1. Mass Property Analysis
Introduction to Engineering Design
Unit 3 – Lesson 3.3 – Structural Analysis
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2. Mass Property Analysis
Introduction to Engineering Design
Unit 3 – Lesson 3.3 – Structural Analysis
Mass Property Analysis
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3. Mass Property Analysis
Introduction to Engineering Design
Unit 3 – Lesson 3.3 – Structural Analysis
Mass Property Analysis
The size, volume, surface area, and other properties available from a solid model are most often part of the design constraints your design must satisfy.
The following are mass property calculations available in today’s solid modeling programs:
Volume Density Mass
Surface area Centroid Moment of Inertia
Product of Inertia Radii of Gyration Principal Axes
Principal Moments
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4. Mass Property Analysis
Introduction to Engineering Design
Unit 3 – Lesson 3.3 – Structural Analysis
Mass Properties
In this lesson, you will investigate the following mass properties:
Volume
Surface Area
Density
Mass
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5. Mass Property Analysis
Introduction to Engineering Design
Unit 3 – Lesson 3.3 – Structural Analysis
Volume
Volume is the amount of three-dimensional space contained within an object.
Design engineers use volume to determine the amount of material needed to produce a part.
Different formulas for different shapes 8 4
Rectangular Prism
The teacher may want to supplement student knowledge about the use of formulas and related mathematical properties using variables.
V = H x W x L
V = 4” x 4” x 8”
V = 128 in3
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6. Mass Property Analysis
Introduction to Engineering Design
Unit 3 – Lesson 3.3 – Structural Analysis
Volume in Cubic Units
Measure volume using cubic units:
Cubic inches (in3)
Cubic feet (ft3)
Cubic yards (yds3)
Cubic centimeters (cm3)
Cubic meters (m3)
It is imperative to keep your units the same when measuring and calculating volume.
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7. Volume Formulas for Prisms, Cylinders, Pyramids, or Cones
Mass Property Analysis
Introduction to Engineering Design
Unit 3 – Lesson 3.3 – Structural Analysis
Volume Formulas for Prisms, Cylinders, Pyramids, or Cones
If B is the area of the base of a prism, cylinder, pyramid, or cone and H is the height of the solid, then the formula for the volume is
V = BH
Note: You will need to calculate the area of the shape for the base of the prism. For example: If the solid is a triangular prism, then you will need to calculate the area of the triangle for the base and then calculate the volume.
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8. Area Formulas for Bases of Prisms, Cylinders, and Pyramids
Mass Property Analysis
Introduction to Engineering Design
Unit 3 – Lesson 3.3 – Structural Analysis
Area Formulas for Bases of Prisms, Cylinders, and Pyramids
Rectangular Prism – base is rectangle, therefore A = length * width or A = lw
Cylinder – base is a circle, therefore A = pi * radius of circle squared or A = πr2
Square Pyramid – base is a square, therefore A = length * width or A = lw or side squared since the sides are the same on a square or A = s2.
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9. Volume of a Cone A Special Case
Mass Property Analysis
Introduction to Engineering Design
Unit 3 – Lesson 3.3 – Structural Analysis
Volume of a Cone A Special Case
A cone is 1/3 of a cylinder.
The base of a cylinder is a circle.
The area of a circle is A=πr2
Therefore, the formula for the volume of a cone is
V= 1/3Ah
where A=πr2 and h is the height of the cone.
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10. Mass Property Analysis
Introduction to Engineering Design
Unit 3 – Lesson 3.3 – Structural Analysis
Density
Density is defined as mass per unit volume.
Density is different for every material and can be found in a machinist handbook.
Density is always provided, either by looking in a machinist handbook or from tables provided in 3D modeling software.
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11. Mass Property Analysis
Introduction to Engineering Design
Unit 3 – Lesson 3.3 – Structural Analysis
Mass
Mass is the amount of matter in an object or the quantity of the inertia of the object.
Many materials are purchased by weight; to find weight, you need to know the mass.
Polypropylene has a density of .035 lbs/in3
and
Mass = Volume x Density
Explain to students that the units for the inches cubed are cancelled out through division; since there are inches cubed in the numerator and inches cubed in the denominator they equal one. One times pounds leaves pounds.
Mass = 128 in3 x .035 lbs/in3
Mass = 4.48 lbs
Using the volume from the previous example: V = 128 in3
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12. Mass Property Analysis
Introduction to Engineering Design
Unit 3 – Lesson 3.3 – Structural Analysis
Surface Area
Surface area is the squared
dimensions of the exterior surface.
Surface area is important when determining coatings and heat transfer of a part.
A= 4in x 4in = 16 in2
B= 4in x 8in = 32 in2
C= 4in x 8in = 32 in2
D= 4in x 8in = 32 in2
E= 4in x 8in = 32 in2
F= 4in x 4in = 16 in2 B C D E F A
A + B+ C + D+ E + F = 160 in2
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13. Mass Property Analysis
Introduction to Engineering Design
Unit 3 – Lesson 3.3 – Structural Analysis
To start the Mass Property function, right click the solid model name in the Browser.
Pick Properties
Mass Property values will be used for predicting material quantity needed for production, finishing, packaging and shipping.
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14. Additional Mass Properties
Mass Property Analysis
Introduction to Engineering Design
Unit 3 – Lesson 3.3 – Structural Analysis
Additional Mass Properties
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15. Mass Property Analysis
Introduction to Engineering Design
Unit 3 – Lesson 3.3 – Structural Analysis
Centroid
A 3D point defining the
geometric center of a solid.
Do not confuse centroid with the center of gravity.
The two only exist at the same 3D point when the part has uniform geometry and density.
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16. Mass Property Analysis
Introduction to Engineering Design
Unit 3 – Lesson 3.3 – Structural Analysis
Moments of Inertia
An object’s opposition
to changing its motion about an axis.
This property is most often used when calculating the deflection of beams.
= Integral (Calculus)
I = Moments of Inertia
r = Distance of all points in an element from the axis
p = Density of the material
dV= Division of the entire body into small volume units.
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17. Mass Property Analysis
Introduction to Engineering Design
Unit 3 – Lesson 3.3 – Structural Analysis
Products of Inertia
Is similar to moments of inertia only that products of inertia are relative to two axes instead of one.
You will notice an XY, YZ, or ZX after the I symbol when defining products of inertia compared to moments of inertia.
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18. Mass Property Analysis
Introduction to Engineering Design
Unit 3 – Lesson 3.3 – Structural Analysis
Radii of Gyration
A dimension from the axis
where all mass is concentrated,
and will produce the same
moment of inertia.
K = Radius of gyration about an axis
M = Mass
I = Moments of inertia
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19. Mass Property Analysis
Principal Axes
Mass Property Analysis
Introduction to Engineering Design
Unit 3 – Lesson 3.3 – Structural Analysis
The lines of intersection
created from three mutually
perpendicular planes, with the three planes’ point of intersection at the centroid of the part.
The X, Y, and Z axes show the principal axes of the ellipsoid.
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20. Mass Property Analysis
Introduction to Engineering Design
Unit 3 – Lesson 3.3 – Structural Analysis
Principal Moments
Principal moments are the moments of inertia related to the principal axes of the part.
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21. Mass Property Analysis
Introduction to Engineering Design
Unit 3 – Lesson 3.3 – Structural Analysis
Sources
Brodinski, K. G. (1989). Engineering materials properties and selection. Prentice Hall, Inc., ISBN
Budinski, K. G. (1992). Engineering materials, 4th Edition. Prentice Hall, Inc., ISBN
Gere, J. M., & Timoshenko, S. P. (1997). Mechanics of materials, PWS Publishing Company, ISBN
Lockhart, S. D., & Johnson, C. M. (1999). Engineering design communication: Conveying design through graphics, Preliminary Edition, Addison Wesley Longman, Inc., ISBN
Madsen, D. A., Shumaker, T. M., Turpin, J. L., & Stark, C. (1994). Engineering design and drawing, 2nd Edition, Delmar Publishers Inc., ISBN
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