Chézy Formula

The Chézy formula is an semi-empirical resistance equation which estimates mean flow velocity in open channel conduits. The relationship was realized and developed in 1768 by French physicist and engineer Antoine de Chézy (1718–1798) while designing Paris's water canal system. Chézy discovered a similarity parameter that could be used for estimating flow characteristics in one channel based on the measurements of another. The Chézy formula relates the flow of water through an open channel with the channel's dimensions and slope. The Chézy equation is a pioneering formula in the field of fluid mechanics and was expanded and modified by Irish Engineer Robert Manning in 1889.Manning, R., "On the flow of Water in Open Channels and Pipes." ''Transactions Institute of Civil Engineers of Ireland, vol. 20, pp. 161–209, Dublin, 1891, Supplement, vol 24, pp. 179–207, 1895'' Manning's modifications to the Chézy formula allowed the entire similarity parameter to be calculated by channel characteristics rather than by experimental measurements. Today, the Chézy and Manning equations continue to accurately estimate open channel fluid flow and are standard formulas in all fields that relate to fluid mechanics and hydraulics, including physics, mechanical engineering and civil engineering.

The Chézy formula

The Chézy formula describes mean flow velocity in turbulent open channel flow and is used broadly in fields related to fluid mechanics and fluid dynamics. Open channels refer to any open conduit, such as rivers, ditches, canals, or partially full pipes. The Chézy formula is defined for uniform equilibrium and non-uniform gradually varied flows.

The formula is written as:
:$V= C\sqrt$
where,
*$V$ is average velocity ength/time
*$R_h$ is the hydraulic radius ength which is the cross-sectional area of flow divided by the wetted perimeter (for a wide channel this is approximately equal to the water depth); and
*$S_0$ is the hydraulic gradient, which for uniform normal depth of flow is the slope of the channel bottom nitless; length/length and
*$C$ is Chézy's coefficient ength^1/2/time The value of this coefficient must be determined by experiments. The Chézy coefficient ranges typically from 30 m^1/2/s (small rough channel) up to 90 m^1/2/s (large smooth channel).

The formula is named after Antoine de Chézy, the French hydraulics engineer who devised it in 1775.

For many years following Antoine de Chézy's development of this formula, researchers assumed that $C$ was a constant independent of flow conditions. However, additional research proved the coefficient's dependence upon both the Reynolds number as well as channel roughness. Accordingly, although the Chézy formula does not appear to incorporate either of these terms, the Chézy coefficient empirically and indirectly represents them.

Hydraulic radius, ''R_h'', is 1/4 the hydraulic diameter and is defined as the area of the flow section divided by the wetted perimeter, ''P.''

$R_h =A/P$  

Exploring Chézy's similarity parameter

The relationship between linear momentum and deformable fluid bodies is well explored elsewhere in Wikipedia, as are Navier–Stokes equations for incompressible flow. However, exploring the relationships foundational to the Chézy formula can be helpful towards understanding the formula in full.

Please note that this is not a full derivation of the Chézy formula. To remain introductory, advanced derivation components are skipped. Please consult a fluid mechanics or open-channel flow textbook for a full derivation of the Chézy equation.

To understand the Chézy similarity parameter, we may consider a simple linear momentum equation to summarize the conservation of momentum of a control volume uniformly flowing through an open channel:

: $\sum F_= \int\limits_ V\rho \, + \int\limits_ V\rho V \cdot \hat \,$

Where the sum of forces on the contents of a control volume in the open channel are equal to the sum of the time rate of change of the linear momentum of the contents of the control volume, plus the net rate of flow of linear momentum through the control surface. The momentum principle may always used for hydrodynamic force calculations.

When we apply the linear momentum equation to a river channel flowing in one dimension, so long as we assume uniform flow, momentum remains conserved and forces are balanced in the direction of flow:

: $\sum F_=0 =F_1 - F_2 - \tau_wPl +W\sin\theta$

where the hydrostatic pressure forces ''F''₁ and ''F''₂, the component (''τ''_''w''Pl) representing the shear force of friction acting on the control volume, and the component (''ω'' sin ''θ'') representing the gravitational force of the fluid's weight acting on the sloped channel bottom are held in balance in the flow direction. The below free-body diagram may help illustrate this equilibrium of forces in open channel flow with uniform flow conditions.

Most open-channel flows are turbulent and characterized with very large Reynolds numbers. Due to the large Reynolds numbers characteristic in open channel flow, the channel shear stress proves to be proportional to the density and velocity of the flow. This can be illustrated in a series of advanced formulas which identify a shear stress similarity parameter characteristic of all turbulent open channels. Combining this parameter with channel components and the conservation of momentum in an open channel flow, we result with the Chézy formula explaining this relationship: $V= C\sqrt$ .

In summary, Chézy's similarity parameter and formula explain how the velocity of water flowing through a channel has a relationship with the slope and sheer stress of the channel bottom, the hydraulic radius of flow, and the Chézy coefficient which empirically incorporates several other parameters of the flowing water. This relationship is driven by the conservation of momentum present during uniform flow conditions.

Chézy's formula inspires the Manning formula

Once this relationship was established by Chézy, many engineers and physicists (see the below section ''Authors of flow formulas'') continued to search for ways to improve Chézy's equation. A slight oversight of Chézy's formula was determined by the research of these colleagues. They determined that the velocity's slope dependence in Chézy's formula (V:S₀) was reasonable, but that the velocity's dependence on the hydraulic radius (V:R_h^1/2) was not, and that the relationship was closer to (V:R_h^2/3). Many compelling formulas based on Chézy's formula have been developed since its discovery by these contemporaries and others, where differing formulas are more suitable in differing conditions.

Most notably, the Chézy formula provided a substantial foundation for a new flow formula proposed in 1889 by Irish engineer Robert Manning. Manning's formula is a modified Chézy formula that combined many of his aforementioned contemporaries' work. Manning's modifications to the Chézy formula allowed the entire similarity parameter to be calculated by channel characteristics rather than by experimental measurements. The Manning equation improved Chézy's equation by better representing the relationship between R_h and velocity, while also replacing the empirical Chézy coefficient ($C$) with the Manning resistance coefficient ($n$), also referenced in places as the Manning roughness coefficient. Unlike the Chézy coefficient ($C$) which could only be determined by field measurements, the Manning coefficient ($n$) was determined to remain constant based on the material of the wetted perimeter, allowing for a standardized table of values to be developed that could reasonably estimate flow velocity. While field measurements remain the most precise way to obtain either Chézy or Manning coefficients, the standardized values that were developed with the use of the Manning formula provided a much-desired simplicity to open-channel flow estimates.

Chézy formula vs Manning formula

The Manning formula is described excellently elsewhere, but is included below for comparison purposes. Below, the minor modifications used by the Manning formula to improve upon the Chézy formula are clear.

: $V= C\sqrt$ $V = \frac \,$

Chézy formula Manning formula

Using Chézy formula with Manning coefficient

This similarity between the Chézy and Manning formulas shown above also means that the standardized Manning coefficients may be used to estimate open channel flow velocity with the Chézy formula, by using them to calculate the Chézy's coefficient as shown below. Manning derived the following relationship between Manning coefficient ($n$) to Chézy coefficient ($C$) based upon experiments:

: C = k\left fracR_h^\right/math>

where

* $C$ is the Chézy coefficient ength^1/2/time a function of relative roughness and Reynolds number;
* $R$ is the hydraulic radius, which is the cross-sectional area of flow divided by the wetted perimeter (for a wide channel this approximately equal to the water depth)
* $n$ is Manning's coefficient ime/length^1/3 and
* $k$ is a constant; k = 1 when using SI units and k = 1.49 when using BG units.

Modern use of Chézy and Manning formulas

Both formulas are widely taught and used in modern times. As both equations reference a single control volume location along the channel, neither address friction factor or head loss directly, but change in pressure head may be calculated by combining them with other formulas such as the Darcy–Weisbach equation. The empirical aspect to the $C$ coefficient indirectly addresses friction factor and Reynold's number, and is the reason why the Chézy formula remains most accurate in certain conditions, such as river channels with non-uniform channel dimensions. Additionally, both equations are explicitly used with uniform or "steady-state" flow where the hydraulic depth is constant, due to their derivation from the conservation of momentum. In contrast, if the hydraulic conditions fluctuate in open channel flow, they are then described as gradually or rapidly varied flow, and will require further analyses beyond these two formula methods.

As partially full pipes are by definition open channels, so long as they aren't pressurized, the Manning and Chézy formulas may also be used to calculate partially full pipe flow, but remember that these formulas are intended for uniform and turbulent flow. Many other formulas that have been developed since these two may produce more accurate pipe flow results, such as the Darcy–Weisbach equation or the Hazen–Williams equation, but lack the simplicity of the Manning or Chézy formulas.

Both formulas continue to be broadly taught and used as foundational to open channel and fluid dynamics research. Today, the Manning formula is likely the most globally used formula for open channel uniform flow analysis, due greatly to its simplicity, proven efficacy, and the fact that most open channel studies are concerned with turbulent flow. However, the Chézy's formula is one of the oldest in the field of fluid mechanics, it applies to a wider range of flows than the Manning equation, and its influence continues to this day.

Authors of flow formulas

* Albert Brahms (1692–1758)
* Antoine de Chézy (1718–1798)
* Claude-Louis Navier (1785–1836)
* Adhémar Jean Claude Barré de Saint-Venant (1797–1886)
* Gotthilf Heinrich Ludwig Hagen (1797–1884)
* Jean Léonard Marie Poiseuille (1797–1869)
* Henri P. G. Darcy (1803–1858)
* Julius Ludwig Weisbach (1806–1871)
* Charles Storrow (1809–1904)
* Robert Manning (1816–1897)
* Wilhelm Rudolf Kutter (1818–1888)
* Emile Oscar Ganguillet (1818–1894)
* Sir George Stokes (1819–1903)
* Philippe Gaspard Gauckler (1826–1905)
* Henri-Émile Bazin (1829–1917)
* Alphonse Fteley (1837–1903)
* Frederic Stearns (1851–1919)
* Ludwig Prandtl (1875–1953)
* Paul Richard Heinrich Blasius (1883–1970)
* Albert Strickler (1887–1963)
* Cyril Frank Colebrook (1910–1997)

See also

* Hydrology
* Hydraulic engineering

References

External links

History of the Chézy Formula

{{DEFAULTSORT:Chezy Formula
Fluid dynamics
Piping
Scientific laws