Kilogram-force
The kilogram-force (symbol: kgf) is a gravitational metric unit of force equal to the magnitude of the force exerted by standard gravity on a mass of one kilogram, precisely 9.80665 newtons (N).[1][2] This definition relies on the conventional value of standard gravity (gn = 9.80665 m/s²), established by the 3rd General Conference on Weights and Measures (CGPM) in 1901 for use in metric technical units.[3][1] Also known as the kilopond (symbol: kp), from the Latin pondus meaning weight, the kilogram-force originated in the 19th-century metric system as part of the technical or gravitational variant, where force was expressed in terms of mass units multiplied by gravity.[1] It is a non-SI unit and is not recommended for new scientific or technical work, as the International System of Units (SI) designates the newton—defined as the force required to accelerate one kilogram at one meter per second squared—as the coherent unit of force.[4][1] Despite this, the kilogram-force persists in legacy engineering applications, such as load calibration, mechanical design, and standards in civil and automotive sectors, especially in countries like Japan and Germany where metric gravitational units were historically prevalent.[2][5] In terms of other units, one kilogram-force is approximately equal to 2.20462 pound-force (lbf), derived from the conversions 1 kgf = 9.80665 N and 1 lbf = 4.4482216152605 N.[1] Smaller subunits include the gram-force (gf = 1/1000 kgf ≈ 0.00980665 N) and milligram-force (mgf = 1/1000000 kgf ≈ 9.80665 × 10−6 N).[1] The unit's deprecation stems from efforts to standardize measurements globally under the SI since the 1960s, promoting consistency by avoiding implicit assumptions about gravitational acceleration.[4]Definition and Fundamentals
Numerical Value
The kilogram-force (kgf) is defined as the force equal to the gravitational attraction exerted by the Earth on a mass of one kilogram under standard gravity conditions.[6] This unit represents the amount of force produced when a 1 kg mass experiences the standard acceleration due to gravity, denoted as g_n.[6] Standard gravity g_n is precisely defined as 9.80665 m/s², an exact value adopted for metrological consistency.[7] Consequently, 1 kgf equals exactly 9.80665 newtons (N), where the newton is the SI unit of force.[6] This numerical value for standard gravity was established by international agreement at the 3rd General Conference on Weights and Measures (CGPM) in 1901, which adopted 980.665 cm/s² (equivalent to 9.80665 m/s²) as the conventional reference for the International Service of Weights and Measures.[3] The magnitude arises from the fundamental relation F = m \times g, where F is the force in kgf, m = 1 kg is the mass (the SI base unit), and g = g_n = 9.80665 m/s² is the standard gravitational acceleration.[6]Relation to Mass and Acceleration
The kilogram-force is fundamentally related to mass and acceleration through Newton's second law of motion, F = ma, where force F is in newtons, mass m is in kilograms, and acceleration a is in meters per second squared. In the case of the kgf, the acceleration is taken as the standard gravity g_n = 9.80665 m/s² with a mass of 1 kg, yielding $1 kgf = 1 kg \times 9.80665 m/s² = 9.80665 N. This definition links the unit to the gravitational acceleration at Earth's surface under conventional conditions, distinguishing it from the SI newton, which assumes an acceleration of 1 m/s².[6]Historical Development
Origins in the Metric System
The kilogram-force emerged in the 19th century amid French efforts to develop coherent units for mechanics following the Revolution of 1789, when the National Assembly tasked scientists with creating a decimal-based system to replace disparate regional measures. This initiative, formalized by 1795, defined the kilogram as the mass of one cubic decimeter of water at its maximum density, laying the foundation for derived units including force as the gravitational attraction on that mass. The kilogram-force thus represented the weight of one kilogram under Earth's gravity, aligning with the metric system's goal of universality and simplicity in scientific and engineering contexts.[8] Closely linked to the gram-force—the weight of one gram of mass—this smaller unit served as the conceptual precursor, but the kilogram-force was scaled up for practicality in handling larger mechanical loads, such as in construction and machinery design. The gram-force, integral to early metric mechanics, facilitated precise calculations in smaller-scale applications, while the kilogram variant addressed the limitations of tiny numerical values in everyday engineering tasks.[9] The unit also reflected influences from contemporaneous European metrology, notably the pond, a German-designated equivalent to the gram-force and thus one-thousandth of a kilogram-force, which gained traction in cross-border scientific exchanges during the metric system's expansion.[10] This integration helped harmonize force measurements across continental engineering practices.[11] A pivotal development occurred in French metrology between 1795 and the early 1800s, paralleling the crafting of the kilogram prototype in 1799, which was deposited in the National Archives as the "Kilogram of the Archives." This artifact not only standardized mass but also enabled the practical conceptualization of force units like the kilogram-force within the burgeoning metric framework.[12]Standardization and Deprecation
The 3rd General Conference on Weights and Measures (CGPM) in 1901 formally defined the kilogram-force as the gravitational force acting on one kilogram of mass at standard gravity, establishing the standard acceleration due to gravity as exactly 980.665 cm/s² (or 9.80665 m/s²), thereby tying 1 kgf to exactly 9.80665 newtons.[3] This unit gained widespread adoption in mechanical engineering, aviation, and technical standards across metric-using countries during the early to mid-20th century, serving as a practical measure of force in contexts where gravitational weight was a common reference.[13] The 9th CGPM in 1948 adopted the name "newton" for the metre-kilogram-second (MKS) unit of force, defined as the force imparting an acceleration of 1 m/s² to a 1 kg mass, marking an initial shift toward coherent units.[13] The 11th CGPM in 1960 then established the International System of Units (SI), designating the newton as the official SI derived unit for force and promoting its exclusive use in scientific and technical applications, while the kilogram-force was retained only in legacy engineering practices but deemed non-preferred for new developments.[14] Subsequent resolutions, including those from the 1948 CGPM on metric unit rationalization, accelerated the transition, with national metrology bodies in the 1970s—such as those in Europe and Japan—mandating SI adoption in industry standards, significantly diminishing the kilogram-force's prominence in favor of the newton.[15] The current SI Brochure classifies the kilogram-force as an obsolete non-SI unit, permissible in limited technical fields like certain pressure gauges but strongly discouraged for general use to maintain coherence with SI principles.[16]Usage and Applications
Engineering and Everyday Contexts
In mechanical engineering, the kilogram-force (kgf) remains a practical unit for specifying loads in components such as springs and presses, where it directly relates force to familiar mass equivalents under standard gravity. For instance, spring designs often calculate load capacities in kgf to ensure deflection and stress limits align with gravitational expectations in assembly processes.[17] In automotive applications, kgf is commonly applied to bolt torque specifications, expressed as kgf·m, to standardize tightening forces for parts like engine mounts and chassis assemblies, facilitating consistent performance in manufacturing.[18] Everyday applications of kgf appear in devices that measure weight intuitively through mass references, such as mechanical food scales that register force in kgf equivalents for portioning ingredients. In fitness settings, gym weights labeled in kilograms—such as "lifting 100 kg"—typically imply 100 kgf, representing the gravitational force exerted by that mass, which aids users in tracking strength without needing force calculations. Household tools like manual torque wrenches also employ kgf·cm scales for tasks such as bicycle repairs or furniture assembly, providing accessible measurements for non-professionals. The persistence of kgf stems from its intuitive connection to the kilogram as a mass unit, allowing quick mental approximations of force in gravitational contexts without converting to newtons, which is particularly beneficial in regions with longstanding metric traditions. This ease makes it suitable for technicians and consumers who prioritize practicality over strict SI compliance. Regionally, kgf sees greater adoption in Asian manufacturing hubs like Japan and China, where historical metric conventions in engineering and tooling sustain its use despite official SI preferences; for example, Japanese automotive specifications often include kgf·m alongside newtons. In contrast, SI-strict nations like the United States favor newtons or pound-force in professional engineering, limiting kgf to legacy or informal contexts.[19]Comparison with Other Non-SI Units
The kilogram-force (kgf) is a gravitational unit of force defined as the force exerted by standard gravity on one kilogram of mass, equivalent to exactly 9.80665 newtons.[1] In comparison, the pound-force (lbf) is the corresponding imperial unit, defined as the force exerted by standard gravity on one avoirdupois pound (approximately 0.45359237 kilograms) of mass, equivalent to approximately 4.448222 newtons.[1] One kilogram-force is thus approximately equal to 2.20462262 pound-forces, a conversion factor derived from the ratio of their defining masses under the same standard acceleration due to gravity (9.80665 m/s²).[1] Both units approximate local gravitational effects but are standardized to this exact value to ensure consistency, though the lbf's base in the non-decimal pound introduces additional conversion complexities when interfacing with metric measurements.[20] The kilopond (kp), also known as the kilogram-force in some contexts, is an exact synonym for the kgf and shares its definition as the gravitational force on one kilogram at standard gravity.[1] Originating from German engineering terminology ("Pond" denoting weight), it equals 9.80665 newtons and is used interchangeably with kgf in technical literature from German-speaking regions, such as in mechanical design and materials testing.[1] The technical atmosphere (at) is a non-SI pressure unit defined as exactly one kilogram-force per square centimeter, linking force to pressure through area and equating to 9.80665 kgf distributed over 1 cm², or 98,066.5 pascals.[21] This unit facilitates comparisons in engineering contexts where pressure is expressed in terms of gravitational force per unit area, such as in hydraulics or boiler specifications, but requires specification of the area to derive an equivalent total force in kgf.[21]| Unit | Equivalent to kgf | Base Definition | SI Equivalent |
|---|---|---|---|
| Pound-force (lbf) | ≈ 0.45359237 kgf | Force on 1 lb mass at standard gravity | 4.448222 N |
| Kilopond (kp) | 1 kgf exactly | Synonym for kgf; force on 1 kg at standard gravity | 9.80665 N |
| Technical atmosphere (at) | 9.80665 kgf per cm² (pressure basis) | 1 kgf/cm² at standard gravity | 98,066.5 Pa (pressure) |
Conversions and Equivalents
To SI Units
The kilogram-force (kgf) is defined such that one kilogram-force is exactly equal to 9.80665 newtons (N), the SI unit of force.[1] This exact conversion arises from the definition of the kilogram-force as the force exerted by standard gravity on a mass of one kilogram.[3] Conversely, one newton is equal to $1/9.80665 kgf, which is approximately 0.101972 kgf.[1] Derived units follow directly from this primary conversion. For energy or work, one kilogram-force meter (kgf·m) equals exactly 9.80665 joules (J), since $1 \, \mathrm{J} = 1 \, \mathrm{N \cdot m}.[1] For pressure, one kilogram-force per square meter (kgf/m²) equals exactly 9.80665 pascals (Pa), since $1 \, \mathrm{Pa} = 1 \, \mathrm{N/m^2}.[1] This exact value of 9.80665 stems from the 1901 General Conference on Weights and Measures (CGPM), which adopted a standard acceleration due to gravity of 980.665 cm/s² (or 9.80665 m/s²) to distinguish mass from weight in the metric system.[3]Practical Calculations and Examples
In practical applications, the kilogram-force (kgf) is often converted to SI units for precise engineering computations, such as determining the equivalent force in newtons for structural analysis. For instance, to convert a load of 50 kgf to newtons, multiply by the standard conversion factor of 9.80665 N/kgf:$50 \times 9.80665 = 490.3325 \, \mathrm{N}.
This calculation is essential in scenarios like evaluating the weight of machinery components under standard gravity.[1] Another common use involves torque calculations in mechanical systems, where a force applied at a distance from a pivot point produces rotational effect. Consider a 10 kgf force applied perpendicularly at a radius of 0.5 m; first convert the force to newtons (10 × 9.80665 = 98.0665 N), then compute torque as force times lever arm:
\tau = 98.0665 \times 0.5 = 49.03325 \, \mathrm{N \cdot m} \approx 49.033 \, \mathrm{J}.
Such computations are typical in designing levers or engine components.[1] In pressure measurements, particularly in hydraulics or material testing, kgf is applied over an area to find equivalent pascals. For 1 kgf distributed over 1 cm² (area = 10^{-4} m²), the pressure is the force in newtons divided by area:
P = \frac{9.80665}{10^{-4}} = 9.80665 \times 10^{4} \, \mathrm{Pa}.
This unit, known as kgf/cm², remains in use for tire pressures or boiler specifications in some industries.[1] For quick estimates in field work or preliminary designs, the conversion factor is often approximated as 9.81 N/kgf, rounding the standard gravity value of 9.80665 m/s² to two decimal places, which introduces negligible error for most non-precision tasks.[1]