INERTIA MEASUREMENT DEVICE

Abstract

This invention relates to devices used to measure the mass moment of inertia (MOI) of physical objects. Embodiments of this invention provide a compact device that is easy to use and adjustable to broaden the range of physical object sizes/MOIs that would not otherwise be measurable with a single nonadjustable device. The device protects certain components from being disturbed or damaged by the user by means of permanent attachment or affixment to the device, while still allowing the adjustability noted. While some parts, such as one or more auxiliary platters, must be fully attached and detached for the purpose of adjustment, other components of this specific invention remain permanently attached to the device to avoid loss or damage while still allowing them to be engaged/connected or disengage/disconnected for adjustment purposes.

Claims

1. An inertia measurement device that facilitates periodic angular oscillatory motion of an object comprising: a. a base having three or more legs; b. a rotor comprising a shaft, a primary platter, and a top surface that rotates about an axis; c. a bearing affixed to the base and intermediate the base and the shaft; d. a pair of primary helical springs each permanently attached at one end to the base and at the other end to a cord, the cord communicating between each helical spring and the shaft and wrapping at least partially around a cord guide on the shaft; e. a noncontact sensor affixed to the base in a permanent way for observing angular motion of the rotor; and f. a means for displaying information to a user.

2. The device of claim 1, further comprising one or more pair of auxiliary-spring sets permanently attached at one end to the base and connected at their other ends to a means to connect to and disconnect from the cord, where each auxiliary-spring set of each pair of auxiliary-spring sets when connected to the cord works in parallel with the respective primary helical spring.

3. The device of claim 2 in which the base further comprises a bottom bearing affixed to the base and intermediate the base and the shaft positioned opposite the cord guide from the bearing as measured along the axis.

4. The device of claim 3 in which the noncontact sensor is a magnetic encoder.

5. The device of claim 3 in which the noncontact sensor is a photoelectric encoder.

6. The device of claim 4 further comprising a microcontroller.

7. The device of claim 6 in which the microcontroller computes a damped period of angular oscillatory motion from the angular motion observed by the noncontact sensor.

8. The device of claim 7 in which the microcontroller computes a natural period by applying logarithmic decrement to the damped period of angular oscillatory motion.

9. The device of claim 8 in which the means for displaying information communicates with the noncontact sensor by way of one or more wires.

10. The device of claim 8 in which the means for displaying information communicates with the noncontact sensor by wireless means.

11. An inertia measurement device that facilitates periodic angular oscillatory motion of an object comprising: a. a base having three or more legs; b. a rotor comprising a shaft, a primary platter, and a top surface that rotates about an axis; c. a bearing affixed to the base and intermediate the base and the shaft; d. a pair of primary helical springs each permanently attached at one end to the base and at the other end to a cord, the cord communicating between each helical spring and the shaft traversing around one or more pulleys intermediate each helical spring and the shaft and wrapping at least partially around a cord guide on the shaft; e. a noncontact sensor affixed to the base in a permanent way for observing angular motion of the rotor; and f. a means for displaying information to a user.

12. The device of claim 11, further comprising one or more pair of auxiliary-spring sets permanently attached at one end to the base and connected at their other ends to a means to connect to and disconnect from the cord, where each auxiliary-spring set of each pair of auxiliary-spring sets when connected to the cord works in parallel with the respective primary helical spring.

13. The device of claim 12 in which the base further comprises a bottom bearing affixed to the base and intermediate the base and the shaft positioned opposite the cord guide from the bearing as measured along the axis.

14. The device of claim 13 in which the noncontact sensor is a magnetic encoder.

15. The device of claim 13 in which the noncontact sensor is a photoelectric encoder.

16. The device of claim 14 further comprising a microcontroller.

17. The device of claim 16 in which the microcontroller computes a damped period of angular oscillatory motion from the angular motion observed by the noncontact sensor.

18. The device of claim 17 in which the microcontroller computes a natural period by applying logarithmic decrement to the damped period of angular oscillatory motion.

19. The device of claim 18 in which the means for displaying information communicates with the noncontact sensor by way of one or more wires.

20. The device of claim 18 in which the means for displaying information communicates with the noncontact sensor by wireless means.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0017] FIG. 1 is a top-front-right oblique view of one embodiment of an inertia measurement device.

[0018] FIG. 2 is a right-back-bottom oblique view of one embodiment of an inertia measurement device.

[0019] FIG. 3 is a right, midplane-section view of one embodiment of an inertia measurement device.

[0020] FIG. 4 is a top-front-right oblique view of one embodiment of an inertia measurement device corresponding to that in FIGS. 1 and 2 showing the addition of an auxiliary platter and auxiliary-spring sets.

[0021] FIG. 5 is a right-back-bottom oblique view of one embodiment of an inertia measurement device corresponding to that in FIGS. 1 and 2 showing the addition of an auxiliary platter and auxiliary-spring sets.

[0022] FIG. 6 is another embodiment of an auxiliary-spring set.

[0023] FIG. 7 is a right-bottom-back oblique view of another embodiment of an inertia measurement device employing auxiliary-spring sets depicted in FIG. 6.

[0024] FIG. 8 is a top-front oblique view of the embodiment shown in FIG. 7 showing the means for stowing permanently attached auxiliary-spring sets when not in use.

[0025] As required, detailed embodiments of the present invention are disclosed herein; however, it is to be understood that the disclosed embodiments are merely exemplary of the invention that may be embodied in various and alternative forms. The figures are not necessarily to scale; some features may be exaggerated or minimized to show details of particular components. Therefore, specific structural and functional details disclosed herein are not to be interpreted as limiting, but merely as a representative basis for teaching one skilled in the art to variously employ the present invention.

DETAILED DESCRIPTION OF THE INVENTION

[0026] The present invention, shown in FIGS. 1 and 2, is an inertia measurement device by which the MOI of an object may be determined by placing it on rotor 1, more specifically on top surface 2 of primary platter 3 of rotor 1. Primary platter 3 is larger in diameter than shaft 4, which is also part of rotor 1. Rotor 1 is free to rotate about axis 5. Top surface 2 typically has threaded holes 6 and optionally non-treaded dowel holes 7, the threaded holes being one means of attaching an auxiliary platter 31 (see FIGS. 4 and 5). Top surface 2 may also have a portion covered with a non-slip material 8 such as but not limited to Dycem®, neoprene, or urethane, upon which the object may be placed to avoid it sliding relative to top surface 2 during a test. Turning to the section view of FIG. 3 shows that rotor 1 is supported by bearing 9 which is mounted in top plate 10. Bearing 9 is shown here as a rolling element bearing, more specifically a ball bearing. Since both axial load—the weight of both rotor 1 and the object being measured—which acts along or parallel to axis 5, must be supported, bearing 9 must be of a type that can support axial load in addition to providing radial location in the plane normal to axis 5. Deep groove ball bearings are a good option, in particular any type that is of very low friction such as but not limited to bearings with ceramic rolling elements and using a very light oil rather than grease, the oil serving the purpose of minimizing oxidation on the bearing surfaces.

[0027] Top plate 10 is attached to legs 11, which include rear leg 11a and front legs 11b and 11c. Since three points define a plane, such as the surface upon which the inertia measurement device will be placed, using three legs is a natural choice and, in this embodiment, the three legs 11 make up the base of the inertia measurement device. Bearing 9 must be supported from below, so in the case where bearing seat 12 is formed in top plate 10 from below (as shown in FIG. 3, the purpose for doing so may be for improved manufacturability), a bearing cover 13 is needed; fasteners, including screws and dowel pins, are omitted in FIG. 3 in various places, for simplicity.

[0028] Rotor 1 is exposed to a restoring force from a pair of primary helical springs 14 that are attached to the base, more specifically rear leg 11a, by way of spring-base attachments 15. The other end of each primary helical spring 14 is attached to cord 16 by way of a respective spring block 17. Each spring block has a primary-spring catch 18. Cord 16 wraps around cord guide 19 on shaft 4. Visible in FIG. 3 is a spring-cord screw 20 that may be installed to assure the cord does not gradually walk around cord guide 19, though, the primary means of non-slip/no-walk is friction between cord 16 and cord guide 19 by way of the capstan effect, which can be enhanced through additional wraps or other cord attachment means such as but not limited to a pin or a hook. The design intent allows the primary helical springs 14 to be permanently connected to the inertia measurement device; as such, spring-base attachments 15 and primary-spring catch 18 would be tightened down and/or include a flat washer or other means to assure the loop on primary helical spring 14 does not fit over the spring-base attachment end 15a or primary-spring catch end 18a.

[0029] If objects to be measured are placed with their CG nearly coincident with axis 5, the moment on bearing 9 is small. Making bearing 9 larger in diameter can help withstand such a moment as well, but at the expense of greater torsional friction for the same quality and type of bearing. However, to improve mechanical durability, as shown in FIG. 3, bottom bearing 21 may be included. This also allows cord guide 19 to be positioned further below bearing 9 since bottom bearing 21 significantly assists in carrying the spring force, as opposed to the spring force being supported by bearing 9 in the form of a spring-induced moment. Keeping the springs lower relative to top plate 10 also provides space for multiple auxiliary-spring sets 33 (see FIGS. 4 and 5) that facilitate adjustability for objects of higher MOI. Bottom bearing 21 is mounted in bottom bearing seat 22 in bottom plate 23. Because axial loads are borne by bearing 9, bottom bearing 21 does not require a cap as was needed at the top (bearing cover 13).

[0030] Regardless of whether bottom bearing 21 is included, shaft 4 interacts in a noncontact manner with sensor 24 generally located in a sensor housing 25. The embodiment in FIG. 3 is representative of using a magnetic sensor, either a switch or an encoder, where a magnet 26 is affixed to shaft 4 adjacent to sensor 24. A photoelectric switch or encoder, being noncontact as well, is another example of sensor type. Sensor 24 is affixed to the base of the inertia measurement device in a way that is not readily accessible/adjustable by the user. This is important to protect sensor 24 and to make measurements consistent across multiple users and over the lifetime of the inertia measurement device.

[0031] Shown in FIGS. 4 and 5, auxiliary platter 31 is affixed to primary platter 3 by way of, but not limited to, fasteners 32 engaging threaded holes 6; alternatives could involve dowl pins, magnets, clips, and similar means of locating platter 31 on top surface 2 in the plane normal to axis 5 and, as needed for objects with their CG substantially misaligned with axis 5, attaching auxiliary platter 31 to primary platter 3. Auxiliary platter 31 may have a portion covered with a non-slip material and may also have markings in the form of concentric circles and/or radial lines to assist in adjusting the object to align its CG with axis 5 as a user may desire. Also shown in FIGS. 4 and 5 are a pair of auxiliary-spring sets 33, each comprising two auxiliary helical springs 33a that, when connected to spring block 17 by way of auxiliary-spring catches 34, straddle their respective primary helical spring 14 of the pair of primary helical springs 14. Each auxiliary-spring set 33 is also permanently attached to the base, more specifically rear leg 11a, by way of each auxiliary helical spring 33a being permanently attached to spring-base attachments 15. As with primary helical springs 14, the design intent allows the auxiliary-spring sets 33 to be permanently attached to the inertia measurement device; as such, spring-base attachments 15, but in this case not axillary-spring catches 34, would be tightened down and/or include a flat washer or other means to assure the loop on auxiliary helical spring 33a does not fit over the spring-base attachment end 15a. When auxiliary-spring sets 33 are not in use they are disconnected from axillary-spring catches 34 and stowed against leg 11a using stowage magnet 35 by way of magnetic attraction of each auxiliary helical spring 33a to stowage magnet 35.

[0032] Another embodiment employs a pair of pulleys 43 to allow a different means of permanently attaching and/or connecting, disconnecting and stowing springs while also permitting a smaller footprint of the inertia measurement device. FIG. 6 shows this alternate embodiment of an auxiliary-spring set 33, still comprising a pair of auxiliary helical springs 33a, but in this case the end that will communicate with spring block 17 does so by way of being attached to an auxiliary-spring spanner 41 by way of an auxiliary-spring fastener 42 or similar means of attachment. FIG. 7 shows a larger auxiliary platter 31 and how two auxiliary-spring sets 33, called out by their axillary helical springs 33a and their auxiliary-spring spanners 41, are connected to a leg 11, specifically 11c, by way of a single spring-base attachment 15. The same arrangement would exist on the other side, attached by way of a second base-spring attachment 15 to leg 11b; thus, in the embodiment shown in FIG. 7, there are two pairs of auxiliary-spring sets 33, the second of each pair (and respective spring-base attachment 15) being not visible, hidden in this view by leg 11a. FIG. 7 also shows cord 16 in communication between cord guide 19 (not visible) and the pair of spring blocks 17 by way of a respective pulley 43 intermediate cord guide 19 and respective spring block 17. On spring block 17 is one auxiliary-spring catch 34 for each auxiliary-spring set 33 on the respective side of the inertia measurement device; in this case shown there are two auxiliary-spring catches 34 per spring block 17, though there could be one or three or more. The auxiliary-spring spanner 41 of each auxiliary-spring set 33 engages a respective auxiliary-spring catch 34 in a way that it is readily connectable and disconnectable without the need for tools.

[0033] FIG. 8 shows how auxiliary-spring sets 33 are stowed when not in use. Each auxiliary-spring spanner 41 of each auxiliary-spring set 33 engages a respective stowage hook 43 on front panel 44.

[0034] Generally, within sensor housing 25 would also be some or all of the electronic devices and circuitry, generally including a microcontroller and algorithms running on the microcontroller necessary for processing sensor information, including but not limited to peak finding, zero-crossing finding, and logarithmic decrement, ultimately communicating raw or processed information to a display that is either a part of the inertia measurement device or external to the inertia measurement device, or both. Communication to the display device may be by a cord or by way of a wireless means, such as but not limited to Bluetooth, WiFi, or radio frequency (RF).

[0035] While exemplary embodiments are described above, it is not intended that these embodiments describe all possible forms of the invention. Rather, the words used in the specification are words of description rather than limitation, and it is understood that various changes may be made without departing from the spirit and scope of the invention. Additionally, the features of various implementing embodiments may be combined to form further embodiments of the invention.