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Pressure Drop in Plate Type Heat Exchanger given Reynolds Number Formula

GoPressure Drop in Plate Type Heat Exchanger Formula

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Plate Pressure Drop refers to the loss of fluid pressure as the fluid flows through the channels formed by the plates. Check FAQs

ΔP p = 8 \cdot (0.6 \cdot ({Re}^{- 0.3})) \cdot (\frac{L p}{D e}) \cdot (ρ fluid \cdot \frac{{u p}^{2}}{2})

ΔP_p - Plate Pressure Drop?Re - Reynold Number?L_p - Path Length?D_e - Equivalent Diameter?ρ_fluid - Fluid Density?u_p - Channel Velocity?

Pressure Drop in Plate Type Heat Exchanger given Reynolds Number Example

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Here is how the Pressure Drop in Plate Type Heat Exchanger given Reynolds Number equation looks like with Values.

Here is how the Pressure Drop in Plate Type Heat Exchanger given Reynolds Number equation looks like with Units.

Here is how the Pressure Drop in Plate Type Heat Exchanger given Reynolds Number equation looks like.

120988.3465 = 8 \cdot (0.6 \cdot ({23.159}^{- 0.3})) \cdot (\frac{631.47}{16.528}) \cdot (995 \cdot \frac{{1.845}^{2}}{2})

120988.3465Pa = 8 \cdot (0.6 \cdot ({23.159}^{- 0.3})) \cdot (\frac{631.47mm}{16.528mm}) \cdot (995kg/m³ \cdot \frac{{1.845m/s}^{2}}{2})

120988.3465 = 8 \cdot (0.6 \cdot ({23.159}^{- 0.3})) \cdot (\frac{631.47}{16.528}) \cdot (995 \cdot \frac{{1.845}^{2}}{2})

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Pressure Drop in Plate Type Heat Exchanger given Reynolds Number Solution

Follow our step by step solution on how to calculate Pressure Drop in Plate Type Heat Exchanger given Reynolds Number?

FIRST Step Consider the formula

ΔP p = 8 \cdot (0.6 \cdot ({Re}^{- 0.3})) \cdot (\frac{L p}{D e}) \cdot (ρ fluid \cdot \frac{{u p}^{2}}{2})

Next Step Substitute values of Variables

∴

ΔP p = 8 \cdot (0.6 \cdot ({23.159}^{- 0.3})) \cdot (\frac{631.47mm}{16.528mm}) \cdot (995kg/m³ \cdot \frac{{1.845m/s}^{2}}{2})

Next Step Convert Units

∴

ΔP p = 8 \cdot (0.6 \cdot ({23.159}^{- 0.3})) \cdot (\frac{0.6315m}{0.0165m}) \cdot (995kg/m³ \cdot \frac{{1.845m/s}^{2}}{2})

Next Step Prepare to Evaluate

∴

ΔP p = 8 \cdot (0.6 \cdot ({23.159}^{- 0.3})) \cdot (\frac{0.6315}{0.0165}) \cdot (995 \cdot \frac{{1.845}^{2}}{2})

Next Step Evaluate

∴

ΔP p = 120988.346458467Pa

LAST Step Rounding Answer

∴

ΔP p = 120988.3465Pa

Pressure Drop in Plate Type Heat Exchanger given Reynolds Number Formula Elements

Variables

Plate Pressure Drop

Plate Pressure Drop refers to the loss of fluid pressure as the fluid flows through the channels formed by the plates.

Symbol: ΔP_p

Measurement: PressureUnit: Pa

Note: Value should be greater than 0.

Formulas to find Plate Pressure Drop

Reynold Number

Reynold Number is defined as the ratio of inertial force to the viscous force of fluid.

Symbol: Re

Measurement: NAUnit: Unitless

Note: Value should be greater than 0.

Formulas to find Reynold Number

Path Length

Path Length refers to the distance that the fluid travels between the plates. It represents the length of the flow path within the heat exchanger channels formed by adjacent plates.

Symbol: L_p

Measurement: LengthUnit: mm

Note: Value should be greater than 0.

Formulas to find Path Length

Equivalent Diameter

Equivalent diameter represents a single characteristic length that takes into account the cross-sectional shape and flow path of a non-circular or irregularly shaped channel or duct.

Symbol: D_e

Measurement: LengthUnit: mm

Note: Value should be greater than 0.

Formulas to find Equivalent Diameter

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

Channel Velocity

Channel Velocity refers to the average velocity of the fluid flowing through the channels formed by adjacent plates.

Symbol: u_p

Measurement: SpeedUnit: m/s

Note: Value should be greater than 0.

Formulas to find Channel Velocity

Other Formulas to find Plate Pressure Drop

Go Pressure Drop in Plate Type Heat Exchanger

ΔP p = 8 \cdot J f \cdot (\frac{L p}{D e}) \cdot \frac{ρ fluid \cdot ({u p}^{2})}{2}

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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 Pressure Drop in Plate Type Heat Exchanger given Reynolds Number?

Pressure Drop in Plate Type Heat Exchanger given Reynolds Number evaluator uses Plate Pressure Drop = 8*(0.6*(Reynold Number^(-0.3)))*(Path Length/Equivalent Diameter)*(Fluid Density*(Channel Velocity^2)/2) to evaluate the Plate Pressure Drop, The Pressure Drop in Plate Type Heat Exchanger given Reynolds Number formula is defined as the decrease in pressure experienced by the fluid as it travels through the flow channels created by the stacked plates. Plate Pressure Drop is denoted by ΔP_p symbol.

How to evaluate Pressure Drop in Plate Type Heat Exchanger given Reynolds Number using this online evaluator? To use this online evaluator for Pressure Drop in Plate Type Heat Exchanger given Reynolds Number, enter Reynold Number (Re), Path Length (L_p), Equivalent Diameter (D_e), Fluid Density (ρ_fluid) & Channel Velocity (u_p) and hit the calculate button.

FAQs on Pressure Drop in Plate Type Heat Exchanger given Reynolds Number

What is the formula to find Pressure Drop in Plate Type Heat Exchanger given Reynolds Number?

The formula of Pressure Drop in Plate Type Heat Exchanger given Reynolds Number is expressed as Plate Pressure Drop = 8*(0.6*(Reynold Number^(-0.3)))*(Path Length/Equivalent Diameter)*(Fluid Density*(Channel Velocity^2)/2). Here is an example- 120988.3 = 8*(0.6*(23.159^(-0.3)))*(0.63147/0.016528)*(995*(1.845^2)/2).

How to calculate Pressure Drop in Plate Type Heat Exchanger given Reynolds Number?

With Reynold Number (Re), Path Length (L_p), Equivalent Diameter (D_e), Fluid Density (ρ_fluid) & Channel Velocity (u_p) we can find Pressure Drop in Plate Type Heat Exchanger given Reynolds Number using the formula - Plate Pressure Drop = 8*(0.6*(Reynold Number^(-0.3)))*(Path Length/Equivalent Diameter)*(Fluid Density*(Channel Velocity^2)/2).

What are the other ways to Calculate Plate Pressure Drop?

Here are the different ways to Calculate Plate Pressure Drop-

Plate Pressure Drop=8*Friction Factor*(Path Length/Equivalent Diameter)*(Fluid Density*(Channel Velocity^2))/2

Can the Pressure Drop in Plate Type Heat Exchanger given Reynolds Number be negative?

No, the Pressure Drop in Plate Type Heat Exchanger given Reynolds Number, measured in Pressure cannot be negative.

Which unit is used to measure Pressure Drop in Plate Type Heat Exchanger given Reynolds Number?

Pressure Drop in Plate Type Heat Exchanger given Reynolds Number 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 Pressure Drop in Plate Type Heat Exchanger given Reynolds Number can be measured.

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Pressure Drop in Plate Type Heat Exchanger given Reynolds Number Formula

​GoPressure Drop in Plate Type Heat Exchanger Formula

Pressure Drop in Plate Type Heat Exchanger given Reynolds Number Example

Pressure Drop in Plate Type Heat Exchanger given Reynolds Number Solution

Pressure Drop in Plate Type Heat Exchanger given Reynolds Number Formula Elements

Other Formulas to find Plate Pressure Drop

Other formulas in Basic Formulas of Heat Exchanger Designs category

How to Evaluate Pressure Drop in Plate Type Heat Exchanger given Reynolds Number?

FAQs on Pressure Drop in Plate Type Heat Exchanger given Reynolds Number

Variable Name

GoPressure Drop in Plate Type Heat Exchanger Formula