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CALCULATOR MODULE : Piping Fitting Minor Loss Factor ±
Calculate pipe fitting minor loss factors. Minor loss factors can be defined as: - Av (SI) flow coefficient - the flow in cubic meters per second fluid density 1 kilogram per cubic meter which gives a pressure drop of 1 Pa
- Cv-uk (UK) flow coefficient - the flow in UK gallons per minute of water at 60 degrees F which gives a pressure drop of 1 psi
- Cv-us (US) flow coefficient - the flow in US gallons per minute of water at 60 degrees F which gives a pressure drop of 1 psi
- Cv-met (Metric) flow coefficient - the flow in liters per minute of water at 16 degrees C which gives a pressure drop of 1 bar
- Kv (EU) flow coefficient - the flow in cubic meters per hour of water at 16 degrees C which gives a pressure drop of 1 bar
- Cv* the dimensionless US flow factor = Cv-us / din^2 (din is the inside diameter in inches)
- K factor - the ratio of pressure loss over the dynamic pressure
- Cd or discharge coefficient - the ratio of the actual flow rate of the fluid through the fitting over the frictionless flow rate.
The K factor and discharge coefficient are dimensionless and can be used with any consistent set of units. The dimensionless flow coefficient has inconsistent units, and is unit specific. The flow coefficient Av, Cv-us, Cv-uk, Cv-met and Kv have dimensions length squared, and can not be used interchangeably between different systems of units. Note : The friction factor K, discharge coefficient Cd, dimensionless flow coefficient Cv*, and flow coefficients Av, Cv-uk, Cv-us, Cv-met and Kv are used in different situations. The discharge coefficient is usually used for discharge through an orifice, but can also be used in other situations (for example pressure relief valves). The flow coefficients Av, Cv-uk, Cv-us, Cv-met and Kv, and the dimensionless flow coefficient Cv* are usually used for valves, but can also be used for other fittings. Engineering judgement is required to determine the correct minor loss factor to use. Change Module : Related Modules : |
CALCULATOR MODULE : Piping Reducer And Enlarger Minor Loss Factor ±
Calculate typical pipe reducer and enlarger minor loss factors. The minor loss factors can be calculated for either the small diameter, and the large diameter. The nozzle can be either tapered with a transition, or abrupt with no transition. The taper angle is equal to half the cone angle. Note : The calculated values are typical. Manufacturers data should be used if it is available. Minor loss factors are calculated for: - Av (SI) flow coefficient - the flow in cubic meters per second fluid density 1 kilogram per cubic meter which gives a pressure drop of 1 Pa
- Cv-uk (UK) flow coefficient - the flow in UK gallons per minute of water at 60 degrees F which gives a pressure drop of 1 psi
- Cv-us (US) flow coefficient - the flow in US gallons per minute of water at 60 degrees F which gives a pressure drop of 1 psi
- Cv-met (Metric) flow coefficient - the flow in liters per minute of water at 16 degrees C which gives a pressure drop of 1 bar
- Kv (EU) flow coefficient - the flow in cubic meters per hour of water at 16 degrees C which gives a pressure drop of 1 bar
- Cv* the dimensionless US flow factor = Cv-us / din^2 (din is the inside diameter in inches)
- K factor - the ratio of pressure loss over the dynamic pressure
- Cd or discharge coefficient - the ratio of the actual flow rate of the fluid through the fitting over the frictionless flow rate.
Reference : Crane Technical Paper 410M Metric Version : Flow Of Fluids Through Valves, Fittings And Pipe Change Module : Related Modules : |
CALCULATOR MODULE : Piping Wye And Tee Minor Loss Factor ±
Calculate typical pipe wye and tee minor loss factors (K, Cd, Cv*, Av, Cv-uk, Cv-us, Cv-met and Kv). The minor loss factors can be calculated for converging and diverging wyes and tees, and for the run and the branch. The run is assumed to be constant diameter. The branch diameter should be smaller than or equal to the run diameter. The flow ratio should be 0 ≤ Qb/Qc ≤ 1. The flow ratio can be either the mass flowrate ratio, the volume flowrate ratio (for liquids), or the mole flowrate ratio (for gases). Note : In some cases the friction factor K can be negative due to the acceleration of slow moving fluid to the velocity of the combined flow. The discharge coefficient and flow coefficients are invalid for negative friction factor K. Minor loss factors are calculated for: - Av (SI) flow coefficient - the flow in cubic meters per second fluid density 1 kilogram per cubic meter which gives a pressure drop of 1 Pa
- Cv-uk (UK) flow coefficient - the flow in UK gallons per minute of water at 60 degrees F which gives a pressure drop of 1 psi
- Cv-us (US) flow coefficient - the flow in US gallons per minute of water at 60 degrees F which gives a pressure drop of 1 psi
- Cv-met (Metric) flow coefficient - the flow in liters per minute of water at 16 degrees C which gives a pressure drop of 1 bar
- Kv (EU) flow coefficient - the flow in cubic meters per hour of water at 16 degrees C which gives a pressure drop of 1 bar
- Cv* the dimensionless US flow factor = Cv-us / din^2 (din is the inside diameter in inches)
- K factor - the ratio of pressure loss over the dynamic pressure
- Cd or discharge coefficient - the ratio of the actual flow rate of the fluid through the fitting over the frictionless flow rate.
The calculated values are typical. Manufacturers data should be used if it is available. Reference : Crane Technical Paper 410M Metric Version : Flow Of Fluids Through Valves, Fittings And Pipe Change Module : Related Modules : |
CALCULATOR MODULE : Piping Entry And Exit Minor Loss Factor ±
Calculate typical pipe entry and exit minor loss factors (K, Cd, Cv*, Av, Cv-uk, Cv-us, Cv-met and Kv). Minor loss factors canbe calculated for pipe exits, inward protruding entries, sharp edged flush entries, and radiused flush entries. Minor loss factors are calculated for: - Av (SI) flow coefficient - the flow in cubic meters per second fluid density 1 kilogram per cubic meter which gives a pressure drop of 1 Pa
- Cv-uk (UK) flow coefficient - the flow in UK gallons per minute of water at 60 degrees F which gives a pressure drop of 1 psi
- Cv-us (US) flow coefficient - the flow in US gallons per minute of water at 60 degrees F which gives a pressure drop of 1 psi
- Cv-met (Metric) flow coefficient - the flow in liters per minute of water at 16 degrees C which gives a pressure drop of 1 bar
- Kv (EU) flow coefficient - the flow in cubic meters per hour of water at 16 degrees C which gives a pressure drop of 1 bar
- Cv* the dimensionless US flow factor = Cv-us / din^2 (din is the inside diameter in inches)
- K factor - the ratio of pressure loss over the dynamic pressure
- Cd or discharge coefficient - the ratio of the actual flow rate of the fluid through the fitting over the frictionless flow rate.
The calculated values are typical. Manufacturers data should be used if it is available. Reference : Crane Technical Paper 410M Metric Version : Flow Of Fluids Through Valves, Fittings And Pipe Change Module : Related Modules : |
CALCULATOR MODULE : Piping Bend And Elbow Minor Loss Factor ±
Calculate typical pipe bend and elbow minor loss factors (K, Cd, Cv*, Av, Cv-uk, Cv-us, Cv-met and Kv). Minor loss factors can be calculated for miter bends (single miter and multiple miter), formed bends, close return bends, and standard elbows. Minor loss factors are calculated for: - Av (SI) flow coefficient - the flow in cubic meters per second fluid density 1 kilogram per cubic meter which gives a pressure drop of 1 Pa
- Cv-uk (UK) flow coefficient - the flow in UK gallons per minute of water at 60 degrees F which gives a pressure drop of 1 psi
- Cv-us (US) flow coefficient - the flow in US gallons per minute of water at 60 degrees F which gives a pressure drop of 1 psi
- Cv-met (Metric) flow coefficient - the flow in liters per minute of water at 16 degrees C which gives a pressure drop of 1 bar
- Kv (EU) flow coefficient - the flow in cubic meters per hour of water at 16 degrees C which gives a pressure drop of 1 bar
- Cv* the dimensionless US flow factor = Cv-us / din^2 (din is the inside diameter in inches)
- K factor - the ratio of pressure loss over the dynamic pressure
- Cd or discharge coefficient - the ratio of the actual flow rate of the fluid through the fitting over the frictionless flow rate.
The calculated values are typical. Manufacturers data should be used if it is available. Reference : Crane Technical Paper 410M Metric Version : Flow Of Fluids Through Valves, Fittings And Pipe Change Module : Related Modules : |
CALCULATOR MODULE : Piping Valve Minor Loss Factor ±
Calculate typical pipe valve minor loss factors (K, Cd, Cv*, Av, Cv-uk, Cv-us, Cv-met and Kv). The valves are assumed to be fully open. For full port valves the valve port cross section area equals the nominal internal cross section area. For reduced port valves the valve port cross section area is less than the nominal internal cross section area. For circular valve ports the diameter ratio is equal to the valve port diameter over the nominal inside diameter. For non circular valve ports, use the square root of the internal area ratio (the square root of the valve port area over the nominal internal area). Minor loss factors are calculated for: - Av (SI) flow coefficient - the flow in cubic meters per second fluid density 1 kilogram per cubic meter which gives a pressure drop of 1 Pa
- Cv-uk (UK) flow coefficient - the flow in UK gallons per minute of water at 60 degrees F which gives a pressure drop of 1 psi
- Cv-us (US) flow coefficient - the flow in US gallons per minute of water at 60 degrees F which gives a pressure drop of 1 psi
- Cv-met (Metric) flow coefficient - the flow in liters per minute of water at 16 degrees C which gives a pressure drop of 1 bar
- Kv (EU) flow coefficient - the flow in cubic meters per hour of water at 16 degrees C which gives a pressure drop of 1 bar
- Cv* the dimensionless US flow factor = Cv-us / din^2 (din is the inside diameter in inches)
- K factor - the ratio of pressure loss over the dynamic pressure
- Cd or discharge coefficient - the ratio of the actual flow rate of the fluid through the fitting over the frictionless flow rate.
The calculated values are typical. Manufacturers data should be used if it is available. Reference : Crane Technical Paper 410M Metric Version : Flow Of Fluids Through Valves, Fittings And Pipe Change Module : Related Modules : |
CALCULATOR MODULE : Piping Check Valve Minor Loss Factor ±
Calculate typical gas and liquid pipe check valve minimum velocity and minor loss factors (K, Cd, Cv*, Av, Cv-uk, Cv-us, Cv-met and Kv). The minimum flowrate is the flowrate required to keep the check valve fully open. For full port valves the valve port cross section area equals the nominal internal cross section area. For reduced port valves the valve port cross section area is less than the nominal internal cross section area. For circular valve ports the diameter ratio is equal to the valve port diameter over the nominal inside diameter. For non circular valve ports, use the square root of the internal area ratio (the square root of the valve port area over the nominal internal area). Minor loss factors are calculated for: - Av (SI) flow coefficient - the flow in cubic meters per second fluid density 1 kilogram per cubic meter which gives a pressure drop of 1 Pa
- Cv-uk (UK) flow coefficient - the flow in UK gallons per minute of water at 60 degrees F which gives a pressure drop of 1 psi
- Cv-us (US) flow coefficient - the flow in US gallons per minute of water at 60 degrees F which gives a pressure drop of 1 psi
- Cv-met (Metric) flow coefficient - the flow in liters per minute of water at 16 degrees C which gives a pressure drop of 1 bar
- Kv (EU) flow coefficient - the flow in cubic meters per hour of water at 16 degrees C which gives a pressure drop of 1 bar
- Cv* the dimensionless US flow factor = Cv-us / din^2 (din is the inside diameter in inches)
- K factor - the ratio of pressure loss over the dynamic pressure
- Cd or discharge coefficient - the ratio of the actual flow rate of the fluid through the fitting over the frictionless flow rate.
The calculated values are typical. Manufacturers data should be used if it is available. Reference : Crane Technical Paper 410M Metric Version : Flow Of Fluids Through Valves, Fittings And Pipe Change Module : Related Modules : |
CALCULATOR MODULE : Gas Piping Minor Loss Factor ±
Calculate gas pipe fitting minor loss factors. Minor loss factors can be defined as: - Av (SI) flow coefficient - the flow in cubic meters per second fluid density 1 kilogram per cubic meter which gives a pressure drop of 1 Pa
- Cv-uk (UK) flow coefficient - the flow in UK gallons per minute of water at 60 degrees F which gives a pressure drop of 1 psi
- Cv-us (US) flow coefficient - the flow in US gallons per minute of water at 60 degrees F which gives a pressure drop of 1 psi
- Cv-met (Metric) flow coefficient - the flow in liters per minute of water at 16 degrees C which gives a pressure drop of 1 bar
- Kv (EU) flow coefficient - the flow in cubic meters per hour of water at 16 degrees C which gives a pressure drop of 1 bar
- Cv* the dimensionless US flow factor = Cv-us / din^2 (din is the inside diameter in inches)
- K factor - the ratio of pressure loss over the dynamic pressure
- Cd or discharge coefficient - the ratio of the actual flow rate of the fluid through the fitting over the frictionless flow rate.
The K factor and discharge coefficient are dimensionless and can be used with any consistent set of units. The dimensionless flow coefficient has inconsistent units, and is unit specific. The flow coefficient Av, Cv-us, Cv-uk, Cv-met and Kv have dimensions length squared, and can not be used interchangeably between different systems of units. Note : The friction factor K, discharge coefficient Cd, dimensionless flow coefficient Cv*, and flow coefficients Av, Cv-uk, Cv-us, Cv-met and Kv are used in different situations. The discharge coefficient is usually used for discharge through an orifice, but can also be used in other situations (for example pressure relief valves). The flow coefficients Av, Cv-uk, Cv-us, Cv-met and Kv, and the dimensionless flow coefficient Cv* are usually used for valves, but can also be used for other fittings. Engineering judgement is required to determine the correct minor loss factor to use. Change Module : Related Modules : |
CALCULATOR MODULE : Liquid Piping Minor Loss Factor ±
Calculate liquid pipe fitting minor loss factors. Minor loss factors can be defined as: - Av (SI) flow coefficient - the flow in cubic meters per second fluid density 1 kilogram per cubic meter which gives a pressure drop of 1 Pa
- Cv-uk (UK) flow coefficient - the flow in UK gallons per minute of water at 60 degrees F which gives a pressure drop of 1 psi
- Cv-us (US) flow coefficient - the flow in US gallons per minute of water at 60 degrees F which gives a pressure drop of 1 psi
- Cv-met (Metric) flow coefficient - the flow in liters per minute of water at 16 degrees C which gives a pressure drop of 1 bar
- Kv (EU) flow coefficient - the flow in cubic meters per hour of water at 16 degrees C which gives a pressure drop of 1 bar
- Cv* the dimensionless US flow factor = Cv-us / din^2 (din is the inside diameter in inches)
- K factor - the ratio of pressure loss over the dynamic pressure
- Cd or discharge coefficient - the ratio of the actual flow rate of the fluid through the fitting over the frictionless flow rate.
The K factor and discharge coefficient are dimensionless and can be used with any consistent set of units. The dimensionless flow coefficient has inconsistent units, and is unit specific. The flow coefficient Av, Cv-us, Cv-uk, Cv-met and Kv have dimensions length squared, and can not be used interchangeably between different systems of units. Note : The friction factor K, discharge coefficient Cd, dimensionless flow coefficient Cv*, and flow coefficients Av, Cv-uk, Cv-us, Cv-met and Kv are used in different situations. The discharge coefficient is usually used for discharge through an orifice, but can also be used in other situations (for example pressure relief valves). The flow coefficients Av, Cv-uk, Cv-us, Cv-met and Kv, and the dimensionless flow coefficient Cv* are usually used for valves, but can also be used for other fittings. Engineering judgement is required to determine the correct minor loss factor to use. Change Module : Related Modules : |
DATA MODULE : Pipe Fitting And Valve ( Open In Popup Workbook ) ±
Fluid flow friction factors for pressure loss calculations. Friction factors include K factors, flow coefficients Cv, and discharge coefficients Cd. Related Modules : |