1. SI Unit System Overview
The International System of Units (SI) is the modern form of the metric system and the most widely used system of measurement worldwide. Understanding both SI and imperial (US Customary) units is essential for midstream engineers working on international projects.
Base units
Seven fundamentals
meter, kilogram, second, ampere, kelvin, mole, candela.
Derived units
Combinations
Pascal (pressure), Joule (energy), Watt (power) from base units.
Decimal system
Powers of 10
kilo (10³), mega (10⁶), milli (10⁻³), micro (10⁻⁶) prefixes.
Global standard
ISO compliance
ISO 80000 series defines SI units for engineering applications.
SI Base Units
| Quantity | SI Unit | Symbol | Imperial Equivalent |
|---|---|---|---|
| Length | meter | m | 3.281 feet |
| Mass | kilogram | kg | 2.205 pounds |
| Time | second | s | 1 second (same) |
| Temperature | kelvin | K | °R (Rankine) / 1.8 |
| Amount of substance | mole | mol | 1 lb-mol = 453.6 mol |
Common SI Prefixes
| Prefix | Symbol | Factor | Example (Pipeline/Gas) |
|---|---|---|---|
| giga | G | 10⁹ | GPa (pipe yield strength, 1 GPa = 145,000 psi) |
| mega | M | 10⁶ | MPa (pressure, 1 MPa = 145 psi) |
| kilo | k | 10³ | kPa (pressure, 1 kPa = 0.145 psi) |
| centi | c | 10⁻² | cm (diameter, 1 cm = 0.394 in) |
| milli | m | 10⁻³ | mm (pipe wall thickness, 1 mm = 0.0394 in) |
| micro | µ | 10⁻⁶ | µg (mercury concentration, 1 µg = 1 × 10⁻⁶ g) |
| nano | n | 10⁻⁹ | ng (LNG mercury spec, 1 ng = 1 × 10⁻⁹ g) |
Unit consistency: Mixing imperial and metric units in the same calculation is the most common source of engineering errors. Always convert all inputs to a consistent unit system (all SI or all imperial) before performing calculations, then convert results to desired output units.
Imperial (US Customary) System
The imperial system remains prevalent in United States pipeline and midstream operations:
- Length: inch (in), foot (ft), mile (mi)
- Mass: pound (lb), ton (2000 lb)
- Force: pound-force (lbf) — distinct from pound-mass (lbm)
- Pressure: psi (lb/in²), psig (gauge), psia (absolute)
- Temperature: Fahrenheit (°F), Rankine (°R = °F + 459.67)
- Volume: cubic foot (ft³), gallon (gal), barrel (bbl = 42 gal)
2. Length & Area Conversions
Length conversions are fundamental for pipe sizing, distance measurements, and area calculations in pipeline engineering.
Length Conversion Factors
Exact Definitions:
1 inch = 25.4 mm (exact, by definition since 1959)
1 foot = 0.3048 m (exact)
1 mile = 1.609344 km (exact)
Derived conversions:
1 meter = 39.37 inches = 3.281 feet
1 kilometer = 0.6214 miles
1 millimeter = 0.03937 inches
Comprehensive Length Conversion Table
| From | To | Multiply By | Example |
|---|---|---|---|
| inches | millimeters | 25.4 | 24 in × 25.4 = 609.6 mm (24" pipe OD) |
| inches | centimeters | 2.54 | 36 in × 2.54 = 91.44 cm |
| feet | meters | 0.3048 | 100 ft × 0.3048 = 30.48 m (pipe segment) |
| miles | kilometers | 1.60934 | 50 mi × 1.60934 = 80.47 km (pipeline length) |
| millimeters | inches | 0.03937 | 12.7 mm × 0.03937 = 0.500 in (wall thickness) |
| meters | feet | 3.28084 | 10 m × 3.28084 = 32.81 ft |
| kilometers | miles | 0.621371 | 100 km × 0.621371 = 62.14 mi |
Area Conversions
Area Conversion Factors:
1 in² = 645.16 mm²
1 ft² = 0.092903 m²
1 acre = 4,046.86 m² = 0.404686 hectares
1 mile² = 2.58999 km²
Common pipeline cross-section:
Pipe ID = 20 inches
Imperial area:
A = π × (20/2)² = π × 100 = 314.16 in²
Metric area:
A = 314.16 in² × 645.16 mm²/in² = 202,683 mm² = 0.2027 m²
Or directly:
ID = 20 × 25.4 = 508 mm = 0.508 m
A = π × (0.508/2)² = 0.2027 m² ✓
Pipe Size Conversions (NPS to DN)
| NPS (Nominal Pipe Size) | OD (inches) | DN (Diameter Nominal) | OD (mm) |
|---|---|---|---|
| 2" | 2.375 | DN 50 | 60.3 |
| 4" | 4.500 | DN 100 | 114.3 |
| 6" | 6.625 | DN 150 | 168.3 |
| 8" | 8.625 | DN 200 | 219.1 |
| 12" | 12.750 | DN 300 | 323.9 |
| 16" | 16.000 | DN 400 | 406.4 |
| 20" | 20.000 | DN 500 | 508.0 |
| 24" | 24.000 | DN 600 | 609.6 |
| 36" | 36.000 | DN 900 | 914.4 |
| 42" | 42.000 | DN 1050 | 1066.8 |
Pipe size notation: NPS (Nominal Pipe Size) and DN (Diameter Nominal) are not exact conversions. NPS is in inches, DN is approximately in millimeters, but both are nominal designations. Always use actual OD/ID dimensions for calculations, not nominal sizes.
3. Pressure & Temperature Conversions
Pressure and temperature conversions are critical for all pipeline and process calculations. Understanding absolute vs gauge pressure and temperature scale offsets is essential.
Pressure Conversion Factors
Fundamental Pressure Conversions:
1 psi (lb/in²) = 6.89476 kPa (exact to 5 decimals)
1 bar = 100 kPa = 14.5038 psi
1 atm (atmosphere) = 101.325 kPa = 14.696 psi
1 MPa = 1000 kPa = 145.038 psi
Common approximations:
1 psi ≈ 6.895 kPa (0.01% error)
1 bar ≈ 14.5 psi (0.03% error)
1 MPa ≈ 145 psi (0.03% error)
Gauge vs Absolute:
psia = psig + 14.7 (at sea level)
kPa(a) = kPa(g) + 101.325
bar(a) = bar(g) + 1.01325
Pressure Conversion Table
| From | To | Multiply By | Example (Pipeline) |
|---|---|---|---|
| psi | kPa | 6.89476 | 1000 psig × 6.895 = 6895 kPa(g) |
| psi | bar | 0.0689476 | 1000 psi × 0.06895 = 68.95 bar |
| psi | MPa | 0.00689476 | 1440 psi × 0.006895 = 9.93 MPa (ANSI 900#) |
| kPa | psi | 0.145038 | 10,000 kPa × 0.145 = 1450 psi |
| bar | psi | 14.5038 | 70 bar × 14.5 = 1015 psi (pipeline MAOP) |
| MPa | psi | 145.038 | 15 MPa × 145 = 2176 psi |
| in H₂O | kPa | 0.248844 | 100 in H₂O × 0.249 = 24.9 kPa (orifice ΔP) |
| mm Hg | kPa | 0.133322 | 760 mm Hg × 0.133 = 101.3 kPa (1 atm) |
Temperature Conversions
Temperature Scale Conversions:
Celsius to Fahrenheit:
°F = (°C × 1.8) + 32
Fahrenheit to Celsius:
°C = (°F - 32) / 1.8
Absolute temperature scales:
K = °C + 273.15
°R = °F + 459.67
Kelvin to Rankine:
°R = K × 1.8
Common reference points:
- Water freezes: 0°C = 32°F = 273.15 K = 491.67°R
- Water boils: 100°C = 212°F = 373.15 K = 671.67°R
- Absolute zero: -273.15°C = -459.67°F = 0 K = 0°R
Example conversions:
60°F = (60 - 32)/1.8 = 15.56°C (standard conditions)
100°C = (100 × 1.8) + 32 = 212°F (boiling water)
Common Temperature Conversions
| °F | °C | K | °R | Typical Application |
|---|---|---|---|---|
| -40 | -40 | 233.15 | 419.67 | Low-temperature gas processing |
| 32 | 0 | 273.15 | 491.67 | Hydrate formation reference |
| 60 | 15.56 | 288.71 | 519.67 | US standard conditions |
| 70 | 21.11 | 294.26 | 529.67 | Typical ambient (design) |
| 100 | 37.78 | 310.93 | 559.67 | Summer pipeline temperature |
| 150 | 65.56 | 338.71 | 609.67 | Compressor discharge (typical) |
| 212 | 100 | 373.15 | 671.67 | Water boiling point (1 atm) |
Absolute vs gauge pressure: Gas law calculations (PV = nRT) require absolute pressure and absolute temperature. Using gauge pressure or relative temperature scales (°C, °F) will produce incorrect results. Always convert to psia/kPa(a) and °R/K for thermodynamic calculations.
Worked Example: Combined Conversion
Problem: Convert pipeline conditions from imperial to metric:
P = 950 psig, T = 80°F
Solution:
Step 1: Convert pressure to absolute
P(psia) = 950 + 14.7 = 964.7 psia
Step 2: Convert to kPa
P(kPa) = 964.7 × 6.89476 = 6,651 kPa(a)
Step 3: Convert temperature to Celsius
T(°C) = (80 - 32) / 1.8 = 26.67°C
Step 4: Convert to Kelvin for gas calculations
T(K) = 26.67 + 273.15 = 299.82 K
Final answer: 6,651 kPa(a), 26.67°C (or 299.82 K for gas law)
4. Flow Rate & Volume Conversions
Flow rate and volume conversions are essential for production reporting, pipeline capacity calculations, and custody transfer.
Volumetric Flow Rate Conversions
Gas Flow Rate Conversions:
1 scf (standard cubic foot) = 0.0283168 Sm³ (standard cubic meter)
1 MMscfd = 1,000,000 scfd = 28,316.8 Sm³/d
1 MMscfd = 1,179.9 Sm³/h = 0.3278 Sm³/s
European notation:
1 Nm³ (normal cubic meter) ≈ 1 Sm³ (standard cubic meter)
(Note: Nm³ at 0°C, 1 atm; Sm³ at 15°C, 1 atm — small difference)
Common conversions:
scfd to Sm³/d: multiply by 0.0283168
MMscfd to Sm³/h: multiply by 1,179.9
Sm³/d to scfd: multiply by 35.3147
Gas Flow Rate Conversion Table
| From | To | Multiply By | Example |
|---|---|---|---|
| scfd | Sm³/d | 0.0283168 | 100,000 scfd × 0.0283 = 2,832 Sm³/d |
| MMscfd | Sm³/d | 28,316.8 | 50 MMscfd × 28,317 = 1,415,840 Sm³/d |
| MMscfd | Sm³/h | 1,179.9 | 10 MMscfd × 1,180 = 11,800 Sm³/h |
| scfm | Sm³/h | 1.699 | 1,000 scfm × 1.699 = 1,699 Sm³/h |
| Sm³/d | scfd | 35.3147 | 10,000 Sm³/d × 35.31 = 353,147 scfd |
| Sm³/h | MMscfd | 0.000847 | 50,000 Sm³/h × 0.000847 = 42.4 MMscfd |
Liquid Flow Rate Conversions
Liquid Flow Rate Conversions:
1 barrel (bbl) = 42 US gallons = 0.158987 m³ = 158.987 liters
1 bbl/d = 0.00658 m³/h
1 gpm (gallon per minute) = 0.227125 m³/h = 3.785 L/min
Common oil/NGL flow rates:
1,000 bbl/d × 0.158987 = 159 m³/d
10,000 bbl/d = 69.4 m³/h = 1,590 m³/d
Condensate production:
100 bbl/MMscf × 1 MMscfd = 100 bbl/d
= 100 × 0.158987 = 15.9 m³/d
= 15.9 m³/d ÷ 28,317 Sm³/d = 0.561 m³/1000 Sm³
Volume Conversions
| From | To | Multiply By | Application |
|---|---|---|---|
| ft³ | m³ | 0.0283168 | Vessel volumes, pipeline inventory |
| barrel (bbl) | m³ | 0.158987 | Oil/NGL storage, production |
| gallon (US) | liter | 3.78541 | Chemical injection, small volumes |
| in³ | cm³ (mL) | 16.3871 | Laboratory samples |
| m³ | ft³ | 35.3147 | Reverse conversion |
| m³ | barrel | 6.28981 | Reverse conversion |
| liter | gallon | 0.264172 | Reverse conversion |
Mass Flow Rate Conversions
Mass Flow Rate:
1 lb/h = 0.000126 kg/s = 0.4536 kg/h
1 ton/h (US) = 2,000 lb/h = 907.2 kg/h
1 tonne/h (metric) = 1,000 kg/h = 2,204.6 lb/h
Example: Compressor throughput
Flow = 100 MMscfd natural gas (SG = 0.65, MW = 18.8)
At standard conditions (60°F, 14.7 psia):
ρ = (14.7 × 18.8) / (10.73 × 519.67) = 0.0496 lb/ft³
Mass flow = 100 × 10⁶ scfd × 0.0496 lb/ft³
= 4,960,000 lb/d = 206,667 lb/h
Convert to kg/h:
206,667 lb/h × 0.4536 kg/lb = 93,744 kg/h = 93.7 tonne/h
Standard conditions matter: Gas flow rates are always referenced to standard conditions, but these differ by region (60°F/14.7 psia in US, 15°C/101.325 kPa in ISO). A 100 MMscfd flow at US standard = 103.6 MMscf at ISO standard due to temperature difference. Always specify which standard is used.
5. Standard Conditions & Unit Consistency
Standard conditions for gas measurement vary by region and industry. Understanding these differences is critical for accurate flow rate reporting and contract compliance.
Standard Condition Definitions
| Standard | Temperature | Pressure | Application |
|---|---|---|---|
| US (API, GPSA) | 60°F (15.56°C) | 14.696 psia (101.325 kPa) | US pipeline contracts, API standards |
| ISO 13443 | 15°C (59°F) | 101.325 kPa (14.696 psia) | International standard, LNG contracts |
| Normal (European) | 0°C (32°F) | 101.325 kPa (14.696 psia) | European pipeline systems |
| CAGI (compressed air) | 68°F (20°C) | 14.5 psia (100 kPa) | Compressed air systems (not natural gas) |
| SPE (petroleum) | 60°F (15.56°C) | 14.65 psia (101 kPa) | Some reservoir engineering applications |
Impact of Standard Condition Differences
Volume Correction Between Standards:
Using ideal gas law: V₁/T₁ = V₂/T₂ (at same pressure)
Convert US standard to ISO standard:
T₁ = 60°F = 519.67°R
T₂ = 15°C = 288.15 K = 518.67°R
V_ISO / V_US = T_ISO / T_US = 518.67 / 519.67 = 0.9981
Therefore: 100 MMscfd (US) = 99.81 MMscfd (ISO)
Convert US standard to Normal (European):
T_normal = 0°C = 273.15 K = 491.67°R
V_normal / V_US = 491.67 / 519.67 = 0.9461
Therefore: 100 MMscfd (US) = 94.61 Nm³/d × 35.31 scf/Sm³
= 3,340 Nm³/d
Wait, this is confusing. Let's restart:
100 MMscfd (US) = 100 × 10⁶ scfd × 0.0283168 Sm³/scf = 2,831,680 Sm³/d at 60°F
Correct to 0°C (Normal):
V_Nm³ = V_Sm³ × (T_normal / T_standard)
V_Nm³ = 2,831,680 × (273.15 / 288.71) = 2,679,400 Nm³/d
Difference: 5.4% lower at 0°C standard vs 15°C standard
Unit Consistency in Calculations
Common pitfalls and how to avoid them:
Example: Orifice Meter Flow Calculation
Given:
ΔP = 100 in H₂O
ρ = 0.045 lb/ft³
d = 3.5 inches
WRONG (mixed units):
Q = √(ΔP / ρ) [This will give nonsense units]
CORRECT (convert all to consistent system):
Imperial approach:
Convert ΔP to psi: 100 in H₂O × 0.03613 psi/in H₂O = 3.613 psi
Keep ρ in lb/ft³: 0.045 lb/ft³
Keep d in inches: 3.5 in
Now use AGA-3 orifice equation with all imperial units.
Metric approach:
Convert ΔP to kPa: 100 in H₂O × 0.2488 kPa/in H₂O = 24.88 kPa
Convert ρ to kg/m³: 0.045 lb/ft³ × 16.0185 kg/m³ per lb/ft³ = 0.721 kg/m³
Convert d to mm: 3.5 in × 25.4 mm/in = 88.9 mm
Now use ISO 5167 orifice equation with all metric units.
Density Conversion Factors
| From | To | Multiply By | Common Value |
|---|---|---|---|
| lb/ft³ | kg/m³ | 16.0185 | Natural gas: 0.05 lb/ft³ = 0.80 kg/m³ |
| lb/gal | kg/L (or SG) | 0.11983 | Water: 8.34 lb/gal = 1.0 kg/L |
| API gravity | SG (specific gravity) | SG = 141.5/(API+131.5) | 40°API oil = 0.825 SG |
| lb/bbl | kg/m³ | 2.8531 | Condensate: 300 lb/bbl = 856 kg/m³ |
Energy Conversions
Energy and Heating Value:
1 Btu = 1.05506 kJ = 0.000293 kWh
1 MMBtu = 1.05506 GJ = 293.1 kWh
1 therm = 100,000 Btu = 105.506 MJ
Gas heating value:
1,000 Btu/scf × 0.0373 MJ/Sm³ per Btu/scf = 37.3 MJ/Sm³
Typical natural gas: 1,030 Btu/scf = 38.4 MJ/Sm³ (HHV)
Energy content of gas volume:
100 MMscfd × 1,030 Btu/scf = 103,000 MMBtu/d = 108,670 GJ/d
Power:
1 HP (horsepower) = 0.7457 kW = 2,545 Btu/h
1 ton refrigeration = 12,000 Btu/h = 3.517 kW
Viscosity Conversions
| From | To | Multiply By | Example |
|---|---|---|---|
| cP (centipoise) | Pa·s | 0.001 | Gas: 0.011 cP = 1.1 × 10⁻⁵ Pa·s |
| lb/(ft·s) | Pa·s | 1.48816 | Oil: 0.001 lb/(ft·s) = 0.00149 Pa·s |
| cSt (centistokes) | m²/s | 1 × 10⁻⁶ | Kinematic: 10 cSt = 1 × 10⁻⁵ m²/s |
Best practice for unit consistency: Create a reference table at the start of each calculation showing all input values in BOTH unit systems. Perform calculation entirely in one system, then convert final result to desired output units. Never mix units mid-calculation — this is the #1 cause of engineering calculation errors.
Common Conversion Mistakes
- Forgetting absolute pressure: Using 1000 psig in gas law instead of 1014.7 psia (1.5% error)
- Mixing °F and °R: Using °F directly in PV = nRT (causes ~65% error at 60°F)
- Confusing scf and cf: Standard cubic feet (scf) at base conditions vs actual cubic feet (acf) at flowing conditions
- Ignoring standard condition differences: Assuming US standard when contract specifies ISO (0.2% error)
- Mass vs force units: Using lbm and lbf interchangeably (requires g_c = 32.174 lb·ft/(lbf·s²) conversion)
- Area conversions: Using linear conversion for area (1 ft = 0.3048 m, but 1 ft² = 0.0929 m², not 0.3048 m²)
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