Convert bar to PSIG, PSIA, kPa, atm, and mmHg. Handles gauge vs. absolute pressure with adjustable atmospheric baseline.
The bar to PSIG converter handles four conversion modes: Bar→PSIG, PSIG→Bar, Bar→PSIA, and PSIA→Bar. It distinguishes between gauge pressure (PSIG, relative to atmosphere) and absolute pressure (PSIA, relative to vacuum), which matters any time a number comes from a nameplate, a gauge, or a process spec that does not spell out the reference clearly. In practice, the same pressure can look different depending on whether the reading starts at zero gauge or zero vacuum, so the converter keeps both views visible instead of forcing a single interpretation.
Enter your pressure, select the mode, and get results in PSIG, PSIA, bar, kPa, MPa, atmospheres, mmHg, and inHg. The atmospheric baseline is adjustable for altitude corrections, which is useful when equipment is installed away from sea level or when a local barometer reading should replace the standard 14.696 PSI baseline. That lets you compare a field gauge with a vendor sheet without quietly baking in the wrong reference pressure.
Preset buttons cover common industrial pressures from bicycle tires to hydrogen storage tanks. The reference table maps 15 pressure levels from vacuum to 700 bar with all unit equivalents. This makes it easier to validate instrumentation readings, compare vendor specs, and communicate pressure values clearly across maintenance teams and compliance documentation. It also helps when a vendor sheet reports bar absolute while field technicians are looking at a PSIG gauge, especially during commissioning or calibration work.
Industrial equipment often mixes bar and PSI on nameplates, and the gauge-versus-absolute distinction is easy to miss when the numbers are being compared quickly. Misreading PSIG as PSIA can introduce a full-atmosphere error, which is enough to throw off a pressure check or make a system look out of spec when it is not.
This converter is useful because it keeps PSIG, PSIA, bar, and the atmospheric baseline in the same view. That makes commissioning, troubleshooting, and documentation checks safer than using a plain one-factor unit converter, especially when you need to explain why two readings that look close are not the same thing.
PSIA = Bar × 14.5038. PSIG = PSIA − atmospheric pressure. 1 bar = 100 kPa = 14.5038 PSI. 1 atm = 1.01325 bar = 14.696 PSI.
Result: 10 bar = 145.0 PSIA = 130.3 PSIG
10 × 14.5038 = 145.04 PSIA. Subtract 14.696 (1 atm) = 130.34 PSIG.
Most pressure instruments (tire gauges, boiler gauges, shop air regulators) read gauge pressure — zero at atmospheric. Scientific and thermodynamic calculations require absolute pressure. Confusing the two causes errors of ~1 atm (14.7 PSI / 1 bar), which can be catastrophic in high-pressure systems.
Shop compressors: 6–10 bar (90–150 PSIG). Hydraulic systems: 100–350 bar (1,500–5,000 PSIG). Scuba tanks: 200–300 bar (3,000–4,500 PSIG). Hydrogen fuel cells: 350–700 bar (5,000–10,000 PSIG). Each application requires specific fittings and materials rated for the pressure range.
Atmospheric pressure drops about 1.2 kPa per 100 m of elevation. Denver (5,280 ft / 1,609 m) has ~12.1 PSI atmosphere vs. 14.7 PSI at sea level. For accurate gauge-to-absolute conversions at altitude, use a local barometer reading.
PSIG (gauge) measures pressure above atmospheric, while PSIA (absolute) measures from perfect vacuum. PSIA = PSIG + atmospheric pressure, so the same reading changes if you move from sea level to a different altitude.
1 bar = 14.5038 PSI (absolute). In gauge terms, 1 bar gauge is close to 14.5 PSIG, but the exact number depends on the atmospheric baseline you are using.
By convention, "bar" in engineering usually means bar gauge (barg). "bar absolute" (bara) is specified when absolute pressure is meant, and the distinction matters when you are comparing to PSIA or vacuum readings.
1 standard atmosphere = 1.01325 bar = 14.696 PSI = 101.325 kPa = 760 mmHg. That is the baseline the converter uses unless you change it for altitude or local conditions.
Add atmospheric PSI to get PSIA, then divide by 14.5038. For example, 100 PSIG + 14.696 = 114.696 PSIA, which becomes about 7.91 bar absolute.
Gauge pressure depends on local atmospheric conditions. At higher altitudes, atmospheric pressure is lower, so the same PSIG reading corresponds to a lower PSIA and slightly different absolute-equivalent values.