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Curing of Concrete01:20

Curing of Concrete

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The hydration of cement takes place within the water-filled capillary pores. However, environmental elements can disrupt this process by evaporating water from the concrete surfaces. Sealed concrete with a water-cement ratio below 0.5 experiences self-desiccation, leading to water loss. The water loss in concrete is mitigated by curing. This technique involves keeping the concrete saturated to maintain the necessary temperature and moisture conditions, to optimally fill the spaces in the cement...
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Curing Methods01:26

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Concrete members with a small surface-to-volume ratio are cured by oiling and moistening the forms before casting the concrete member. These forms can be left in place for a prolonged period to prevent moisture loss, and can be wetted if made of a material suitable for wetting. If the forms are removed early, the concrete member is moistened and covered with polythene sheets to maintain moisture. For large horizontal concrete surfaces exposed to dry weather, a temporary covering is suspended...
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Accelerating concrete curing is achieved by applying heat and additional moisture. This process accelerates the hydration of the cement, resulting in an earlier strength gain in the concrete. Steam curing is a method wherein the concrete products are either transported through a chamber on a conveyor belt or encased in plastic, allowing steam at atmospheric pressure to circulate freely around them. This process begins with a phase of moist curing that typically lasts between 3 to 5 hours, after...
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Metallic solids such as crystals of copper, aluminum, and iron are formed by metal atoms. The structure of metallic crystals is often described as a uniform distribution of atomic nuclei within a “sea” of delocalized electrons. The atoms within such a metallic solid are held together by a unique force known as metallic bonding that gives rise to many useful and varied bulk properties.
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Solids in which the atoms, ions, or molecules are arranged in a definite repeating pattern are known as crystalline solids. Metals and ionic compounds typically form ordered, crystalline solids. A crystalline solid has a precise melting temperature because each atom or molecule of the same type is held in place with the same forces or energy. Amorphous solids or non-crystalline solids (or, sometimes, glasses) which lack an ordered internal structure and are randomly arranged. Substances that...
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Fabrication of Engineered Vascular Flaps Using 3D Printing Technologies
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Photopolymerizable Resins for 3D-Printing Solid-Cured Tissue Engineered Implants.

Antonio J Guerra1,2, Hernan Lara-Padilla2,3, Matthew L Becker4

  • 1Mechanical Engineering and Civil Construction, Universitat de Girona, Girona, Spain.

Current Drug Targets
|January 17, 2019
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Summary
This summary is machine-generated.

Advancements in 3D printing materials are crucial for regenerative medicine. This review details photopolymerizable resins and 3D printing methods for creating resorbable scaffolds and medical devices.

Keywords:
Additive manufacturing (3D printing)Digital Light Processing (DLP)Digital Micromirror Device (DMD)Liquid Crystal Display (LCD)biocompatibilityco-crosslinkercrosslinkercytotoxicitydispersantemulsifierfabrication additivelight attenuatormask projectionphotocrosslinkingphotoinitiatorregenerative medicinestereolithographytissue engineering.

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Area of Science:

  • Biomaterials Science
  • Regenerative Medicine
  • Polymer Chemistry

Background:

  • 3D printing enables new resorbable polymeric materials for medical applications.
  • Limited biocompatible photo-crosslinkable polymers and additives hinder biofabrication.
  • Advances are needed for 4D properties of 3D printed scaffolds for regenerative medicine.

Purpose of the Study:

  • To review common photopolymerizable resins for 3D printed scaffolds and medical devices.
  • To discuss methodological advances in 3D printing tissue-engineered implants.
  • To highlight the need for expanded material options in clinical use.

Main Methods:

  • Review of photopolymerizable resins including polyethylene glycol (PEG), poly(D, L-lactide) (PDLLA), poly-ε-caprolactone (PCL), and poly(propylene fumarate) (PPF).
  • Discussion of 3D printing techniques such as stereolithography (SLA), continuous Digital Light Processing (cDLP), and Liquid Crystal Display (LCD).

Main Results:

  • Identified key photopolymerizable resins and their properties for 3D printing.
  • Outlined advancements in 3D printing methodologies for tissue engineering.
  • Highlighted limitations in current material availability and biocompatibility.

Conclusions:

  • Development of novel resorbable polymers and additives is essential for advanced 3D bioprinting.
  • Further research into material properties and 3D printing techniques will drive regenerative medicine.
  • Expanding the library of clinically validated materials is critical for future applications.