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Convert Kilogram-meters squared to Slug-feet squared

Instantly convert Kilogram-meters squared (kg·m²) to Slug-feet squared (slug·ft²) with our free online calculator.

Reviewed by Christopher FloiedUpdated

Formula: kg·m² to slug·ft²multiply by 0.737561

Reference Table

Kilogram-meters squared (kg·m²)Slug-feet squared (slug·ft²)
10.737561
53.68781
107.37561
2518.439
5036.8781
10073.7561

How to Convert Kilogram-meters squared to Slug-feet squared

Formula

To convert Kilogram-meters squared (kg·m²) to Slug-feet squared (slug·ft²): multiply by 0.737561

Step-by-Step

  1. Start with your value in Kilogram-meters squared (kg·m²).
  2. Multiply by 0.737561 to perform the conversion.
  3. The result is your value expressed in Slug-feet squared (slug·ft²).

Conversion Factor

1 kg·m² = 0.737561 slug·ft²

Reverse Factor

1 slug·ft² = 1.35582 kg·m²

Worked Example

Convert 25 Kilogram-meters squared to Slug-feet squared: 25 kg·m² = 18.439 slug·ft²

About Kilogram-meter squared (kg·m²)

The SI unit of mass moment of inertia (ISO 80000-4 §4-12) — the rotational analog of mass, measuring a rigid body's resistance to angular acceleration about a specified axis (τ = I·α, the rotational form of Newton's second law). kg·m² is the universal working unit in rotational dynamics, flywheel-energy-storage design, gyroscope analysis, spacecraft attitude-control system (ACS) design, automotive driveline modeling (engine + clutch + transmission + driveshafts inertias propagated through gear ratios), and CAD/CAE mass-properties output (Autodesk Inventor, SolidWorks, CATIA, NX all compute Ixx/Iyy/Izz and the off-diagonal cross-products in kg·m²). Reference values: a typical 1-meter-radius solid steel cylinder of 100 kg ≈ 50 kg·m²; a figure skater's body mass moment of inertia changes from ~8 kg·m² (arms extended) to ~2 kg·m² (arms tucked tight) demonstrating angular-momentum conservation as spin rate increases ~4× when tucked; the International Space Station has ~10⁸ kg·m² principal-axis inertia. Convert kg·m² to lb·ft² by multiplying by 23.730; to slug·ft² by multiplying by 0.7376.

About Slug-foot squared (slug·ft²)

A US aerospace mass-moment-of-inertia unit (1 slug·ft² ≈ 1.35582 kg·m² per NIST SP 811). Because US aerospace engineers keep Newton's second law F = m·a (and its rotational analog τ = I·α) dimensionally consistent in imperial units without inserting a gravitational-constant factor gc by using slugs as the mass unit, aircraft and missile inertia properties are reported in slug·ft² in flight-dynamics textbooks (Etkin & Reid, Stevens-Lewis-Johnson, Roskam), stability derivative tables, simulation data decks (FlightGear, X-Plane, MATLAB Aerospace Toolbox), and FAR Part 25 transport-category aircraft type-certificate data sheets. Reference values: Boeing 737 roll inertia Ixx ≈ 1.8 × 10⁶ slug·ft²; pitch inertia Iyy ≈ 1.3 × 10⁷ slug·ft²; yaw inertia Izz ≈ 1.5 × 10⁷ slug·ft². Cessna 172 Ixx ≈ 1,285 slug·ft². Convert slug·ft² to kg·m² by multiplying by 1.3558.

Quick Facts

  • 1 Kilogram-meter squared equals 0.737561 Slug-feet squared
  • 1 Slug-foot squared equals 1.35582 Kilogram-meters squared
  • Kilogram-meter squared is a unit of mass moment of inertia
  • Slug-foot squared is a unit of mass moment of inertia
  • This conversion is commonly used in rotational dynamics, flywheel design, and robotics
  • The Kilogram-meter squared belongs to the metric system
  • The Slug-foot squared belongs to the imperial system

Common Kilogram-meter squared to Slug-foot squared Conversions

Kilogram-meters squared (kg·m²)Slug-feet squared (slug·ft²)
0.010.00737561
0.10.0737561
0.250.18439
0.50.368781
10.737561
21.47512
32.21268
53.68781
107.37561
1511.0634
2014.7512
2518.439
5036.8781
7555.3171
10073.7561
250184.39
500368.781
1000737.561
50003687.81
100007375.61

Understanding Kilogram-meters squared

The Kilogram-meter squared (symbol: kg·m²) is a unit of mass moment of inertia. The SI unit of mass moment of inertia (ISO 80000-4 §4-12) — the rotational analog of mass, measuring a rigid body's resistance to angular acceleration about a specified axis (τ = I·α, the rotational form of Newton's second law). kg·m² is the universal working unit in rotational dynamics, flywheel-energy-storage design, gyroscope analysis, spacecraft attitude-control system (ACS) design, automotive driveline modeling (engine + clutch + transmission + driveshafts inertias propagated through gear ratios), and CAD/CAE mass-properties output (Autodesk Inventor, SolidWorks, CATIA, NX all compute Ixx/Iyy/Izz and the off-diagonal cross-products in kg·m²). Reference values: a typical 1-meter-radius solid steel cylinder of 100 kg ≈ 50 kg·m²; a figure skater's body mass moment of inertia changes from ~8 kg·m² (arms extended) to ~2 kg·m² (arms tucked tight) demonstrating angular-momentum conservation as spin rate increases ~4× when tucked; the International Space Station has ~10⁸ kg·m² principal-axis inertia. Convert kg·m² to lb·ft² by multiplying by 23.730; to slug·ft² by multiplying by 0.7376.

It belongs to the metric measurement system.

Kilogram-meters squared are commonly used in rotational dynamics, flywheel design, and robotics.

Understanding Slug-feet squared

The Slug-foot squared (symbol: slug·ft²) is a unit of mass moment of inertia. A US aerospace mass-moment-of-inertia unit (1 slug·ft² ≈ 1.35582 kg·m² per NIST SP 811). Because US aerospace engineers keep Newton's second law F = m·a (and its rotational analog τ = I·α) dimensionally consistent in imperial units without inserting a gravitational-constant factor gc by using slugs as the mass unit, aircraft and missile inertia properties are reported in slug·ft² in flight-dynamics textbooks (Etkin & Reid, Stevens-Lewis-Johnson, Roskam), stability derivative tables, simulation data decks (FlightGear, X-Plane, MATLAB Aerospace Toolbox), and FAR Part 25 transport-category aircraft type-certificate data sheets. Reference values: Boeing 737 roll inertia Ixx ≈ 1.8 × 10⁶ slug·ft²; pitch inertia Iyy ≈ 1.3 × 10⁷ slug·ft²; yaw inertia Izz ≈ 1.5 × 10⁷ slug·ft². Cessna 172 Ixx ≈ 1,285 slug·ft². Convert slug·ft² to kg·m² by multiplying by 1.3558.

It belongs to the imperial measurement system.

Slug-feet squared are commonly used in rotational dynamics, flywheel design, and robotics.

Why Convert Kilogram-meters squared to Slug-feet squared?

Converting between Kilogram-meters squared and Slug-feet squared is a frequent requirement for engineers, scientists, and students working with mass moment of inertia values. Different industries and regions favour different unit systems, so having a dependable conversion tool saves time and prevents errors in technical calculations. Whether you are verifying a specification sheet, cross-checking simulation results, or preparing a report for an international audience, accurate mass moment of inertia conversion is essential.

Frequently Asked Questions

How do I convert Kilogram-meters squared to Slug-feet squared?

The SI unit of mass moment of inertia (ISO 80000-4 §4-12) — the rotational analog of mass, measuring a rigid body's resistance to angular acceleration about a specified axis (τ = I·α, the rotational form of Newton's seco... To convert Kilogram-meters squared to Slug-feet squared, multiply by 0.737561. For example, 25 kg·m² equals 18.439 slug·ft².

How many Slug-feet squared are in 1 Kilogram-meter squared?

There are 0.737561 Slug-feet squared in 1 Kilogram-meter squared.

How many Kilogram-meters squared are in 1 Slug-foot squared?

There are 1.35582 Kilogram-meters squared in 1 Slug-foot squared.

What is the formula for Kilogram-meter squared to Slug-foot squared conversion?

The formula is: multiply by 0.737561. This means 1 kg·m² = 0.737561 slug·ft².

Is a Kilogram-meter squared bigger than a Slug-foot squared?

Yes. One Kilogram-meter squared is larger than one Slug-foot squared because 1 kg·m² equals 0.737561 slug·ft², which is less than 1.

When do you need to convert between Kilogram-meters squared and Slug-feet squared?

A US aerospace mass-moment-of-inertia unit (1 slug·ft² ≈ 1. Kilogram-meter squared and Slug-foot squared are both mass moment units, so conversion comes up whenever one source of information uses one unit and another uses the other — a classic cross-reference challenge in engineering, trade, travel, and everyday life.

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