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Factors Affecting Workability01:24

Factors Affecting Workability

220
The workability of concrete is a critical characteristic that influences the ease of mixing, handling, and finishing the concrete. It is affected by several factors including water content, aggregate properties, and admixtures like air entrainment. Water plays a fundamental role as it lubricates the concrete mix, facilitating easier movement and placement. However, the water requirement varies depending on the texture and shape of aggregates. Finer particles and angular, rough-textured...
220
Compacting Factor test01:22

Compacting Factor test

435
The compacting factor test is a method used to assess the workability of concrete. It is  especially suitable for concrete mixes containing aggregates up to one and a half inches in size. This test involves specialized equipment consisting of two truncated cone-shaped hoppers and a cylinder, all with polished interior surfaces to minimize friction.
The procedure begins by placing concrete into the upper hopper without any compaction. Once filled, the bottom door of this hopper is opened,...
435
Fineness of Cement01:15

Fineness of Cement

367
The fineness of cement directly influences the rate of hydration, as the hydration begins at the surface of the cement particles. In addition to hydration, the fineness of cement is vital for various properties of concrete including workability, gypsum requirement, and long-term behavior. The fineness of cement is represented in terms of the specific surface of cement which is typically measured in square meters per kilogram, with several methods available for this determination.
Direct...
367
Strength and Heat of Hydration01:29

Strength and Heat of Hydration

532
The hydration of cement is an exothermic reaction in which heat is generated as cement hydrates. This heat of hydration is critical to cement's strength development. The rate at which this heat is generated affects the temperature rise, with a majority of the heat being released early in the hydration process, half within the first three days, and about 75% within the first week.
The heat of hydration for each cement compound is significant; for instance, tricalcium aluminate (C3A) and...
532
Additives and Fillers in Concrete01:29

Additives and Fillers in Concrete

238
Additives and fillers are integral to enhancing the properties of concrete. Pozzolans and blast-furnace slag are additives or admixtures due to their reactions with calcium hydroxide released during cement hydration. Fillers, which are finely ground and similar in fineness to Portland cement, improve concrete attributes such as workability density, and reduce capillary bleeding or cracking. Some fillers possess hydraulic properties or participate in benign reactions within the cement paste.
The...
238
Types of Cement II01:22

Types of Cement II

291
Portland blast-furnace cement is made by blending Portland cement clinker with granulated blast-furnace slag, which accounts for 25 to 65 percent of the cement's weight. Despite its similarities to ordinary Portland (Type I) cement in terms of fineness and setting times, its early strength is lower, though it achieves comparable strength later on. It's particularly suited for mass concrete structures and marine environments due to its lower heat of hydration and superior sulfate...
291

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Related Experiment Video

Updated: Dec 11, 2025

Negative Additive Manufacturing of Complex Shaped Boron Carbides
06:45

Negative Additive Manufacturing of Complex Shaped Boron Carbides

Published on: September 18, 2018

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What We Should Consider for Full Densification when Sintering.

Suk-Joong L Kang1

  • 1Department of Materials Science and Engineering, Korea Advanced Institute of Science and Technology (KAIST), Daejeon 34141, Korea.

Materials (Basel, Switzerland)
|August 23, 2020
PubMed
Summary
This summary is machine-generated.

Achieve full powder densification by preventing gas and pore entrapment. Controlling grain growth is key to avoiding pore entrapment during sintering for improved material properties.

Keywords:
densificationentrapped gasesfast firingflash sinteringgrain boundarygrain growthmicrostructural evolutionpore entrapmentspark plasma sinteringtwo-step sintering

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Area of Science:

  • Materials Science
  • Powder Metallurgy
  • Ceramics Engineering

Background:

  • Full densification of powder compacts is crucial for optimal material performance.
  • Pore and gas entrapment hinder the densification process, leading to defects.
  • Understanding grain growth mechanisms is essential for controlling pore evolution.

Purpose of the Study:

  • To provide general directions for promoting full densification in powder metallurgy.
  • To emphasize strategies for preventing pore entrapment through grain growth control.
  • To discuss current techniques for enhancing densification while suppressing grain growth.

Main Methods:

  • Review of general principles for avoiding gas and pore entrapment.
  • Focus on grain growth control as a method to prevent pore entrapment.
  • Description and discussion of existing techniques that enhance densification and suppress grain growth.

Main Results:

  • Identified two critical factors to avoid for full densification: insoluble gas entrapment and isolated pore entrapment within grains.
  • Highlighted grain growth control as a primary strategy to prevent pore entrapment.
  • Summarized and analyzed techniques that simultaneously promote densification and inhibit grain growth.

Conclusions:

  • Preventing gas entrapment and controlling grain growth to avoid pore entrapment are vital for achieving full powder densification.
  • Grain growth control offers a promising pathway to enhance sintering and material integrity.
  • Further investigation into available techniques can optimize powder processing for superior material properties.