Physics, asked by nehasheenam3001, 11 months ago

Why there is more energy loss in turbulent flow compared to laminar flow

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Answered by sujoy967
2

There are two types of flow in pipes:

There are two types of flow in pipes:1. Laminar flow:This is also known as streamline or viscous flow and in

There are two types of flow in pipes:1. Laminar flow:This is also known as streamline or viscous flow and instreamline flow, the fluid appears to move by sliding of laminations of infinitesimal thickness

There are two types of flow in pipes:1. Laminar flow:This is also known as streamline or viscous flow and instreamline flow, the fluid appears to move by sliding of laminations of infinitesimal thickness relative to adjacent layers; that is, the particles move in definite and observable paths or

There are two types of flow in pipes:1. Laminar flow:This is also known as streamline or viscous flow and instreamline flow, the fluid appears to move by sliding of laminations of infinitesimal thickness relative to adjacent layers; that is, the particles move in definite and observable paths or streamlines. The flow characteristic of a viscous fluid is one in which viscosity plays a

There are two types of flow in pipes:1. Laminar flow:This is also known as streamline or viscous flow and instreamline flow, the fluid appears to move by sliding of laminations of infinitesimal thickness relative to adjacent layers; that is, the particles move in definite and observable paths or streamlines. The flow characteristic of a viscous fluid is one in which viscosity plays a significant part.

There are two types of flow in pipes:1. Laminar flow:This is also known as streamline or viscous flow and instreamline flow, the fluid appears to move by sliding of laminations of infinitesimal thickness relative to adjacent layers; that is, the particles move in definite and observable paths or streamlines. The flow characteristic of a viscous fluid is one in which viscosity plays a significant part. Laminar flow.......

2.Turbulent flow: . It is characterized by a fluid flowing in random

2.Turbulent flow: . It is characterized by a fluid flowing in random way. The movement of particles fluctuates up and down in a direction perpendicular as well as

2.Turbulent flow: . It is characterized by a fluid flowing in random way. The movement of particles fluctuates up and down in a direction perpendicular as well as parallel to the mean flow direction.

2.Turbulent flow: . It is characterized by a fluid flowing in random way. The movement of particles fluctuates up and down in a direction perpendicular as well as parallel to the mean flow direction.This mixing action generates turbulence due to the colliding fluid particles. This causes a

2.Turbulent flow: . It is characterized by a fluid flowing in random way. The movement of particles fluctuates up and down in a direction perpendicular as well as parallel to the mean flow direction.This mixing action generates turbulence due to the colliding fluid particles. This causes a considerable more resistance to flow and thus greater energy losses than those produced by

2.Turbulent flow: . It is characterized by a fluid flowing in random way. The movement of particles fluctuates up and down in a direction perpendicular as well as parallel to the mean flow direction.This mixing action generates turbulence due to the colliding fluid particles. This causes a considerable more resistance to flow and thus greater energy losses than those produced by laminar flow. A distinguishing characteristic of turbulence is its irregularity, there being no

2.Turbulent flow: . It is characterized by a fluid flowing in random way. The movement of particles fluctuates up and down in a direction perpendicular as well as parallel to the mean flow direction.This mixing action generates turbulence due to the colliding fluid particles. This causes a considerable more resistance to flow and thus greater energy losses than those produced by laminar flow. A distinguishing characteristic of turbulence is its irregularity, there being no definite frequency, as in wave motion, and no observable pattern, as in the case of large eddies.

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