The present application relates generally to powered tools for rotating workpieces. More particularly, the present application relates to powered tools for rotating a workpiece by transmitting torque from a split gear body to a removable drive insert.
Ratchet sets are well-known tools that are used to rotate a workpiece and fasten two objects together. For example, a user can tighten a workpiece by rotating the ratchet, and can return the ratchet to its original position by rotating the ratchet in the opposite direction, which will not rotate the workpiece. Ratchet sets are typically hand-powered, and pneumatically-powered ratchet sets are typically bulky and space consuming. Thus, a need exists for a more compact ratchet set that is powered by pneumatic or other automatic means.
Ratchet sets also include a socket that is adapted to engage a workpiece to apply torque to the workpiece. The socket can be, for example, hexagonally shaped to fit around a hexagonally-shaped head of the workpiece. When the user rotates the ratchet, the socket applies torque to the workpiece to fasten or unfasten the workpiece. Conventional sockets are interchangeable with the ratchet by including a friction fit, detent, or locking design so that the socket can engage with corresponding mating portions of the ratchet. However, this structure is difficult to adapt into a more automatic means of powering the tool other than by manual user power, because the socket is only mechanically joined with the ratchet and does not include any functional interface with the ratchet.
The present application relates to a power tool with a split gear body that rotates a gear assembly, and that indirectly rotates a removable drive insert component for transmitting torque to a workpiece. In particular, the present application discloses a tool including a base, a motor coupled to the base, a gear train in functional communication with the motor, and an interchangeable drive insert engaged with the gear train, the interchangeable drive insert including a receiving portion adapted to engage a workpiece and apply rotational force thereto, and a plurality of gear teeth adapted to engage and be driven by the gear train.
Also disclosed is a tool including a motor, a drive body in functional communication with the motor, the drive body including an upper gear and a lower gear and a first pinion gear disposed therebetween, a second pinion gear engaged with the first pinion gear, an idler gear engaged with the second pinion gear, and a ratchet gear engaged with the idler gear, the ratchet gear adapted to apply rotational force to a workpiece based on torque transmitted by the idler gear.
Further disclosed is a tool including an idler gear, and an interchangeable drive insert that includes a ratchet gear having gear teeth on an external radial portion thereof and including a radial opening that extends between first and second endpoints of the ratchet gear and that is shaped and sized to receive a workpiece therein, and an insert cavity adapted to receive the ratchet gear and allow rotational movement thereof and including an opening shaped and sized to cooperate with the radial opening of the ratchet gear and permit entry of a workpiece therein, wherein the insert cavity is positioned adjacent the idler gear such that at least one point of the ratchet gear is engaged with the idler gear during a full radial movement of the ratchet gear.
For the purpose of facilitating an understanding of the subject matter sought to be protected, there is illustrated in the accompanying drawing embodiments thereof, from an inspection of which, when considered in connection with the following description, the subject matter sought to be protected, its construction and operation, and many of its advantages should be readily understood and appreciated.
While this invention is susceptible of embodiments in many different forms, there is shown in the drawings and will herein be described in detail a preferred embodiment of the invention with the understanding that the present disclosure is to be considered as an exemplification of the principles of the invention and is not intended to limit the broad aspect of the invention to embodiments illustrated.
The present application discloses an apparatus, method and system for transmitting power to a workpiece.
The motor 115 can be any form of motor, for example electric, pneumatic, hydraulic or manually-powered, that is adapted to transmit torque indirectly or directly to the ratchet gear 155 to rotate a workpiece. As discussed, a user can actuate the motor 115 by pushing on a button 115a, and can deactivate the motor 115 by pushing on the button 115a a second time. Alternate forms of turning the motor on and off can be provided without departing from the scope and spirit of the present application. Also, the motor 115 can have different modes of power output (e.g., low, medium, and high) where button 115a can actuate the motor 115 between these different power outputs through successive actuations of the button 115a.
The drive body 140 can include an upper gear 140a, a lower gear 140b, and a pinion gear 140c disposed in between the upper gear 140a and the lower gear 140b. A pawl gear 160 can be spring loaded against the drive body 140 in order to limit rotational movement of the drive body 140 in at least one rotational direction.
As shown, the pawl gear 160 is meshingly engageable with a plurality of teeth of the upper gear 140a and the lower gear 140b, but is not coupled to the pinion gear 140c. This split gear body affords a more compact design and further maintains a symmetric loading on the pawl gear 160 when coupled to the upper gear 140a and lower gear 140b. The pawl gear 160 can also engage each of the upper gear 140a, lower gear 140b and pinion gear 140c to more securely hold the gears during rotational movement of the ratchet.
In an embodiment, the upper gear 140a and lower gear 140b can be thinner and wider relative to the pinion gear 140c. However, the drive body 140 can be structured differently. For example, the pinion gear 140c can be wider than the upper gear 140a and the lower gear 140b, and the pawl gear 160 can be split in two portions in order to provide a symmetric load on the drive body 140.
The pinion gear 145 engages the pinion gear 140c of the drive body 140 to transmit torque from the drive body 140 to the idler gears 150. The pinion gear 145 can be positioned at approximately mid-plane in the tool 100 so as to have sufficient clearance from the top and bottom of the case enclosing the tool components. As shown, the pinion gear 145 includes similar features as the pinion gear 140c. However, the pinion gear 145 can be of a different shape, size, material, structure, or appearance from that of the pinion gear 140c without departing from the spirit and scope of the present application.
The idler gears 150 are adapted to transmit torque from the pinion gear 145 to the ratchet gear 155. As shown, the idler gears 150 are provided on two sides of the ratchet gear 155, and include two idler gears 150 on each side: one idler gear 150 that meshingly engages the pinion gear 145, and a second idler gear 150 that meshingly engages the ratchet gear 155. In an embodiment, one idler gear 150 is provided and the tool 100 still functions as intended. For example, one idler gear 150 can be disposed intermediate the pinion gear 145 and the ratchet gear 155 to transmit torque from the drive body 140 to the ratchet gear 155. Further, idler gears 150 need not be disposed on multiple sides of the ratchet gear 155, and only one set of idler gears 150 can be disposed in engagement with the ratchet gear 155. In another embodiment, no idler gears 150 are necessary, and pinion gear 145 meshingly engages directly with the ratchet gear 155 to provide torque to the ratchet gear 155.
In an embodiment, the ratchet gear 155 is a gear provided on the drive head 110 and is adapted to transmit torque from the idler gears 150 to a workpiece. As shown, the ratchet gear 155 has an internal opening that defines the receiving portion 125 for receiving a head of a workpiece. The receiving portion 125 engages and rotates the workpiece with torque transmitted from the motor 115 to the ratchet gear 155. In an embodiment, the ratchet gear 155 is not integral with a structure that defines the receiving portion 125, and can be separate therefrom.
The lever arms 120 can be any structure that allows the drive head 110 to releasably engage the main body 105 of the tool 100. For example, the lever arms 120 can be resiliently biased against receiving portions of the main body 105 by way of a biasing structure, such as springs. Alternately, the lever arms 120 can be magnetically coupled to corresponding magnetic structures on the main body 105 of the tool 100 in order to releasably hold the drive head 110 thereon. The support 170 can be any structure that is adapted to support the drive head 110 within the main body 105 of the tool 100. In an embodiment, and as shown, the support 170 is a small column that extends between the two sets of idler gears 150 and is adapted to support the drive head 110 within the inside of the tool 100.
The drive head 110 provides a convenient and releasable structure wherein a user can actuate the lever arms 120 to remove the drive head 110 from the main body 105 of the tool 100. Further, the drive head 110 may include gear teeth disposed on the ratchet gear 155 that engage directly with the idler gears 150 on the main body 105. Thus, a more compact design can be obtained that allows for the motor 115 to transmit power to a releasable drive head 110 and eventually to a workpiece disposed within the receiving portion 125 of the drive head 110.
As shown in
The open-ended ratchet gear 505 is similar to the ratchet gear 155 discussed above, except that the open-ended ratchet gear 505 is arcuately shaped. The opening 515 of the ratchet gear 155 allows a workpiece to be radially inserted into the ratchet gear 505, and further allows the ratchet gear 155 to transmit torque to the workpiece without the necessity to axially engage the workpiece with the tool 100.
The insert cavity 510 includes a radial boundary that is adapted to allow the open-ended ratchet gear 505 to rotate and meshingly engage one or more of the idler gears 550. The open ratchet gear 505 is disposed within the insert cavity 510 such that at least one point of the ratchet gear 505 is engaged with the idler gear(s) 150 during full radial movement of the ratchet gear 505. The geometry of the insert cavity 510 thus allows uninterrupted power transmission to the ratchet gear 505.
The manner set forth in the foregoing description and accompanying drawings and examples, is offered by way of illustration only and not as a limitation. More particular embodiments have been shown and described, and it will be apparent to those skilled in the art that changes and modifications may be made without departing from the broader aspects of Applicant's contribution. The actual scope of the protection sought is intended to be defined in the following claims when viewed in their proper prospective based on the prior art.