Maiarutselvan V
PSG College of Technology (PSGCT), Coimbatore
Maiarutselvan V has created this Calculator and 300+ more calculators!
Shikha Maurya
Indian Institute of Technology (IIT), Bombay
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11 Other formulas that you can solve using the same Inputs

Conversion factor when flow velocity is given
conversion factor=((flow velocity*roughness coefficient of conduit surface)/((energy loss^(1/2))*hydraulic radius^(2/3))) GO
Hydraulic radius when flow velocity is given
hydraulic radius=((flow velocity*roughness coefficient of conduit surface)/(conversion factor*energy loss^(1/2)))^(3/2) GO
Roughness coefficient when flow velocity is given
roughness coefficient of conduit surface=(conversion factor*hydraulic radius^(2/3)*energy loss^(1/2))/flow velocity GO
Energy loss when flow velocity is given
energy loss=((flow velocity*roughness coefficient of conduit surface)/(conversion factor*hydraulic radius^(2/3)))^2 GO
Specific Weight of Liquid When Hydraulic Transmission Power is Given
specific weight of liquid=Power/(Rate of flow*(Total Head at Entrance-Head loss)) GO
Rate of Flow When Hydraulic Transmission Power is Given
Rate of flow=Power/(specific weight of liquid*(Total Head at Entrance-Head loss)) GO
Hydraulic Transmission of Power
Power=specific weight of liquid*Rate of flow*(Total Head at Entrance-Head loss) GO
Head Loss When Efficiency of Hydraulic Transmission is Given
Head loss=Total Head at Entrance-(Efficiency *Total Head at Entrance) GO
Efficiency of transmission
Efficiency =(Total Head at Entrance-Head loss)/Total Head at Entrance GO
Area when water flow equation is given
Cross sectional area=water flow/flow velocity GO
Water flow equation
water flow=Cross sectional area*flow velocity GO

11 Other formulas that calculate the same Output

Efficiency of spiral gears
Efficiency =(cos(Spiral angles of gear teeth for gear 1+Angle of friction)*Pitch circle diameter of gear 2*Speed of gear 2)/(cos(Spiral angles of gear teeth for gear 1-Angle of friction)*Pitch circle diameter of gear 1*Speed of gear 1) GO
Efficiency of spiral gears
Efficiency =(cos(Spiral angles of gear teeth for gear 1+Angle of friction)*cos(Spiral angles of gear teeth for gear 1))/(cos(Spiral angles of gear teeth for gear 1-Angle of friction)*cos(Spiral angles of gear teeth for gear 1)) GO
Efficiency of screw jack when screw friction as well as collar friction considered
Efficiency =(Weight*tan(Helix Angle)*Mean diameter of Screw)/((Weight of Load*tan(Helix Angle+Limiting angle of friction)*Mean diameter of Screw)+(Coefficient of friction for collar*Weight of Load*Mean radius of collar)) GO
Efficiency of Square Threaded Screw
Efficiency =tan(Helix Angle)/((Coefficient of Friction+tan(Helix Angle))/(1-Coefficient of Friction*tan(Helix Angle))) GO
Maximum efficiency of spiral gears
Efficiency =(cos(Shaft angle+Angle of friction)+1)/(cos(Shaft angle-Angle of friction)+1) GO
Maximum efficiency of screw a jack
Efficiency =(1-sin(Limiting angle of friction))/(1+sin(Limiting angle of friction)) GO
Efficiency of screw jack when only screw friction considered
Efficiency =tan(Helix Angle)/tan(Helix Angle+Limiting angle of friction) GO
Efficiency of transmission
Efficiency =(Total Head at Entrance-Head loss)/Total Head at Entrance GO
Mechanical Efficiency
Efficiency =Induced voltage*Armature Current/Angular Speed*Torque GO
Rotor Efficiency
Efficiency =Motor Speed/Synchronous Speed GO
Motor Efficiency Using Slip
Efficiency =1-Slip GO

Efficiency of power transmission through nozzle for velocity and total head Formula

Efficiency =(flow velocity^2)/(2*[g]*Total Head at Entrance)
n=(V^2)/(2*[g]*H)
More formulas
Loss of head due to sudden enlargement GO
Velocity at section 1-1 for sudden enlargement GO
Velocity at section 2-2 for sudden enlargement GO
Loss of head due to sudden contraction GO
Velocity at section 2-2 for sudden contraction GO
Coefficient of contraction for sudden contraction GO
Power lost due to sudden enlargement GO
Loss of head at the entrance of a pipe GO
Velocity of fluid in pipe for head loss at the entrance of a pipe GO
Loss of head at the exit of pipe GO
Velocity at the outlet for head loss at the exit of pipe GO
Loss of head due to obstruction in a pipe GO
Velocity of fluid for head loss due to obstruction in a pipe GO
Velocity of liquid at vena-contracta GO
Maximum area of obstruction in the pipe GO
Loss of head due to bead in a pipe GO
Difference in liquid level in three compound pipes with same friction coefficient GO
Loss of head in the equivalent pipe GO
Discharge in the equivalent pipe GO
Diameter of the equivalent pipe GO
Length of the equivalent pipe GO
Power transmission through pipes GO
Efficiency of power transmission in flow through pipes GO
Head loss due to friction for the efficiency of power transmission GO
Total head available at inlet of pipe for efficiency of power transmission GO
Head available at the base of the nozzle GO
Total head at the inlet of pipe for head available at the base of the nozzle GO
Velocity of flow at the outlet of the nozzle GO
Efficiency of power transmission through the nozzle GO
Velocity of flow at the outlet of the nozzle for efficiency and head GO
Diameter of nozzle for maximum power transmission through nozzle GO
Area of the pipe for maximum power transmission through nozzle GO
Area of the nozzle at outlet for maximum power transmission through nozzle GO
Length of pipe for maximum power transmission through nozzle GO
Intensity of pressure wave produced for gradual closure of valves GO
Time required to close the valve for gradual closure of valves GO
Retarding force for gradual closure of valves GO
Time taken by pressure wave to travel GO

What is isentropic nozzle flow?

The Isentropic nozzle flow describes the movement of a gas or fluid through a narrowing opening without an increase or decrease in entropy.

What is a flow nozzle?

The flow nozzles is a flow tube consisting of a smooth convergent section leading to a cylindrical throat area.

How to Calculate Efficiency of power transmission through nozzle for velocity and total head?

Efficiency of power transmission through nozzle for velocity and total head calculator uses Efficiency =(flow velocity^2)/(2*[g]*Total Head at Entrance) to calculate the Efficiency , The Efficiency of power transmission through nozzle for velocity and total head formula is known while considering the velocity of flow at the outlet of nozzle and the total head available at the inlet of pipe. Efficiency and is denoted by n symbol.

How to calculate Efficiency of power transmission through nozzle for velocity and total head using this online calculator? To use this online calculator for Efficiency of power transmission through nozzle for velocity and total head, enter flow velocity (V) and Total Head at Entrance (H) and hit the calculate button. Here is how the Efficiency of power transmission through nozzle for velocity and total head calculation can be explained with given input values -> 0.509858 = (1^2)/(2*[g]*0.1).

FAQ

What is Efficiency of power transmission through nozzle for velocity and total head?
The Efficiency of power transmission through nozzle for velocity and total head formula is known while considering the velocity of flow at the outlet of nozzle and the total head available at the inlet of pipe and is represented as n=(V^2)/(2*[g]*H) or Efficiency =(flow velocity^2)/(2*[g]*Total Head at Entrance). flow velocity is the velocity of the flow of any fluid and Total Head at Entrance is the number of the head at the entrance of the pipe.
How to calculate Efficiency of power transmission through nozzle for velocity and total head?
The Efficiency of power transmission through nozzle for velocity and total head formula is known while considering the velocity of flow at the outlet of nozzle and the total head available at the inlet of pipe is calculated using Efficiency =(flow velocity^2)/(2*[g]*Total Head at Entrance). To calculate Efficiency of power transmission through nozzle for velocity and total head, you need flow velocity (V) and Total Head at Entrance (H). With our tool, you need to enter the respective value for flow velocity and Total Head at Entrance and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.
How many ways are there to calculate Efficiency ?
In this formula, Efficiency uses flow velocity and Total Head at Entrance. We can use 11 other way(s) to calculate the same, which is/are as follows -
  • Efficiency =Motor Speed/Synchronous Speed
  • Efficiency =1-Slip
  • Efficiency =Induced voltage*Armature Current/Angular Speed*Torque
  • Efficiency =tan(Helix Angle)/tan(Helix Angle+Limiting angle of friction)
  • Efficiency =(Weight*tan(Helix Angle)*Mean diameter of Screw)/((Weight of Load*tan(Helix Angle+Limiting angle of friction)*Mean diameter of Screw)+(Coefficient of friction for collar*Weight of Load*Mean radius of collar))
  • Efficiency =(1-sin(Limiting angle of friction))/(1+sin(Limiting angle of friction))
  • Efficiency =(cos(Shaft angle+Angle of friction)+1)/(cos(Shaft angle-Angle of friction)+1)
  • Efficiency =(cos(Spiral angles of gear teeth for gear 1+Angle of friction)*cos(Spiral angles of gear teeth for gear 1))/(cos(Spiral angles of gear teeth for gear 1-Angle of friction)*cos(Spiral angles of gear teeth for gear 1))
  • Efficiency =(cos(Spiral angles of gear teeth for gear 1+Angle of friction)*Pitch circle diameter of gear 2*Speed of gear 2)/(cos(Spiral angles of gear teeth for gear 1-Angle of friction)*Pitch circle diameter of gear 1*Speed of gear 1)
  • Efficiency =(Total Head at Entrance-Head loss)/Total Head at Entrance
  • Efficiency =tan(Helix Angle)/((Coefficient of Friction+tan(Helix Angle))/(1-Coefficient of Friction*tan(Helix Angle)))
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