Turbomachinery - Knowledge (XXG)

138: 563: 508: 575:- When the path of the throughflow is wholly or mainly in a plane perpendicular to the rotation axis, the device is termed a radial flow turbomachine. Therefore, the change of radius between the entry and the exit is finite. A radial turbomachine can be inward or outward flow type depending on the purpose that needs to be served. The outward flow type increases the energy level of the fluid and vice versa. Due to continuous change in direction, several radial stages are generally not used. 903: 648: 613: 748: 867:- Gas turbines in marine applications are becoming more popular due to their smaller size, increased efficiency, and ability to burn cleaner fuels. They run just like gas turbines for power generation, but are also much smaller and do require more machinery for propulsion. They are most popular in naval ships as they can be at a dead stop to full power in minutes (Kayadelen, 2013), and are much smaller for a given amount of power. 122: 687: 25: 861:- Steam turbines in marine applications are very similar to those in power generation. The few differences between them are size and power output. Steam turbines on ships are much smaller because they don't need to power a whole town. They aren't very common because of their high initial cost, high specific fuel consumption, and expensive machinery that goes with it. 256: 520:- When the path of the through-flow is wholly or mainly parallel to the axis of rotation, the device is termed an axial flow turbomachine. The radial component of the fluid velocity is negligible. Since there is no change in the direction of the fluid, several axial stages can be used to increase power output. 944:

are another very popular turbomachine. Although there are very many different types of pumps, they all do the same thing. Pumps are used to move fluids around using some sort of mechanical power, from electric motors to full size diesel engines. Pumps have thousands of uses, and are the true basis to

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Any device that extracts energy from or imparts energy to a continuously moving stream of fluid can be called a turbomachine. Elaborating, a turbomachine is a power or heat generating machine which employs the dynamic action of a rotating element, the rotor; the action of the rotor changes the energy

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are one of the most popular turbomachines. They are used mainly for adding power to engines by adding more air. It combines both forms of turbomachines. Exhaust gases from the engine spin a bladed wheel, much like a turbine. That wheel then spins another bladed wheel, sucking and compressing outside

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acquired de Laval's designs in 1897. Since then, development has skyrocketed from Parsons’ early design, producing 0.746 kW, to modern nuclear steam turbines producing upwards of 1500 MW. Furthermore, steam turbines accounted for roughly 45% of electrical power generated in the United States in

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that extracts energy from an energetic fluid flow. The source of this energetic fluid flow could be one or a combination of many things, including the decomposition of hydrogen peroxide, the combustion of a portion of the propellants, or even the heating of cryogenic propellants run through coolant

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shaped rotor and stator blades. The velocity of the fluid through the sets of blades increases slightly (as with a nozzle) as it passes from rotor to stator and vice versa. The velocity of the fluid then decreases again once it has passed between the gap. Pressure and enthalpy consistently decrease

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Many types of dynamic continuous flow turbomachinery exist. Below is a partial list of these types. What is notable about these turbomachines is that the same fundamentals apply to all. Certainly there are significant differences between these machines and between the types of analysis that are

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used in power generation come in many different variations. The overall principle is high pressure steam is forced over blades attached to a shaft, which turns a generator. As the steam travels through the turbine, it passes through smaller blades causing the shaft to spin faster, creating more

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In contrast to positive displacement machines (particularly of the reciprocating type which are low speed machines based on the mechanical and volumetric efficiency considerations), the majority of turbomachines run at comparatively higher speeds without any mechanical problems and volumetric

286:, they are called axial flow machines, and when flow is perpendicular to the axis of rotation, they are referred to as radial (or centrifugal) flow machines. There is also a third category, called mixed flow machines, where both radial and axial flow velocity components are present. 877:

drive is like an aircraft turbojet with the difference that the operating fluid is water instead of air. Water jets are best suited to fast vessels and are thus used often by the military. Water jet propulsion has many advantages over other forms of marine propulsion, such as

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work much like steam turbines. Air is forced in through a series of blades that turn a shaft. Then fuel is mixed with the air and causes a combustion reaction, increasing the power. This then causes the shaft to spin faster, creating more electricity.

846:, windmills are increasing in popularity for their ability to efficiently use the wind to generate electricity. Although they come in many shapes and sizes, the most common one is the large three-blade. The blades work on the same principle as an 669:

describes the transfer of energy for reaction turbines. A pressure casement is needed to contain the working fluid. For compressible working fluids, multiple turbine stages are usually used to harness the expanding gas efficiently.

850:. As wind passes over the blades, it creates an area of low and high pressure, causing the blade to move, spinning a shaft and creating electricity. It is most like a steam turbine, but works with an infinite supply of wind. 928:

are used for engine-power enhancement as well, but only work off the principle of compression. They use the mechanical power from the engine to spin a screw or vane, some way to suck in and compress the air into the engine.

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by expanding flow to lower pressures. Of particular interest are applications which contain pumps, fans, compressors and turbines. These components are essential in almost all mechanical equipment systems, such as power and

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Soares, C. M. (n.d.). GAS TURBINES IN SIMPLE CYCLE & COMBINED CYCLE APPLICATIONS. 1-72. Retrieved April 10, 2017, from https://www.netl.doe.gov/File%20Library/Research/Coal/energy%20systems/turbines/handbook/1-1.pdf

227:, appeared intermittently but the temperatures and pressures required for a practically efficient turbine exceeded the manufacturing technology of the time. The first patent for gas turbines were filed in 1791 by 1289:"Combining Support Vector Machines and Segmentation Algorithms for Efficient Anomaly Detection: A Petroleum Industry Application". International Joint Conference SOCO’14-CISIS’14-ICEUTE’14. 2014. pp.269-278. 996:

typically applied to specific cases. This does not negate the fact that they are unified by the same underlying physics of fluid dynamics, gas dynamics, aerodynamics, hydrodynamics, and thermodynamics.

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describes the transfer of energy. Impulse turbomachines do not require a pressure casement around the rotor since the fluid jet is created by the nozzle prior to reaching the blading on the rotor.

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are another very popular turbomachine. They work on the principle of compression by sucking in and compressing air into a holding tank. Air compressors are one of the most basic turbomachines.

590:– When axial and radial flow are both present and neither is negligible, the device is termed a mixed flow turbomachine. It combines flow and force components of both radial and axial types. 1144: 761:

The following dimensionless ratios are often used for the characterisation of fluid machines. They allow a comparison of flow machines with different dimensions and boundary conditions.

982:- Rocket engines require very high propellant pressures and mass flow rates, meaning their pumps require a lot of power. One of the most common solutions to this issue is to use a 1425:

Nagpurwala, Q. (n.d.). Steam Turbines. Retrieved April 10, 2017, from http://164.100.133.129:81/eCONTENT/Uploads/13-Steam%20Turbines%20%5BCompatibility%20Mode%5D.pdf

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The first impulse type turbine was created by Carl Gustaf de Laval in 1883. This was closely followed by the first practical reaction type turbine in 1884, built by

211:, which appeared between the 3rd and 1st centuries BCE in the Mediterranean region. These were used throughout the medieval period and began the first 631:

of the fluid decreases as the velocity increases. Pressure and enthalpy drop over the rotor blades is minimal. Velocity will decrease over the rotor.

176:. While a turbine transfers energy from a fluid to a rotor, a compressor transfers energy from a rotor to a fluid. It is an important application of 1434:Škorpík, J. (2017, January 1). Lopatkový stroj-English version. Retrieved April 9, 2017, from http://www.transformacni-technologie.cz/en_11.html 1431:

Perlman, U. H. (2016, December 2). Hydroelectric power: How it works. Retrieved April 10, 2017, from https://water.usgs.gov/edu/hyhowworks.html

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are also turbomachines that transfer energy from a rotor to a fluid, usually a liquid, while turbines and compressors usually work with a gas.

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act on an infinite extent of fluid, whereas closed machines operate on a finite quantity of fluid as it passes through a housing or casing.

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started to be used, as the first power source driven by the combustion of a fuel rather than renewable natural power sources, this was as

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level of the continuously flowing fluid through the machine. Turbines, compressors and fans are all members of this family of machines.

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Most turbomachines use a combination of impulse and reaction in their design, often with impulse and reaction parts on the same blade.

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turbomachinery uses potential energy stored in water to flow over an open impeller to turn a generator which creates electricity

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2021. Then the first functioning industrial gas turbines were used in the late 1890s to power street lights (Meher-Homji, 2000).

231:. Practical hydroelectric water turbines and steam turbines did not appear until the 1880s. Gas turbines appeared in the 1930s. 1480: 708: 412: 42: 712: 89: 46: 267:

In general, the two kinds of turbomachines encountered in practice are open and closed turbomachines. Open machines such as

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Vandad Talimi (Original author unknown). "Mechanical Equipment and Systems". 2013. Memorial University of Newfoundland.

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Baskharone, E. A. "Principles of Turbomachinery in Air-Breathing Engines". 2006. Cambridge University Press. 580 pages.

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Turbomachines may be further classified into two additional categories: those that absorb energy to increase the

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Turbomachines can be categorized on the basis of the nature of the flow path through the passage of the rotor:

235: 137: 627:(the stator blade) onto the rotor blade. The nozzle serves to change the incoming pressure into velocity, the 507: 1475: 1201: 57: 1217:. McGraw-Hill series in mechanical engineering. Boston, Mass.: McGraw-Hill Higher Education. p. 735. 1011: 634: 228: 149: 1438: 1061: 586: 212: 666: 902: 1305:

Wills, J. George. "Lubrication fundamentals". 1980. Mobil oil corporation. Marcel Dekker. 460 pages.

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Turbomachines are also categorized according to the type of flow. When the flow is parallel to the

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Produce power by expanding fluid to a lower pressure or head (hydraulic, steam and gas turbines).

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Dixon, S. L. "Fluid mechanics and thermodynamics of turbomachinery". 1998. Elsevier. 460 pages.

976:- Aerospace gas turbines, more commonly known as jet engines, are the most common gas turbines. 647: 612: 1329: 1306: 1290: 1274: 1218: 1414: 1406: 1021: 1001: 811: 579: 389: 379: 298: 283: 243: 196: 161: 82: 747: 1046: 1036: 1016: 962: 594: 368: 338: 177: 492:

Absorb power to increase the fluid pressure or head (ducted fans, compressors and pumps).

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Rajadurai, J. S. "Thermodynamics and thermal engineering". 2003. New Age International.

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operate by accelerating and changing the flow direction of fluid through a stationary

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Turbomachines can be categorized on the basis of the direction of energy conversion:

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These two types of machines are governed by the same basic relationships including

1405:. Turbomachinery Laboratory Turbomachinery and Pump Symposia. pp. 281–322. 1139: 1041: 832: 686: 437: 216: 208: 24: 1106: 1051: 879: 516: 452: 224: 1239:"How electricity is generated - U.S. Energy Information Administration (EIA)" 1460: 1455: 1101: 1096: 1086: 1006: 983: 887: 383: 354: 268: 255: 1418: 1202:

http://www.engr.mun.ca/~yuri/Courses/MechanicalSystems/Turbomachinery.pdf

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Turbomachines can finally be classified on the relative magnitude of the

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Ctrend website to calculate the head of centrifugal compressor online

624: 398: 344: 260: 157: 1410: 901: 746: 646: 611: 561: 506: 254: 223:. Primitive turbines and conceptual designs for them, such as the 165: 136: 120: 238:. Parsons’ first design was a multi-stage axial-flow unit, which 1397:

S. M. Yahya. "Turbines Compressors and Fans". 1987. McGraw Hill.

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Logan, Earl. "Handbook of turbomachinery". 1995. Marcel Deckker.

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Three-dimensional losses and correlation in turbomachinery

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Classification of fluid machinery in species and groups

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Air and exhaust flow through engine and turbocharger

49:. Unsourced material may be challenged and removed. 1443:7th International Advanced Technologies Symposium 658:operate by reacting to the flow of fluid through 141:Aircraft engine, in this case a Boeing 777 engine 242:acquired and began manufacturing in 1895, while 677:Dimensionless ratios to describe turbomachinery 207:The first turbomachines could be identified as 1215:Fluid mechanics: fundamentals and applications 582:is an example of a radial flow turbomachine. 8: 965:are the most general type of turbomachines. 775:(including delivery or volume number called) 558:= Tangential or Whirl component of velocity. 1213:Çengel, Yunus A.; Cimbala, John M. (2006). 987:jackets in the combustion chamber's walls. 715:. Unsourced material may be challenged and 1403:The Historical Evolution Of Turbomachinery 16:Machine for exchanging energy with a fluid 1196: 1194: 1192: 1190: 1188: 1186: 735:Learn how and when to remove this message 475:efficiency close to one hundred percent. 109:Learn how and when to remove this message 1324: 1322: 1320: 1318: 1176: 1174: 1172: 1170: 1168: 1166: 1164: 1162: 1160: 609:changes that take place across a stage: 527:is an example of an axial flow turbine. 316: 305:, and those that produce energy such as 1260: 1258: 1156: 597:is an example of a mixed-flow turbine. 756:Walchensee Hydroelectric Power Station 566:Radial Turbomachine's Velocity Diagram 511:Axial Turbomachine's Velocity Diagram 7: 1346:"Waterjet drives propulsion systems" 713:adding citations to reliable sources 47:adding citations to reliable sources 991:Partial list of turbomachine topics 14: 189:Euler's pump and turbine equation 1135:Secondary flow in turbomachinery 945:turbomachinery (Škorpík, 2017). 685: 441:(inlet consists of a compressor) 23: 413:pumped-storage hydroelectricity 34:needs additional citations for 1401:Meher-Homji, Cyrus B. (2000). 1: 1027:Centrifugal type supercharger 185:Newton's second Law of Motion 663:through the sets of blades. 1445:. Retrieved April 15, 2017. 1502: 572:Radial flow turbomachines 405:Voith turbo-transmissions 651:A Reaction Turbine Stage 616:An Impulse Turbine Stage 587:Mixed flow turbomachines 517:Axial flow turbomachines 402:(hydrodynamic gearbox); 1481:Mechanical engineering 1456:Hydrodynamics of Pumps 1437:Kayadelen, H. (2013). 1012:Centrifugal compressor 907: 758: 656:Reaction Turbomachines 652: 644:is an impulse design. 617: 567: 544:V = Absolute velocity, 512: 264: 150:mechanical engineering 142: 134: 1062:Mixed flow compressor 918:air into the engine. 905: 754:being installed into 750: 650: 621:Impulse Turbomachines 615: 565: 510: 429:(compressible fluid) 259:A steam turbine from 258: 221:reciprocating engines 213:Industrial Revolution 140: 124: 778:Performance numbers 709:improve this section 551:= Relative velocity, 312:refrigeration cycles 263:subsidiary MAN Turbo 43:improve this article 1439:Marine Gas Turbines 1370:"WaterJet Overview" 635:Newton's second law 534:U = Blade velocity, 319: 240:George Westinghouse 193:compressible fluids 1350:www.castoldijet.it 1032:Exoskeletal engine 908: 888:shafted propellers 842:- Also known as a 759: 667:Newton's third law 653: 618: 568: 513: 351:open turbomachine 317: 265: 143: 135: 1295:978-3-319-07995-0 1224:978-0-07-247236-3 771:Flow coefficient 745: 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