technical atmospheres (at) to pounds per square inch (psi) conversion

1 at = 14.22334 psipsiat
Formula
1 at = 14.22334 psi

Understanding technical atmospheres to pounds per square inch Conversion

The technical atmosphere (at) equals one kilogram-force per square centimetre, a metric pressure unit common in European hydraulic and pneumatic systems. The pound per square inch (psi) is the imperial and US customary unit, dominant in North American tyre, compressed-air, and plumbing specifications. Converting technical atmospheres to psi is essential when matching metric-rated equipment to imperial gauges and datasheets.

Conversion Formula

1 at=14.2233 psi1\ \text{at} = 14.2233\ \text{psi}

To convert technical atmospheres to pounds per square inch, multiply by this factor:

psi=at×14.22334\text{psi} = \text{at} \times 14.22334

Step-by-Step Example

Convert 25 technical atmospheres to pounds per square inch.

psi=25×14.22334=355.584 psi\text{psi} = 25 \times 14.22334 = 355.584\ \text{psi}

How to Convert technical atmospheres to pounds per square inch

Multiply the technical atmosphere value by the imperial pressure factor to obtain psi.

  1. Note the factor: One technical atmosphere equals 14.22334 psi.
  2. Multiply: Multiply your value in at by 14.22334.
  3. Work the example: For 25 at, compute 25 × 14.22334.
  4. Read the result: The answer is 355.584 psi.

technical atmospheres to pounds per square inch conversion table

technical atmospheres (at)pounds per square inch (psi)
00
114.22334
228.44669
342.67003
456.89337
571.11672
685.34006
799.5634
8113.7867
9128.0101
10142.2334
15213.3501
20284.4669
25355.5836
30426.7003
40568.9337
50711.1672
60853.4006
70995.634
801137.867
901280.101
1001422.334
1502133.501
2002844.669
2503555.836
3004267.003
4005689.337
5007111.672
6008534.006
7009956.34
80011378.67
90012801.01
100014223.34
200028446.69
300042670.03
400056893.37
500071116.72
10000142233.4
25000355583.6
50000711167.2
1000001422334
2500003555836
5000007111672
100000014223340

What is the technical atmosphere?

The technical atmosphere (at) is a non-SI unit of pressure equal to one kilogram-force per square centimeter. It was widely used in engineering, especially in Europe, before the pascal became standard.

Definition

The technical atmosphere is defined as the pressure of one kilogram-force acting on one square centimeter:

1 at=98066.5 Pa1\ \text{at} = 98066.5\ \text{Pa}

This equals exactly 1 kgf/cm² (98,066.5 Pa), because standard gravity is 9.80665 m/s². It is close to, but distinct from, the standard atmosphere (atm = 101,325 Pa) and the bar (100,000 Pa).

Origin and History

The technical atmosphere arose from the gravitational metric system of units, which used the kilogram-force rather than the newton. Expressing pressure as kilogram-force per square centimeter was intuitive for engineers weighing loads, and the unit became common in mechanical and hydraulic engineering, boilers, and pneumatics through much of the 20th century.

Law and Notable Facts

The technical atmosphere is not part of the SI and its use is discouraged in favor of the pascal or bar. It is easily confused with the standard atmosphere; the two differ by about 3.3%. Gauge and absolute variants were often written "atü" (gauge) and "ata" (absolute) in German-language engineering.

Real-World Examples and Conversions

  • 1 at = 1 kgf/cm² = 98.0665 kPa ≈ 0.9678 atm.
  • 1 at ≈ 14.223 psi, close to but slightly below the 14.696 psi of one standard atmosphere.
  • A pressure of 10 at (about 981 kPa) is a common rating benchmark for industrial hydraulic components.
  • 1 at ≈ 0.980665 bar, so the bar and technical atmosphere differ by under 2%.

What is pounds per square inch?

Pounds per square inch (psi) is a unit of pressure that's commonly used, especially in the United States. Understanding what it represents and how it's derived helps to grasp its significance in various applications.

Definition of Pounds per Square Inch (psi)

Pounds per square inch (psi) is a unit of pressure defined as the amount of force in pounds (lbs) exerted on an area of one square inch (in2in^2).

Pressure(psi)=Force(lbs)Area(in2)Pressure (psi) = \frac{Force (lbs)}{Area (in^2)}

How psi is Formed

Psi is derived by dividing the force applied, measured in pounds, by the area over which that force is distributed, measured in square inches. It's a direct measure of force intensity. For example, 10 psi means that a force of 10 pounds is acting on every square inch of the surface.

Applications and Examples of psi

  • Tire Pressure: Car tires are typically inflated to 30-35 psi. This ensures optimal contact with the road, fuel efficiency, and tire wear.

  • Compressed Air Systems: Air compressors used in workshops and industries often operate at pressures of 90-120 psi to power tools and equipment.

  • Hydraulic Systems: Hydraulic systems in heavy machinery (like excavators and cranes) can operate at thousands of psi to generate the immense force needed for lifting and moving heavy loads. Pressures can range from 3,000 to 5,000 psi or even higher.

  • Water Pressure: Standard household water pressure is usually around 40-60 psi.

  • Scuba Diving Tanks: Scuba tanks are filled with compressed air to pressures of around 3,000 psi to allow divers to breathe underwater for extended periods.

Pascal's Law and Pressure Distribution

Pascal's Law is relevant to understanding pressure in fluids (liquids and gases). Blaise Pascal was a French mathematician, physicist, and philosopher. Pascal's Law states that pressure applied to a confined fluid is transmitted equally in all directions throughout the fluid. This principle is fundamental to hydraulics and pneumatic systems where pressure is used to transmit force. Pascal's Law can be summarized as:

A change in pressure at any point in a confined fluid is transmitted undiminished to all points in the fluid.

More formally:

ΔP=ρgΔh\Delta P = \rho g \Delta h

Where:

  • ΔP\Delta P is the hydrostatic pressure difference (in Pascals or psi)
  • ρ\rho is the fluid density (in kg/m3kg/m^3 or lbs/in3lbs/in^3)
  • gg is the acceleration due to gravity (approximately 9.81m/s29.81 m/s^2 or 32.2ft/s232.2 ft/s^2)
  • Δh\Delta h is the height difference (in meters or inches)

For more information, you can refer to this excellent explanation of Pascal's Law at NASA

Frequently Asked Questions

How many psi are in one technical atmosphere?

One technical atmosphere equals about 14.2233 psi, since 1 kgf/cm² maps onto roughly 14.22 pounds-force per square inch.

How do I convert psi back to technical atmospheres?

Multiply the psi value by 0.07030696, or divide by 14.22334.

Is a technical atmosphere close to one standard atmosphere in psi?

Reasonably: a technical atmosphere is about 14.22 psi versus 14.70 psi for a standard atmosphere.

Where is this conversion practical?

Matching European hydraulic pumps rated in kgf/cm² to North American systems and gauges calibrated in psi.

What is 3 technical atmospheres in psi?

Multiply 3 by 14.22334 to get about 42.67 psi.

Complete technical atmospheres conversion table

at
UnitResult
pascals (Pa)98066.5 Pa
kilopascals (kPa)98.0665 kPa
megapascals (MPa)0.0980665 MPa
hectopascals (hPa)980.665 hPa
millibar (mbar)980.665 mbar
bar (bar)0.980665 bar
torr (torr)735.5592 torr
meters of water @ 4°C (mH2O)10 mH2O
millimeters of mercury (mmHg)735.5591 mmHg
standard atmospheres (atm)0.9678411 atm
centimeters of water (cmH2O)1000 cmH2O
centimeters of mercury (cmHg)73.55591 cmHg
pounds per square inch (psi)14.22334 psi
kilopound per square inch (ksi)0.01422334 ksi
Inches of mercury (inHg)28.95902 inHg