1. What is a Pressure to Flow Calculator?

Definition: This calculator determines the fluid flow rate through a pipe or channel based on pressure difference, fluid density, and cross-sectional area.

Purpose: It helps engineers and technicians in fluid systems design and analysis to convert pressure measurements into flow rates.

2. How Does the Calculator Work?

The calculator uses two formulas:

Where:

• \( V \) — Fluid velocity (feet per second)
• \( P_1 \) — Inlet pressure (psi)
• \( P_2 \) — Outlet pressure (psi)
• \( \rho \) — Fluid density (pounds per cubic foot)
• \( Q \) — Flow rate (gallons per minute)
• \( A \) — Cross-sectional area (square feet)

Explanation: The first equation calculates velocity from pressure difference, then the second converts velocity to flow rate using the pipe area.

3. Importance of Pressure-Flow Calculations

Details: Accurate flow rate determination is essential for proper system design, pump selection, and ensuring adequate fluid delivery in piping systems.

4. Using the Calculator

Tips: Enter the pressure difference (P₁ - P₂), fluid density (default 62.4 lb/ft³ for water), and cross-sectional area. All values must be positive.

5. Frequently Asked Questions (FAQ)

Q1: Why is there a 144 in the formula?
A: This converts psi (lb/in²) to lb/ft² (1 ft² = 144 in²) for consistent units.

Q2: What's the 448.83 conversion factor?
A: This converts ft³/s to GPM (1 ft³/s = 448.83 GPM).

Q3: What density should I use for other fluids?
A: Use 49.2 lb/ft³ for gasoline, 78.6 lb/ft³ for seawater, or look up specific values for your fluid.

Q4: Does this account for friction losses?
A: No, this is ideal flow. For real-world applications, consider additional factors like pipe roughness and length.

Q5: How do I calculate pipe cross-sectional area?
A: For circular pipes: \( A = \pi \times (diameter/2)^2 \), with diameter in feet.