What is superheated steam? What is saturated steam? When water molecules exist in a gaseous-state at a temperature above the boiling temperature of water, it is called the superheated steam-state. When at the boiling-temperature, the steam is called saturated steam. The boiling temperature depends on the pressure (e.g. 100°C for 1 atmosphere, or 134°C for 3 atmosphere and so on).
What is the difference between saturated steam and superheated steam? Saturated steam is steam at the boiling point whereas superheated steam is at a higher temperature that the boiling point (at that pressure). The main difference between saturated and superheated steam is that the saturated steam is at a two-phase stability temperature – so could contain water droplets, whereas the higher-temperature superheated steam is a high enthalpy gas (called high quality steam) with considerably more work potential. Work potential enables mechanical work and chemical reactions. Saturated steam is often classified as a low quality steam.
What is high-temperature superheated steam? Steam at 300°C and above the boiling point is broadly classified as high-temperature superheated steam*. For many modern applications of steam, the steam temperature has to be much higher than the boiling temperature (well into the superheated steam temperature range). How is it made? In rapid steam-generators whereas saturated steam is made in slow-boilers. Modern steam generators avoid the requirement of requiring high pressures unlike traditional-boilers. Instantly made high quality-clean steam with high temperatures ranging from 300°C to 1300°C is now available for many beneficially steam applications. The temperature for most combinatory-steam applications should be higher than the inversion temperature (typically above 260°C) for reaping the benefits of a superheated-steam enabled processes like drying, bio-energy, high level cleaning, energy production, antimicrobial, bio-digestion, chemical reactions and many others become possible where work potential is required. A new area of research is the combinatory steam area for energy reduction. * MHI definition is invoked. The temperature of good superheated steam is above any inversion temperature and much higher than the equilibrium saturation temperature. The equilibrium saturation temperature is the temperature (at a given pressure) where water or water droplets can coexist with steam-gas egg the boiling point 100°C at 1 Bar or 121°C at 2 bar and so on. 4DSintering is a registered MHI Trademark.
Where is high temperature steam typically used?Antimicrobial Use, Oxidation and Erosion Studies, Food Industry, Packaging, Chemicals, Materials. Bio-processes, Energy, Hydrolysis, Process Heating, Flavors, Drying,Textiles and even for the Simulation of Martian Atmospheres (Nature, December 2017).
What superheated-steam is not? It is not mist nor fog. Mist and fog have some water droplets in the gas, and thus the name fog. View comparison pictures of the difference between mist/fog-steam and a high temperature steam-gas even when produced such that the nozzle area has no mist.. In the picture please note that MHI steam generators produce mist free gas.
How is good high temperature steam superheated steam made? Such steam is often produced efficiently by special patent protected steam generators without the need for any pressure requirement during the generation process. When the steam is at a high temperature, especially above the inversion temperature, key-applications like continuous rapid drying, rapid heat transfer, reforming type reactions, cleaning at many levels,or bio-energy and other rapid reactions become feasible. Steam generators are very rapid acting (produce steam within seconds). Superheated steam often leads to a reduction in the number of boilers, a reduction in the feed water usage, reduction in boiler load, improvement in the process timing, a reduction in the reagents, and emulsification with a overall better yield. Inquire about 3DPrinting and 4DSintering with steam.
Why are these devices only possible from MHI? MHI uses patented nano-structured surfaces and other novel materials which have only recently become available commercially for use with active steam. MHI combines decades of thermal know-how and recent patented technologies with with the well accepted/reliable MHI control systems for high power and high-temperature delivery of steam. It is a part of MHI’s overall development scheme of smart power for modern thermal applications. Substantial energy savings result from OAB® steam use.
High-grade, high-quality superheated steam offers a good multiplier to process efficiencies – i.e. it is SmartSteam™. The temperature of the MHI steam models reflect the actual steam temperature. The savings efficiencies reported are from On to Off condition. No requirement to heat any tubes or nozzles to produce steam. Several US and International Patents protect MHI steam generators. MHI Steam generators are influencing the ease of use, and ease of installation of steam devices because of the availability of the higher temperatures from them. In contrast to conventional pressure-boilers, steam generators produce steam quickly on start-up, produce high-quality steam and have less restrictions for piping. Steam Energy Calculator. Videos and Media Gallery.
Very Low to No Moisture even during start-up in the OAB. MHI BoilerFree™ Technology allows for continuous superheated steam generation unlike a boiler which has to fill up a steam chamber then discharge the steam in a batch mode.
Energy efficient is reported socket to output. Nearly 90-99% Outlet to Output Efficiency, MHI Rating.
Zero Combustion or No High-Frequency Processes. No High Frequency Disruption, Zero Device NOX Emissions, No Ventilation Needed for combustion gasses. Offers multiple hot exit choices. More Information
Easy Fit to Industrial Production Machines and Tunnels
Energy Saving Tunnels
Industries where superheated steam is used: Energy, Cleaning, Textile Processing, Pulp and Paper, Cooking, Drying, Disinfection and Sterilization, Cleaning and Recycling, Drying Paint, Drying Machine Parts, Re-forming Surfaces. Food and storage products, Tobacco Products, Textile Mill Products, Apparel and Other Textile Products, Lumber and Wood Products, Bio mass energy, Bio Pharma, Oxidation studies (inorganic and organic), Paper and Allied Products, Steam spray in hospital uses, green house, soil, Printing and Publishing, Chemicals and Allied Products, Petroleum and Coal Products, Petroleum Refining, Rubber and polymers, steam injection, emulsification, Plastics Products, Leather and Leather Products, Stone, Clay and Glass Products, Cement, Grain, Cannola, Alfa-alfa.
Industries where continuous steam is used: Hydraulic, Primary Metal Industries, Blast Furnace and Basic Steel Products, Fabricated Metal Products, Industrial Machinery and Equipment, Electronic and Other Electric Equipment, Transportation Equipment, Instruments and Related Products, Chemicals/Petrochemicals, Electronics, Oil and Gas, Ethanol, pre-treatment of biomass, Pyrolysis, Oil, herbs, Steam Reforming, Complex Methane Ammonia Producing Reactions, Hydrogen reforming, Biodiesel fuels, Finishing, Food, Packaging, Printing, Paper, Pulp, Converting, Forest Products, Pharmaceuticals, Plastics, Rubber, Batteries, Electrode drying, Vinyl, Bio-solids, Sanitation, Disinfection, WGSR reactions, Low oxygen content H2O gas, so dry and could sometimes even be for sterilization, Soil re mediation, steam stripping of Volatile, industrial propane dehydrogenation processes, Pulp, hog/animal-fuel, clean or emulsify bark sludges, Reverse water gas-shift reactions and flavor reactions, Lumber and/or efficient Paper-drying, peat/jute drying, Gasification-reactor, Consider for vacuum production steam in ejector nozzles with steam or steam air mixes with over 50m/s steam exit velocity, Textile-drying, Drying. Swelling Starch, Starch Granules, Starch Gelatinization. Cleaning with MightySteam • Humidification for Dry and Humid Atmospheres in Ceramic, Paper Rolls and Comfort Processing, Work and Propulsion by Steam, Heating and Sterilization, Vacuum, Oven-use. Atomization of Fluids, Motorization and modification
Steam Chambers up to 1300C for oxidation studies and food contact studies in a pure steam environment.
Steam for Packaging and Textiles
While several applications offer down-the-line energy-efficiencies with high temperature superheated steam use, one typical application is to make hydrogen with steam reforming of methane or organic materials, here the higher temperatures give rise to considerably better efficiencies of reactions. Food Safety Use. Dryer Configurations: Batch/Cabinet, Can/Drum, Continuous/Conveyor, Deck, Loop, Loft, Paddle, Ring, Roll/Cylinder, Rotary, Shelf/Tray/Truck, Skin (both artificial and inorganic), Tensionless, Frame, Tower, Tunnel, Warp, Web, Wicket. Dryer Types Possible: Centrifugal, Combination Infrared/Convection, Attenuate CFC and HCFC Conduction, Convection – Counter flow, Convection – Impingement, Convection -Flotation, Convection, -Through-Air, Dehumidifying, Flash, Fluid-Bed, Infrared – catalytic, Infrared – Long -wave, Infrared – Medium-wave, Infrared – Short -wave, Microwave, Radio Frequency, Spray, Steam, Vacuum. Energy Source: Dual Fuel, Electricity, Steam. Materials Dried, Food, Paste/Mixes, Powders, Slurries, Solids, Solvent-based Materials, Water-based Materials. Manufacturing Process: Calcining, Curing, Dehydrating, Drying, Dry sand and investment molds, Finishing, Fusing, Granulating, Heat Setting, Acoustics, Research, Heat Shrinking, Laminating, Moisture Profiling, Pasteurizing, Pre-and Post-Drying. Industries Served: Chemicals/Petrochemicals, Electronics, Oil and Gas, biotic and abiotic cleaning, Ethanol, Biodiesel Fuels, Hydrolysis, Finishing, Food, Packaging, Printing, Paper, Pulp, Converting, Forest Products, Pharmaceuticals, Plastics, Rubber, functionalize graphite, graphine, Boron nitride, Vinyl. Biosolids, includes Sterilization, Soil remediation-steam stripping of volatile, pulp, hog-fuel, bark sludges, Paper Drying, Peat/Jute Drying gasification reactor, Textile drying, salt drying and reclamation. Should you be using steam, steam, water and steam air mixes in deSuperheaters, a better control could be directly with OAB or HGA-M models.
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