust methodologies for reliable data.