Example 2: Cylindrical Three Point Bending, Study notes of Geometry

A cylindrical specimen is subjected to a three-point bending test. ... Finally, we must calculate I , the polar moment of inertia, for our rectangular ...

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Example 2: Cylindrical Three Point Bending
A cylindrical specimen is subjected to a three-point bending test. The specimen is 10 centimeters long,
has an inner radius ( ) of 2.5 mm and an outer radius ( ) of 5.0 mm. The specimen is placed on two
supports that are 5 cm apart (L), and the actuator is applying a force in the exact middle of the two
supports (L/2). Immediately before failure, the Instron records a force (F) of 50N, and a deformation of
2mm. We need to determine the maximum flexural strength (σ) and Young’s Modulus (E) of the
specimen.
To accomplish this task, we are going to use the two following equations:
(Eq. 2.1 and 2.2)
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Example 2: Cylindrical Three Point Bending

A cylindrical specimen is subjected to a three-point bending test. The specimen is 10 centimeters long, has an inner radius ( ) of 2.5 mm and an outer radius ( ) of 5.0 mm. The specimen is placed on two supports that are 5 cm apart (L), and the actuator is applying a force in the exact middle of the two supports (L/2). Immediately before failure, the Instron records a force (F) of 50N, and a deformation of 2mm. We need to determine the maximum flexural strength (σ) and Young’s Modulus (E) of the specimen.

To accomplish this task, we are going to use the two following equations:

(Eq. 2.1 and 2.2)

Where M is the moment (or torque) applied at the middle of the specimen, y is the distance from the

center of the specimen to the convex surface, and I is the “polar moment of inertia,” a term used to

define how the geometry of the specimen influences its reaction to loads.

First, we must calculate the reaction forces at the supports. We have two unknown values, and therefore must use two equations to solve the system. Based on static mechanics, we can use the following two equations:

∑ (Eq. 2.3)

and

∑ (^) (Eq. 2.4)

In our case, these equations are as follows:

Or

(Eq. 2.5)

Using the (Eq. 2.4), we find:

∑ ( ) ( )

( ) ( )

Solving for we find:

( )

Substituting the value of 25N for back into (Eq. 2.5), we find:

Therefore