1 the force applied to a unit area of surface; measured in pascals (SI unit) or in dynes (cgs unit); "the compressed gas exerts an increased pressure" [syn: pressure level, force per unit area]
2 a force that compels; "the public brought pressure to bear on the government"
3 the act of pressing; the exertion of pressure; "he gave the button a press"; "he used pressure to stop the bleeding"; "at the pressing of a button" [syn: press, pressing]
4 the state of urgently demanding notice or attention; "the press of business matters" [syn: imperativeness, insistence, insistency, press]
5 the somatic sensation of pressure; "the sensitivity of his skin to pressure and temperature was normal" [syn: pressure sensation]
6 an oppressive condition of physical or mental or social or economic distress
1 to cause to do through pressure or necessity, by physical, moral or intellectual means :"She forced him to take a job in the city"; "He squeezed her for information" [syn: coerce, hale, squeeze, force]
- Rhymes: -ɛʃə(r)
- The amount of force that is applied over a given area divided by the size of this area.
- mental strain caused by one's own or others' expectations on one's own performance
force to area in physics
- Chinese: 压力 (yālì)
- Czech: tlak
- Dutch: druk
- Finnish: paine
- French: pression
- German: Druck
- Hungarian: nyomás, levegőnyomás
- Indonesian: tekanan
- Italian: pressione
- Japanese: 圧力 (あつりょく, atsuryoku)
- Korean: 압력 (amnyeok)
- Latvian: spiediens
- Polish: ciśnienie
- Portuguese: pressão
- Romanian: presiune
- Russian: давление (davlénije)
- Spanish: presión
- Swedish: tryck
- Telugu: పీడనం (peeDanam), ఒత్తిడి (ottiDi)
Pressure (symbol: 'p') is the force over an area applied to an object in a direction perpendicular to the surface. Gauge pressure is the pressure relative to the local atmospheric or ambient pressure.
DefinitionPressure is an effect which occurs when a Force is applied on a surface.The symbol of Pressure is p which can also be written as P .
FormulaMathematically: p = \frac\ \mbox\ p = \frac
- p is the pressure,
- F is the normal force,
- A is the area.
- F is the normal force,
Pressure is a scalar quantity, and has SI units of pascals; 1 Pa = 1 N/m2, and has EES units of psi; 1 psi = 1 lb/in2.
Pressure is transmitted to solid boundaries or across arbitrary sections of fluid normal to these boundaries or sections at every point. It is a fundamental parameter in thermodynamics and it is conjugate to volume.
The SI unit for pressure is the pascal (Pa), equal to one newton per square metre (N·m-2 or kg·m-1·s-2). This special name for the unit was added in 1971; before that, pressure in SI was expressed simply as N/m2.
Non-SI measures such as pound per square inch (psi) and bar are used in parts of the world. The cgs unit of pressure is the barye (ba), equal to 1 dyn·cm-2. Pressure is sometimes expressed in grams-force/cm2, or as kg/cm2 and the like without properly identifying the force units. But using the names kilogram, gram, kilogram-force, or gram-force (or their symbols) as units of force is expressly forbidden in SI. The technical atmosphere (symbol: at) is 1 kgf/cm2. In US Customary units, it is 14.696 psi.
Some meteorologists prefer the hectopascal (hPa) for atmospheric air pressure, which is equivalent to the older unit millibar (mbar). Similar pressures are given in kilopascals (kPa) in most other fields, where the hecto prefix is rarely used. The unit inch of mercury (inHg, see below) is still used in the United States. Oceanographers usually measure underwater pressure in decibars (dbar) because an increase in pressure of 1 dbar is approximately equal to an increase in depth of 1 meter. Scuba divers often use a manometric rule of thumb: the pressure exerted by ten metres depth of water is approximately equal to one atmosphere.
The standard atmosphere (atm) is an established constant. It is approximately equal to typical air pressure at earth mean sea level and is defined as follows:
- standard atmosphere = 101325 Pa = 101.325 kPa = 1013.25 hPa.
Because pressure is commonly measured by its ability to displace a column of liquid in a manometer, pressures are often expressed as a depth of a particular fluid (e.g., inches of water). The most common choices are mercury (Hg) and water; water is nontoxic and readily available, while mercury's high density allows for a shorter column (and so a smaller manometer) to measure a given pressure. The pressure exerted by a column of liquid of height h and density ρ is given by the hydrostatic pressure equation p = ρgh. Fluid density and local gravity can vary from one reading to another depending on local factors, so the height of a fluid column does not define pressure precisely. When millimeters of mercury or inches of mercury are quoted today, these units are not based on a physical column of mercury; rather, they have been given precise definitions that can be expressed in terms of SI units. The water-based units still depend on the density of water, a measured, rather than defined, quantity. These manometric units are still encountered in many fields. Blood pressure is measured in millimeters of mercury in most of the world, and lung pressures in centimeters of water are still common.
Presently or formerly popular pressure units include the following:
- manometric units:
- imperial units:
- non-SI metric units:
ExamplesAs an example of varying pressures, a finger can be pressed against a wall without making any lasting impression; however, the same finger pushing a thumbtack can easily damage the wall. Although the force applied to the surface is the same, the thumbtack applies more pressure because the point concentrates that force into a smaller area. Pressure is transmitted to solid boundaries or across arbitrary sections of fluid normal to these boundaries or sections at every point. Unlike stress, pressure is defined as a scalar quantity.
Another example is of a common knife. If we try and cut a fruit with the flat side it obviously won't cut. But if we take the thin side, it will cut smoothly. The reason is, the flat side has a greater surface area and so it does not cut the fruit. When we take the thin side, the surface area is reduced and so it cuts the fruit easily and quickly. This shows one of the good effects of Pressure.
The gradient of pressure is called the force density. For gases, pressure is sometimes measured not as an absolute pressure, but relative to atmospheric pressure; such measurements are called gauge pressure (also sometimes spelled gage pressure). An example of this is the air pressure in an automobile tire, which might be said to be "220 kPa", but is actually 220 kPa above atmospheric pressure. Since atmospheric pressure at sea level is about 100 kPa, the absolute pressure in the tire is therefore about 320 kPa. In technical work, this is written "a gauge pressure of 220 kPa". Where space is limited, such as on pressure gauges, name plates, graph labels, and table headings, the use of a modifier in parentheses, such as "kPa (gauge)" or "kPa (absolute)", is permitted. In non-SI technical work, a gauge pressure of 32 psi is sometimes written as "32 psig", though the other methods explained above that avoid attaching characters to the unit of pressure are preferred.
Gauge pressure is the relevant measure of pressure wherever one is interested in the stress on storage vessels and the plumbing components of fluidics systems. However, whenever equation-of-state properties, such as densities or changes in densities, must be calculated, pressures must be expressed in terms of their absolute values. For instance, if the atmospheric pressure is 100 kPa, a gas (such as helium) at 200 kPa (gauge) (300 kPa [absolute]) is 50 % more dense than the same gas at 100 kPa (gauge) (200 kPa [absolute]). Focusing on gauge values, one might erroneously conclude the first sample had twice the density of the second one.
Scalar natureIn a static gas, the gas as a whole does not appear to move. The individual molecules of the gas, however, are in constant random motion. Because we are dealing with an extremely large number of molecules and because the motion of the individual molecules is random in every direction, we do not detect any motion. If we enclose the gas within a container, we detect a pressure in the gas from the molecules colliding with the walls of our container. We can put the walls of our container anywhere inside the gas, and the force per unit area (the pressure) is the same. We can shrink the size of our "container" down to an infinitely small point, and the pressure has a single value at that point. Therefore, pressure is a scalar quantity, not a vector quantity. It has a magnitude but no direction sense associated with it. Pressure acts in all directions at a point inside a gas. At the surface of a gas, the pressure force acts perpendicular to the surface.
A closely related quantity is the stress tensor σ, which relates the vector force F to the vector area A via \mathbf=\mathbf\,
This tensor may be divided up into a scalar part (pressure) and a traceless tensor part shear. The shear tensor gives the force in directions parallel to the surface, usually due to viscous or frictional forces. The stress tensor is sometimes called the pressure tensor, but in the following, the term "pressure" will refer only to the scalar pressure.
Explosion or deflagration pressuresExplosion or deflagration pressures are the result of the ignition of explosive gases, mists, dust/air suspensions, in unconfined and confined spaces.
Negative pressuresWhile pressures are generally positive, there are several situations in which negative pressures may be encountered:
- When dealing in relative (gauge) pressures. For instance, an absolute pressure of 80 kPa may be described as a gauge pressure of -21 kPa (i.e., 21 kPa below an atmospheric pressure of 101 kPa).
- When attractive forces (e.g., Van der Waals forces) between the particles of a fluid exceed repulsive forces. Such scenarios are generally unstable since the particles will move closer together until repulsive forces balance attractive forces. Negative pressure exists in the transpiration pull of plants.
- The Casimir effect can create a small attractive force due to interactions with vacuum energy; this force is sometimes termed 'vacuum pressure' (not to be confused with the negative gauge pressure of a vacuum).
- Depending on how the orientation of a surface is chosen, the same distribution of forces may be described either as a positive pressure along one surface normal, or as a negative pressure acting along the opposite surface normal.
- In the cosmological constant.
Stagnation pressureStagnation pressure is the pressure a fluid exerts when it is forced to stop moving. Consequently, although a fluid moving at higher speed will have a lower static pressure, it may have a higher stagnation pressure when forced to a standstill. Static pressure and stagnation pressure are related by the Mach number of the fluid. In addition, there can be differences in pressure due to differences in the elevation (height) of the fluid. See Bernoulli's equation (note: Bernoulli's equation only applies for incompressible flow).
The pressure of a moving fluid can be measured using a Pitot tube, or one of its variations such as a Kiel probe or Cobra probe, connected to a manometer. Depending on where the inlet holes are located on the probe, it can measure static pressure or stagnation pressure.
Surface pressureThere is a two-dimensional analog of pressure -- the lateral force per unit length applied on a line perpendicular to the force.
Surface pressure is denoted by π and shares many similar properties with three-dimensional pressure. Properties of surface chemicals can be investigated by measuring pressure/area isotherms, as the two-dimensional analog of Boyle's law, πA = k, at constant temperature.
- \pi = \frac.
- Atmospheric pressure
- Blood pressure
- Boyle's Law
- Combined gas law
- Conversion of units
- Units conversion by factor-label
- Ideal gas law
- Kinetic theory
- Partial pressure
- Sound pressure
- Orders of magnitude (pressure)
- Timeline of temperature and pressure measurement technology
- Vacuum pump
- Vapor pressure
- A Java pressure simulation applet
- Thermodynamics - A chapter from an online textbook
- Introduction to Fluid Statics and Dynamics on Project PHYSNET
- An exercise in air pressure
- Pressure being a scalar quantity
- Online pressure converter for 52 different pressure units
- Pressure conversions - for both SI and non-SI units
pressure in Afrikaans: Druk
pressure in Tosk Albanian: Druck (Physik)
pressure in Arabic: ضغط
pressure in Asturian: Presión
pressure in Bengali: চাপ
pressure in Belarusian: Ціск
pressure in Belarusian (Tarashkevitsa): Ціск
pressure in Bosnian: Pritisak
pressure in Bulgarian: Налягане
pressure in Catalan: Pressió
pressure in Czech: Tlak
pressure in Danish: Tryk (fysik)
pressure in German: Druck (Physik)
pressure in Estonian: Rõhk
pressure in Modern Greek (1453-): Πίεση
pressure in Spanish: Presión
pressure in Esperanto: Premo
pressure in Basque: Presio
pressure in Persian: فشار
pressure in French: Pression
pressure in Galician: Presión
pressure in Korean: 압력
pressure in Croatian: Tlak
pressure in Ido: Preso
pressure in Indonesian: Tekanan
pressure in Italian: Pressione
pressure in Hebrew: לחץ
pressure in Kazakh: Қысым
pressure in Latvian: Spiediens
pressure in Lithuanian: Slėgis
pressure in Hungarian: Nyomás
pressure in Macedonian: Притисок
pressure in Malay (macrolanguage): Tekanan
pressure in Dutch: Druk
pressure in Japanese: 圧力
pressure in Norwegian: Trykk
pressure in Norwegian Nynorsk: Trykk
pressure in Polish: Ciśnienie
pressure in Portuguese: Pressão
pressure in Romanian: Presiune
pressure in Quechua: Ñit'iy
pressure in Russian: Давление
pressure in Simple English: Pressure
pressure in Slovak: Tlak
pressure in Slovenian: Tlak
pressure in Serbian: Притисак
pressure in Serbo-Croatian: Tlak
pressure in Finnish: Paine
pressure in Swedish: Tryck
pressure in Tamil: அழுத்தம்
pressure in Vietnamese: Áp suất
pressure in Turkish: Basınç
pressure in Ukrainian: Тиск
pressure in Yiddish: דרוק
pressure in Chinese: 压强
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