Saturated steam temperature calculator

Author: s | 2025-04-24

Calculate steam saturation pressure and temperature (ASME Steam Table). The saturation point can be calculated from either the saturation temperature, or the saturation pressure. The Calculate the enthalpy of saturated steam: Use the steam table or a steam property calculator to find the enthalpy of saturated steam at the saturation temperature. Calculate the enthalpy of

calculate temperature of saturated steam discharged to

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). 20 Oct 2024 Tags: Mechanical Engineering Applied Thermodynamics Concepts Quality of Steam Popularity: ⭐⭐⭐Quality of Steam in Mechanical EngineeringThis calculator provides the calculation of the quality of steam for mechanical engineering applications.ExplanationCalculation Example: The quality of steam is a measure of the proportion of water vapor to dry steam in a mixture of the two. It is given by the formula Q = (H - hfg) / hfg, where H is the enthalpy of the steam, hfg is the enthalpy of vaporization, and Q is the quality of the steam.Related QuestionsQ: What is the importance of the quality of steam in mechanical engineering?A: The quality of steam is important in mechanical engineering because it affects the performance of steam engines and turbines. A higher quality of steam means that the steam engine or turbine will be more efficient.Q: How can the quality of steam be improved?A: The quality of steam can be improved by increasing the temperature of the steam or by reducing the pressure of the steam.Variables Symbol Name Unit T Temperature °C P Pressure kPa H Enthalpy kJ/kg S Entropy kJ/kg⋅K Calculation ExpressionQuality: The quality of steam is given by Q = (H - hfg) / hfg(H - hfg) / hfgCalculatorTemperature (°C): Pressure (kPa): Enthalpy (kJ/kg): Entropy (kJ/kg⋅K): Calculated valuesConsidering these as variable values: P=100.0, S=7.5, T=100.0, H=2500.0, the calculated value(s) are given in table below Derived Variable Value Quality (2500.0-hfg)/hfg Sensitivity Analysis GraphsQuality: The quality of steam is given by Q = (H - hfg) / hfgSimilar Calculators Explorations of Mathematical Functionality Analysis of Conceptual Frameworks Mathematical Formulations in Educational Contexts Fundamentals of Aeronautical Mathematics Mathematical Paradigms in Tabletop RPG Design An Exploration of Conceptual Frameworks Conceptual Formalization of Mathematical Definitions Principles of ME: Mathematical Modeling Exploring Conceptual Affordances Quantifying Pedagogical ConstructsExplore Steam power cycle Steam turbine Boiler A steam boiler produces saturated steam at 10 bar pressure. If the enthalpy of evaporation at this pressure is 2270 kJ/kg and the specific volume of dry saturated vapor is 1.01 m³/kg. What is the quality of the steam produced by the boiler? Calculate the quality of steam in a 5 kg/min flow rate of saturated steam at 3 bar gauge, if the enthalpy of evaporation at this pressure is 2080 kJ/kg and specific volume of dry saturated vapor is 2.38 m³/kg. A steam engine receives 15 kg/s of saturated steam at 8 bar pressure with an enthalpy of evaporation at this pressure being 2235 kJ/kg. If the total mass flow rate of the mixture is 18 kg/s, calculate the quality of the steam flowing through the engine.Calculator Apps Gear Design in 3D & Learning

Calculator: Saturated Steam Table by Temperature

Remains the same but the saturated liquid is being changed into a saturated vapor. During this period the water is referred to as a liquid/vapor mixture. When enough latent heat is added so that all of the liquid is converted into vapor, the water becomes a saturated vapor. Note that the saturated vapor is 100% vapor and exists at the same temperature as the saturated liquid. Above the saturated steam point, vapor exists at a temperature higher than saturation temperature. This is the superheated vapor region. c. Steam tables are a useful tool for determining the properties of steam and water at various temperatures and pressures. The steam tables are broken into three tables.D. Mollier Diagram 1. The Mollier diagram is a small portion of data from the steam tables graphed onto enthalpy-entropy coordinates. It presents the region that is commonly found in propulsion plant steam systems. Examine the last section of the steam tables for a representation of a Mollier diagram. 2. Locating information off the Mollier diagram is done as follows: The horizontal axis is entropy (s) in BTU/lbm-°R. The vertical axis is enthalpy (h) in BTU/lbm. The dark line across the middle of the chart is called a “steam dome” because of its shape. Above this line, the data is for superheated steam. Below this line, the data is for a steam-water mixture. The data directly on the line is for saturated steam. 3. To find data in the steam-water mixture region of the chart, enter the chart using the absolute pressure and %-moisture (y). Once you find the intersection of these two parameters, read off the number directly across from the intersection point for enthalpy. Read off the number directly below the intersection point for entropy. To find data in the superheated region of the chart, enter the chart using the measured temperature and pressure of the steam. Again, find the intersection point of these two parameters and read off the values for entropy and enthalpy. Notice that moisture does not plot in the superheat region. This is because moisture is a parameter which only exists in saturated conditions.. Calculate steam saturation pressure and temperature (ASME Steam Table). The saturation point can be calculated from either the saturation temperature, or the saturation pressure. The

Saturated Steam Table Calculator by Temperature

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 Of liquid water that changed from saturated steam under the same temperature and pressure. Latent heat: the amount of thermal energy released from 1kg of saturated steam during the conversion of vapor into liquid under the same temperature and pressure. Total heat: includes sensible heat and latent heat. From Table 1, we can see that the sensible heat is directly related to steam temperature while latent heat is related to steam pressure. As the pressure rising up, the steam temperature as well as sensible heat are increased, while the latent heat is decreased; [1]As for the total heat, it is increased slowly as the steam pressure enlarged. Since the pressure of steam applied in a feed mill usually is from 2kg/cm2 to 8kg/cm, the change of the total heat is not so obvious.2. A proper configuration of steam system2.1 Steam application principle: delivering under a high pressure and applying under a low pressure the application of steam provides a controllable method for conveying energy from the concentrative, automatic, highly efficient boiler room to the jobsite.Delivering steam under a high pressure It can be seen from the specific volume shown in Table 1, high pressure delivery has the following advantages: - The reducible pipeline contributes to a fast flowing speed, little thermal loss, low pipeline cost, low maintenance cost and low labor cost; - Low cost for heat pipeline isolation; - Much drier steam obtained at the application point through depressurizing; - The boiler will be more efficient when running under

Saturated Steam Temperature Calculator - Blogger

This Excel Spreadsheet helps you to calculate the Kv, the flow rate and the differential pressure of a valve or solenoid valve. (Pressure, length and temperature unit conversion is integrated in the excel tool).Valve Kv Sizing CalculatorThis program operates with Microsoft© Excel software.Depending on your application, choose one of the 3 spread sheets in excel file for air and gas/water and oil/steam. Enter your data in the boxes with blue letters.You will automatically obtain your results in the printed sheet (data will be in red letters).What this Kv sizing Excel Tool can be used for? To determine the 1. necessary Kv value of a valve2. pressure drop (DP) across the valve3. volumetric flowDownload Valve Kv Sizing CalculatorHow to use this Kv sizing Calculator Password : instrumentationtools.com1. To select the correct valve size, calculate Kv valueInput data:inlet pressurerequired volumetric flowallowed pressure drop (DP)Result : Kv value2. To determine the volumetric flow passing the valveInput data:inlet pressureKv value of the valveallowed pressure drop (DP)Result: Actual volumetric flow3. To determine the required pressure drop across the valve to reach the desirable volumetric flowInput data:inlet pressureKv value of the valvedesirable volumetric flowResult: Required pressure drop (DP)How to use this Kv sizing Calculator1. Select the correct sheet according to the medium. (air or water or steam)2. Select either the medium or the specific gravity (except for steam).3. Select the unit of inlet pressure4. Select the unit of flow coefficient5. Select the unit of volumetric flow6. Select the unit of pressure drop (DP)7. Use temperature correction if necessary (available option only at Air & Gases sheet).8. Enter the input data, BLUE colored numbers9. The results are marked with RED colored numbers.Other options, table and conversion tables.1. Estimated orifice size of the Kv values.2. Conversion table of different flow coefficients.3. Assistance to determine saturated steam pressure relating

Calculator: Saturated Steam Table by Temperature - TLV

✖Steam Flow is the rate by which steam flows to produce a one-kilowatt hour of electricity.ⓘ Steam Flow [m] +10%-10%✖Specific Heat Capacity is the heat required to raise the temperature of the unit mass of a given substance by a given amount.ⓘ Specific Heat Capacity [c] +10%-10%✖Temperature Difference is the measure of the hotness or the coldness of an object.ⓘ Temperature Difference [ΔT] +10%-10% ✖Heat rate is the amount of energy required by an electrical generator or a power plant to produce a one-kilowatt hour of electricity.ⓘ Heat Rate [Qrate] ⎘ Copy Heat Rate Solution STEP 0: Pre-Calculation SummarySTEP 1: Convert Input(s) to Base UnitSteam Flow: 30 Kilogram per Second --> 30 Kilogram per Second No Conversion RequiredSpecific Heat Capacity: 4.184 Kilojoule per Kilogram per K --> 4184 Joule per Kilogram per K (Check conversion ​here)Temperature Difference: 29 Kelvin --> 29 Kelvin No Conversion RequiredSTEP 2: Evaluate FormulaSTEP 3: Convert Result to Output's Unit3640080 Watt --> No Conversion Required Others and Extra Calculators Heat Rate Formula ​LaTeX ​GoHeat Rate = Steam Flow*Specific Heat Capacity*Temperature Difference Qrate = m*c*ΔT How to Calculate Heat Rate? Heat Rate calculator uses Heat Rate = Steam Flow*Specific Heat Capacity*Temperature Difference to calculate the Heat Rate, Heat rate is the amount of energy required by an electrical generator or a power plant to produce a one-kilowatt hour of electricity. Heat Rate is denoted by Qrate symbol. How to calculate Heat Rate using this online calculator? To use this online calculator for Heat Rate, enter Steam Flow (m), Specific Heat Capacity (c) & Temperature Difference (ΔT) and hit the calculate button. Here is how the Heat Rate calculation can be explained with given input values -> 3.6E+6 = 30*4184*29. FAQ What is Heat Rate?Heat rate is the amount of energy required by an electrical generator or a power plant to produce a one-kilowatt hour of electricity and is represented as Qrate = m*c*ΔT or Heat Rate = Steam Flow*Specific Heat Capacity*Temperature Difference. Steam Flow is the rate by which steam flows to produce a one-kilowatt hour of electricity, Specific Heat Capacity is the heat required to raise the temperature of the unit mass of a given substance by a given amount & Temperature Difference is the measure of the hotness or the coldness of an object.How to calculate Heat Rate?Heat rate is the amount of energy required by an electrical generator or a power plant to produce a one-kilowatt hour of electricity is calculated using Heat Rate = Steam Flow*Specific Heat Capacity*Temperature Difference. To calculate Heat Rate, you need Steam Flow (m), Specific Heat Capacity (c) & Temperature Difference (ΔT). With our tool, you need to enter the respective value for Steam Flow, Specific Heat Capacity &. Calculate steam saturation pressure and temperature (ASME Steam Table). The saturation point can be calculated from either the saturation temperature, or the saturation pressure. The

Saturated Water And Steam (Temperature-Based) Calculator

Chemical Fluid The inputs include state variables of pressure and temperature. Outputs include several properties including critical presssure, temperature, acentric factor, specific volume, enthalphy, entropy, internal energy, specific heat, global warming potential, ozone depletion potential etc, Water/Steam The inputs include state variables of pressure and temperature for determination of properties for superheated steam or compressed water. For saturated state the inputs required are Pressure-Quality or Temperature-Quality. Outputs include phase information, saturation temperature or pressure and specific volume, enthalphy, entropy, internal energy etc. Hydrocarbon/Gas Mixture The inputs include state variables of pressure and temperature. Typical composition list of API 617 gas compressors is used. The input include state variables of pressure and temperature. The outputs include crtiical pressure, temperature, compressibility factor (Z), ideal gas specific heat etc. The compressibility factor is determined using Nelson-Obert, LeeKesler and PengRobinson equation of state. Hooper 2K Method Get pressure drop in pipes and fittings using the Hooper 2K method Reciever Sizing Calculation to obtain the volume of receiver vessels based on hold up time consideration or maximum permissible switching(load/unload) frequency of the associated compressor.