Kethavath Srinath
Osmania University (OU), Hyderabad
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Urvi Rathod
Vishwakarma Government Engineering College (VGEC), Ahmedabad
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11 Other formulas that you can solve using the same Inputs

Periodic time of SHM for compound pendulum in terms of radius of gyration
Periodic time for compound pendulum=2*pi*sqrt(((Radius of gyration^2)+(Distance of point of suspension of pendulum from the center of gravity^2))/(Acceleration Due To Gravity*Distance of point of suspension of pendulum from the center of gravity)) GO
Restoring torque for simple pendulum
Torque=Mass*Acceleration Due To Gravity*sin(Angle through which the string is displaced)*Length of the string GO
Minimum periodic time of SHM for compound pendulum
Time Period SHM=2*pi*sqrt(2*Radius of gyration/Acceleration Due To Gravity) GO
Deflection of spring when mass m is attached to it
Deflection of Spring=Mass*Acceleration Due To Gravity/Stiffness of spring GO
Periodic time for one beat of SHM
Time Period SHM=pi*sqrt(Length of the string/Acceleration Due To Gravity) GO
Final Velocity of freely falling body from height h, when it reaches ground
Velocity on reaching ground=sqrt(2*Acceleration Due To Gravity*Height) GO
Force of Friction between the cylinder and the surface of inclined plane if cylinder is rolling without slipping down a ramp
Force=(Mass*Acceleration Due To Gravity*sin(Angle of Inclination))/3 GO
Periodic time for SHM
Time Period SHM=2*pi*sqrt(Displacement/Acceleration Due To Gravity) GO
Archimedes Principle
Archimedes Principle=Density*Acceleration Due To Gravity*Velocity GO
Potential Energy
Potential Energy=Mass*Acceleration Due To Gravity*Height GO
Pressure when density and height are given
Pressure=Density*Acceleration Due To Gravity*Height GO

2 Other formulas that calculate the same Output

Angle of Jet When Time of Flight of Liquid Jet is Given
Angle of the Liquid jet=asin(Time of Flight*Acceleration Due To Gravity/(2*Initial velocity of liquid jet)) GO
Angle of Jet When Time to Reach the Highest Point is Given
Angle of the Liquid jet=asin(Time of Flight*Acceleration Due To Gravity/(Initial velocity of liquid jet)) GO

Angle of Jet When Maximum Vertical Elevation is Given Formula

Angle of the Liquid jet=asin(sqrt((Maximum Vertical Elevation*2*Acceleration Due To Gravity)/(Initial velocity of liquid jet)^(2)))
Θ=asin(sqrt((H*2*g)/(V<sub>o)^(2)))
More formulas
Knudsen Number GO
Kinematic viscosity GO
Pressure Wave Velocity in Fluids GO
Surface tension GO
Bulk Modulus GO
Weight GO
Upthrust Force GO
Viscous Stress GO
Stokes Force GO
Reynolds Number GO
Specific Weight GO
Specific Volume GO
Inertial Force Per Unit Area GO
Body Force Work Rate GO
Heat Loss due to Pipe GO
Dynamic viscosity of fluids GO
Dynamic Viscosity of Gases GO
Viscous Force Per Unit Area GO
Terminal Velocity GO
Poiseuille's Formula GO
Dynamic Viscosity of Liquids GO
Pressure Inside the Liquid Drop GO
Center of Gravity GO
Center of Buoyancy GO
Metacenter GO
Pressure Inside the Soap Bubble GO
Turbulence GO
Height of Capillary Rise GO
Capillarity Through Parallel Plates GO
Capillarity Through an Annular Space GO
Capillarity Through a Circular Tube if inserted in liquid of S1 above a liquid of S2 GO
Cavitation Number GO
Pressure in Excess of Atmospheric Pressure GO
Absolute Pressure at a Height h GO
Normal Stress 1 GO
Normal Stress 2 GO
Differential pressure between two points GO
U-Tube Manometer equation GO
Differential pressure-Differential Manometer GO
Pressure using inclined Manometer GO
Sensitivity of inclined manometer GO
Total Hydrostatic force GO
Center of pressure GO
Buoyancy Force GO
Center of Pressure on Inclined Plane GO
Metacentric Height GO
Metacentric Height when Moment of Inertia is Given GO
Unstable Equilibrium of a Floating Body GO
Experimental determination of Metacentric height GO
Time period of Rolling GO
Rate of Flow GO
Equation of Continuity for Incompressible Fluids GO
Equation of Continuity for Compressible Fluids GO
Vorticity GO
Dynamic Pressure GO
Stagnation Pressure head GO
Dynamic Pressure head-pitot tube GO
Theoretical Velocity - Pitot Tube GO
Theoretical discharge -Venturimeter GO
Discharge through an Elbow meter GO
Variation of y with x in Free Liquid Jet GO
Time of Flight of Jet GO
Time to Reach Highest Point GO
Maximum Vertical Elevation of a Jet Profile GO
Horizontal Range of the Jet GO
Power Required to Overcome the Frictional Resistance in Laminar Flow GO
Frictional Factor of Laminar flow GO
Head loss due to Laminar Flow GO
Friction velocity GO
Force in direction of jet striking a stationary vertical plate GO
Hydraulic Transmission of Power GO
Efficiency of transmission GO
Bulk Modulus When Velocity Of Pressure Wave Is Given GO
Mass Density When Velocity Of Pressure Wave Is Given GO
Surface Energy When Surface Tension Is Given GO
Surface Area When Surface Tension Is Given GO
Shear Stress When Dynamic Viscosity Of A Fluid Is Given GO
Velocity Of Moving Plates When Dynamic Viscosity Is Given GO
Distance Between Plates When Dynamic Viscosity Of A Fluid Is Given GO
Surface Tension Of Liquid Drop When Change In Pressure Is Given GO
Diameter Of Droplet When Pressure Change Is Given GO
Surface Tension Of Soap Bubble When Pressure Change Is Given GO
The diameter Of Soap Bubble When Pressure Change Is Given GO
Specific Weight Of A Liquid When Absolute Pressure Of That liquid At A height is Given GO
Height Of Liquid When Absolute Pressure Of That Liquid Is Given GO
Specific Weight Of Fluid 1 When Differential Pressure Between Two Points Is Given GO
Specific Weight Of Fluid 2 When Differential Pressure Between Two Points Is Given GO
Height Of Fluid 1 When Differential Pressure Between Two Points Is Given GO
Height Of Fluid 2 When Differential Pressure Between Two Points Is Given GO
Specific Weight of Inclined Manometer Liquid When Pressure at A Point is Given GO
Length of Inclined Manometer When Pressure at a Point is Given GO
Angle of Inclined Manometer When Pressure at a Point is Given GO
Angle of Inclined Manometer When Sensitivity is Given GO
Specific Weight of Liquid When Total Hydrostatic Force is given GO
Depth of Centroid When Total Hydrostatic Force is Given GO
Area of the Surface Wetted When Total Hydrostatic Force is Given GO
Moment of Inertia about Centroid When Center of Pressure is Given GO
Area of Surface Wetted When Center of Pressure is Given GO
Depth of Centroid When Center of Pressure is Given GO
Specific Weight Of The Liquid When Buoyancy Force Is Given GO
The Volume Of The Submerged Object When buoyancy Force Is Given GO
Moment of Inertia of Waterline Area When Metacentric Height is Given GO
Volume of the Liquid Displaced When Metacentric Height is Given GO
Distance Between Buoyancy Point and Center of Gravity When Metacenter Height is Given GO
Radius of Gyration When Time Period of Rolling is Given GO
Metacentric Height When Time Period of Rolling is Given GO
Velocity of Fluid When Dynamic Pressure is Given GO
Density of the Liquid When Dynamic Pressure is Given GO
Initial Velocity When Time of Flight of the Liquid Jet is Given GO
Angle of Jet When Time of Flight of Liquid Jet is Given GO
Initial Velocity When Time to Reach the Highest Point of Liquid is Given GO
Angle of Jet When Time to Reach the Highest Point is Given GO
Initial Velocity of Liquid Jet When Maximum Vertical Elevation is Given GO
Reynolds Number When Frictional Factor of Laminar Flow is Given GO
Viscous Force When Head loss Due to Laminar Flow is Given GO
Rate of Flow When Head loss In Laminar Flow is Given GO
Length of Pipe When Head loss is Given GO
Specific Weight of Liquid When Head loss Due to Laminar Flow is Given GO
Diameter of Pipe When Head Loss due to Laminar Flow is Given GO
Mean Velocity When Frictional Velocity is Given GO
Friction Factor When Frictional Velocity is Given GO
Specific Weight of Liquid When Hydraulic Transmission Power is Given GO
Rate of Flow When Hydraulic Transmission Power is Given GO
Head Loss When Efficiency of Hydraulic Transmission is Given GO

What is a projectile?

A projectile is any object thrown by the exertion of a force. It can also be defined as an object launched into the space and allowed to move free under the influence of gravity and air resistance.Although any object in motion through space may be called projectiles.

How to Calculate Angle of Jet When Maximum Vertical Elevation is Given?

Angle of Jet When Maximum Vertical Elevation is Given calculator uses Angle of the Liquid jet=asin(sqrt((Maximum Vertical Elevation*2*Acceleration Due To Gravity)/(Initial velocity of liquid jet)^(2))) to calculate the Angle of the Liquid jet, The Angle of Jet When Maximum Vertical Elevation is Given formula is defined as the angle of projection of the liquid jet at time ,t=0. Angle of the Liquid jet and is denoted by Θ symbol.

How to calculate Angle of Jet When Maximum Vertical Elevation is Given using this online calculator? To use this online calculator for Angle of Jet When Maximum Vertical Elevation is Given, enter Maximum Vertical Elevation (H), Acceleration Due To Gravity (g) and Initial velocity of liquid jet (Vo) and hit the calculate button. Here is how the Angle of Jet When Maximum Vertical Elevation is Given calculation can be explained with given input values -> 0.062651 = asin(sqrt((0.5*2*9.8)/(50)^(2))).

FAQ

What is Angle of Jet When Maximum Vertical Elevation is Given?
The Angle of Jet When Maximum Vertical Elevation is Given formula is defined as the angle of projection of the liquid jet at time ,t=0 and is represented as Θ=asin(sqrt((H*2*g)/(Vo)^(2))) or Angle of the Liquid jet=asin(sqrt((Maximum Vertical Elevation*2*Acceleration Due To Gravity)/(Initial velocity of liquid jet)^(2))). Maximum Vertical Elevation is defined as the highest point of the projectile motion of the free liquid jet, The Acceleration Due To Gravity is acceleration gained by an object because of gravitational force and The initial velocity of liquid jet is defined as the velocity possed by the liquid jet at time T=0.
How to calculate Angle of Jet When Maximum Vertical Elevation is Given?
The Angle of Jet When Maximum Vertical Elevation is Given formula is defined as the angle of projection of the liquid jet at time ,t=0 is calculated using Angle of the Liquid jet=asin(sqrt((Maximum Vertical Elevation*2*Acceleration Due To Gravity)/(Initial velocity of liquid jet)^(2))). To calculate Angle of Jet When Maximum Vertical Elevation is Given, you need Maximum Vertical Elevation (H), Acceleration Due To Gravity (g) and Initial velocity of liquid jet (Vo). With our tool, you need to enter the respective value for Maximum Vertical Elevation, Acceleration Due To Gravity and Initial velocity of liquid jet 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 Angle of the Liquid jet?
In this formula, Angle of the Liquid jet uses Maximum Vertical Elevation, Acceleration Due To Gravity and Initial velocity of liquid jet. We can use 2 other way(s) to calculate the same, which is/are as follows -
  • Angle of the Liquid jet=asin(Time of Flight*Acceleration Due To Gravity/(2*Initial velocity of liquid jet))
  • Angle of the Liquid jet=asin(Time of Flight*Acceleration Due To Gravity/(Initial velocity of liquid jet))
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