The present disclosure relates to excavating apparatuses for coring or drilling concrete or paved ground surfaces.
The following paragraphs are not an admission that anything discussed in them is prior art or part of the knowledge of persons skilled in the art.
U.S. Pat. No. 7,757,780 discloses an excavation apparatus that includes a support structure mountable to a truck bed, the support structure defining a longitudinal direction extending front-to-back of the truck bed, and a lateral direction extending side-to-side of the truck bed. The apparatus further includes a rotary spindle pivotably supported by the support structure at a first pivot joint defining a generally horizontal first pivot axis, the spindle extending lengthwise along a spindle axis and rotatable thereabout for driving a cutting head; the spindle pivotable about the horizontal first pivot axis between a stowed position wherein the spindle axis is generally horizontal, and a deployed position wherein the spindle axis is generally vertical. The support structure includes a first adjustment device for adjusting the position of the spindle in the longitudinal direction when deployed, and a second adjustment device for adjusting the position of the spindle in the lateral direction when deployed.
U.S. Pat. No. 8,327,950 discloses an excavation apparatus that includes a base structure mountable to a vehicle, and a first supporting member pivotally coupled to the base structure. The first supporting member is pivotable about a pivot axis that is generally parallel to a lateral direction between a retracted position and an advanced position. A second supporting member is rotatably coupled to the first supporting member. A rotary spindle is supported by the second supporting member and extends lengthwise along a cutting axis and is rotatable thereabout for driving a cutting element. When the first supporting member is in the advanced position, the second supporting member is rotatable about a rotation axis that is generally parallel to a longitudinal direction between a stowed position in which the cutting axis is generally parallel to the lateral direction and a deployed position in which the cutting axis is generally parallel to a vertical direction.
U.S. Pat. No. 9,856,698 discloses a self-propelled, towable coring apparatus that includes a base structure having at least one primary wheel. A rotary spindle drives a coring element. A support mechanism supports the rotary spindle and displaces the rotary spindle upwardly and downwardly relative to a ground surface. At least one engine is supported by the base structure and provides power to the at least one primary wheel to propel the apparatus, and to the rotary spindle to drive the coring element. A tow member is connected to the base structure for trailering the apparatus by a towing vehicle.
The following paragraphs are intended to introduce the reader to the more detailed description that follows and not to define or limit the claimed subject matter.
According to an aspect of the present disclosure, an excavation apparatus can include: a supporting linkage mountable to a vehicle; and a rotary spindle operable to drive a coring element about a cutting axis. The supporting linkage can support the rotary spindle and can be operable to displace the rotary spindle relative to a ground surface.
The supporting linkage can be configured to lower the rotary spindle relative to a ground surface to a deployed position, and raise the rotary spindle relative to the ground surface to a stored position. The cutting axis can be maintained in a generally vertical direction in the deployed and stored positions. The supporting linkage can include an inner bracket, an outer bracket that is spaced apart from the inner bracket, at least one upper bar that is pivotably connected to the inner and outer brackets, and at least one lower bar that is pivotably connected to the inner and outer brackets. The supporting linkage can include an actuator for moving the supporting linkage between the deployed and stored positions. The actuator can include a bottom end pivotably connected to the inner bracket, and an upper end pivotably connected to the at least one upper bar. Extension of the actuator can cause the supporting linkage to move from the deployed position to the stored position, and retraction of the actuator can cause the supporting linkage to move from the stored position to the deployed position. At least one of the upper and lower bars can include an actuator for adjusting an angle of the cutting axis.
The apparatus can include a vertical supporting member that couples the rotary spindle to the supporting linkage. The rotary spindle can be configured to translate along the vertical supporting member. The apparatus can include a platform slidably coupled to the vertical supporting member, and the rotary spindle can be mounted to the platform. The apparatus can include a motor for driving the rotary spindle, and the motor is mounted to the platform. The apparatus can include a linear actuator configured to move the platform relative to the vertical supporting member.
The rotary spindle can be configured to move relative to the supporting linkage about a hinge axis. The hinge axis can be generally parallel to a vertical direction. The apparatus can include a hinge pin that connects an outer bracket of the supporting linkage to a vertical supporting member that is coupled to the rotary spindle.
The apparatus can include a horizontal supporting member for coupling the supporting linkage to the vehicle. The supporting linkage can be configured to translate along the horizontal supporting member. The apparatus can include a linear actuator configured to move the supporting linkage relative to the horizontal supporting member.
According to an aspect of the present disclosure, the apparatus can be combined with the vehicle. The supporting linkage can be mounted to a rear of the vehicle, the rotary spindle can be configured to move relative to the supporting linkage about a hinge axis to a cleared position, the hinge axis being generally parallel to a vertical direction, and, in the cleared position, the rotary spindle can be arranged outside of a lateral extent of the rear of the vehicle.
According to an aspect of the present disclosure, an excavation apparatus can include: a supporting linkage mountable to a vehicle; a vertical supporting member connected to the supporting linkage; and a rotary spindle coupled to the vertical supporting member and operable to drive a coring element about a cutting axis. The vertical supporting member can be configured to move relative to the supporting linkage about a hinge axis that is generally parallel to a vertical direction.
According to an aspect of the present disclosure, an excavation apparatus can include: a supporting linkage including an inner bracket, an outer bracket that is spaced apart from the inner bracket, at least one upper bar that is pivotably connected to the inner and outer brackets, and at least one lower bar that is pivotably connected to the inner and outer brackets; a vertical supporting member connected to the outer bracket of the supporting linkage; and a rotary spindle coupled to the vertical supporting member and operable to drive a coring element about a cutting axis. The inner bracket of the supporting linkage can be mountable to a vehicle. The supporting linkage can be configured to lower the vertical supporting member relative to a ground surface to a deployed position, and raise the vertical supporting member relative to the ground surface to a stored position. The vertical supporting member can be configured to move relative to the supporting linkage about a hinge axis that is generally parallel to a vertical direction.
Other aspects and features of the teachings disclosed herein will become apparent, to those ordinarily skilled in the art, upon review of the following description of the specific examples of the present disclosure.
The drawings included herewith are for illustrating various examples of apparatuses and methods of the present disclosure and are not intended to limit the scope of what is taught in any way. In the drawings:
Various apparatuses or methods are described below to provide an example of an embodiment of each claimed invention. No example described below limits any claimed invention and any claimed invention may cover apparatuses and methods that differ from those described below. The claimed inventions are not limited to apparatuses and methods having all of the features of any one apparatus or method described below or to features common to multiple or all of the apparatuses or methods described below. It is possible that an apparatus or method described below is not an embodiment of any claimed invention. Any invention disclosed in an apparatus or method described below that is not claimed in this document may be the subject matter of another protective instrument, and the applicant(s), inventor(s) and/or owner(s) do not intend to abandon, disclaim or dedicate to the public any such invention by its disclosure in this document.
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In
In the example illustrated, the supporting linkage 18 includes an inner bracket 32 and an outer bracket 34 that is spaced apart from the inner bracket 32. The inner bracket 32 can be used to attach or mount the apparatus 10 to the vehicle 12 (
In the example illustrated, the supporting linkage 18 further includes an upper bar 36 and a pair of lower bars 38. The bars 36, 38 extend between the brackets 32, 34. The upper bar 36 is connected to the inner bracket 32 by a pair of pivot joints 40, and is connected to the outer bracket 34 by a pivot joint 42. The lower bars 38 are connected to the inner bracket 32 by a pair of pivot joints 44, and are connected to the outer bracket 34 by a pair of pivot joints 44. Thus, the supporting linkage 18 takes the form of a four-bar linkage, with each of the joints 40, 42, 44, 46 permitting movement about pivot axes that are generally parallel to the lateral direction 26.
In the example illustrated, a hinge pin 48 connects the outer bracket 34 of the supporting linkage 18 to the vertical supporting member 20. The hinge pin 48 permits movement of the vertical supporting member 20 relative to the supporting linkage 18 about a hinge axis 50 (
The motor 22 is configured to rotatably drive the cutting element 24 about a cutting axis 52 (
In the example illustrated, the vertical supporting member 20 is elongate and extends lengthwise generally parallel to the vertical direction 30. The apparatus 10 can be configured so that the rotary spindle 54 translates relative to the vertical supporting member 20 to adjust the positioning of the cutting element 24 in the vertical direction 30.
In the example illustrated, the upper bar 36 includes an actuator for controlling the length of the upper bar 36. By adjusting the length of the upper bar 36, the apparatus 10 can be leveled as desired so that the cutting axis can be maintained generally perpendicular to the ground surface. As shown, the upper bar 36 can include a hydraulic cylinder. In other examples, the actuator can be, for example but not limited to, a pneumatic cylinder or an electric actuator.
In the example illustrated, the apparatus 10 includes a platform 56. The motor 22, the rotary spindle 54 and the cutting element 24 are mounted to the platform 56, and the platform 56 is slidably coupled to the vertical supporting member 20. Displacement of the platform 56 relative to the vertical supporting member 20 provides a range of motion of the rotary spindle 54 and the cutting element 24 in the vertical direction 30, i.e. parallel to the cutting axis 52 and generally perpendicular to the ground surface.
Referring to
In the example illustrated, stabilizers 60 are disposed generally at respective opposing ends of the horizontal supporting member 58. Each of the stabilizers 60 is operable to move between a stabilizing position and a raised position. In the stabilizing position, each of the stabilizers 60 engages the ground surface to absorb or counteract forces created during the cutting operation. In the raised position, each of the stabilizers 60 is disengaged from the ground surface, permitting the vehicle 12 to be driven.
Referring again to
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Thus, in the example illustrated, the cutting element 24 and the rotary spindle 54 can be translated with displacement of the supporting linkage 18. Additionally, the cutting element 24 and the rotary spindle 54 can be translated with displacement of the platform 56, independently of displacement of the supporting linkage 18. As described above, leveling of the cutting element 24 can be achieved by actuating the cylinder of the upper bar 36.
The supporting linkage 18 can be operable to securely maintain the vertical supporting member 20 and the components mounted thereto in the stored position. In some examples, the supporting linkage 18 maintains this assembly of components raised so that the cutting element 24 is held at least about 18″ above the ground surface.
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It should be appreciated that the apparatus 10 can include various electrical cables, hydraulic/pneumatic lines and other power connections for controlling the motor 22, the stabilizers 60, the actuator of the upper bar 36, the actuator 74, the actuators of the members 20, 58, and/or other components, which have been omitted from the drawings for the sake of clarity.
It should be appreciated that space for any kind of attachment can be limited at the rear of a typical hydro evacuation vehicle, where the vacuum excavation function is located. The way the apparatus 10 is mounted in that limited available space at the rear of the vehicle, including application of the four-bar mechanism 18, enables the unit to be lowered down to core and then elevated back up into the stored position. In the stored position, the apparatus 10 can have a safe vertical road clearance for transit, in a manner that does not interfere with the vacuuming operations, which can be the principal function of the vehicle.
In use, the vehicle 12 with the apparatus 10 in the stored position can be driven into an approximate target position at an excavation site. The stabilizers 60 can be moved to engage the ground in the stabilizing position and securely support the apparatus 10 over the target position. The apparatus 10 can be moved into the deployed position by retraction of the actuator 74. Once in the deployed position, the position of the cutting element 24 can be compared to the target position. The position of the cutting element 24 can be adjusted laterally along the horizontal supporting member 58. The position of the cutting element 24 can be adjusted vertically by displacing the platform 56 up or down. The angle of the cutting axis can be adjusted by actuating the cylinder of the upper bar 36.
Once the cutting element 24 is accurately located and arranged in a desired position above the target, the motor 22 can then be initiated to drive the rotary spindle 54 and the cutting element 24, which can be lowered by displacing the platform 56 downwards. The cutting element 24 can used to cut a cylindrical hole. Once a desired cutting depth is reached, the cutting element 24 can be raised by displacing the platform 56 upwards. Then, the apparatus 10 can be moved back into the stored position by extension of the actuator 74. The vehicle 12 can then be driven to another excavation site.
When it comes time to tip-up and dump the spoils tank 16, the apparatus 10, in the raised stored position, can be swung out of the way of the dump by unlatching the gate-like connection on which it is hinged to swing it out towards the curb side of the vehicle 12 and avoid splash-back from the dump. When the dump is completed, the apparatus 10 can be swung back to its stored position and re-latched.
An advantage of the apparatus of the present disclosure is its ability to combine both coring and vacuuming functions on the same vehicle in a way that does not compromise either function when deployed. It also can eliminate the need for a separate or towed coring unit, or an independent truck mounted coring unit, to cut through the pavement, which can allow the vacuum unit fitted with its own coring attachment to quickly and independently core through the pavement to allow the operator to vacuum excavate to access underground infrastructure buried under concrete or pavement.
While the above description provides examples of one or more apparatuses or methods, it will be appreciated that other apparatuses or methods may be within the scope of the accompanying claims.
This application claims priority to U.S. Provisional Application No. 62/704,873 filed on Jun. 1, 2020, the entire contents of which are hereby incorporated herein by reference.
Number | Date | Country | |
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62704873 | Jun 2020 | US |