Description
Hydrothermal Reactors and Autoclaves (SS – 316)
- -Designed for hydrothermal synthesis, a method involving chemical reactions in high-temperature and high-pressure water environments
- -Entirely constructed with stainless steel to ensure corrosion resistance and durability
- -Capable of withstanding elevated temperatures and pressures, creating an ideal environment for hydrothermal reactions
- -Widely used in materials science, nanotechnology, and organic synthesis for the production of nanoparticles, nanocomposites, and unique materials
- -Suitable for various reactions, including crystallisation, polymerization, and modification of materials under hydrothermal conditions
- -Stainless steel construction enhances safety by preventing corrosion or contamination of the reaction mixture
- -Engineered with precision to control temperature and pressure parameters, ensuring the reproducibility of experiments
- -The stainless steel design facilitates easy cleaning and maintenance, crucial for consistent and reliable performance
- -Widely utilised in research institutions, universities, and laboratories for innovative studies and experiments in the field of hydrothermal chemistry
- -Stainless steel hydrothermal reactors offer a cost-effective solution for researchers requiring a robust and corrosion-resistant apparatus for their experiments
Hydrothermal Reactors and Autoclaves (Made of Titanium):
- -Hydrothermal reactors are vessels designed to handle high-pressure and high-temperature conditions for chemical reactions
- -When constructed entirely of titanium, these reactors exhibit exceptional corrosion resistance and durability
- -Titanium’s resistance to corrosion makes it ideal for applications involving harsh chemical environments, such as hydrothermal reactions
- -Hydrothermal reactors are used in processes where water is a solvent under extreme conditions, typically above its critical point (374°C and 221 bar)
- -Titanium’s strength and resistance to corrosion enable these reactors to withstand the demanding pressure and temperature requirements
- -Titanium hydrothermal reactors find applications in various chemical processes, including the synthesis of nanoparticles, organic compounds, and hydrothermal carbonisation
- -They are utilised for catalytic reactions and the synthesis of advanced materials due to their ability to maintain integrity under aggressive hydrothermal conditions
- -Titanium’s stability and inertness ensure the precision and reliability of hydrothermal reactions, contributing to consistent and reproducible experimental outcomes
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