Consider the steady, incompressible, and fully developed laminar flow of a fluid through a circular pipe. Here, \( \Delta P \) is the pressure drop in the direction of the flow and \( V \) is the average axial velocity of the fluid at any cross-section. The relation between \( \Delta P \) and \( V \) is:
\[
\Delta P = K V^n
\]
Here, \( K \) and \( n \) are constants.
Which one of the following options is the correct value of \( n \)?
\[ \Delta P = K V^n \] Here, \( K \) and \( n \) are constants.
Which one of the following options is the correct value of \( n \)?
Show Hint
- 1
- 2
- 1.75
- 0.5
The Correct Option is A
Solution and Explanation
This relationship is derived from the Darcy-Weisbach equation for laminar flow, where the pressure drop depends linearly on the velocity. For laminar flow, the value of \( n \) is 1, indicating that the pressure drop increases directly as the velocity increases. This simple relationship holds because the resistance to flow in laminar flow is a linear function of the velocity.
Thus, the correct answer is (A) 1, which represents the case for fully developed laminar flow in a circular pipe.
Top Questions on Fluid Mechanics
- An oil of density \(870 \, {kg/m}^3\) and viscosity \(0.036 \, {Pa.s}\) flows through a straight pipe of 10 cm diameter and 1.5 km length at the flow rate of 250 liters per minute under the steady and incompressible flow conditions.
To control the flow rate of oil, a valve is fixed at the middle of the pipe causing no change in the total length of the pipe. The total head loss measured across the two ends of the pipe is \(11.60 \, {m}\). Using gravitational acceleration as \(10 \, {m/s}^2\), the minor head loss contributed by the presence of the valve in m {(rounded off to 2 decimal places) is ..........}- GATE XE - 2025
- Engineering Sciences
- Fluid Mechanics
A fixed control volume has four one-dimensional boundary sections (1, 2, 3, and 4). For a steady flow inside the control volume, the flow properties at each section are tabulated below:
The rate of change of energy of the system which occupies the control volume at this instant is \( E \times 10^6 \, {J/s} \). The value of \( E \) (rounded off to 2 decimal places) is ........- GATE XE - 2025
- Engineering Sciences
- Fluid Mechanics
A liquid flows under steady and incompressible flow conditions from station 1 to station 4 through pipe sections P, Q, R, and S as shown in the figure. Consider, \( d \), \( V \), and \( h \) represent the diameter, velocity, and head loss, respectively, in each pipe section with subscripts ‘P’, ‘Q’, ‘R’, and ‘S’. \( \Delta h \) represents the head difference between the inlet (station 1) and outlet (station 4). All the pipe sections are placed on the same horizontal plane for which the figure shows the top view.
(Insert diagram here, if possible)- GATE XE - 2025
- Engineering Sciences
- Fluid Mechanics
Figure shows the steady and incompressible flow of a fluid in the direction of the arrow from section A to section D. Three pipe connectors are to be placed between sections at A and D having Total Energy Line (TEL) and Hydraulic Grade Line (HGL) as depicted in the figure. Consider, \( g \), \( P \), \( Q \), \( V \), \( \gamma \), and \( Z \) denote gravitational acceleration, pressure, volume flow rate, velocity, specific weight, and elevation of the centerline of the pipe connectors from the datum, respectively. Which one of the following options, in sequence, indicates the correct nature of connectors between sections A and B, B and C, and C and D in the direction of flow?
- GATE XE - 2025
- Engineering Sciences
- Fluid Mechanics
- A solid body of uniform specific gravity floats in a deep liquid pool. Take \( B \), \( G \), and \( M \) as the centre of buoyancy, centre of gravity, and metacentre of the body, respectively. Which one of the following options is correct for the stable floatation of the body in the pool when the body is given a small tilt angle?
- GATE XE - 2025
- Engineering Sciences
- Fluid Mechanics
Questions Asked in GATE XE exam
In the figures given below, L and H indicate low and high pressure centers, respectively; PGF, CoF and CeF indicate Pressure Gradient Force, Coriolis Force and Centrifugal Force, respectively; \( V \) is Velocity. [The arrows indicate only the directions but not the magnitudes of the forces and velocity.]
Which of the following is/are the correct representation(s) of the directions of various forces and velocity in the gradient wind balance in the northern hemisphere?
- GATE XE - 2025
- Atmospheric Science
Which of the following is the correct form of the mass divergence form of the continuity equation for a compressible fluid? [In the given equations, \( \rho \) is the density and \( \nabla \) the three-dimensional velocity vector of the fluid.]
[(i)] $\displaystyle \frac{\partial \rho}{\partial t} + \nabla \times (\rho \mathbf{v}) = 0$
[(ii)] $\displaystyle \frac{\partial \rho}{\partial t} + \nabla \cdot (\rho \mathbf{v}) = 0$
[(iii)] $\displaystyle \frac{\partial \mathbf{v}}{\partial t} + \rho \cdot \nabla \mathbf{v} = 0$
[(iv)] $\displaystyle \frac{\partial \rho}{\partial t} + \mathbf{v} \cdot \nabla \rho = 0$- GATE XE - 2025
- Atmospheric Science
- The north-Atlantic deep-water is associated with .........
- GATE XE - 2025
- Indian Ocean Current Systems
- The zonal gradient of meridional current and the meridional gradient of zonal current is \( -0.3 \times 10^{-3} \, {s}^{-1} \) and \( 0.3 \times 10^{-3} \, {s}^{-1} \), respectively, at a location P (87°E, 15°N). Which one of the following best explains the nature of the flow?
- GATE XE - 2025
- Indian Ocean Current Systems
The vertical (depth) profiles for three parameters P1, P2, and P3 in the northern Indian Ocean are given in the figure below. The values along the x-axis are the normalized values of the parameters and y-axis is the depth (m).
Identify the parameters P1, P2, and P3 from the options given below.
- GATE XE - 2025
- Indian Ocean Current Systems