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[[File:Joukowsky-Pressure-Shock-01.jpg|thumbnail|300px|Effect of a pressure surge on a float gauge]]
[[File:Joukowsky-Pressure-Shock-01.jpg|thumbnail|300px|Effect of a pressure surge on a float gauge]]


'''Hydraulic shock''' ([[colloquial]]: '''water hammer'''; '''fluid hammer''') is a [[pressure]] surge or wave caused when a [[fluid]] in motion, usually a liquid but sometimes also a gas, is forced to stop or change direction suddenly; a [[momentum]] change. This phenomenon commonly occurs when a valve closes suddenly at an end of a [[pipeline transport|pipeline]] system, and a pressure wave propagates in the pipe.
'''Hydraulic shock''' ([[colloquial]]: '''water hammer'''; '''fluid hammer''') is a [[pressure]] surge or wave caused when a [[fluid]] in motion, usually a liquid but sometimes also a gas is forced to stop or change direction suddenly; a [[momentum]] change. This phenomenon commonly occurs when a valve closes suddenly at an end of a [[pipeline transport|pipeline]] system, and a pressure wave propagates in the pipe.


This pressure wave can cause major problems, from noise and vibration to pipe rupture or collapse. It is possible to reduce the effects of the water hammer pulses with [[Hydraulic accumulator|accumulators]], [[expansion tank]]s, [[surge tank]]s, [[blowoff valve]]s, and other features. The effects can be avoided by ensuring that no valves will close too quickly with significant flow, but there are many situations that can cause the effect.
This pressure wave can cause major problems, from noise and vibration to pipe rupture or collapse. It is possible to reduce the effects of the water hammer pulses with [[Hydraulic accumulator|accumulators]], [[expansion tank]]s, [[surge tank]]s, [[blowoff valve]]s, and other features. The effects can be avoided by ensuring that no valves will close too quickly with significant flow, but there are many situations that can cause the effect.

Revision as of 20:29, 5 December 2021

Effect of a pressure surge on a float gauge

Hydraulic shock (colloquial: water hammer; fluid hammer) is a pressure surge or wave caused when a fluid in motion, usually a liquid but sometimes also a gas is forced to stop or change direction suddenly; a momentum change. This phenomenon commonly occurs when a valve closes suddenly at an end of a pipeline system, and a pressure wave propagates in the pipe.

This pressure wave can cause major problems, from noise and vibration to pipe rupture or collapse. It is possible to reduce the effects of the water hammer pulses with accumulators, expansion tanks, surge tanks, blowoff valves, and other features. The effects can be avoided by ensuring that no valves will close too quickly with significant flow, but there are many situations that can cause the effect.

Rough calculations can be made using the Zhukovsky (Joukowsky) equation,[1] or more accurate ones using the method of characteristics.[2]

History

In the 1st century B.C., Marcus Vitruvius Pollio described the effect of water hammer in lead pipes and stone tubes of the Roman public water supply.[3][4] Water hammer was exploited before there was even a word for it; in 1772, Englishman John Whitehurst built a hydraulic ram for a home in Cheshire, England.[5] In 1796, French inventor Joseph Michel Montgolfier (1740–1810) built a hydraulic ram for his paper mill in Voiron.[6] In French and Italian, the terms for "water hammer" come from the hydraulic ram: coup de bélier (French) and colpo d'ariete (Italian) both mean "blow of the ram".[7] As the 19th century witnessed the installation of municipal water supplies, water hammer became a concern to civil engineers.[8][9][10] Water hammer also interested physiologists who were studying the circulatory system.[11]

Although it was prefigured in work by Thomas Young,[12][11] the theory of water hammer is generally considered to have begun in 1883 with the work of German physiologist Johannes von Kries (1853–1928), who was investigating the pulse in blood vessels.[13][14] However, his findings went unnoticed by civil engineers.[15][16] Kries's findings were subsequently derived independently in 1898 by the Russian fluid dynamicist Nikolay Yegorovich Zhukovsky (1847–1921),[1][17] in 1898 by the American civil engineer Joseph Palmer Frizell (1832–1910),[18][19] and in 1902 by the Italian engineer Lorenzo Allievi (1856–1941).[20]

Cause and effect

When a pipe with water flowing through it is suddenly closed at the outlet (downstream), the mass of water before the closure is still moving, thereby building up pressure and a resulting shock wave. In domestic plumbing this shock wave is experienced as a loud banging resembling a hammering noise. Water hammer can cause pipelines to break if the pressure is high enough. Air traps or stand pipes (open at the top) are sometimes added as dampers to water systems to absorb the potentially damaging forces caused by the moving water.

In hydroelectric generating stations, the water traveling along the tunnel or pipeline may be prevented from entering a turbine by closing a valve. For example, if there is 14 km (8.7 mi) of tunnel of 7.7 m (25 ft) diameter full of water travelling at 3.75 m/s (8.4 mph),[21] that represents approximately 8,000 megajoules (2,200 kWh) of kinetic energy that must be arrested. This arresting is frequently achieved by a surge shaft[22] open at the top, into which the water flows. As the water rises up the shaft its kinetic energy is converted into potential energy, which causes the water in the tunnel to decelerate. At some hydroelectric power (HEP) stations, such as the Saxon Falls Hydro Power Plant In Michigan, what looks like a water tower is actually one of these devices, known in these cases as a surge drum.[23]

At home, a water hammer may occur when a dishwasher, washing machine or toilet shuts off water flow. The result may be heard as a loud bang, repetitive banging (as the shock wave travels back and forth in the plumbing system), or as some shuddering.

On the other hand, when an upstream valve in a pipe closes, water downstream of the valve attempts to continue flowing creating a vacuum that may cause the pipe to collapse or implode. This problem can be particularly acute if the pipe is on a downhill slope. To prevent this, air and vacuum relief valves or air vents are installed just downstream of the valve to allow air to enter the line to prevent this vacuum from occurring.

Other causes of water hammer are pump failure and check valve slam (due to sudden deceleration, a check valve may slam shut rapidly, depending on the dynamic characteristic of the check valve and the mass of the water between a check valve and tank). To alleviate this situation, it is recommended to install non-slam check valves as they do not rely on gravity or fluid flow for their closure. For vertical pipes, other suggestions include installing new piping that can be designed to include air chambers to alleviate the possible shockwave of water due to excess water flow.[24]

Water hammer can also occur when filling an empty pipe that has a restriction such as a partially open valve or an orifice that allows air to pass easily as the pipe rapidly fills, but once full the water suddenly encounters the restriction and the pressure spikes.

Expansion joints on a steam line that have been destroyed by steam hammer

Steam distribution systems may also be vulnerable to a situation similar to water hammer, known as steam hammer. In a steam system, this phenomenon most often occurs when some of the steam condenses into water in a horizontal section of the piping. The rest of the steam forces this liquid water along the pipe, forming a "slug", and hurls this at high velocity into a pipe fitting, creating a loud hammering noise and greatly stressing the pipe. This condition is usually caused by a poor condensate drainage strategy: having more condensate in the pipe makes the slug easier to form. Vacuum caused by condensation from thermal shock can also cause a steam hammer.

Steam hammer can be avoided by using sloped pipes and installing steam traps. Where air-filled traps are used, these eventually become depleted of their trapped air over a long period through absorption into the water. This can be cured by shutting off the supply, opening taps at the highest and lowest locations to drain the system (thereby restoring air to the traps), and then closing the taps and re-opening the supply.

On turbocharged internal combustion engines, a "gas hammer" can take place when the throttle is closed while the turbocharger is forcing air into the engine. There is no shockwave but the pressure can still rapidly increase to damaging levels or cause compressor surge. A pressure relief valve placed before the throttle prevents the air from surging against the throttle body by diverting it elsewhere, thus protecting the turbocharger from pressure damage. This valve can either recirculate the air into the turbocharger's intake (recirculation valve), or it can blow the air into the atmosphere and produce the distinctive hiss-flutter of an aftermarket turbocharger (blowoff valve).

From a jet of water

If a stream of high velocity water impinges on a surface, water hammer can quickly erode and destroy it. In the 2009 Sayano-Shushenskaya power station accident, the lid to a 640 MW turbine was ejected upwards, hitting the ceiling above. During the accident, the rotor was seen flying through the air, still spinning, about 3 meters above the floor. Unrestrained, 256 cubic metres (67,600 US gal) per second of water began to spray all over the generator hall.[25] The geyser caused the structural failure of steel ceiling joists, precipitating a roof collapse around the failed turbine.

During an explosion

When an explosion happens in an enclosed space, water hammer can cause the walls of the container to deform. However, it can also impart momentum to the enclosure if it is free to move. An underwater explosion in the SL-1 nuclear reactor vessel caused the water to accelerate upwards through 2.5 feet (0.76 m) of air before it struck the vessel head at 160 feet per second (49 m/s) with a pressure of 10,000 pounds per square inch (69,000 kPa). This pressure wave caused the 26,000 pounds (12,000 kg) steel vessel to jump 9 feet and 1 inch (2.77 m) into the air before it dropped into its prior location.[26] It is imperative to perform ongoing preventive maintenance to avoid water hammer, as the aftermaths of these powerful explosions have resulted in fatalities.[27]

Mitigation measures

Water hammer has caused accidents and fatalities, but usually damage is limited to breakage of pipes or appendages. An engineer should always assess the risk of a pipeline burst. Pipelines transporting hazardous liquids or gases warrant special care in design, construction, and operation. Hydroelectric power plants especially must be carefully designed and maintained because the water hammer can cause water pipes to fail catastrophically.

The following characteristics may reduce or eliminate water hammer:

  • Reduce the pressure of the water supply to the building by fitting a regulator.
  • Lower fluid velocities. To keep water hammer low, pipe-sizing charts for some applications recommend flow velocity at or below 1.5 m/s (4.9 ft/s)
  • Fit slowly closing valves. Toilet fill valves are available in a quiet fill type that closes quietly.
  • Non-slam check valves do not rely on fluid flow to close and will do so before the water flow reaches significant velocity.
  • High pipeline pressure rating (does not reduce the effect but protects against damage).
  • Good pipeline control (start-up and shut-down procedures).
  • Water towers (used in many drinking water systems) or surge tanks help maintain steady flow rates and trap large pressure fluctuations.
  • Air vessels such as expansion tanks and some types of hydraulic accumulators work in much the same way as water towers, but are pressurized. They typically have an air cushion above the fluid level in the vessel, which may be regulated or separated by a bladder. Sizes of air vessels may be up to hundreds of cubic meters on large pipelines. They come in many shapes, sizes and configurations. Such vessels often are called accumulators or expansion tanks.
  • A hydropneumatic device similar in principle to a shock absorber called a 'Water Hammer Arrestor' can be installed between the water pipe and the machine, to absorb the shock and stop the banging.
  • Air valves often remediate low pressures at high points in the pipeline. Though effective, sometimes large numbers of air valves need be installed. These valves also allow air into the system, which is often unwanted. Blowoff valves may be used as an alternative.
  • Shorter branch pipe lengths.
  • Shorter lengths of straight pipe, i.e. add elbows, expansion loops. Water hammer is related to the speed of sound in the fluid, and elbows reduce the influences of pressure waves.
  • Arranging the larger piping in loops that supply shorter smaller run-out pipe branches. With looped piping, lower velocity flows from both sides of a loop can serve a branch.
  • Flywheel on a pump.
  • Pumping station bypass.

Magnitude of the pulse

Typical pressure wave caused by closing a valve in a pipeline

One of the first to successfully investigate the water hammer problem was the Italian engineer Lorenzo Allievi.

Water hammer can be analyzed by two different approaches—rigid column theory, which ignores compressibility of the fluid and elasticity of the walls of the pipe, or by a full analysis that includes elasticity. When the time it takes a valve to close is long compared to the propagation time for a pressure wave to travel the length of the pipe, then rigid column theory is appropriate; otherwise considering elasticity may be necessary.[28] Below are two approximations for the peak pressure, one that considers elasticity, but assumes the valve closes instantaneously, and a second that neglects elasticity but includes a finite time for the valve to close.

Instant valve closure; compressible fluid

The pressure profile of the water hammer pulse can be calculated from the Joukowsky equation[29]

So for a valve closing instantaneously, the maximal magnitude of the water hammer pulse is

where ΔP is the magnitude of the pressure wave (Pa), ρ is the density of the fluid (kg/m3), a0 is the speed of sound in the fluid (m/s), and Δv is the change in the fluid's velocity (m/s). The pulse comes about due to Newton's laws of motion and the continuity equation applied to the deceleration of a fluid element.[30]

Equation for wave speed

As the speed of sound in a fluid is , the peak pressure depends on the fluid compressibility if the valve is closed abruptly.

where

a = wave speed,
B = equivalent bulk modulus of elasticity of the system fluid–pipe,
ρ = density of the fluid,
K = bulk modulus of elasticity of the fluid,
E = elastic modulus of the pipe,
D = internal pipe diameter,
t = pipe wall thickness,
c = dimensionless parameter due to system pipe-constraint condition[clarify] on wave speed.[30][page needed]

Slow valve closure; incompressible fluid

When the valve is closed slowly compared to the transit time for a pressure wave to travel the length of the pipe, the elasticity can be neglected, and the phenomenon can be described in terms of inertance or rigid column theory:

Assuming constant deceleration of the water column (dv/dt = v/t), this gives

where:

F = force [N],
m = mass of the fluid column [kg],
a = acceleration [m/s2],
P = pressure [Pa],
A = pipe cross-section [m2],
ρ = fluid density [kg/m3],
L = pipe length [m],
v = flow velocity [m/s],
t = valve closure time [s].

The above formula becomes, for water and with imperial unit,

For practical application, a safety factor of about 5 is recommended:

where P1 is the inlet pressure in psi, V is the flow velocity in ft/s, t is the valve closing time in seconds, and L is the upstream pipe length in feet.[31]

Hence, we can say that the magnitude of the water hammer largely depends upon the time of closure, elastic components of pipe & fluid properties.[32]

Expression for the excess pressure due to water hammer

When a valve with a volumetric flow rate Q is closed, an excess pressure ΔP is created upstream of the valve, whose value is given by the Joukowsky equation:

In this expression:[33]

ΔP is the overpressurization in Pa;
Q is the volumetric flow in m3/s;
Z is the hydraulic impedance, expressed in kg/m4/s.

The hydraulic impedance Z of the pipeline determines the magnitude of the water hammer pulse. It is itself defined by

where

ρ the density of the liquid, expressed in kg/m3;
A cross sectional area of the pipe, m2;
B equivalent modulus of compressibility of the liquid in the pipe, expressed in Pa.

The latter follows from a series of hydraulic concepts:

  • compressibility of the liquid, defined by its adiabatic compressibility modulus Bl, resulting from the equation of state of the liquid generally available from thermodynamic tables;
  • the elasticity of the walls of the pipe, which defines an equivalent bulk modulus of compressibility for the solid Bs. In the case of a pipe of circular cross-section whose thickness t is small compared to the diameter D, the equivalent modulus of compressibility is given by the formula , in which E is the Young's modulus (in Pa) of the material of the pipe;
  • possibly compressibility Bg of gas dissolved in the liquid, defined by
    γ being the specific heat ratio of the gas,
    α the rate of ventilation (the volume fraction of undissolved gas),
    and P the pressure (in Pa).

Thus, the equivalent elasticity is the sum of the original elasticities:

As a result, we see that we can reduce the water hammer by:

  • increasing the pipe diameter at constant flow, which reduces the flow velocity and hence the deceleration of the liquid column;
  • employing the solid material as tight as possible with respect to the internal fluid bulk (solid Young modulus low with respect to fluid bulk modulus);
  • introducing a device that increases the flexibility of the entire hydraulic system, such as a hydraulic accumulator;
  • where possible, increasing the fraction of undissolved gases in the liquid.

Dynamic equations

The water hammer effect can be simulated by solving the following partial differential equations.

where V is the fluid velocity inside pipe, is the fluid density, B is the equivalent bulk modulus, and f is the Darcy–Weisbach friction factor.[34]

Column separation

Column separation is a phenomenon that can occur during a water-hammer event. If the pressure in a pipeline drops below the vapor pressure of the liquid, cavitation will occur (some of the liquid vaporizes, forming a bubble in the pipeline, keeping the pressure close to the vapor pressure). This is most likely to occur at specific locations such as closed ends, high points or knees (changes in pipe slope). When subcooled liquid flows into the space previously occupied by vapor the area of contact between the vapor and the liquid increases. This causes the vapor to condense into the liquid reducing the pressure in the vapor space. The liquid on either side of the vapor space is then accelerated into this space by the pressure difference. The collision of the two columns of liquid (or of one liquid column if at a closed end) causes a large and nearly instantaneous rise in pressure. This pressure rise can damage hydraulic machinery, individual pipes and supporting structures. Many repetitions of cavity formation and collapse may occur in a single water-hammer event.[35]

Simulation software

Most water hammer software packages use the method of characteristics[30] to solve the differential equations involved. This method works well if the wave speed does not vary in time due to either air or gas entrainment in a pipeline. The wave method (WM) is also used in various software packages. WM lets operators analyze large networks efficiently. Many commercial and non-commercial packages are available.

Software packages vary in complexity, dependent on the processes modeled. The more sophisticated packages may have any of the following features:

  • Multiphase flow capabilities.
  • An algorithm for cavitation growth and collapse.
  • Unsteady friction: the pressure waves dampens as turbulence is generated and due to variations in the flow velocity distribution.
  • Varying bulk modulus for higher pressures (water becomes less compressible).
  • Fluid structure interaction: the pipeline reacts on the varying pressures and causes pressure waves itself.

Applications

  • The water hammer principle can be used to create a simple water pump called a hydraulic ram.
  • Leaks can sometimes be detected using water hammer.
  • Enclosed air pockets can be detected in pipelines.

See also

References

  1. ^ a b Joukowsky, Nikolay (1900), "Über den hydraulischen Stoss in Wasserleitungsröhren" [On hydraulic shock in water pipes], Mémoires de l'Académie Impériale des Sciences de St.-Pétersbourg, 8th series (in German), 9 (5): 1–71
  2. ^ Shu, Jian-Jun (2003), "Modelling vaporous cavitation on fluid transients", International Journal of Pressure Vessels and Piping, 80 (3): 187–195, arXiv:1409.8042, doi:10.1016/S0308-0161(03)00025-5, S2CID 28398872
  3. ^ Vitruvius Pollio with Morris Hicky Morgan, trans. The Ten Books on Architecture (Cambridge, Massachusetts: Harvard University Press, 1914) ; Book 8, Chapter 6, sections 5-8 , pp. 245-246. Archived 2012-07-11 at the Wayback Machine Vitruvius states that when a water pipe crosses a wide valley, it must sometimes be constructed as an inverted siphon. He states that cavities ("venters") must be constructed periodically along the pipe "and in the venter, water cushions must be constructed to relieve the pressure of the air." "But if there is no such venter made in the valleys, nor any substructure built on a level, but merely an elbow, the water will break out, and burst the joints of the pipes." Swiss engineer Martin Schwarz — Martin Schwarz, "Neue Forschungsergebnisse zu Vitruvs colliviaria" [New research results on Vitruvius' colliviaria], pp. 353-357, in: Christoph Ohlig, ed., Cura Aquarum in Jordanien (Siegburg, Germany: Deutschen Wasserhistorischen Gesellschaft, 2008) — argues that Vitruvius' phrase vis spiritus referred not to air pressure, but to pressure transients (water hammer) in the water pipes. He found stone plugs (colliviaria) in Roman water pipes, which could be expelled by water hammer, allowing water in the pipe to flood the air chamber above the pipe, instead of rupturing the pipe.
  4. ^ Ismaier, Andreas (2011), Untersuchung der fluiddynamischen Wechselwirkung zwischen Druckstößen und Anlagenkomponenten in Kreiselpumpensystemen [Investigation of the fluid dynamic interaction between pressure surges and system components in centrifugal pumping systems], Schriftenreihe des Lehrstuhls für Prozessmaschinen und Anlagentechnik, Universität Erlangen; Nürnberg Lehrstuhl für Prozessmaschinen und Anlagentechnik (in German), vol. 11, Shaker, ISBN 978-3-8322-9779-4
  5. ^ Whitehurst, John (1775), "Account of a machine for raising water, executed at Oulton, in Cheshire, in 1772", Philosophical Transactions of the Royal Society of London, 65: 277–279, doi:10.1098/rstl.1775.0026, archived from the original on 2017-03-28 See also plate preceding page 277.
  6. ^ Montgolfier, J. M. de (1803), "Note sur le bélier hydraulique, et sur la manière d'en calculer les effets" [Note on the hydraulic ram, and on the method of calculating its effects] (PDF), Journal des Mines (in French), 13 (73): 42–51, archived (PDF) from the original on 2013-10-18
  7. ^ Tijsseling, A. S.; Anderson, A. (2008), "Thomas Young's research on fluid transients: 200 years on" (PDF), Proceedings of the 10th International Conference on Pressure Surges, Edinburgh, UK: 21–33, archived (PDF) from the original on 2013-10-24 see page 22.
  8. ^ Ménabréa*, L. F. (1858), "Note sur les effects de choc de l'eau dans les conduites" [Note on the effects of water shocks in pipes], Comptes rendus (in French), 47: 221–224, archived from the original on 2017-03-28 *Luigi Federico Menabrea (1809–1896), Italian general, statesman and mathematician.
  9. ^ Michaud*, J. (1878), "Coups de bélier dans les conduites. Étude des moyens employés pour en atténeur les effects" [Water hammer in pipes. Study of means used to mitigate its effects], Bulletin de la Société Vaudoise des Ingénieurs et des Architectes (in French), 4 (3, 4): 56–64, 65–77 Available at: E.T.H. (Eidgenössische Technische Hochschule, Federal Institute of Technology) (Zürich, Switzerland). *Jules Michaud (1848–1920), Swiss engineer.
  10. ^ Castigliano, Alberto (1874). "Intorno alla resistenza dei tubi alle pressioni continue e ai colpi d'ariete" [Regarding the resistance of pipes to continuous pressures and water hammer]. Atti della Reale accademia della scienze di Torino [Proceedings of the Royal Academy of Sciences of Turin] (in Italian). 9: 222–252. *Carlo Alberto Castigliano (1847–1884), Italian mathematician and physicist.
  11. ^ a b Tijsseling, A. S.; Anderson, A. (2008). Hunt, S. (ed.). "Thomas Young's research on fluid transients: 200 years on". Proc. Of the 10th Int. Conf. On Pressure Surges. Edinburgh, United Kingdom: BHR Group: 21–33. ISBN 978-1-85598-095-2.
  12. ^ Young, Thomas (1808). "Hydraulic investigations, subservient to an intended Croonian lecture on the motion of the blood". Philosophical Transactions of the Royal Society of London. 98: 164–186.
  13. ^ von Kries, J. (1883), "Ueber die Beziehungen zwischen Druck und Geschwindigkeit, welche bei der Wellenbewegung in elastischen Schläuchen bestehen" [On the relationships between pressure and velocity, which exist in connection with wave motion in elastic tubing], Festschrift der 56. Versammlung Deutscher Naturforscher und Ärzte (Festschrift of the 56th Convention of German Scientists and Physicians) (in German), Tübingen, Germany: Akademische Verlagsbuchhandlung: 67–88, archived from the original on 2017-03-28
  14. ^ von Kries, J. (1892), Studien zur Pulslehre [Studies in Pulse Science] (in German), Tübingen, Germany: Akademische Verlagsbuchhandlung, archived from the original on 2017-03-28
  15. ^ Tijsseling, Arris S.; Anderson, Alexander (2004), "A precursor in waterhammer analysis – rediscovering Johannes von Kries" (PDF), Proceedings of the 9th International Conference on Pressure Surges, Chester, UK: 739–751, archived (PDF) from the original on 2016-03-04
  16. ^ Tijsseling, Arris S.; Anderson, Alexander (2007), "Johannes von Kries and the history of water hammer", Journal of Hydraulic Engineering, 133 (1): 1–8, doi:10.1061/(ASCE)0733-9429(2007)133:1(1)
  17. ^ Tijsseling, Arris S.; Anderson, Alexander (2006), The Joukowsky equation for fluids and solids (PDF), archived (PDF) from the original on 2012-09-12
  18. ^ Frizell, J. P. (1898), "Pressures resulting from changes of velocity of water in pipes", Transactions of the American Society of Civil Engineers, 39: 1–18, doi:10.1061/TACEAT.0001315, archived from the original on 2017-03-28
  19. ^ Hale, R. A. (September 1911), "Obituary: Joseph Palmer Frizell, M. Am. Soc. C. E.", Transactions of the American Society of Civil Engineers, 73: 501–503, archived from the original on 2017-03-29
  20. ^ See:
    • Allievi, L. (1902), "Teoria generale del moto perturbato dell'acqua nei tubi in pressione (colpo d'ariete)" [General theory of the perturbed motion of water in pipes under pressure (water hammer)], Annali della Società degli Ingegneri ed Architetti Italiani (Annals of the Society of Italian Engineers and Architects) (in Italian), 17 (5): 285–325
    • Reprinted: Allievi, L. (1903). "Teoria generale del moto perturbato dell'acqua nei tubi in pressione (colpo d'ariete)". Atti dell'Associazione elettrotecnica italiana [Proceedings of the Italian Electrotechnical Association] (in Italian). 7 (2–3): 140–196.
  21. ^ [1]
  22. ^ "Archived copy". Archived from the original on 2011-12-20. Retrieved 2012-07-16.{{cite web}}: CS1 maint: archived copy as title (link)
  23. ^ "Saxon Falls Hydro Generating Station | Xcel Energy". www.xcelenergy.com. Archived from the original on 2017-08-16. Retrieved 2017-08-16.
  24. ^ "How To Prevent Water Hammer | DFT Valves". DFT Valves. Archived from the original on 2017-08-16. Retrieved 2017-08-16.
  25. ^ "Archived copy". Archived from the original on 2011-12-13. Retrieved 2011-12-06.{{cite web}}: CS1 maint: archived copy as title (link)
  26. ^ Flight Propulsion Laboratory Department, General Electric Company, Idaho Falls, Idaho (November 21, 1962), Additional Analysis of the SL-1 Excursion: Final Report of Progress July through October 1962 (PDF), U.S. Atomic Energy Commission, Division of Technical Information, IDO-19313, archived (PDF) from the original on September 27, 2011{{citation}}: CS1 maint: multiple names: authors list (link); also TM-62-11-707
  27. ^ Wald, Matthew L. (1993-05-07). "U.S. Blames Con Ed Error For Fatal Plant Explosion". The New York Times. ISSN 0362-4331. Archived from the original on 2017-08-16. Retrieved 2017-08-16.
  28. ^ Bruce, S.; Larock, E.; Jeppson, R. W.; Watters, G. Z. (2000), Hydraulics of Pipeline Systems, CRC Press, ISBN 0-8493-1806-8
  29. ^ Thorley, A. R. D. (2004), Fluid Transients in Pipelines (2nd ed.), Professional Engineering Publishing, ISBN 0-79180210-8[page needed]
  30. ^ a b c Streeter, V. L.; Wylie, E. B. (1998), Fluid Mechanics (International 9th Revised ed.), McGraw-Hill Higher Education[page needed]
  31. ^ "Water Hammer & Pulsation". Archived 2008-07-01 at the Wayback Machine
  32. ^ "What is Water Hammer/Steam Hammer ?". www.forbesmarshall.com. Retrieved 2019-12-26.
  33. ^ Faisandier, J., Hydraulic and Pneumatic Mechanisms, 8th edition, Dunod, Paris, 1999, ISBN 2100499483.
  34. ^ Chaudhry, Hanif (1979). Applied Hydraulic Transients. New York: Van Nostrand Reinhold.
  35. ^ Bergeron, L., 1950. Du Coup de Bélier en Hydraulique - Au Coup de Foudre en Electricité. (Waterhammer in hydraulics and wave surges in electricity.) Paris: Dunod (in French). (English translation by ASME Committee, New York: John Wiley & Sons, 1961.)