Water and steam properties

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Water and Steam Properties, known as WASP, is a Windows 95 application Water and Steam Properties, known as WASP the physical properties of ice, water and steam. HVAC Solution - Pro. 282. Steam-water-properties is a comprehensive steam

Water And Steam Properties Download - Water and Steam Properties

Water And Steam Properties for Windows 19.0DownloadWater and Steam Properties, known as WASP, is a Windows 95 application3.7 7 votes Your vote:Latest version:2.0.36See allDeveloper:Katmar SoftwareReviewDownloadComments Questions & Answers 1 / 2Awards (1)Show all awardsUsed by 3 peopleAll versionsWater And Steam Properties for Windows 2.0.36 (latest)DownloadEdit program infoInfo updated on:Nov 02, 2024Software InformerDownload popular programs, drivers and latest updates easilyNo specific info about version 19.0. Please visit the main page of Water And Steam Properties for Windows on Software Informer.Share your experience:Write a review about this program Comments 3.77 votes32011Your vote:Notify me about replies Comment viaFacebookRelated software EPANET FreeSimulate and run complete analysis of hydraulic systems.Oligo Analyzer FreePowerful tool to evaluate physical properties of primersSteam and Water Properties A comprehensive steam table software for finding steam and water properties.Physical Properties Estimation Can estimate physical properties for pure components based on correlations.ADIOS 2 FreeADIOS2 (Automated Data Inquiry for Oil Spills) is an oil weathering model.Related storiesSee allSpotlight: File Explorer in Windows 11The GFS backup strategy: never lose your data (again)6 free backup tools for WindowsHow to get Windows 11 24H2, and what’s special about itRelated suggestionsWater steam properties waspSteam table .xlsSearch wasp appProperties water calculatorWindows 7.1Steam tables applicationKatmar wasp software free downloadUsers are downloadingSurferSTATISTICAQM for WindowsTunerPro RTChemDraw ProDicktator Saturated Water and Superheated Steam Water Properties Calculator.This calculator handles English and Metric units of measurement, and by entering search values (handles decimals) within the established technical parameters, it delivers the following results:For Saturated Water Properties:- Absolute Pressure (kPa abs. - Psia)- Temperature (°C - °F)- Saturated Liquid Specific Volume (m3/kg - ft3/lbm)- Specific Volume of Saturated Steam (m3/kg - ft3/lbm)- Saturated Liquid Internal Energy (kJ/kg - Btu/lbm)- Internal Evaporation Energy (kJ/kg - Btu/lbm)- Internal Energy of Saturated Steam (kJ/kg - Btu/lbm)- Saturated Liquid Enthalpy (kJ/kg - Btu/lbm)- Enthalpy of Evaporation (kJ/kg - Btu/lbm)- Saturated Steam Enthalpy (kJ/kg - Btu/lbm)- Saturated Liquid Entropy (kJ/kg*K - Btu/lbm*R)- Entropy of Evaporation (kJ/kg*K - Btu/lbm*R)- Saturated Steam Entropy (kJ/kg*K - Btu/lbm*R).For Properties of Superheated Steam Water:- Absolute Pressure (MPa abs. - Psia)- Temperature (°C - °F)- Specific Volume of Superheated Steam (m3/kg - ft3/lbm)- Internal Energy Superheated Steam (kJ/kg - Btu/lbm)- Superheated Steam Enthalpy (kJ/kg - Btu/lbm)- Entropy of Superheated Steam (kJ/kg*K - Btu/lbm*R).

Properties of Water and Steam

Calculation of pressure drop in steam and water lines The pressure drop in a water & steam lines refers to the decrease in pressure that occurs as water/steam flows through a pipe or conduit due to factors such as friction and flow resistance. Several factors influence the magnitude of pressure drop in a water line:Pipe Characteristics: The diameter, length, and roughness of the pipe impact the resistance to flow and consequently the pressure drop. Smaller diameter pipes and longer pipe lengths tend to result in higher pressure drops. Additionally, rougher pipe surfaces create more friction and increase pressure drop compared to smoother surfaces.Flow Rate: The rate at which water/steam flows through the pipe affects the pressure drop. Higher flow rates generally result in higher pressure drops due to increased frictional resistance.Fluid Properties: The physical properties of the water/steam being transported, such as viscosity and density, can influence the pressure drop. However, for water at typical temperatures and pressures, these effects are usually negligible. Pipe Fittings and Valves: The presence of fittings, such as elbows, bends, valves, and other obstructions in the water line, can contribute to pressure drop. These components disrupt the flow and introduce additional resistance. It's important to note that pressure drop calculations for steam lines can be complex and require a comprehensive understanding of steam properties and fluid dynamics. Pressure drop in water line:Head loss in water line for turbulent flow is given asHead loss in meter = 4fLV2 / (2gD) Where, f = Friction loss in pipe, generally varies from 0.005 to 0.007L = Pipe lengthD = Diameter of the pipeg = Acceleration due to gravity, 9.81 m/s2V = Velocity of the fluid Example:A Boiler feed pump is delivering feed water flow 50 TPH to the boiler at a distance of 70 meter.The steam drum height. Water and Steam Properties, known as WASP, is a Windows 95 application Water and Steam Properties, known as WASP the physical properties of ice, water and steam. HVAC Solution - Pro. 282. Steam-water-properties is a comprehensive steam

Steam Properties, properties of steam or water - taftan.com

SteamTab Quad™Thermodynamic and Transport Properties of Water and SteamAvailable for both Windows and Mac OSX ExcelEngineers working on repair or retrofit legacy steam equipment built in prior times often find the need to compare the performance differences of a design using different steam/water property correlations. At the request of those who have this need, ChemicaLogic put all 4 commonly used steam/water properties formulations in one package as SteamTab Quad™. ChemicaLogic SteamTab Quad™ Version 4.0 is a spreadsheet add-in software for thermodynamic and transport properties of water and steam. SteamTab Quad™ V4.0 makes available all 4 commonly used steam/water properties formulations (1. IAPWS-95, 2. the older NBS/NRC-84, 3. IAPWS-IF97 and 4. the older IFC-67) in one package. SteamTab Quad V4.0 EnhancementsWindows: Compatible with Excel 2016/2013/2010 on Windows 10/8.x./7 (and maintains compatibility with Excel 2003, 2007 running on Windows XP and later).Windows: Supports both 32-bit and 64-bit Excel 2016/2013/2010.Mac OSX: Microsoft Excel 2011 (New) Includes automatic installation (and uninstalling) on the supported platforms.Fully compatible with all previous versions of SteamTab Quad.The ability to use a numeric property code as well as a mnemonic string (the string version is case insensitive). For example, to calculate the enthalpy of steam you can use either 8 or “H”. Added two new properties: the isentropic exponent and latent heat of vaporization. Model ComparisonsUsing this unique tool, we are now able to compare the results of the different models. Our analysis is presented here.Product InformationFeatures unique to this product are described here. Pricing information is also available.Technical InformationFind out about the technical basis for this product.PricingOur pricing policy.DemoWe have a fully functional version of SteamTab Quad available for your evaluation. Download it now!DownloadsIn addition to the demo, we have collected all of the free downloads available and catalogued them in one convenient page. Home Blog Gastroenterology Top 10 Home Remedies for Chest Congestion Here are ten home remedies that can help alleviate chest congestion: Steam inhalation : Inhale steam from a bowl of hot water or take a hot shower. The steam helps to loosen mucus and relieve congestion. Warm fluids : Drink warm liquids such as herbal tea, clear broths, or warm water with honey and lemon. This can help soothe the throat and thin mucus. Honey : Add a teaspoon of honey to warm water or herbal tea. Honey has natural antibacterial and soothing properties that can help relieve chest congestion and cough. Ginger : Drink ginger tea or chew on a small piece of fresh ginger. Ginger has expectorant properties that can help break up mucus and relieve congestion. Eucalyptus oil : Add a few drops of eucalyptus essential oil to hot water and inhale the steam. Eucalyptus oil can help clear the airways and relieve chest congestion. Warm compress : Apply a warm compress or hot water bottle to your chest for a few minutes. The warmth can help loosen mucus and provide relief. Elevate your upper body : Prop yourself up with pillows or sleep with your head elevated to help ease chest congestion and promote easier breathing. Garlic : Include garlic in your diet or chew on a small piece of raw garlic. Garlic has antimicrobial properties that can help fight infections and relieve congestion. Stay hydrated : Drink plenty of fluids, preferably warm or at room

Water And Steam Properties Download - Water and Steam

Of water will raise its temperature until it boils. Once the substance reaches the necessary temperature at a given pressure to change state, the addition of latent heat causes the substance to change state. Adding latent heat to the boiling water does not get the water any hotter, but changes the liquid (water) into a gas (steam). 2. One can state that a certain amount of heat is required to raise the temperature of a substance 1°F. This energy is called the specific heat capacity. The specific heat capacity of a substance depends upon the volume and pressure of the material. For water, the specific heat capacity is 1 BTU/lbm-°F and remains constant. This means that if we add 1 BTU of heat to 1 lbm of water, the temperature will rise 1°F. C. Introduction to Steam Tables 1. When a teapot of water is placed on a hot burner, sensible heat begins to heat the water. The energy added to the water raises its internal energy and its temperature. When the water reaches 212°F, the temperature no longer rises as latent heat begins to change the water from a liquid to a vapor. The mass inside the teapot is slowly changing from a 100% water / 0% steam mixture into a 0% water / 100% steam mixture. If we add only half the necessary latent heat, then only half the water will boil into steam. The result would be a 50% water / 50% steam mixture at 212°F. If we add all the latent heat necessary, then the water at 212°F changes completely into steam at 212°F. Continuing to add heat to the 212°F steam results in a temperature increase (superheating), and we are again raising the temperature by adding sensible heat. Refer to figure 3.2-1 (sensible/latent heat and enthalpy). 2. While the properties of water at atmospheric pressure are commonly known, water under different pressures will exhibit different properties. When water is boiled at pressures higher than atmospheric, the same events occur as described above with two exceptions. First, the boiling temperature will be higher than 212°F. Second, less latent heat is required to be added to change the water completely into steam. If water were to be boiled at a pressure lower than atmospheric pressure, then we would find that the boiling temperature would be less than 212°F and a larger amount of latent heat would be required to change the water completely into steam. Refer to figure 3.2-2 (temperature vs. latent heat). a. When water is below the boiling point, the addition of heat is seen as sensible heat. This water is said to be a subcooled liquid. When enough sensible heat is added so that the temperature of the water approaches saturation temperature but no steam has yet been formed, the water is said to be a saturated liquid. b. As the water is transformed from a saturated liquid to saturated steam, boiling is occurring. As latent heat is added, the temperature of the water

Properties of Water and Steam (Thermodynamic Properties

PROPERTIES OF STEAM AND WATER INTRODUCTIONThe process by which we convert water into steam and use the steam to turn a propulsion shaft encompasses the generation and expansion phases of the steam cycle. A study of the properties of water and steam at these critical phases is necessary to understand the steam cycle. This lesson defines terms associated with these properties and processes, and explains the use of steam tables to calculate the work and efficiency created by steam.REFERENCES Basic Thermodynamics Understanding Thermodynamics The Laws of Thermodynamics: A Very Short Introduction (Very Short Introductions) INFORMATION A. Basic Thermodynamic Terms 1. Enthalpy (h), measured in British thermal units per pound (mass), or BTU/lbm, represents the total energy content of steam. It expresses the internal energy and flow work, or the total potential energy and kinetic energy contained within a substance. The advantage of enthalpy is that we can express in one term all of the energy in a substance which is due to its pressure and temperature. Enthalpy values are used to represent the energy level of steam entering a turbine, a value useful for determining turbine efficiency. By superheating steam, we can add enthalpy to steam without raising the pressure of the steam. For example, steam at 620 psig and 850°F can do more work in a turbine than steam that is 620 psig and 650°F. 2. Entropy (s), measured in BTU/lbm-°R, represents the unavailability of energy (°R=Rankine temperature scale where 0°R = absolute zero and 460°R = 0°F). The second law of thermodynamics states that when heat is transferred from high temperature to low temperature regions, some of the heat will be rejected and not converted into mechanical work. Entropy is a measure of how much heat must be rejected to a lower temperature receiver at a given pressure and temperature. a. A complex explanation of the mathematical significance of the definition of entropy is unnecessary. It is a term which attempts to describe the universe’s tendency to evenly distribute all mass and energy throughout space. Processes which produce entropy are possible and those which destroy entropy are impossible. b. Bodies with a high temperature will, when brought in contact with a body of a lower temperature, always cause heat to transfer from the hot body to the cold body. This will lower the internal energy of the hot body and raise the internal energy of the cold body. This is the principle that guides the design and operation of all naval heat exchangers. For example, a main engine lube oil cooler directs hot lube oil over cool seawater piping, so that the hot lube oil will transfer some of its heat to the cooler seawater. If left together indefinitely, the property of entropy would cause the heat from the lube oil to be equally distributed between the oil and the water, so that both would have the same temperature. c. Entropy would not be important except for the fact that the purpose of any engine is to collect,. Water and Steam Properties, known as WASP, is a Windows 95 application Water and Steam Properties, known as WASP the physical properties of ice, water and steam. HVAC Solution - Pro. 282. Steam-water-properties is a comprehensive steam Water and Steam Properties, known as WASP, is a Windows 95 application Water and Steam Properties, known as WASP the physical properties of ice, water and steam. HVAC Solution - Pro. 282. Steam-water-properties is a comprehensive steam

Properties of Water and Steam (Thermodynamic Properties of

Pumping High temperatures and danger of impeller cavitation is the major challenge for condensate pumping in steam systems. Cryogenic Fluids and Liquefied Gas Properties Cryogenic properties as density, boiling points and heat of evaporation for fluids like hydrogen, methane, oxygen, nitrogen, fluorine and helium. Density of Gases Data Densities and molecular weights of common gases like acetylene, air, methane, nitrogen, oxygen and others. Evaporation from a Water Surface Evaporation of water from a water surface - like a swimming pool or an open tank - depends on water temperature, air temperature, air humidity and air velocity above the water surface - online calculator. Feed Pumps in Steam Systems - Suction Lift Head vs. Temperature Cavitation of impellers increases with water temperatures. Fuels - Boiling Points Fuels and their boiling points. Fusion and Evaporation Heat of common Materials Melting points, heat of fusions, boiling points and heat to evaporate common substances - like hydrogen, water, gold and more .. Gases - Specific Gravities Specific gravities of air, ammonia, butadiene, carbon dioxide, carbon monoxide and some other common gases. Glycerine - Boiling and Freezing Points Boiling and freezing points of glycerine aqueous solutions. Hydrocarbons - Physical Data Molweight, melting and boiling point, density, flash point and autoignition temperature, as well as number of carbon and hydrogen atoms in each molecule for 200 different hydrocarbons. Hydrocarbons, Alcohols and Acids - Boiling points Boiling temperatures (°C and °F) with varying carbon numbers up to C33. Liquids - Latent Heat of Evaporation Latent heat of vaporization for fluids like alcohol, ether, nitrogen, water and more. LPG - Liquefied Petroleum Gas LPG or Liquefied Petroleum Gas. Melting points of Hydrocarbons, Alcohols and Acids Melting temperature (°C and °F) with carbon number up to C33. Refrigerants - Physical Properties Physical properties of refrigerants - molecular weight, boiling, freezing and critical points. Water - Boiling Points at Vacuum Pressure Online calculator, figures and tables giving the boiling temperatures of water in varying vacuum, SI and Imperial units. Water - Boiling Points vs. Altitude Elevation above sea level and the boiling point of water. Water Boiling Point at Higher Pressures – Data & Calculator Online calculator, figures and tables showing boiling points of water at pressures ranging from 14.7 to 3200 psia (1 to 220 bara). Temperature given as °C, °F, K and °R. Our Mission The Engineering ToolBox provides a wide range of free tools, calculators, and information resources aimed at engineers and designers. It offers detailed technical data and calculations for various fields such as fluid mechanics, material properties, HVAC systems, electrical engineering, and more.The site includes resources for common engineering tasks, such as calculating physical properties (e.g., density, viscosity, thermal conductivity), converting units, and designing systems like heating and water distribution. With sections on everything from acoustics to hydraulics, it serves as a comprehensive tool for both students and professionals in technical and engineering disciplines. About the Engineering ToolBox! Privacy Policy We don't collect information from our users. More about the Engineering ToolBox Privacy Policy We