Using the velocity distribution for a laminar, incompressible flow of a Newtonian fluid in a long vertical tube, for a fluid whose density is 300 kg per cubic meter and viscosity is 1x10 - 4 Pascal-second travelling along a long circular tube of cross sectional area of 1 cm? owing to a pressure gradient of 1,000 Pascal per meter, the average velocity in meter per second (m/s) is Blank 1. **EXPRESS YOUR ANSWER INTO WHOLE SIGNIFICANT FIGURE (NO DECIMAL PLACE)**

Using the velocity distribution for a laminar, incompressible flow of a Newtonian fluid in a long vertical tube, for a fluid whose density is 300 kg per cubic meter and viscosity is 1x10 - 4 Pascal-second travelling along a long circular tube of cross sectional area of 1 cm? owing to a pressure gradient of 1,000 Pascal per meter, the average velocity in meter per second (m/s) is Blank 1. EXPRESS YOUR ANSWER INTO WHOLE SIGNIFICANT FIGURE (NO DECIMAL PLACE)

Principles of Heat Transfer (Activate Learning with these NEW titles from Engineering!)

8th Edition

ISBN:9781305387102

Author:Kreith, Frank; Manglik, Raj M.

Publisher:Kreith, Frank; Manglik, Raj M.

Chapter5: Analysis Of Convection Heat Transfer

Section: Chapter Questions

Problem 5.20P

See similar textbooks

Similar questions

Using the velocity distribution for a laminar, incompressible flow of a Newtonian fluid in a long vertical tube, for a fluid whose density is 300 kg per cubic meter and viscosity is 1x10 - 4 Pascal-second travelling along a long circular tube of cross sectional area of 1 cm2 owing to a pressure gradient of 1,000 Pascal per meter, the average velocity in meter per second (m/s) is Blank 1.
ANSWER ASAP Using the velocity distribution for a laminar, incompressible flow of a Newtonian fluid in a long vertical tube, for a fluid whose density is 300 kg per cubic meter and viscosity is 1x10 - 4 Pascal-second travelling along a long circular tube of cross sectional area of 1 cm2 owing to a pressure gradient of 1,000 Pascal per meter, the average velocity in meter per second (m/s) is Blank 1.
PROB E. A capillary –tube viscometer is being selected to measure viscosity of a liquid food. The maximum viscosity to be measured will be 230 cP and the maximum mass rate is 900 grams per hour. If the tube length is 10 cm and the maximum sustainable pressure is 25 Pa, determine the nominal diameter size of the tube to be used.
An ideal gas at 250 °C and atmospheric pressure flows through a smooth pipe with ID 6-in. The molecular weight of the ideal gas is 35 g/mol, and its viscosity is 0.002 cP. If the average velocity of the gas is 3.5 m/s, determine the pressure drop per unit length (m).
3.1 A cylindrical plug, 120mm long with a diameter of 95 mm, slides concentrically in a fixed cylinderwith an internal diameter of 95,2 mm. The radial clearance is filled with oil with a viscosity of 0.2 Pa.sCalculate the Force required to slide the plug along the cylinder at a speed of 5 m/s against the viscousresistance of the oil, the power lost due to the viscous resistance and the Kinematic viscosity of the oil ifits density is 850 kg/m 3 . A pressure intensifier is used in reverse deboost the pressure in a hydraulic system from 15MPa to7MPa. The volume of fluid required in the low pressure side is 700ml and the length of the stroke of thepiston is to be half the diameter of the low pressure piston. Calculate the diameters of the high-pressureand low pressure sides as well as the stroke length of the piston.
Conduct thorough a research on Reynolds Number, laminar and turbulent flow as it relates to mechanics of fluids
7. Using the velocity distribution for a laminar, incompressible flow of a Newtonian fluid in a long vertical tube, for a fluid whose density is 300 kg per cubic meter and viscosity is 1x10 - 4 Pascal-second travelling along a long circular tube of cross sectional area of 1 cm2 owing to a pressure gradient of 1,000 Pascal per meter, the average velocity in meter per second (m/s) is Please help asap
i) With Froude’s number as the criterion of dynamic similarity for a certain flow situation, work out the scale factors for velocity, time, discharge, acceleration, and power in terms of the scale factor for length. ii) Compare and contrast the velocity profile of laminar flow and turbulent flow in pipe and comment on them and state any two(2) practical examples.
Calculate the pressure drop through horizontal sanitary stainless steel tubing (9 mminner radius and 1.2 m long) for an apple juice drink that flows with a velocity of 3.13 ms -1 . The density and viscosity of apple juice drink are 1100 kg m -3 and 0.8 x 10 -3 kg m -1 s -1 , respectively. Use the Moody diagram to solve this problem.
Ethylene Glycol at 60°C with a velocity of 4 cm/s enters a 2.5 cm diameter tube. The viscosity at the given temperature is 4.75 x 10−6 ?2/s. Determine the Reynolds number and its type of fluid flow. Show your step by step solution.
Draw neat sketches of the following and label them:D. An open system with variable imaginary boundaryE. Turbulent flow through a pipe with velocity distribution
A 1/4” inside diameter pipe is used to transport SAE 30 motor oil (µ = 0.006266 slug/ft-s and ρ =1.7267 slug/ft3) over a distance of 100 ft. Assuming that the pipe is horizontal and the flow throughit is steady, laminar, and fully-developed, what gauge pressure must a pump develop at the head ofthe pipe to provide a flow rate of sufficient to fill a quart bottle every 5 seconds? [6291 psi] Whatis the Reynolds number (based on diameter) for this flow? [112.5] Is the assumption of laminar flowreasonable?