Impact of jet
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Nov 27, 2019
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About This Presentation
Impact of jet on plate - flat, inclined, curved
Slide Content
IMPACT OF JET
Impact of Jet
The jet is a stream of liquid coming out from
nozzle with a high velocity under constant
pressure.
Impact of Jet means the force exerted by the jet
on a plate which may be stationary or moving.
The plate may be flat or curved.
This force is obtained from Newton’s 2nd law
of motion or Impulse – Momentum principle.
The jet is a stream of liquid coming out from
nozzle with a high velocity under constant
pressure.
Impact of Jet means the force exerted by the jet
on a plate which may be stationary or moving.
The plate may be flat or curved.
This force is obtained from Newton’s 2nd law
of motion or Impulse – Momentum principle.
Impulse-Momentum Theorem
The impulse-momentum theorem states that
the change in momentum of an object equals
the impulse applied to it.
For constant mass dm = 0. change in momentum may
occurs due to a change in the magnitude of velocity or
in its direction or due to both.
The impulse-momentum theorem states that
the change in momentum of an object equals
the impulse applied to it.
For constant mass dm = 0. change in momentum may
occurs due to a change in the magnitude of velocity or
in its direction or due to both.
The following cases of the impact of jet, i.e. the
force exerted by the jet on a plate will be
considered:‐
Force exerted by the jet on a stationary plate
1)Plate is vertical to the jet
2)Plate is inclined to the jet
3)Plate is curved
Force exerted by the jet on a moving plate
1)Plate is vertical to the jet
2)Plate is inclined to the jet
3)Plate is curved
force exerted by the jet on a plate will be
considered:‐
Force exerted by the jet on a stationary plate
1)Plate is vertical to the jet
2)Plate is inclined to the jet
3)Plate is curved
Force exerted by the jet on a moving plate
1)Plate is vertical to the jet
2)Plate is inclined to the jet
3)Plate is curved
Force exerted by the jet on Vertical Flat Plate
1.When the plate is stationary
Let, V = Velocity of the jet in the direction of x
d = diameter of the jet
a = area of c/s of the jet =
?????? �
4
2
1.When the plate is stationary
Let, V = Velocity of the jet in the direction of x
d = diameter of the jet
a = area of c/s of the jet =
?????? �
4
2
Consider a jet of water strikes a stationary vertical flat plate as shown
in fig. The jet after striking the plate will deflected through 90°. So final
velocity of fluid in the direction of the jet after striking plate will be
zero.
The force exerted by the jet on the plate in the direction of jet.
Fx = Rate of change of momentum in the direction of force
=
??????��????????????� �������� − ????????????�??????� ��������
????????????��
=
????????????�� ?????? ??????��????????????� ??????����??????�� − ????????????�� ?????? ????????????�??????� ??????����??????��
????????????��
=
????????????��
????????????��
[??????�???????????????????????? ??????????????????�???????????????????????? – ????????????�???????????? ??????????????????�????????????????????????]
= Mass/sec [Velocity of jet before striking - Velocity of jet after striking ]
= ρaV (V - 0) [Mass/sec = ρ x aV]
= ρaV
2
in fig. The jet after striking the plate will deflected through 90°. So final
velocity of fluid in the direction of the jet after striking plate will be
zero.
The force exerted by the jet on the plate in the direction of jet.
Fx = Rate of change of momentum in the direction of force
=
??????��????????????� �������� − ????????????�??????� ��������
????????????��
=
????????????�� ?????? ??????��????????????� ??????����??????�� − ????????????�� ?????? ????????????�??????� ??????����??????��
????????????��
=
????????????��
????????????��
[??????�???????????????????????? ??????????????????�???????????????????????? – ????????????�???????????? ??????????????????�????????????????????????]
= Mass/sec [Velocity of jet before striking - Velocity of jet after striking ]
= ρaV (V - 0) [Mass/sec = ρ x aV]
= ρaV
2
2. When the plate is moving
Let, u = Velocity of the plate
Consider a jet of water strikes a vertical flat plate which is moving with a
uniform velocity. In this case jet strikes the plate with a relative velocity.
Relative velocity of jet with respect to plate = V – u
Fx = Rate of change of momentum in the direction of force
= ρa (V – u)[(V - u) – 0]
= ρa (V−u)
2
Let, u = Velocity of the plate
Consider a jet of water strikes a vertical flat plate which is moving with a
uniform velocity. In this case jet strikes the plate with a relative velocity.
Relative velocity of jet with respect to plate = V – u
Fx = Rate of change of momentum in the direction of force
= ρa (V – u)[(V - u) – 0]
= ρa (V−u)
2
Fx = Rate of change of momentum in the direction of force
= ρa (V – u)[(V – u) – 0]
= ρa (V−u)
2
In this case, work is done by the jet on the plate as the plate
is moving,
for stationary plate the work done is zero.
Work done by the jet on the flat moving plate
Wd/sec = Force x Distance in the direction of force/ Time
= ρa (V−u)
2
x u
= ρa (V – u)[(V – u) – 0]
= ρa (V−u)
2
In this case, work is done by the jet on the plate as the plate
is moving,
for stationary plate the work done is zero.
Work done by the jet on the flat moving plate
Wd/sec = Force x Distance in the direction of force/ Time
= ρa (V−u)
2
x u
1. When the plate is stationary
Let V = Velocity of the jet in the direction of x
a = area of c/s of the jet
θ = Angle between the jet and plate
Mass of water striking the plate per sec = ρ x aV
Force exerted by the jet on a Inclined Plate
(90º˗θ)
Let V = Velocity of the jet in the direction of x
a = area of c/s of the jet
θ = Angle between the jet and plate
Mass of water striking the plate per sec = ρ x aV
Force exerted by the jet on a Inclined Plate
(90º˗θ)
Force exerted by jet on the inclined plate in the
direction normal to the plate, Fn
Fn = Mass of water striking/sec x [Initial velocity – Final velocity]
= ρaV (V sinθ – 0)
= ρaV
2
sinθ
This normal force can be resolved into two components one in the
direction of jet and other perpendicular to the direction of jet.
Fx = Component of Fn in the direction of flow
= Fn cos (90º – θ) = Fn x sinθ = ρaV
2
sin
2
θ
Fy = Component of Fn perpendicular to the flow
= Fn sin (90º – θ) = Fn x cosθ = ρaV
2
sinθ cosθ
direction normal to the plate, Fn
Fn = Mass of water striking/sec x [Initial velocity – Final velocity]
= ρaV (V sinθ – 0)
= ρaV
2
sinθ
This normal force can be resolved into two components one in the
direction of jet and other perpendicular to the direction of jet.
Fx = Component of Fn in the direction of flow
= Fn cos (90º – θ) = Fn x sinθ = ρaV
2
sin
2
θ
Fy = Component of Fn perpendicular to the flow
= Fn sin (90º – θ) = Fn x cosθ = ρaV
2
sinθ cosθ
2. When the plate is moving
Let V = Velocity of the jet
a = area of c/s of the jet
u = Velocity of the plate
θ = Angle between the jet and plate
In this case jet strikes the plate with a relative velocity.
Relative velocity of jet with respect to plate = V – u
Mass of water striking the plate per sec = ρ x a(V–u)
Let V = Velocity of the jet
a = area of c/s of the jet
u = Velocity of the plate
θ = Angle between the jet and plate
In this case jet strikes the plate with a relative velocity.
Relative velocity of jet with respect to plate = V – u
Mass of water striking the plate per sec = ρ x a(V–u)
Force exerted by jet on the inclined plate in the direction
normal to the plate, Fn
Fn = Mass of water striking/sec x [Initial velocity – Final velocity]
= ρa(V–u)((V–u)sin θ – 0)
= ρa(V–u)
2
sin θ
This normal force can be resolved into two components one in the direction of
jet and other perpendicular to the direction of jet.
Fx = Component of Fn in the direction of flow
= Fn cos (90º – θ) = Fn x sin θ = ρa(V–u)
2
sin
2
θ
Fy = Component of Fn perpendicular to the flow
= Fn sin (90º– θ) = Fn x cos θ = ρa(V–u)
2
sinθ cosθ
Wd/sec = Fx x u
= ρa(V–u)
2
sin
2
θ x u
= ρa(V–u)
2
u sin
2
θ
normal to the plate, Fn
Fn = Mass of water striking/sec x [Initial velocity – Final velocity]
= ρa(V–u)((V–u)sin θ – 0)
= ρa(V–u)
2
sin θ
This normal force can be resolved into two components one in the direction of
jet and other perpendicular to the direction of jet.
Fx = Component of Fn in the direction of flow
= Fn cos (90º – θ) = Fn x sin θ = ρa(V–u)
2
sin
2
θ
Fy = Component of Fn perpendicular to the flow
= Fn sin (90º– θ) = Fn x cos θ = ρa(V–u)
2
sinθ cosθ
Wd/sec = Fx x u
= ρa(V–u)
2
sin
2
θ x u
= ρa(V–u)
2
u sin
2
θ
1. Plate is stationary and Jet strikes at the centre
Force exerted by jet in the direction of jet (x – axis)
Fx = Mass/sec X [ V
1x – ??????
2� ]
Where, V
1x = Initial velocity in the direction of jet = V
V
2x = Final velocity in the direction of jet = –V cosθ
[–ve sign indicates velocity at outlet is in opposite direction of the jet of water coming out from nozzle]
Fx = ρaV [V – (–V cosθ)]
= ρaV
2
[1 + cosθ ]
Force exerted by the jet on a Curved Plate
Force exerted by jet in the direction of jet (x – axis)
Fx = Mass/sec X [ V
1x – ??????
2� ]
Where, V
1x = Initial velocity in the direction of jet = V
V
2x = Final velocity in the direction of jet = –V cosθ
[–ve sign indicates velocity at outlet is in opposite direction of the jet of water coming out from nozzle]
Fx = ρaV [V – (–V cosθ)]
= ρaV
2
[1 + cosθ ]
Force exerted by the jet on a Curved Plate
2. Plate is moving and Jet strikes at the centre
Relative velocity of jet with respect to plate = V – u
Force exerted by jet in the direction of jet (x – axis)
Fx = Mass/sec X [ V
1x – ??????
2� ] Where, V
1x = V – u , V
2x = –(V – u) cosθ
Fx = ρa(V−u)[(V−u) – (–(V−u)cosθ)]
= ρa(V−u)
2
[1 + cosθ ]
Wd/sec = Fx x u = ρa(V−u)
2
u [1 + cosθ ]
Relative velocity of jet with respect to plate = V – u
Force exerted by jet in the direction of jet (x – axis)
Fx = Mass/sec X [ V
1x – ??????
2� ] Where, V
1x = V – u , V
2x = –(V – u) cosθ
Fx = ρa(V−u)[(V−u) – (–(V−u)cosθ)]
= ρa(V−u)
2
[1 + cosθ ]
Wd/sec = Fx x u = ρa(V−u)
2
u [1 + cosθ ]
Jet strikes the curved Plate at one end tangentially
The curved plate is symmetrical about x-axis. So the angle made by tangents at the two
ends of the plate will be same.
Let,
V = Velocity of the jet
θ = Angle made by jet with x-axis at inlet tip of the plate
Force exerted by jet in the direction of jet
Fx = Mass/sec X [ V
1x – ??????
2� ]
Fx = ρaV [V cosθ – (–V cosθ)]
= ρaV [V cosθ + V cosθ)]
= 2ρaV
2
cosθ
Force exerted by the jet on a Stationary
Curved Plate (Symmetrical Plate)
The curved plate is symmetrical about x-axis. So the angle made by tangents at the two
ends of the plate will be same.
Let,
V = Velocity of the jet
θ = Angle made by jet with x-axis at inlet tip of the plate
Force exerted by jet in the direction of jet
Fx = Mass/sec X [ V
1x – ??????
2� ]
Fx = ρaV [V cosθ – (–V cosθ)]
= ρaV [V cosθ + V cosθ)]
= 2ρaV
2
cosθ
Force exerted by the jet on a Stationary
Curved Plate (Symmetrical Plate)
Jet strikes the curved Plate at one end tangentially
The curved plate is unsymmetrical about x-axis. So the angle made by tangents at the
two ends of the plate will be different.
Let,
θ = Angle made by jet with x-axis at inlet tip of the plate
ϕ = Angle made by jet with x-axis at outlet tip of the plate
Force exerted by jet in the direction of jet
Fx = Mass/sec X [ V
1x – ??????
2� ]
Fx = ρaV [V cosθ – (–V cos ϕ)]
= ρaV [V cosθ + V cos ϕ)]
= ρaV
2
[cosθ + cos ϕ)]
Force exerted by the jet on a Stationary
Curved Plate (Unsymmetrical Plate)
The curved plate is unsymmetrical about x-axis. So the angle made by tangents at the
two ends of the plate will be different.
Let,
θ = Angle made by jet with x-axis at inlet tip of the plate
ϕ = Angle made by jet with x-axis at outlet tip of the plate
Force exerted by jet in the direction of jet
Fx = Mass/sec X [ V
1x – ??????
2� ]
Fx = ρaV [V cosθ – (–V cos ϕ)]
= ρaV [V cosθ + V cos ϕ)]
= ρaV
2
[cosθ + cos ϕ)]
Force exerted by the jet on a Stationary
Curved Plate (Unsymmetrical Plate)
Force exerted by the jet on an
unsymmetrical Moving Curved Plate
unsymmetrical Moving Curved Plate
V
1 = Absolute velocity of the jet at inlet
u
1 = Velocity of the vane at inlet
V
r1= Relative velocity of the jet and plate at inlet
α = Angle between the direction of the jet and direction of motion of the
plate at inlet = Guide blade angle
θ = Angle made by the relative velocity , with the direction of motion of the
vane at inlet = Vane/blade angle at inlet
V
w1 and V
f1= The components of the velocity of the jet , V
1 in the direction of
motion and perpendicular to the direction of motion of the vane respectively.
V
w1 = Velocity of whirl at inlet
V
f1 = Velocity of flow at inlet
V
2 = Absolute velocity of the jet at outlet
u
2 = Velocity of the vane at outlet
V
r2= Relative velocity of the jet and plate at outlet
β = Angle made by the velocity V
2 with the direction of motion of the vane at outlet
Φ = Angle made by the relative velocity, V
r2 with the direction of motion of the vane at
outlet = Vane/blade angle at outlet
V
w2 = Velocity of whirl at outlet
V
f2 = Velocity of flow at outlet
1 = Absolute velocity of the jet at inlet
u
1 = Velocity of the vane at inlet
V
r1= Relative velocity of the jet and plate at inlet
α = Angle between the direction of the jet and direction of motion of the
plate at inlet = Guide blade angle
θ = Angle made by the relative velocity , with the direction of motion of the
vane at inlet = Vane/blade angle at inlet
V
w1 and V
f1= The components of the velocity of the jet , V
1 in the direction of
motion and perpendicular to the direction of motion of the vane respectively.
V
w1 = Velocity of whirl at inlet
V
f1 = Velocity of flow at inlet
V
2 = Absolute velocity of the jet at outlet
u
2 = Velocity of the vane at outlet
V
r2= Relative velocity of the jet and plate at outlet
β = Angle made by the velocity V
2 with the direction of motion of the vane at outlet
Φ = Angle made by the relative velocity, V
r2 with the direction of motion of the vane at
outlet = Vane/blade angle at outlet
V
w2 = Velocity of whirl at outlet
V
f2 = Velocity of flow at outlet
If the vane is smooth and having velocity in the direction of motion at inlet and
outlet equal then we have,
u
1 = u
2 = u = Velocity of vane in the direction of motion of vane
and V
r1 = V
r2
Mass of water striking the vane per second, m = ρaV
r1
Force exerted by the jet in the direction of motion,
Fx = mass of water striking per sec X [Initial velocity with which jet strikes in
the direction of motion – Final velocity of jet in the direction of motion]
Initial velocity with which jet strikes the vane = V
r1 and
component of V
r1 in the direction of motion = V
r1cosθ = (V
w1− u
1)
Similarly, component of V
r2 at outlet = −V
r2cosϕ = −(V
w2+ u
2)
Fx = ρaV
r1 [V
r1cosθ − (−V
r2cosϕ )]
Fx = ρaV
r1 [(V
w1− u
1) + (V
w2+ u
2)]
As we know u
1 = u
2
Fx = ρaV
r1 [V
w1+ V
w2]
Work done per second on the vane by the jet,
W = Fx x u
W = ρaV
r1 u [V
w1+ V
w2]
outlet equal then we have,
u
1 = u
2 = u = Velocity of vane in the direction of motion of vane
and V
r1 = V
r2
Mass of water striking the vane per second, m = ρaV
r1
Force exerted by the jet in the direction of motion,
Fx = mass of water striking per sec X [Initial velocity with which jet strikes in
the direction of motion – Final velocity of jet in the direction of motion]
Initial velocity with which jet strikes the vane = V
r1 and
component of V
r1 in the direction of motion = V
r1cosθ = (V
w1− u
1)
Similarly, component of V
r2 at outlet = −V
r2cosϕ = −(V
w2+ u
2)
Fx = ρaV
r1 [V
r1cosθ − (−V
r2cosϕ )]
Fx = ρaV
r1 [(V
w1− u
1) + (V
w2+ u
2)]
As we know u
1 = u
2
Fx = ρaV
r1 [V
w1+ V
w2]
Work done per second on the vane by the jet,
W = Fx x u
W = ρaV
r1 u [V
w1+ V
w2]
Force exerted by a jet of water on a
series of vanes
series of vanes
The force exerted by a jet of water on a single moving
plate is not practically feasible. Its only a theoretical one.
In actual practice, a large number of plates/blades are
mounted on the circumference of a wheel at a fixed
distance apart as shown in Fig.
The jet strikes a plate and due to the force exerted by the
jet on the plate, the wheel starts moving and the 2nd plate
mounted on the wheel appears before the jet, which again
exerts the force on the 2nd plate.
Thus each plate appears successively before the jet and jet
exerts force on each plate and the wheel starts moving at
a constant speed.
plate is not practically feasible. Its only a theoretical one.
In actual practice, a large number of plates/blades are
mounted on the circumference of a wheel at a fixed
distance apart as shown in Fig.
The jet strikes a plate and due to the force exerted by the
jet on the plate, the wheel starts moving and the 2nd plate
mounted on the wheel appears before the jet, which again
exerts the force on the 2nd plate.
Thus each plate appears successively before the jet and jet
exerts force on each plate and the wheel starts moving at
a constant speed.
Let, V = Velocity of jet,
d = Diameter of jet
u = Velocity of vane
In this case the mass of water coming out from the nozzle per second is always in
contact with the plates, when all the plates are considered.
Hence, mass of water per sec striking the series of plates = ρaV
Also, The jet strikes a plate with velocity = V − u
After striking, the jet moves tangential to the plate and hence the velocity component
in the direction of motion of plate is equals to zero.
Force exerted by the jet in the direction of motion of plate,
Fx = ρaV [(V − u) − 0]
Fx = ρaV (V − u)
Work done by the jet on the series of plates per second,
W = Fx x u
W = ρaV (V − u) x u
W = ρaV u (V − u)
d = Diameter of jet
u = Velocity of vane
In this case the mass of water coming out from the nozzle per second is always in
contact with the plates, when all the plates are considered.
Hence, mass of water per sec striking the series of plates = ρaV
Also, The jet strikes a plate with velocity = V − u
After striking, the jet moves tangential to the plate and hence the velocity component
in the direction of motion of plate is equals to zero.
Force exerted by the jet in the direction of motion of plate,
Fx = ρaV [(V − u) − 0]
Fx = ρaV (V − u)
Work done by the jet on the series of plates per second,
W = Fx x u
W = ρaV (V − u) x u
W = ρaV u (V − u)
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