Contents preface (VII) introduction 1—37

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9.2.1. Hydraulic Jump in Rectangular Channels
9.2.2. Energy Loss in Hydraulic Jump in a Rectangular Channel

Fig. 9.1. Control volume for hydraulic jump
With the assumptions that θ is small (i.e., sin θ ≅ 0), and β₁ = β₂ = 1, Eq. (9.1) becomes
ρ g z₁ A₁ – ρ g z₂ A₂ – F_f = ρQ (u₂ – u₁) (9.2) Equation (9.2) can be rewritten as

F_f

Q²

= _G

A₁

^z1J

− _G

+ A₂

^z2 J

ρ g

gA₂

gA₁

^Ff

= M – M

ρ g

where,

M =

_Q2

+ A z

and M is termed the specific momentum or force function or specific force.

(9.3)

(9.4)

(9.5)

SURFACE AND SUBSURFACE FLOW CONSIDERATIONS FOR DESIGN OF CANAL STRUCTURES

319

If the jump occurs in a horizontal channel and is not assisted by any other means, such as baffle blocks, then F_f ~₌ 0, and Eq. (9.4) yields

		M₁ = M₂		(9.6)
or	Q²	+ A₁	z₁	=	Q²	+ A₂ z₂	(9.7)
gA₁	gA₂						(9.7)

9.2.1. Hydraulic Jump in Rectangular Channels
A hydraulic jump formed in a smooth, wide, and horizontal rectangular channel is termed classical hydraulic jump. For rectangular channel of width B,

Q = u₁ A₁ = u₂ A₂
A₁ = B₁ h₁	and	A₂ = B₂h₂
z₁ = h₁/2	and	z₂ = h₂/2

Substituting these values into Eq. (9.7) one can, after simplification, obtain

1	h h (h	+ h ) =	q²
2	g
		1 2 1	2

where, q = Q/B. Equation (9.8) has the following solutions :

	^h2 ₌	¹ ( 1 + 8F ²	− 1)
	h₁		2	1

and	h₁	=		¹ ( 1 + 8F	2	− 1)
and	h₂		2	2

(9.8)

(9.9)
(9.10)

in which, F₁ and F₂ are the Froude numbers at sections 1 and 2, respectively. Froude number

F equals u/ gD in which, D is the hydraulic depth and equals A/T where, T is the top width of flow. Equations (9.9) and (9.10) are the well-known Belanger’s momentum equations.
9.2.2. Energy Loss in Hydraulic Jump in a Rectangular Channel
In a horizontal rectangular channel with the channel bed chosen as the datum, the total energies at sections 1 and 2, (Fig. 9.1 with θ = 0) are equal to the specific energies E₁ and E₂ at sections 1 and 2, respectively, i.e.,

q²
^E1 ⁼ ^h1 ⁺ ₂ _{g h}₁2

q² ^E2 ⁼ ^h2 ⁺ ₂_{g h}₂2

so that energy loss, ∆E = E₁ – E₂

q²

⁼ ^h1 ^– ^h2 ⁺ ₂ _g

1 = (h₁ – h₂) + ₄

L	1	1	O
M		−		P
h ²	h ²
M	1	2	P
N					Q

	F h ²	− h	² I
h₁h₂(h₁	+ h₂) _G	2		1	J
h₁	2	2
		H		h₂		K

(9.11)

(9.12)
(9.13)

320 IRRIGATION AND WATER RESOURCES ENGINEERING

					4h		² h − 4h	²h	+ h h ²	− h ³	+ h ³	− h	²h
	=	1	2		2	1	1	2			1	2	1	2
	=										4h₁ h₂
											4h₁ h₂
					h ³		− h	³ + 3h ² h − 3h h	2
	=		2		1				1	2	1		2
								4h₁ h₂
								4h₁ h₂
					(h		− h )³
∴	∆E =	2		1													(9.14)
		4h₁ h₂

	∆E		[ h	+ (u	² /2 g )] − [ h +	(u	2	/2 g)]
Also,		=	1		1				2	2						(9.15)
						[ h₁ + u₁² /2 g]
	^E1
	=			h [ 1 − ( h	/ h )] +		( q ² /2 g h	² ) [ 1 − ( h	/ h ) ²	]
	=	1			2	1					1		1	2
											( h /2) [ 2	+ F	2 _]
											1				1
	∆E2 − 2 ( h	/ h ) + F	² [ 1 − ( h		/ h ) ²	]
∴		=					2		1	1		1		2			(9.16)
								2 + F₁²
	^E1
Combining Eq. (9.8), (9.11) and (9.14), one can obtain
	∆E	8 F	⁴ + 20 F ²	− (8 F ² + 1) ^{3 /2} − 1
		=	1				1		1									(9.17)
							8 F₁² ( 2 + F₁² )
	^E1

Hence, for a supercritical Froude number F₁ equal to 20, the energy loss ∆E is equal to 0.86 E₁. This means that 86 per cent of the initial specific energy is dissipated. Because of this energy dissipating capability, hydraulic jump is widely used as an energy dissipator for spillways and other hydraulic structures. In a hydraulic jump, the mean kinetic energy is first converted into turbulence and then dissipated through the action of viscosity. Equation (9.17) can be rewritten as

E		(8 F	² + 1) ³	^/2 − 4 F	2	+ 1
2	=	1		1			...(9.18)
E₁		8 F₁² ( 2 + F₁² )
E₁

The term E₂/E₁ is called the efficiency of the jump.

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