2093. Using the ""Moment of Inertia Method"" to Determine Product of Inertia

Title2093. Using the ""Moment of Inertia Method"" to Determine Product of Inertia
Publication TypeConference Paper
Paper Number2093
Year of Publication1992
AuthorsWiener, K., and Boynton Richard S.
Conference51st Annual Conference, Hartford, Connecticut, May 18-20
Conference LocationHartford, Connnecticut
PublisherSociety of Allied Weight Engineers, Inc.
Date Published5/18/92
Abstract

Product of inertia is generally measured using a spin balance machine. In this type of machine, the object is rotated at a speed of about 100 RPM, and the reaction forces against the upper and lower spindle bearings are measured. Product of inertia is then calculated automatically by the machine's on line computer, using formulas that involve the vertical spacing between the upper and lower bearings and the height of the object above the mounting surface of the machine. Objects such as control fins and satellites with extended solar panels cannot be measured using this method because of the large, non-repeatable errors which are introduced by the entrained and entrapped air and turbulence. This paper outlines a method of determining product of inertia by making a series of moment of inertia measurements with the object oriented in six different positions. Product of inertia can then be calculated using formulas which involve the rotation angles of the different fixture positions. Moment of inertia is measured by oscillating the object on a torsion pendulum. Since the object moves very slowly during this measurement, there are negligible centrifugal and windage forces exerted on the object Furthermore, the mass of the entrapped and entrained air can be compensated for by making a second set of measurements in helium and extrapolating the data to predict the mass properties in a vacuum. This paper gives step-by-step instructions on how to measure product of inertia on a torsion pendulum. Special fixtures must be constructed to move the object to the six positions while keeping both the object and the fixture CG near the center of oscillation. We have included design details of such a fixture. Since vacuum data was required, measurements were made in a chamber which could be filled with helium. The design of this chamber is also explained in detail. To illustrate this method, we have used as an example real measurements which were made of airfoil control fins manufactured by one of our customers. For this example, we determined all mass properties: weight, center of gravity along three axes, moment of inertia about three axes, and product of inertia in three planes, all referred to vacuum conditions.

Pages27
Key Words06. Inertia Measurements
Order this Paperhttp://www.sawe.org/store/product_info.php?products_id=45649
Price

Non-Member Price: $17.01. Members may download this paper for free. Click here. (Login Required. See SAWE Frequently Asked Questions.)

Register