Convert dynamic viscosity units — Pascal-second, Poise, centipoise, lb/(ft·s) and more.
| Unit | Name | Value |
|---|---|---|
| Pa·s | Pascal-second | 1 |
| P | Poise | 10 |
| cP | Centipoise | 1000 |
| lb/(ft·s) | Pound/(Foot·Second) | 0.67197076 |
| mPa·s | Millipascal-second | 1000 |
Formula: lb/(ft·s) = kg/(m·s) × 0.672
Multiply any kg/(m·s) value by 0.672 to get lb/(ft·s).
Reverse: kg/(m·s) = lb/(ft·s) × 1.488
Water reference (20°C): 0.001002 kg/(m·s) = 0.0006733 lb/(ft·s)
Values at ~20°C unless noted. Factor: 1 kg/(m·s) = 0.672 lb/(ft·s)
| kg/(m·s) (kg/(m·s)) | lb/(ft·s) (lb/(ft·s)) | Fluid |
|---|---|---|
| 1.800e-05 kg/(m·s) | 1.210e-05 lb/(ft·s) | Air (20°C) |
| 0.001002 kg/(m·s) | 0.0006733 lb/(ft·s) | Water (20°C) |
| 0.0012 kg/(m·s) | 0.0008064 lb/(ft·s) | Ethanol |
| 0.0035 kg/(m·s) | 0.002352 lb/(ft·s) | Blood (37°C) |
| 0.065 kg/(m·s) | 0.04368 lb/(ft·s) | SAE 10W motor oil |
| 0.084 kg/(m·s) | 0.05645 lb/(ft·s) | Olive oil |
| 0.2 kg/(m·s) | 0.1344 lb/(ft·s) | Maple syrup |
| 0.3 kg/(m·s) | 0.2016 lb/(ft·s) | SAE 30 motor oil |
| 5 kg/(m·s) | 3.36 lb/(ft·s) | Honey |
| 50 kg/(m·s) | 33.6 lb/(ft·s) | Ketchup |
| 100 kg/(m·s) | 67.2 lb/(ft·s) | Molten glass (700°C) |
| 250 kg/(m·s) | 168 lb/(ft·s) | Peanut butter |
| 3e+04 kg/(m·s) | 2.016e+04 lb/(ft·s) | Tar (room temp) |
| 2.3e+08 kg/(m·s) | 1.546e+08 lb/(ft·s) | Pitch (20°C) |
1 kg/(m·s) = 0.672 lb/(ft·s).
Water at 20°C ≈ 1 cP = 1 mPa·s = 0.001 Pa·s = 0.01 P. Use as reference.
Multiply result by 1.488 to recover the original kg/(m·s) value.
Specifies oil viscosity in cP or mPa·s for formulation and quality control of lubricants.
Uses Pa·s and cP for pipeline flow calculations, pump design, and mixing operations.
Measures sauce, syrup, and dough viscosity in cP for texture optimization and process control.
Controls drug formulation viscosity in mPa·s for injectables, topical creams, and oral suspensions.
Specifies paint, ink, and adhesive viscosity in cP for application equipment compatibility.
Characterizes polymer melt viscosity in Pa·s for extrusion and injection molding process design.
Kilogram per meter per second (kg/(m·s)) is numerically identical to the pascal-second (Pa·s), since 1 Pa·s = 1 N·s/m² = 1 kg/(m·s). Both express the same physical quantity. Some older engineering texts prefer kg/(m·s) to make the dimensional analysis explicit.
kg/(m·s) appears in some fluid mechanics textbooks and engineering reference tables, particularly older European texts. The equivalence Pa·s = kg/(m·s) is exact — they are the same unit expressed with different dimensional notation.
Interesting fact: The equivalence Pa·s = kg/(m·s) can be derived dimensionally: Pa = kg/(m·s²), so Pa·s = kg/(m·s). This makes dynamic viscosity dimensionally the same as linear momentum density — an elegant connection in continuum mechanics.
Pound per foot per second (lb/(ft·s)) is the Imperial dynamic viscosity unit, equal to 1.48816 Pa·s. It is rarely used in modern practice but appears in older US engineering handbooks and some aerospace fluid specifications in the foot-pound-second system.
Water at 20°C ≈ 0.000672 lb/(ft·s). Air at 20°C ≈ 1.21×10⁻⁵ lb/(ft·s). The poundal-second per square foot (pdl·s/ft²) is sometimes confused with lb/(ft·s) — they differ by a factor of 32.174 (g). Most US engineering now uses cP even in Imperial contexts.
Interesting fact: Viscosity in Imperial units involves multiple conventions that confuse even experienced engineers. The slug/(ft·s) = 47.88 Pa·s is the viscosity unit consistent with pound-force; lb/(ft·s) uses pound-mass. These give numerically different values for the same fluid.
Dynamic viscosity measures a fluid's resistance to flow. The SI unit is Pa·s (= kg/(m·s)); cP and mPa·s are numerically identical and most widely used; P (Poise) is the CGS unit. Key anchor: water at 20°C ≈ 1 cP = 1 mPa·s = 0.001 Pa·s = 0.01 P.
Exact factor: 1 kg/(m·s) = 0.672 lb/(ft·s). Reverse: 1 lb/(ft·s) = 1.488 kg/(m·s).
All conversions use IEEE 754 double-precision arithmetic, accurate to at least 8 significant figures.