The present invention generally relates to the field of mechanical tools and methods thereof and, more particularly, to tools for removing in-ground stakes and associated methods of use.
Commonly used in construction projects, stakes serve multiple purposes from surveying to securing concrete. In particular, they provide a temporary marker or support in various construction projects. The stakes are commonly made of metal, wood or plastic and comprise a pointed end allowing them to be driven deep into the soil or concrete using a sledgehammer thereby increasing their stability.
Stakes are often manually removed once a project is complete or if they are no longer required. Depending on the depth at which the stakes are buried or the material they are buried in, their removal can prove challenging and time consuming. Moreover, the large number of stakes commonly used in construction projects can often be physically exhausting for workers while extending the construction time.
Various stake removal tools have been proposed for the easy removal of stakes. For example, U.S. Pat. No. 7,017,962 discloses a stake removal tool having two handles linked by a link bar, wherein the limits of the handles define gripper surfaces being opposite to one another. The gripper surfaces are spaced apart to allow a stake to be positioned therebetween which can be engaged by the gripper surfaces for removal.
U.S. Pat. No. 8,356,799 discloses a stake removal tool comprising two loops disposed on opposite ends of the device. A first loop is configured to receive a top end of a stake while the second loop is configured to receive a user's forearm. As the user engages the device, the first loop tightens around the stake thereby facilitating its removal.
The use of the aforementioned removal tools presents certain drawbacks, namely the continued physical effort required by the users. There is therefore a need for a manual or powered stake removal tool.
The shortcomings of the prior art are generally mitigated by a stake removal tool configured for removing in-ground stakes, the stake removal tool comprising an elongated member defining a proximal end and a distal end, a carriage, a lift system configured to drive the carriage along a longitudinal direction of the elongated member, and a fulcrum, wherein the carriage comprises a chassis and a pivoting member configured to pivot about the fulcrum and defining first and second engagement members, the engagement members being configured to engage the stake and grasp the stake when the pivoting member is pivoted.
The pivoting member may further define a passage between the first and second engagement members, wherein the passage has a dimension along an axis normal to a longitudinal axis of the stake being smaller than a width of the stake when the pivoting member is suspended, and wherein the dimension along the axis normal to the longitudinal axis of the stake of the opening is greater than the width of the stake when the pivoting member is pivoted about the fulcrum. A rotation of the pivoting member may be limited by the width of the stake when said stake is in the opening and the pivoting member is pivoted.
The pivoting member may be configured to remove the stake from the ground when the engagement members grasp the stake and the carriage is driven upwardly, and the pivoting member may loosely pivot about a pivot point of the carriage. The pivoting member may pivot about an elongated aperture of the carriage and the lift system may comprise an endless gear configured to threadingly engage the carriage.
The stake removal tool may further comprise a resilient member adapted to dampen a displacement of the carriage at the distal end of the elongated member, and the lifting system may comprise an elongated rod, the elongated rod comprising a threaded portion threadingly engaging the carriage, an axle portion for receiving the resilient member, and a drive connector.
The stake removal tool may further comprise a bearing adapted to receive and rotate the elongated rod, the lifting system may be unitary, and at least one of the first and second engagement members may comprise serrations.
The shortcomings of the prior art are further mitigated by a method for removing a stake from a surface, the method comprising driving a carriage toward the stake along an elongated member, inserting the stake into an opening of a pivoting attachment member, and driving the carriage to suspend the pivoting member and to grasp the stake with the attachment member.
The method may further comprise pivoting the attachment member to a position being substantially normal to a longitudinal axis of the stake prior to inserting the stake into the opening, wherein grasping the stake may comprise pressing serrations of first and second engagement members of the attachment member against a surface of the stake.
The method may further comprise dampening a displacement of the driving carriage and/or aligning an axle of a drive system with a rotational axis of the endless screw, wherein driving the carriage may comprise rotating an endless screw configured to threadingly engage the carriage.
Other and further aspects and advantages of the present invention will be obvious upon an understanding of the illustrative embodiments about to be described or will be indicated in the appended claims, and various advantages not referred to herein will occur to one skilled in the art upon employment of the invention in practice.
The above and other aspects, features and advantages of the invention will become more readily apparent from the following description, reference being made to the accompanying drawings in which:
A novel system and method for removing a stake will be described hereinafter. Although the invention is described in terms of specific illustrative embodiments, it is to be understood that the embodiments described herein are by way of example only and that the scope of the invention is not intended to be limited thereby.
Referring to
The elongated member 40 typically defines a proximal end 41 adapted to be manipulated by a user and a distal end 44 adapted to engage a stake.
The base 30 is typically affixed at a distal end 44 of the elongated member 40 and is generally adapted to support the stake removal tool 100 when in use. Still referring to
The base 30 may be affixed to the elongated member 40 using a fastener, an adhesive or any other suitable method. In other embodiments, the base 30 may be detachably affixed to the elongated member 40 and selectively affixed when required. In yet other embodiments, the base 30 may be pivotally attached to the distal end 44 of the elongated member 40, generally aiming at conforming with an uneven ground 7.
The stake removal tool 100 may further comprise a carriage 10 configured to be moved longitudinally in relation with the elongated member 40. To that end, the carriage 10 may be slidably attached to the elongated member 40 using any suitable means. The carriage 10 generally comprises an attachment portion 12 (shown in
In certain embodiments, the stake removal tool 100 further comprises a lift system 50. The lift system 50 may extend along the elongated member 40 and is adapted to displace the carriage 10 along the said elongated member 40. The lift system 50 may comprise any suitable mechanism for generating a displacement of the carriage along the elongated member 40, such as but not limited to, an endless screw, a screw jack, a belt system, a magnetic system or any combination thereof. Referring again to
In order to displace the carriage 10, the lift system 50 may engage or may be attached to the attachment portion 12 of the carriage 10. Referring now to
The gripping or attaching system 20 may be attached to or unitary with the carriage 10. Broadly, the attaching system 20 is adapted to grip or firmly retain the stake 5 when the carriage 10 is moved upwardly. The attaching system 20 may additionally comprise one or more aperture or openings 22 allowing the passage of the stake 5.
Referring now to
In the illustrated embodiment, the attaching system 20 comprises a supporting member or link 24 for pivotally attaching the attaching system 20 to the carriage 10. The attaching system 20 may therefore be pivotally attached to the carriage 10 at the pivot point 15 of the carriage 10. The supporting member 24 may comprise a pin, a bolt or any other suitable component.
Referring now to
In certain embodiments, the attaching system 20 may be loose about the pivot point 15 to be impacted by gravitational forces and to allow a free rotation thereabout. Accordingly, the attaching system 20 may tilt downwardly when unsupported with the first gripping member 26 being lower than the second gripping member 28 due to gravitational forces acting upon the attaching system 20. In preferred embodiments, the pivoting range of motion of the attaching system 20 is limited due to the geometry of the attaching system 20, the carriage 10, a stopper (not shown) or any other suitable means.
Referring to
In other embodiments, the fulcrum 36 may be replaced by a resilient member or any pivoting system allowing the attaching member 20 to be pivoted when engaging with the stake 5 as to be substantially parallel with the ground (or substantially perpendicular with the stake 5).
Referring now to
Referring now to
In a preferred embodiment, the stake removal tool 100 may be configured to force the stake 5 upwardly and to dislodge it from the ground 7 as the attaching member 20 pivots when it is raised. Once the stake 5 has been dislodged, the carriage 10 may continue to be driven upwardly by the lift system 50. As carriage 10 is driven upward, the gravitational forces still force the attaching member 20 into its pivoted state, thus allowing the engagement members 26, 28 to maintain their grip on the stake 5. To that end, the stake 5 may be removed from the ground 7 as the carriage 10 continues to be driven upwardly.
Understandably, any other methods to grip or attach the stake by moving the carriage 10 up and down may be used within the scope of the present invention. As such, in some embodiments, a roller may be pushed against the stake to maintain pressure against a gripping member.
The lifting system 50 typically comprises a drive system (not shown) configured to drive the lift system 50. The drive system may comprise any suitable system to operate and control the lift system such as, for example, an engine, a motor or more preferably a power tool such as a drill configured to engage and rotate the endless screw 52. The stake removal tool 100 may further comprise a drive bracket 54 adapted to align the axle of the drive system with the rotational axis of the endless screw to increase mechanical efficiency and generally to avoid side forces on the pivoting shaft, which may create breakages.
The drive bracket 54 may be adapted to be securely attached to the drive motor and to the elongated member 40. In one embodiment, the drive motor may be dismantled, the bracket 55 may be inserted within the two or more dismantled parts and be secured within the drive motor, offering a rigid connection to the drive motor.
In certain embodiments, the endless screw 52 may be axially connected to a socket 56, such as a standard socket for drilling. The drive system may be engaged with the socket 56 to turn the endless screw 52 in any direction. A first direction of rotation drives the carriage 10 down while the opposite direction moves the carriage 10 upwards.
To further ease the operation of the stake removal tool, the stake removal tool 100 may comprise one or more handles 60 to be engaged by the user during the operation of the stake removal tool 100, as shown in
In use, the tool 100 is placed on the ground, typically against the base 30. The tool 100 is positioned to align the elongated member 40 or the attaching member 20 with the stake 5 in the ground 7. The drive system 50 is activated to move the carriage 10 down, such as rotating the endless screw 52 in a first direction. When the attaching system 20 has made contact with the fulcrum 36 and pivoted sufficiently to engage and dislodge the stake 5 from the ground 7, the drive system 50 is stopped and/or reversed to move the carriage 10 upwards (the endless screw 52 turns in a second direction, opposite to the first direction). By moving up, gravitational forces pivot the attaching system 20 in an opposite direction once again engaging the stake 5. As the carriage 10 moves up, the stake 5 is solidly gripped between the first and second gripping members 26 and 28.
Referring now to
Referring to
Referring now to
The attachment system 220 generally comprises a supporting member 224 pivotally attached to the carriage 210. In the illustrated embodiment, the supporting member 224 is kingpin insertable in the pivot point 215 of the carriage. As such, the attachment system 220 may comprise one or more annular members 222 (shown in
In certain embodiments, the first and second gripping members 226, 228 may comprise serrations 229 configured to increase the points of contact between the first and second gripping members 226, 228 and the stake 5 while additionally increasing the applied pressure at each contact point. Understandably, the serrations 229 may allow the first and second gripping members 226, 228 to securely grip the stake 5 while additionally preventing a rotation of said stake 5 about its longitudinal axis.
In such embodiment, the carriage 210 comprises a threaded aperture 212 adapted to receive the threaded portion 252 of the lifting system 250. As the threaded portion 252 rotates, the carriage 210 moves upwardly or downwardly following the direction of rotation of the threaded portion 252. In the illustrated embodiment, the threaded aperture 212 is solidly fixed to the body 214 of the carriage 210. In such embodiment, the body 214 of the carriage 210 extends downwardly from the threaded aperture 212 to position the attachment system 220 at the base of the stake 5 to be pulled or removed.
In certain embodiments and referring again to
The elongated opening 216 is configured to receive a supporting member 224 of the attaching system 220 while allowing a vertical displacement of said supporting member 224 relative to the carriage 210. By allowing a relative displacement between the supporting member 224 and the carriage 210, the attaching system 220 may remain substantially horizontal while the carriage 210 is in a broader range of positions along the elongated member 240.
Referring now to
The stake removal tool 200 may further comprise a rotating member 280 adapted to receive and facilitate the rotation of the lifting system 250. The rotating member 280 may be a bearing receiving a portion of the elongate rod. In the illustrated embodiment, the drive connector 256 extends above the rotating member 280 to allow a drive system to engage with the lifting system 250. Understandably, any type of bearing, such as standard bearings may be used to embody the rotating member 280.
Referring now to
While illustrative and presently preferred embodiments of the invention have been described in detail hereinabove, it is to be understood that the inventive concepts may be otherwise variously embodied and employed and that the appended claims are intended to be construed to include such variations except insofar as limited by the prior art.
The present patent application claims the benefits of priority of U.S. Provisional Patent Application No. 63/174,869, entitled “SYSTEM AND METHOD FOR REMOVING A STAKE”, and filed at the United States Patent Office on Apr. 14, 2021, the content of which is incorporated herein by reference.
Number | Date | Country | |
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63174869 | Apr 2021 | US |