词条 | Pressure vessel | ||||||||
释义 |
A pressure vessel is a container designed to hold gases or liquids at a pressure substantially different from the ambient pressure. Pressure vessels can be dangerous, and fatal accidents have occurred in the history of their development and operation. Consequently, pressure vessel design, manufacture, and operation are regulated by engineering authorities backed by legislation. For these reasons, the definition of a pressure vessel varies from country to country. Design involves parameters such as maximum safe operating pressure and temperature, safety factor, corrosion allowance and minimum design temperature (for brittle fracture). Construction is tested using nondestructive testing, such as ultrasonic testing, radiography, and pressure tests. Hydrostatic tests use water, but pneumatic tests use air or another gas. Hydrostatic testing is preferred, because it is a safer method, as much less energy is released if a fracture occurs during the test (water does not rapidly increase its volume when rapid depressurization occurs, unlike gases like air, which fail explosively). In most countries, vessels over a certain size and pressure must be built to a formal code. In the United States that code is the ASME Boiler and Pressure Vessel Code (BPVC). These vessels also require an authorized inspector to sign off on every new vessel constructed and each vessel has a nameplate with pertinent information about the vessel, such as maximum allowable working pressure, maximum temperature, minimum design metal temperature, what company manufactured it, the date, its registration number (through the National Board), and ASME's official stamp for pressure vessels (U-stamp). The nameplate makes the vessel traceable and officially an ASME Code vessel. History of pressure vesselsThe earliest documented design of pressure vessels was described in 1495 in the book by Leonardo da Vinci, the Codex Madrid I, in which containers of pressurized air were theorized to lift heavy weights underwater.[1] However, vessels resembling those used today did not come about until the 1800s, when steam was generated in boilers helping to spur the industrial revolution.[1] However, with poor material quality and manufacturing techniques along with improper knowledge of design, operation and maintenance there was a large number of damaging and often fatal explosions associated with these boilers and pressure vessels, with a death occurring on a nearly daily basis in the United States.[1] Local providences and states in the US began enacting rules for constructing these vessels after some particularly devastating vessel failures occurred killing dozens of people at a time, which made it difficult for manufacturers to keep up with the varied rules from one location to another and the first pressure vessel code was developed starting in 1911 and released in 1914, starting the ASME Boiler and Pressure Vessel Code (BPVC).[1] In an early effort to design a tank capable of withstanding pressures up to {{convert|10000|psi|MPa|abbr=on}}, a {{convert|6|in|adj=on}} diameter tank was developed in 1919 that was spirally-wound with two layers of high tensile strength steel wire to prevent sidewall rupture, and the end caps longitudinally reinforced with lengthwise high-tensile rods.[2] The need for high pressure and temperature vessels for petroleum refineries and chemical plants gave rise to vessels joined with welding instead of rivets (which were unsuitable for the pressures and temperatures required) and in the 1920s and 1930s the BPVC included welding as an acceptable means of construction, and welding is the main means of joining metal vessels today.[1] There have been many advancements in the field of pressure vessel engineering such as advanced non-destructive examination, phased array ultrasonic testing and radiography, new material grades with increased corrosion resistance and stronger materials, and new ways to join materials such as explosion welding (to attach one metal sheet to another, usually a thin corrosion resistant metal like stainless steel to a stronger metal like carbon steel), friction stir welding (which attaches the metals together without melting the metal), advanced theories and means of more accurately assessing the stresses encountered in vessels such as with the use of Finite Element Analysis, allowing the vessels to be built safer and more efficiently. Today vessels in the USA require BPVC stamping but the BPVC is not just a domestic code, many other countries have adopted the BPVC as their official code. There are, however, other official codes in some countries (some of which rely on portions of and reference the BPVC), Japan, Australia, Canada, Britain, and Europe have their own codes. Regardless of the country nearly all recognize the inherent potential hazards of pressure vessels and the need for standards and codes regulating their design and construction. Pressure vessel featuresShape of a pressure vesselPressure vessels can theoretically be almost any shape, but shapes made of sections of spheres, cylinders, and cones are usually employed. A common design is a cylinder with end caps called heads. Head shapes are frequently either hemispherical or dished (torispherical). More complicated shapes have historically been much harder to analyze for safe operation and are usually far more difficult to construct. Theoretically, a spherical pressure vessel has approximately twice the strength of a cylindrical pressure vessel with the same wall thickness,[3] and is the ideal shape to hold internal pressure.[1] However, a spherical shape is difficult to manufacture, and therefore more expensive, so most pressure vessels are cylindrical with 2:1 semi-elliptical heads or end caps on each end. Smaller pressure vessels are assembled from a pipe and two covers. For cylindrical vessels with a diameter up to 600 mm (NPS of 24 in), it is possible to use seamless pipe for the shell, thus avoiding many inspection and testing issues, mainly the nondestructive examination of radiography for the long seam if required. A disadvantage of these vessels is that greater diameters are more expensive, so that for example the most economic shape of a {{convert|1000|l|cuft}}, {{convert|250|bar|psi|lk=on}} pressure vessel might be a diameter of {{convert|91.44|cm|in|0}} and a length of {{convert|1.7018|m|in|0}} including the 2:1 semi-elliptical domed end caps. Construction materialsMany pressure vessels are made of steel. To manufacture a cylindrical or spherical pressure vessel, rolled and possibly forged parts would have to be welded together. Some mechanical properties of steel, achieved by rolling or forging, could be adversely affected by welding, unless special precautions are taken. In addition to adequate mechanical strength, current standards dictate the use of steel with a high impact resistance, especially for vessels used in low temperatures. In applications where carbon steel would suffer corrosion, special corrosion resistant material should also be used. Some pressure vessels are made of composite materials, such as filament wound composite using carbon fibre held in place with a polymer. Due to the very high tensile strength of carbon fibre these vessels can be very light, but are much more difficult to manufacture. The composite material may be wound around a metal liner, forming a composite overwrapped pressure vessel. Other very common materials include polymers such as PET in carbonated beverage containers and copper in plumbing. Pressure vessels may be lined with various metals, ceramics, or polymers to prevent leaking and protect the structure of the vessel from the contained medium. This liner may also carry a significant portion of the pressure load.[4][5] Pressure Vessels may also be constructed from concrete (PCV) or other materials which are weak in tension. Cabling, wrapped around the vessel or within the wall or the vessel itself, provides the necessary tension to resist the internal pressure. A "leakproof steel thin membrane" lines the internal wall of the vessel. Such vessels can be assembled from modular pieces and so have "no inherent size limitations".[6] There is also a high order of redundancy thanks to the large number of individual cables resisting the internal pressure. The very small vessels used to make liquid butane fueled cigarette lighters are subjected to about 2 bar pressure, depending on ambient temperature. These vessels are often oval (1 x 2 cm ... 1.3 x 2.5 cm) in cross section but sometimes circular. The oval versions generally include one or two internal tension struts which appear to be baffles but which also provide additional cylinder strength.
Working pressureThe typical circular-cylindrical high pressure gas cylinders for permanent gases (that do not liquify at storing pressure, like air, oxygen, nitrogen, hydrogen, argon, helium) have been manufactured by hot forging by pressing and rolling to get a seamless steel vessel. Working pressure of cylinders for use in industry, skilled craft, diving and medicine had a standardized working pressure (WP) of only 150 bars in Europe until about 1950. Since about 1975 until now the standard pressure is 200 bar. Firemen need slim (and lightweight) cylinders to move in confined spaces, about 1995 cylinders for 300 bar WP came up – first in pure steel. The push to lighter weight lead to different generations of composite (fiber and matrix, over a liner) cylinders that are more easily damageable by a hit from outside. Wall thickness helps to resist. Therefore composite cylinders – fire fighting is an important market – usually are built for 300 bar. Hydraulic (filled with water) testing pressure is – since ever – usually 50 % higher than the working pressure. Vessel threadUntil 1990 all high pressure cylinders were produced with conical (tapered) threads to fit the accordingly manufactured cylinder valves. Two types of threads have dominated the full metal cylinders in industrial use from 0.2 to 50 litres in volume. To screw in the valve a high torque of typically 200 Nm is necessary for the larger (23 mm?) threads, and 100 Nm for the smaller (17 mm?) ones. Until around 1950 hemp was used as a sealant. Later, a thin sheet of lead pressed to a hat with a hole on top was used. Since 2005, PTFE-tape has been used to avoid using lead. A tapered thread provides simple assembly, but requires high torque for connecting, and leads to high radial forces in the vessel neck. All cylinders built for 300 bar working pressure, all diving cylinders, and all composite cylinders use parallel threads. Either 25 x 1.5 mm or 18 x 1.5 mm for smaller cylinders. These connections are sealed by an elastomer O-ring pressurized by the gas, have a bed-stop, and need only about 20 Nm of torque which is compatible with all three types of composite cylinders. Development of composite vesselsTo classify the different making principles of composite cylinders 4 types are defined.
Type 2 and 3 cylinders came up around 1995. Type 4 cylinders are commercially available at least from 2016 on. Safety featuresLeak before burstLeak before burst describes a pressure vessel designed such that a crack in the vessel will grow through the wall, allowing the contained fluid to escape and reducing the pressure, prior to growing so large as to cause fracture at the operating pressure. Many pressure vessel standards, including the ASME Boiler and Pressure Vessel Code[7] and the AIAA metallic pressure vessel standard, either require pressure vessel designs to be leak before burst, or require pressure vessels to meet more stringent requirements for fatigue and fracture if they are not shown to be leak before burst.[8] Safety valvesAs the pressure vessel is designed to a pressure, there is typically a safety valve or relief valve to ensure that this pressure is not exceeded in operation. Maintenance featuresPressure vessel closuresPressure vessel closures are pressure retaining structures designed to provide quick access to pipelines, pressure vessels, pig traps, filters and filtration systems. Typically pressure vessel closures allow maintenance personnel. UsesPressure vessels are used in a variety of applications in both industry and the private sector. They appear in these sectors as industrial compressed air receivers and domestic hot water storage tanks. Other examples of pressure vessels are diving cylinders, recompression chambers, distillation towers, pressure reactors, autoclaves, and many other vessels in mining operations, oil refineries and petrochemical plants, nuclear reactor vessels, submarine and space ship habitats, pneumatic reservoirs, hydraulic reservoirs under pressure, rail vehicle airbrake reservoirs, road vehicle airbrake reservoirs, and storage vessels for liquified gases such as ammonia, chlorine, and LPG (propane, butane). A unique application of a pressure vessel is the passenger cabin of an airliner: the outer skin carries both the aircraft maneuvering loads and the cabin pressurization loads. Alternatives to pressure vessels
Depending on the application and local circumstances, alternatives to pressure vessels exist. Examples can be seen in domestic water collection systems, where the following may be used:
DesignScalingNo matter what shape it takes, the minimum mass of a pressure vessel scales with the pressure and volume it contains and is inversely proportional to the strength to weight ratio of the construction material (minimum mass decreases as strength increases[11]). Scaling of stress in walls of vesselPressure vessels are held together against the gas pressure due to tensile forces within the walls of the container. The normal (tensile) stress in the walls of the container is proportional to the pressure and radius of the vessel and inversely proportional to the thickness of the walls.[12] Therefore, pressure vessels are designed to have a thickness proportional to the radius of tank and the pressure of the tank and inversely proportional to the maximum allowed normal stress of the particular material used in the walls of the container. Because (for a given pressure) the thickness of the walls scales with the radius of the tank, the mass of a tank (which scales as the length times radius times thickness of the wall for a cylindrical tank) scales with the volume of the gas held (which scales as length times radius squared). The exact formula varies with the tank shape but depends on the density, ρ, and maximum allowable stress σ of the material in addition to the pressure P and volume V of the vessel. (See below for the exact equations for the stress in the walls.) Spherical vesselFor a sphere, the minimum mass of a pressure vessel is , where:
Other shapes besides a sphere have constants larger than 3/2 (infinite cylinders take 2), although some tanks, such as non-spherical wound composite tanks can approach this. Cylindrical vessel with hemispherical endsThis is sometimes called a "bullet"{{citation needed|date=March 2014}} for its shape, although in geometric terms it is a capsule. For a cylinder with hemispherical ends, , where
Cylindrical vessel with semi-elliptical endsIn a vessel with an aspect ratio of middle cylinder width to radius of 2:1, . Gas storageIn looking at the first equation, the factor PV, in SI units, is in units of (pressurization) energy. For a stored gas, PV is proportional to the mass of gas at a given temperature, thus . (see gas law) The other factors are constant for a given vessel shape and material. So we can see that there is no theoretical "efficiency of scale", in terms of the ratio of pressure vessel mass to pressurization energy, or of pressure vessel mass to stored gas mass. For storing gases, "tankage efficiency" is independent of pressure, at least for the same temperature. So, for example, a typical design for a minimum mass tank to hold helium (as a pressurant gas) on a rocket would use a spherical chamber for a minimum shape constant, carbon fiber for best possible , and very cold helium for best possible . Stress in thin-walled pressure vesselsStress in a shallow-walled pressure vessel in the shape of a sphere is , where is hoop stress, or stress in the circumferential direction, is stress in the longitudinal direction, p is internal gauge pressure, r is the inner radius of the sphere, and t is thickness of the sphere wall. A vessel can be considered "shallow-walled" if the diameter is at least 10 times (sometimes cited as 20 times) greater than the wall depth.[15] Stress in a shallow-walled pressure vessel in the shape of a cylinder is , , where:
Almost all pressure vessel design standards contain variations of these two formulas with additional empirical terms to account for variation of stresses across thickness, quality control of welds and in-service corrosion allowances. All formulae mentioned above assume uniform distribution of membrane stresses across thickness of shell but in reality, that is not the case. Deeper analysis is given by Lame's theory. The formulae of pressure vessel design standards are extension of Lame's theory by putting some limit on ratio of inner radius and thickness. For example, the ASME Boiler and Pressure Vessel Code (BPVC) (UG-27) formulas are:[16] Spherical shells: Thickness has to be less than 0.356 times inner radius Cylindrical shells: Thickness has to be less than 0.5 times inner radius where E is the joint efficiency, and all others variables as stated above. The factor of safety is often included in these formulas as well, in the case of the ASME BPVC this term is included in the material stress value when solving for pressure or thickness. Winding angle of carbon fibre vesselsWound infinite cylindrical shapes optimally take a winding angle of 54.7 degrees, as this gives the necessary twice the strength in the circumferential direction to the longitudinal.[17] Operation standardsPressure vessels are designed to operate safely at a specific pressure and temperature, technically referred to as the "Design Pressure" and "Design Temperature". A vessel that is inadequately designed to handle a high pressure constitutes a very significant safety hazard. Because of that, the design and certification of pressure vessels is governed by design codes such as the ASME Boiler and Pressure Vessel Code in North America, the Pressure Equipment Directive of the EU (PED), Japanese Industrial Standard (JIS), CSA B51 in Canada, Australian Standards in Australia and other international standards like Lloyd's, Germanischer Lloyd, Det Norske Veritas, Société Générale de Surveillance (SGS S.A.), Lloyd’s Register Energy Nederland (formerly known as Stoomwezen) etc. Note that where the pressure-volume product is part of a safety standard, any incompressible liquid in the vessel can be excluded as it does not contribute to the potential energy stored in the vessel, so only the volume of the compressible part such as gas is used. List of standards
See also{{div col}}
Notes1. ^1 2 3 4 5 Nilsen, Kyle. (2011) "Development of low pressure filter testing vessel and analysis of electrospun nanofiber membranes for water treatment" 2. ^Ingenious Coal-Gas Motor Tank, Popular Science monthly, January 1919, page 27, Scanned by Google Books: https://books.google.com/books?id=HykDAAAAMBAJ&pg=PA13 3. ^{{cite book|last=Hearn|first=E.J.|title=Mechanics of Materials 1. An Introduction to the Mechanics of Elastic and Plastic Deformation of Solids and Structural Materials - Third Edition|year=1997|publisher=Butterworth-Heinemann|location=Chapter 9|isbn=0-7506-3265-8|pages=199–203}} 4. ^NASA Tech Briefs, "Making a Metal-Lined Composite Overwrapped Pressure Vessel", 1 Mar 2005. 5. ^Frietas, O., "Maintenance and Repair of Glass-Lined Equipment", Chemical Engineering, 1 Jul 2007. 6. ^"High Pressure Vessels",D. Freyer and J. Harvey, 1998 7. ^{{Cite book|title=Aero Engine Combustor Casing: Experimental Design and Fatigue Studies|last=Sashi Kanta Panigrahi, Niranjan Sarangi|first=|publisher=CRC Press|year=2017|isbn=9781351642835|location=|pages=4-45}} 8. ^ANSI/AIAA S-080-1998, Space Systems - Metallic Pressure Vessels, Pressurized Structures, and Pressure Components, §5.1 9. ^{{cite web|first=Doug |last=Pushard |url=http://www.harvesth2o.com/faq.shtml |title=Domestic water collection systems also sometimes able to function on gravity |publisher=Harvesth2o.com |year=2005 |accessdate=2009-04-17}}{{Verify source|date=April 2009}} 10. ^{{cite web|first=Doug |last=Pushard |url=http://www.harvesth2o.com/pumps_or_tanks.shtml |title=Alternatives to pressure vessels in domestic water systems |publisher=Harvesth2o.com |date= |accessdate=2009-04-17}} 11. ^{{cite journal|first=Paul|last=Puskarich|url=http://www.gmic.org/Student%20Contest%20Entries/2007%20Contest%20Entries/26-Paul%20Puskarich%20-%20Glass%20for%20Pipeline%20Systems.pdf|title=Strengthened Glass for Pipeline Systems|date=2009-05-01|format=PDF|publisher=MIT|accessdate=2009-04-17|deadurl=yes|archiveurl=https://web.archive.org/web/20120315184643/http://www.gmic.org/Student%20Contest%20Entries/2007%20Contest%20Entries/26-Paul%20Puskarich%20-%20Glass%20for%20Pipeline%20Systems.pdf|archivedate=2012-03-15|df=}} 12. ^{{cite book|title=Mechanics of Materials |first1=Ferdinand P. |last1=Beer |first2=E. Russel |last2=Johnston, Jr. |first3=John T. |last3=DeWolf |edition=fourth |chapter=7.9 |page=463 |isbn=9780073659350 |publisher=McGraw-Hill}} 13. ^For a sphere the thickness d = rP/2σ, where r is the radius of the tank. The volume of the spherical surface then is 4πr2d = 4πr3P/2σ. The mass is determined by multiplying by the density of the material that makes up the walls of the spherical vessel. Further the volume of the gas is (4πr3)/3. Combining these equations give the above results. The equations for the other geometries are derived in a similar manner 14. ^{{Cite web|url=http://www.fxsolver.com/browse/formulas/Mass+of+pressure+Cylindrical+vessel+with+hemispherical+ends(+capsule)|title=Mass of pressure Cylindrical vessel with hemispherical ends( capsule) - calculator - fxSolver|website=www.fxsolver.com|access-date=2017-04-11}} 15. ^Richard Budynas, J. Nisbett, Shigley's Mechanical Engineering Design, 8th ed., New York:McGraw-Hill, {{ISBN|978-0-07-312193-2}}, pg 108 16. ^{{cite book|title=An International Code 2007 ASME Boiler & Pressure Vessel Code|year=2007|publisher=The Americal Society of Mechanical Engineers|url=http://www.asme.org/kb/standards/bpvc-resources}} 17. ^MIT pressure vessel lecture 18. ^{{cite web|title=AS 1200 Pressure Vessels|url=http://infostore.saiglobal.com/store2/Details.aspx?ProductID=356464|archive-url=https://archive.is/20120709084148/http://infostore.saiglobal.com/store2/Details.aspx?ProductID=356464|dead-url=yes|archive-date=9 July 2012|publisher=SAI Global|accessdate=14 November 2011}} 19. ^{{cite web | url=http://infostore.saiglobal.com/store/details.aspx?ProductID=374650 | title=AS_NZS 3788: 2006 Pressure equipment - In-service inspection | publisher=SAI Global | accessdate=September 4, 2015}} 20. ^{{cite web|url=http://global.ihs.com/doc_detail.cfm?item_s_key=00010564 |title=Pressure Vessel Inspection Code: In-Service Inspection, Rating, Repair, and Alteration |publisher=API |date=June 2006}} 21. ^.{{cite web|url=http://www.iso.org/iso/catalogue_detail?csnumber=33298 |title=Gas cylinders - High pressure cylinders for the on-board storage of natural gas as a fuel for automotive vehicles |publisher=ISO |date=2006-07-18 |accessdate=2009-04-17}} References
Further reading
External links{{wiktionary}}{{commons|Pressure vessel|Pressure vessel}}
2 : Pressure vessels|Gas technologies |
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