Implementations shown in the disclosure relate generally to tool support systems and more particularly to implementations for a guide assembly to balance a tool for rotation and tilt without undesirable additional torque on an operator's hand, wrist, or arm.
Pneumatic or electrically powered tools are employed by mechanics and assemblers during manufacturing and maintenance operations. Many tools are used repeatedly positioned and oriented manually by an operator during a shift. Typical of those tools are pneumatically operated drill motors, such as a nutplate drill motor. These drill motors can be quite heavy. To alleviate some issues associated with the weight of the drill motor, the drill motor can be attached to a robot for automated drilling. However, robots and automation can be expensive, and the robot may not be able to fit in confined spaces. When manual drilling is performed, the drill motor can be supported by a gimbal. The gimbal may have a center of gravity that conflicts with the center of gravity of the drill motor, which would impart a moment force to the operator's hand/wrist. Further, the gimbal may interfere with the operator's hand on the tool. An alternative is to support the weight of the tool by using an overhead winch. However, the cable attached to the winch may prevent rotation of the tool or the cable arrangement may impart a torque to the operator's hand, wrist, or arm when drilling non-horizontal holes. Accordingly, even where an overhead winch or gimbal is provided, operators may not find the winch or gimbal to be convenient in operation and may not use the winch or gimbal consistently.
Exemplary implementations provide a guide assembly for supporting a tool. The guide assembly has an arcuate guide configured to have a tether coupled thereto. The arcuate guide is configured to apply a reaction force to the tether to oppose gravitational force applied to the tool. The assembly further includes a mount assembly is configured to couple the arcuate guide to the tool. At least one support bar is coupled to the arcuate guide and the mount assembly. The arcuate guide, the mount assembly, and the at least one support bar are configured to maintain the reaction force in alignment with a center of gravity of the tool as the tool is rotated with respect to the center of gravity.
A system implementation provides a tool system having an overhead support. A tether is coupled to the overhead support. A tool having a center of gravity is coupled to a guide assembly. The guide assembly has an arcuate guide configured to be coupled to the tether, the tether opposing gravitational force on the tool with a reaction force on the arcuate guide. A mount assembly is configured to couple the arcuate guide to the tool. At least one support bar coupled to the arcuate guide and the mount assembly, wherein the arcuate guide, the mount assembly, and the at least one support bar are configured to maintain the reaction force in alignment with a center of gravity of the tool as the tool is rotated with respect to the tether.
The exemplary implementations allow a method for operation of a tool having a tool center of gravity. A tether is coupled to the guide assembly. The tool is rotated about a roll axis such that the tether slides relative to the arcuate guide to maintain the reaction force in alignment with the tool center of gravity.
The features, functions, and advantages that have been discussed can be achieved independently in various implementations or may be combined in yet other implementations further details of which can be seen with reference to the following description and drawings.
The exemplary implementations described herein provide a tool guide assembly that includes an arcuate guide that keeps an upward force applied by a support over a center of gravity of a tool as the tool is rotated (i.e., rolled or pitched). The support may be provided by a tether, a tool balance arm, or other suspending device providing a single point of attachment. The description and drawings of the implementations herein employ a cable or fabric tether but as used herein the term “tether” is defined as any overhead single point support. The tether attaches to the arcuate guide with a clip. In exemplary implementations, the arcuate guide is a rail and the clip slides along the guide rail as the tool is rolled to drill holes that are not perpendicular to a surface of a workpiece. Slight friction between the tether clip and the guide rail maintains a position/orientation (i.e., angle) of the guide rail with respect to the tether as a hole is drilled. Alternatively, a bearing or bushing around the guide rail may be employed to reduce friction along the guide rail when the clip slides along the guide rail. An alternative exemplary implementation of the guide assembly includes a plate with an arcuate slot cut through the plate. Either the slotted plate or the guide rail can include engaging indices, such as notches or bumps, to maintain a fixed angle of rotation of the tool. In exemplary implementations, the notches, indentations, or bumps can be spaced along the inner surface of the guide rail or arcuate slot at predetermined increments, such as 5° increments. The tool can be, for example, a hand tool or a manually-operated power tool. In a particular embodiment, the tool is an electrically-powered drill motor that is manually positioned and oriented by an operator.
Referring to the drawings,
The tool system 10 has a tether 36 suspended from an overhead support 38. The tether 36 can suspend a clip 34 from the overhead support 38. Details of the overhead support 38 are not shown, but the overhead support 38 may be a winch, a gantry, an overhead beam, a crane, or a ceiling attachment. The overhead support 38 may provide two or three-dimensional positioning of the tool 18. The overhead support 38 may provide vertical adjustment of the length or height of the tether 36 to assist in positioning the tool 18 for operation. The clip 34 may be permanently engaged to the rail 16 but normally employs a gate 40 pivotally movable to allow insertion of the rail 16 into an aperture 42 defined by the clip 34. The clip 34 may be sufficiently lubricious to allow the rail 16 to slip laterally through the aperture 42. A bushing or bearing 44 is alternatively attached to either the clip 34 or the rail 16. The bearing 44 can enhance sliding movement of the rail 16 through the clip 34 providing greater lubricity than the direct contact of the materials of the clip 34 and rail 16, for roll movement as will be described in greater detail subsequently. In a simplified implementation, the tether 36 may be looped around the rail 16 and secured to itself with the loop replacing the clip 34.
The force of gravity acting on the tool 18 (represented by arrow 46) through the center of gravity 24 is reacted by the guide assembly 12 to the overhead support 38 with a reaction force 48 nominally axially centered in the tether 36 but shown offset from the tether for clarity. The arcuate guide 14 is configured to apply the reaction force 48 to the tether 36 to oppose gravitational force applied to the tool 18. In other words, the tether 36 opposes the gravitational force with the reaction force 48 applied on the arcuate guide 14. The operator can therefore operate the tool 18 without having to support the weight of the tool 18 with a vertically-applied force. The arcuate guide 214 and the guide assemblies 212, 312, 314 described in more detail below function similarly to the arcuate guide 14 to applying the reaction force 48 that opposes the gravitational force.
As seen in
The tool system 210 has a tether 36 suspended from the overhead support 38. The tether 36 can suspend a clip 234 from the overhead support 38. The clip 234 may be permanently engaged to the plate 215 but normally employs a gate 240 pivotally movable to allow insertion of the clip 234 into the arcuate slot 216. The clip 234 may be sufficiently lubricious to allow the clip 234 to slip laterally along the arcuate slot 216. Alternatively, a bushing or bearing 244 is attached to the clip 234 to enhance movement of the clip 234 along the arcuate slot 216. The arcuate slot 216 may incorporate a coating of lubricious material on which the clip 234 slides. The arcuate slot 216 may additionally or alternatively incorporate a grommet 217 received over an edge of the arcuate slot 216 (seen in
For the implementations as shown in
In certain implementations, it may be impractical to attach trunnions 32 directly to the tool 18. Additionally, the guide assembly 312 can provide for easy replacement of differing tools. In those implementations, as seen in
In yet other exemplary implementations in which only small pitch variations will occur or where attachment of the guide assembly 412 to the tool 18 is most easily accomplished on the top 37a of the tool 18, a mount assembly 426 may be employed as shown in
As seen in
The implementations described provide a method 600 as shown in
Having now described various implementations in detail as required by the patent statutes, those skilled in the art will recognize modifications and substitutions to the specific implementations disclosed herein. Such modifications are within the scope and intent of the present invention as defined in the following claims.