The present invention relates generally to a tool assembly, and more particularly, to a tool assembly that is operable between a tamping mode of operation and a driving mode of operation.
At least some known tamping tools include a tamping plate that is coupled to a rod assembly. Known tamping tools are configured to enable the user to lift the tamping tool above a ground surface and thrust the tamping tool into the ground surface to impart an axial force to the ground surface to facilitate compacting the ground surface. These tamping tools require a high level of exertion from the user by requiring the user to repeatedly lift the tamping tool above the ground to deliver the compacting blow.
At least some known compaction tools includes a pneumatic assembly and/or a gas powered engine that enables the compaction tools to vibrate or bounce along the ground surface to facilitate compacting the ground surface. These compaction tools require an air supply and/or fuel to enable operation of the compaction tools, which increases an operational cost of the compaction tool. In addition, known compaction tools are heavy, and require significant effort from the use to control the direction and operation of the compaction tool.
As such, it is desirable to provide a tool assembly that reduces the effort of the user to compact a ground surface, and reduces an operating cost over known compaction tools. The present invention is aimed at the problem identified above.
In one aspect of the present invention, a tool assembly is provided. The tool assembly includes a housing assembly that includes a first end, a second end, and an inner surface that defines a cavity that extends between the first end and the second end along a longitudinal axis. A rod assembly is slideably coupled to the housing assembly and is orientated within the housing cavity such that a portion of the rod assembly extends outwardly from the housing first end. An impact assembly is positioned within the housing cavity and is orientated between the rod assembly and the housing second end. The impact assembly is configured to selectively contact the rod assembly to move the rod assembly along the longitudinal axis. The tool assembly is operable in a first operating mode wherein the rod assembly is movable with respect to the impact assembly and a second operating mode wherein the impact assembly contacts the rod assembly to move the rod assembly outwardly from the housing.
In another aspect of the present invention, a tool assembly is provided. The tool assembly includes a housing assembly that includes a cavity that extends between a first end and a second end, and a rod assembly that is slideably coupled to the housing assembly. The rod assembly is orientated within the housing cavity such that a portion of the rod assembly extends outwardly from the housing first end. An impact assembly is positioned within the housing cavity and is movable between a first position and a second position along a longitudinal axis. A mode selector assembly is coupled to the housing and is configured to selectively contact the impact assembly to operate the tool assembly in a first operating mode and a second operating mode. The impact assembly is positioned at the first position in the first operating mode and is movable between the first position and the second position to contact the rod assembly in the second operating mode.
In yet another embodiment, a method of assembling a tool assembly is provided. The method includes providing a housing assembly that includes a first end, a second end, and an inner surface that defines a cavity that extends between the first end and the second end along a longitudinal axis. A rod assembly is slideably coupled to the housing. The rod assembly is at least partially positioned within the housing cavity and orientated along the longitudinal axis such that at least a portion of the rod assembly extends outwardly from the housing first end. An impact assembly is slideably coupled to the housing assembly. The impact assembly is positioned within the housing cavity and orientated between the rod assembly and the housing second end. The impact assembly is configured to selectively contact the rod assembly to move the rod assembly along the longitudinal axis such that the tool assembly is operable in a first operating mode wherein the rod assembly is movable with respect to the impact assembly and a second operating mode wherein the impact assembly contacts the rod assembly to move the rod assembly outwardly from the housing first end.
Other advantages of the present invention will be readily appreciated as the same becomes better understood by reference to the following detailed description when considered in connection with the accompanying drawings wherein:
Corresponding reference characters indicate corresponding parts throughout the drawings.
The exemplary apparatus and methods described herein overcome at least some disadvantages of known compaction tools by providing a tool assembly that enables a user to manually operate the tool assembly to deliver an axial force to a ground surface. The tool assembly that is selectively operable between a tamping mode wherein the tool assembly impacts a first axial force to a ground surface, and a driving mode, wherein the tool assembly imparts the first axial force and a second axial force to the ground surface. In addition, the tool assembly includes a rod assembly that is slideably coupled to a housing assembly, and is configured to bias the housing assembly from the ground surface to enable the user to operate the tool assembly in a reciprocating motion, and to reduce an effort required to compact the ground surface over known compaction tools. By providing a tool assembly that operates in a plurality of operational modes, and that is operated in a reciprocating motion, the effort required to impart a force to the ground surface is reduced.
In general, the tool assembly 10 includes a rod assembly and an impact assembly and is operable between a tamping mode and a driving mode. In the tamping mode, the rod assembly moves axially along a longitudinal axis with the impact assembly in a stationary position to impart an axial force to a ground surface. In the driving mode, the rod assembly moves imparts a first axial force to the ground surface and engages the impact assembly to move the impact assembly along the longitudinal axis to generate a second axial force. Upon reaching a predefined axial location, the impact assembly disengages the rod assembly, rapidly moves along the longitudinal axis, and strikes the rod assembly to impart the generated second axial force to the rod assembly and the ground surface.
The rod assembly 14 is at least partially positioned within the housing cavity 22, and is movable along the longitudinal axis 28 such that at least a portion of the rod assembly 14 extends outwardly from the housing first end 24. The impact assembly 16 is positioned within the housing cavity 22, and is orientated between the rod assembly 14 and the housing second end 26 along the longitudinal axis 28. The impact assembly 16 is movable along the longitudinal axis 28 within the housing cavity 22.
In the tamping mode 34, the rod assembly 14 is movable along the longitudinal axis 28 with respect to the housing assembly 12 and with respect to the impact assembly 16. More specifically, in the tamping mode 34, the rod assembly 14 moves in a first direction, i.e. a forward direction 40 (shown in
In the driving mode 36, the rod assembly 14 moves the impact assembly 16 in the aft direction 42, and the impact assembly 16 contacts the rod assembly 14 to move the rod assembly 14 in the forward direction 40. More specifically, during the driving mode 36, the rod assembly 14 engages the impact assembly 16 to move the impact assembly 16 in the aft direction 42 a predefined aft distance 44 along the longitudinal axis 28. When the impact assembly 16 reaches a predefined location 46 along the axis 28, the impact assembly 16 disengages the rod assembly 14 and moves in the forward direction 40 a predefined forward distance 48 with respect to the rod assembly 14 to contact the rod assembly 14 to move the rod assembly 14 in the forward direction 40. As the impact assembly 16 contacts the rod assembly 14, the impact assembly 16 imparts an axial force 50 to the rod assembly 14 to drive the rod assembly 14 outwardly from the housing assembly 12.
In the illustrated embodiment, a pedal assembly 72 is coupled to the outer surface 62 of the first housing member 52. The pedal assembly 72 includes a support member 74 that is coupled to the first housing member 52, and a pedal 76 that is pivotably coupled to the support member 74. In one embodiment, the pedal 76 is coupled to the support member 74 with a pin (not shown). Alternatively, the pedal assembly 72 may include a spring (not shown) that is coupled to the pedal 76 and the support member 74 to bias the pedal 76 towards the housing assembly 12. The pedal 76 is positionable between an extended position (not shown) wherein the pedal 76 extends outwardly from the housing assembly 12, and a retracted position 78, wherein the pedal 76 is orientated adjacent to the housing outer surface 62. In the extended position, the pedal assembly 72 is configured to impart an axial force from a user to the tool assembly 10 to assist the user in operating the tool assembly 10. In the illustrated embodiment, the pedal assembly 72 is orientated near the housing first end 24. Alternatively, the pedal assembly 72 may be orientated at any suitable location along the housing outer surface 62 that enables the tool assembly 10 to function as described herein.
The second housing member 54 is removably coupled to the first housing member second end 66 and extends outwardly from the first housing member 52 along the longitudinal axis 28. The second housing member 54 is configured to receive the impact assembly 16 therein. The second housing member 54 includes a sidewall 80 that includes an inner surface 82 and an outer surface 84, and extends between a first end 86 and a second end 88 along the longitudinal axis 28. In the illustrated embodiment, the second housing member inner surface 82 is configured to at least partially receive the first housing member 52 therein. In one embodiment, the first housing member outer surface 62 and the second housing member inner surface 82 each include corresponding threaded surfaces 90 to facilitate coupling the first housing member 52 to the second housing member 54. Alternatively, the first housing member 52 may be coupled to the second housing member 54 with a weld, a bolt, a pin, a fastener, an adhesive, and or any suitable manner in which to couple the first housing member 52 to the second housing member 54. In the illustrated embodiment, the first end 86 includes an end wall 92 that extends inwardly from the inner surface 82 and is orientated substantially perpendicularly to the longitudinal axis 28. The end wall 92 defines an opening 94 that is sized and shaped to receive at least a portion of the rod assembly 14 therethrough. The end wall 92 is orientated to prevent the impact assembly 16 from extending into the first housing member 52.
The end cap 56 is removably coupled to the second housing member second end 88. The end cap 56 includes an inner surface 94 that is sized and shaped to at least partially receive the second end 88 therein such that a portion of the end cap 56 extends a distance 96 across the second housing member outer surface 84. In one embodiment, the end cap 56 is coupled to the second housing member 54 such that the overlap distance 98 is adjustable to adjust an axial force of the impact assembly 16. The end cap inner surface 94 and the second end outer surface 84 each include corresponding threaded areas 100 to facilitate coupling the end cap 56 to the second housing member 54. Alternatively, the end cap 56 is coupled to the second housing member 54 with a weld, a bolt, a pin, a fastener, an adhesive, and/or any suitable manner.
In the illustrated embodiment, the aft section 110 extends through biasing element 104 to enable rod member 102 to move along longitudinal axis 28 in the forward direction 40 and the aft direction 42. The aft section 110 is also sized and shaped to extend through second housing member end wall 92 and into impact assembly 16. In one embodiment, the aft section 110 includes a positioning member 126 that extends outwardly from an axial face 128 of the aft section 110 along the longitudinal axis 28. The positioning member 126 is configured to engage the impact assembly 16 when the tool assembly 10 is in the driving mode 36.
The biasing element 104 is orientated between the rod member flange 114 and the end wall 92 and is configured to bias the rod member 102 away from the end wall 92 and towards the housing first end 24 along the longitudinal axis 28 in the forward direction 40.
In the illustrated embodiment, the impact member 138 includes a substantially circular outer surface 146 and an inner surface 148, and extends between a forward end 150 and aft end 152 along the longitudinal axis 28. In the illustrated embodiment, the impact member 138 is formed from steel. Alternatively, the impact member 138 may be formed from aluminum, a metal alloy, and/or any suitable material that enables the tool assembly 10 to function as described herein. The inner surface 148 defines a bore 154 that extends from the forward end 150 towards the aft end 152 along the longitudinal axis 28. Moreover, the forward end 150 includes an opening 156 that is coupled to the bore 154, and the aft end 152 includes an inner wall 158 that at least partially defines the bore 154, and is spaced a distance 160 from the opening 156 along the longitudinal axis 28. The bore 154 is sized and shaped to receive the rod member 102 therein.
In one embodiment, the impact member 138 includes a groove 162 that is defined along the outer surface 146. The groove 162 is sized and shaped to receive a splined surface 164 that extends inwardly from the housing inner surface 82 to prevent the impact member 138 from rotating about the longitudinal axis 28.
The cam assembly 140 is coupled to the impact member 138 and is configured to selectively provide access to the bore 154. The cam assembly 140 includes a cam member 166 and a spring member 168 that is coupled to the impact member 138 and the cam member 166 to bias the cam member 166 outwardly from the impact member 138. The impact member 138 includes an opening 170 that extends inwardly from the impact member outer surface 146. The opening 170 is sized and shaped to receive the cam assembly 140 therein. The cam assembly 140 is positioned within the opening 170 and is orientated along a transverse axis 172 that is substantially perpendicular to the longitudinal axis 28. The cam member 166 includes an inner surface 174 that defines a cam opening 176 that extends through the cam member 166. The cam opening 176 is orientated along the longitudinal axis 28, and is sized and shaped to receive the rod member 102 therethrough.
In the illustrated embodiment, the cam assembly 140 is movable along the transverse axis 172 and is positionable between a first cam position 178 (shown in
The impact assembly 16 is movable along the longitudinal axis 28 between a first position 182 (shown in
The housing sidewall 18 also includes a cam surface 188 that extends inwardly from the housing inner surface 20 towards the impact assembly 16. The cam surface 188 is positioned a distance 190 from the housing end wall 92 along the longitudinal axis 28, and is sized and shaped to move the cam assembly 140 from the first cam position 178 to the second cam position 180 as the impact assembly 16 moves from the first position 182 to the second position 184.
In the illustrated embodiment, the tool assembly 10 also includes a mode selector 38 that is coupled to the housing assembly 12 and is configured to selectively position the cam assembly 140 in the first cam position 178 or the second cam position 180. More specifically, the mode selector 38 includes a selection member 192 that extends through the housing sidewall 18 along the transverse axis 172, and is configured to selectively contact the cam assembly 140. The selection member 192 is orientated with respect to the second housing member end wall 92 such that the selection member 192 is aligned with the cam assembly 140 with the impact assembly 16 in the first position 182 to move the cam assembly 140 between the first cam position 178 and second cam position 180. The selection member 192 includes a threaded outer surface 194 and is rotatably coupled to the housing sidewall 18 such that a rotation of the mode selector 38 in a first direction 196 about the transverse axis 172 extends the selection member 192 towards the impact member 138 and a rotation of the mode selector 38 in a second opposite direction 198 retracts the selection member 192 away from the impact member 138. In this manner, the user may position the tool assembly 10 in one of the tamping mode 34 and the driving mode 36 by rotating the mode selector 38 in the first direction 196 or the second direction 198.
During operation in the tamping mode 34 (shown in
During operation in the driving mode 36 (shown in
In one embodiment, the rod assembly 14 includes at least one groove 210 that is defined along an outer surface 212 of the aft section 110. The cam assembly 140 includes a corresponding groove 214 that is defined along an outer surface 216 of the cam member 166. In the first cam position 178 the cam groove 214 is aligned with the rod assembly groove 210 to enable the rod assembly 14 to extend into the impact member bore 154. In the second cam position 180, the cam groove 214 is not aligned with the rod assembly groove 210 such that the rod member 102 is prevented from extending through the bore 154. Alternatively, the cam assembly 140 may include a pair of cam members 166 that are orientated on opposite sides of the rod assembly 14.
The above-described apparatus and methods overcome at least some disadvantages of known compaction tools by providing a tool assembly includes a rod assembly that is slideably coupled to a housing assembly, and is configured to bias the housing assembly from the ground surface to enable the user to operate the tool assembly in a reciprocating motion, and to reduce an effort require to compact the ground surface over known compaction tools. In addition, the tool assembly that is selectively operable between a tamping mode wherein the tool assembly impacts a first axial force to a ground surface, and a driving mode, wherein the tool assembly imparts the first axial force and a second axial force to the ground surface. As such, By providing a tool assembly that operates in a plurality of operational modes, and that is operated in a reciprocating motion, the effort required to impart a force to the ground surface is reduced.
Exemplary embodiments of a tool assembly and methods of assembling the same are described above in detail. The systems and methods are not limited to the specific embodiments described herein, but rather, components of the apparatus and/or steps of the methods may be utilized independently and separately from other components and/or steps described herein. For example, the methods may also be used in combination with other compacting devices, and are not limited to practice with only the tool assembly as described herein. Rather, the exemplary embodiment can be implemented and utilized in connection with many other digging and/or compacting applications.
This written description uses examples to disclose the invention, including the best mode, and also to enable any person skilled in the art to practice the invention, including making and using any devices or systems and performing any incorporated methods. The patentable scope of the invention is defined by the claims, and may include other examples that occur to those skilled in the art. Such other examples are intended to be within the scope of the claims if they have structural elements that do not differ from the literal language of the claims, or if they include equivalent structural elements with insubstantial differences from the literal language of the claims.
While the invention has been described in terms of various specific embodiments, those skilled in the art will recognize that the invention may be practiced with modification within the spirit and scope of the claims.
This application claims the benefit of U.S. Provisional Application No. 61/485,042, filed May 11, 2011, the disclosure of which is incorporated herein by reference.
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