FormulaDen.com

Physics Chemistry Math Chemical Engineering Civil Electrical Electronics Electronics and Instrumentation Materials Science Mechanical Production Engineering Financial Health

Tube Side Pressure Drop given Pumping Power and Mass Flowrate of Fluid Formula

GoTube Side Pressure Drop in Heat Exchanger for Laminar Flow Formula

GoTube Side Pressure Drop in Heat Exchanger for Turbulent Flow Formula

Fx Copy

LaTeX Copy

Tube Side Pressure Drop is the difference between inlet and outlet pressure of the tube side fluid in a shell and tube heat exchanger. Check FAQs

ΔP Tube Side = \frac{P p \cdot ρ fluid}{M flow}

ΔP_{Tube Side} - Tube Side Pressure Drop?P_p - Pumping Power?ρ_fluid - Fluid Density?M_flow - Mass Flowrate?

Tube Side Pressure Drop given Pumping Power and Mass Flowrate of Fluid Example

With values

With units

Only example

Here is how the Tube Side Pressure Drop given Pumping Power and Mass Flowrate of Fluid equation looks like with Values.

Here is how the Tube Side Pressure Drop given Pumping Power and Mass Flowrate of Fluid equation looks like with Units.

Here is how the Tube Side Pressure Drop given Pumping Power and Mass Flowrate of Fluid equation looks like.

186854.6036 = \frac{2629.11 \cdot 995}{14}

186854.6036Pa = \frac{2629.11W \cdot 995kg/m³}{14kg/s}

186854.6036 = \frac{2629.11 \cdot 995}{14}

Tip: Use pencil ( Pencil

) icon above to edit Input Values and Units.

Calculate

Recalculate

Solution

Copy

Reset

You are here -

Home » Category

Engineering » Category

Chemical Engineering » Category

Process Equipment Design » fx Tube Side Pressure Drop given Pumping Power and Mass Flowrate of Fluid

Tube Side Pressure Drop given Pumping Power and Mass Flowrate of Fluid Solution

Follow our step by step solution on how to calculate Tube Side Pressure Drop given Pumping Power and Mass Flowrate of Fluid?

FIRST Step Consider the formula

ΔP Tube Side = \frac{P p \cdot ρ fluid}{M flow}

Next Step Substitute values of Variables

∴

ΔP Tube Side = \frac{2629.11W \cdot 995kg/m³}{14kg/s}

Next Step Prepare to Evaluate

∴

ΔP Tube Side = \frac{2629.11 \cdot 995}{14}

Next Step Evaluate

∴

ΔP Tube Side = 186854.603571429Pa

LAST Step Rounding Answer

∴

ΔP Tube Side = 186854.6036Pa

Tube Side Pressure Drop given Pumping Power and Mass Flowrate of Fluid Formula Elements

Variables

Tube Side Pressure Drop

Tube Side Pressure Drop is the difference between inlet and outlet pressure of the tube side fluid in a shell and tube heat exchanger.

Symbol: ΔP_{Tube Side}

Measurement: PressureUnit: Pa

Note: Value should be greater than 0.

Formulas to find Tube Side Pressure Drop

Pumping Power

Pumping Power in a heat exchanger refers to the energy required to circulate the heat transfer fluid (typically a liquid) through the exchanger.

Symbol: P_p

Measurement: PowerUnit: W

Note: Value should be greater than 0.

Formulas to find Pumping Power

Fluid Density

Fluid Density is defined as the ratio of mass of given fluid with respect to the volume that it occupies.

Symbol: ρ_fluid

Measurement: DensityUnit: kg/m³

Note: Value should be greater than 0.

Formulas to find Fluid Density

Mass Flowrate

Mass Flowrate is the mass of a substance that passes per unit of time.

Symbol: M_flow

Measurement: Mass Flow RateUnit: kg/s

Note: Value should be greater than 0.

Formulas to find Mass Flowrate

Other Formulas to find Tube Side Pressure Drop

Go Tube Side Pressure Drop in Heat Exchanger for Laminar Flow

ΔP Tube Side = N Tube Pass \cdot (8 \cdot J f \cdot (\frac{L Tube}{D inner}) \cdot {(\frac{μ fluid}{μ Wall})}^{- 0.25} + 2.5) \cdot (\frac{ρ fluid}{2}) \cdot ({V f}^{2})

Go Tube Side Pressure Drop in Heat Exchanger for Turbulent Flow

ΔP Tube Side = N Tube Pass \cdot (8 \cdot J f \cdot (\frac{L Tube}{D inner}) \cdot {(\frac{μ fluid}{μ Wall})}^{- 0.14} + 2.5) \cdot (\frac{ρ fluid}{2}) \cdot ({V f}^{2})

Other formulas in Basic Formulas of Heat Exchanger Designs category

Go Equivalent Diameter for Square Pitch in Heat Exchanger

D e = (\frac{1.27}{D Outer}) \cdot (({P Tube}^{2}) - 0.785 \cdot ({D Outer}^{2}))

Go Equivalent Diameter for Triangular Pitch in Heat Exchanger

D e = (\frac{1.10}{D Outer}) \cdot (({P Tube}^{2}) - 0.917 \cdot ({D Outer}^{2}))

Go Number of Baffles in Shell and Tube Heat Exchanger

N Baffles = (\frac{L Tube}{L Baffle}) - 1

Go Number of Tubes in Center Row Given Bundle Diameter and Tube Pitch

N r = \frac{D B}{P Tube}

How to Evaluate Tube Side Pressure Drop given Pumping Power and Mass Flowrate of Fluid?

Tube Side Pressure Drop given Pumping Power and Mass Flowrate of Fluid evaluator uses Tube Side Pressure Drop = (Pumping Power*Fluid Density)/Mass Flowrate to evaluate the Tube Side Pressure Drop, The Tube Side Pressure Drop given Pumping Power and Mass Flowrate of Fluid formula is defined as the decrease in pressure that occurs as a fluid flows through the tubes of the heat exchanger. Tube Side Pressure Drop is denoted by ΔP_{Tube Side} symbol.

How to evaluate Tube Side Pressure Drop given Pumping Power and Mass Flowrate of Fluid using this online evaluator? To use this online evaluator for Tube Side Pressure Drop given Pumping Power and Mass Flowrate of Fluid, enter Pumping Power (P_p), Fluid Density (ρ_fluid) & Mass Flowrate (M_flow) and hit the calculate button.

FAQs on Tube Side Pressure Drop given Pumping Power and Mass Flowrate of Fluid

What is the formula to find Tube Side Pressure Drop given Pumping Power and Mass Flowrate of Fluid?

The formula of Tube Side Pressure Drop given Pumping Power and Mass Flowrate of Fluid is expressed as Tube Side Pressure Drop = (Pumping Power*Fluid Density)/Mass Flowrate. Here is an example- 186854.6 = (2629.11*995)/14.

How to calculate Tube Side Pressure Drop given Pumping Power and Mass Flowrate of Fluid?

With Pumping Power (P_p), Fluid Density (ρ_fluid) & Mass Flowrate (M_flow) we can find Tube Side Pressure Drop given Pumping Power and Mass Flowrate of Fluid using the formula - Tube Side Pressure Drop = (Pumping Power*Fluid Density)/Mass Flowrate.

What are the other ways to Calculate Tube Side Pressure Drop?

Here are the different ways to Calculate Tube Side Pressure Drop-

Tube Side Pressure Drop=Number of Tube-Side Passes*(8*Friction Factor*(Length of Tube/Pipe Inner Diameter)*(Fluid Viscosity at Bulk Temperature/Fluid Viscosity at Wall Temperature)^-0.25+2.5)*(Fluid Density/2)*(Fluid Velocity^2)
Tube Side Pressure Drop=Number of Tube-Side Passes*(8*Friction Factor*(Length of Tube/Pipe Inner Diameter)*(Fluid Viscosity at Bulk Temperature/Fluid Viscosity at Wall Temperature)^-0.14+2.5)*(Fluid Density/2)*(Fluid Velocity^2)

Can the Tube Side Pressure Drop given Pumping Power and Mass Flowrate of Fluid be negative?

No, the Tube Side Pressure Drop given Pumping Power and Mass Flowrate of Fluid, measured in Pressure cannot be negative.

Which unit is used to measure Tube Side Pressure Drop given Pumping Power and Mass Flowrate of Fluid?

Tube Side Pressure Drop given Pumping Power and Mass Flowrate of Fluid is usually measured using the Pascal[Pa] for Pressure. Kilopascal[Pa], Bar[Pa], Pound Per Square Inch[Pa] are the few other units in which Tube Side Pressure Drop given Pumping Power and Mass Flowrate of Fluid can be measured.

Let Others Know

✖

Facebook

Twitter

Copied!

: Value
: Unit

Tube Side Pressure Drop given Pumping Power and Mass Flowrate of Fluid Formula

​GoTube Side Pressure Drop in Heat Exchanger for Laminar Flow Formula

​GoTube Side Pressure Drop in Heat Exchanger for Turbulent Flow Formula

Tube Side Pressure Drop given Pumping Power and Mass Flowrate of Fluid Example

Tube Side Pressure Drop given Pumping Power and Mass Flowrate of Fluid Solution

Tube Side Pressure Drop given Pumping Power and Mass Flowrate of Fluid Formula Elements

Other Formulas to find Tube Side Pressure Drop

Other formulas in Basic Formulas of Heat Exchanger Designs category

How to Evaluate Tube Side Pressure Drop given Pumping Power and Mass Flowrate of Fluid?

FAQs on Tube Side Pressure Drop given Pumping Power and Mass Flowrate of Fluid

Variable Name

GoTube Side Pressure Drop in Heat Exchanger for Laminar Flow Formula

GoTube Side Pressure Drop in Heat Exchanger for Turbulent Flow Formula