1. What is Weight of Fluid given Angular Momentum at Inlet?

Weight of Fluid given Angular Momentum at Inlet is a calculation that determines the weight of a fluid based on its angular momentum, specific gravity, final velocity, and the radius of the wheel. This is particularly useful in fluid dynamics and mechanical engineering applications.

2. How Does the Calculator Work?

The calculator uses the formula:

Where:

• \( w_f \) — Weight of Fluid (N)
• \( L \) — Angular Momentum (kg·m²/s)
• \( G \) — Specific Gravity of Fluid (dimensionless)
• \( v_f \) — Final Velocity (m/s)
• \( r \) — Radius of Wheel (m)

Explanation: The formula calculates the weight of the fluid by considering the product of angular momentum and specific gravity divided by the product of final velocity and radius.

3. Importance of Weight of Fluid Calculation

Details: Accurate calculation of fluid weight is crucial for designing and analyzing fluid systems, ensuring proper functioning and efficiency in various engineering applications.

4. Using the Calculator

Tips: Enter angular momentum in kg·m²/s, specific gravity (dimensionless), final velocity in m/s, and radius in meters. All values must be positive and non-zero.

5. Frequently Asked Questions (FAQ)

Q1: What is Angular Momentum?
A: Angular Momentum is a measure of the quantity of rotation of a body, which is the product of its moment of inertia and its angular velocity.

Q2: What is Specific Gravity of Fluid?
A: Specific Gravity of Fluid is the ratio of the density of a substance to the density of a reference substance, typically water for liquids.

Q3: Why is Final Velocity important?
A: Final Velocity is the speed at which the fluid is moving at the end of a process, which affects the momentum and energy calculations.

Q4: How does Radius of Wheel affect the calculation?
A: The Radius of Wheel influences the leverage and moment arm in rotational systems, directly impacting the angular momentum and resulting weight calculation.

Q5: Can this formula be used for all fluids?
A: Yes, as long as the specific gravity is known, the formula can be applied to any fluid, though it is most accurate for Newtonian fluids under standard conditions.