This application claims the benefit of related U.S. patent application Ser. No. 15/149,227, filed May 9, 2016, and PCT Application No. PCT/US17/31508 filed May 8, 2017; the contents of each of which are incorporated herein by reference in their entirety.
The disclosure relates to an adjustable wrench, and in particular to a wrench which engages at least three faces of a bolt or nut with pressure.
A wrench is a hand or machine operated tool to apply mechanical advantage to increase torque while rotating fasteners for tightening or loosening. A closed-ended wrench may be engaged with a nut or bolt when the wrench can be passed over an end of the nut or bolt. An open-ended wrench is used where the nut or bolt can only be accessed from a side approach. Adjustable wrenches include the monkey, pipe, or crescent wrench, as well self-adjusting wrenches.
In an embodiment of the disclosure, a wrench connectable to a standard square shaped extension, comprises a wrench head including opposed jaw faces each having a planar surface portion, the jaw faces mutually defining a transverse plane connecting the jaw faces and lying perpendicular to each of the planar surface portions; and a standard square shaped extension socket affixed to the wrench head, the standard square shaped extension insertable into the standard extension socket along a direction that is non-orthogonal to the transverse plane.
In a variation thereof, the wrench further includes a frame including a fixed jaw forming one of the opposed jaw faces, the fixed jaw having a planar surface portion; a movable jaw forming the other of the opposed jaw faces, the movable jaw including at least one jaw face having a planar surface portion; the planar surface portion of the at least one movable jaw face remaining parallel to the planar surface portion of the fixed jaw face as the movable jaw is moved, the fixed and movable jaw faces mutually defining a transverse plane connecting the fixed and movable jaw faces and lying perpendicular to each of the planar surface portions; a guide connected to the frame and the movable jaw to control movement of the movable jaw along a line; and the standard square shaped extension socket affixed to one of the frame and the guide.
In another embodiment of the disclosure, a wrench connectable to a standard square shaped extension comprises a frame having a fixed jaw face having a planar surface portion; a movable jaw including at least one jaw face having a planar surface portion; the planar surface portion of the at least one movable jaw face remaining parallel to the planar surface portion of the fixed jaw face as the movable jaw is moved; and a guide connected to the frame and the movable jaw to control movement of the movable jaw along a line, the guide including: an elongate rotatable shaft, a portion of the shaft rotatable within a portion of the frame, a portion of the shaft including threads, the shaft rotatable to move the movable jaw; a standard extension socket connected to the frame, the socket forming a standard square extension socket of the type having a square inner profile engageable with a square outer profile at an end of the standard square shaped extension.
In variations thereof, the wrench further includes a widened portion at a free end of the shaft, the widened portion sized and dimensioned to be grasped by the hand of a user of the wrench, the standard extension socket positioned within a free end of the widened portion; the shaft is positioned at least one of alongside or in-line with the movable jaw; the frame, fixed jaw, and movable jaw forming the head portion of a standard monkey wrench; the shaft includes a free end, the portion of the shaft that is rotatable within the frame being an end opposite the free end; the shaft is threadably engaged with the frame; and/or the rotatable shaft is rotatable in a first direction to move the movable jaw away from the fixed jaw and to extend the shaft away from the frame to thereby increase an overall length of the wrench.
In further variations thereof, the at least one movable jaw face includes first and second jaw faces forming an angle of about 120 degrees relative to each other, each of the first and second jaw faces defining a planar surface portion along a longitudinal axis thereof; and the guide is connected to the frame and the movable jaw to control movement of the movable jaw along a line forming an angle of one of about 19.1 and about 40.9 degrees with respect to an intersection of the line and the planar portion of the fixed jaw face. In a variation thereof, the fixed, first, and second jaw faces defining a mutually intersecting plane, there being a part of the wrench lying upon the plane between the first jaw face and the fixed jaw face which is open to admit passage of the fastener along the plane, thereby forming an open end or flare style wrench.
In other variations thereof, the at least one movable jaw face includes first and second jaw faces forming an angle of about 120 degrees relative to each other, each of the first and second jaw faces defining a planar surface portion along a longitudinal axis thereof; and the guide is connected to the frame and the movable jaw to control movement of the movable jaw along a line forming an angle of about 40.9 degrees with respect to an intersection of the line and the planar portion of the fixed jaw face; the guide further includes a channel formed in at least one of the frame and movable jaw, and a projection formed upon the other of the frame and movable jaw, the projection and channel forming a mating slideable connection; the guide further includes a slot within the frame within which the movable jaw is slideably retained; an end of the shaft rotatably received within the movable jaw; the standard extension socket includes a detent dimensioned to receive a spring loaded ball of the standard square shaped extension when the extension is inserted within the socket; and/or the socket is sized to receive one of a ⅛, ¼, ⅜, ½, ¾, or 1 inch standard socket extension.
In another embodiment of the disclosure, a device for rotating a hex shaped fastener comprises a frame having a fixed jaw face defining a planar surface portion extending along a longitudinal axis thereof; a movable jaw including first and second jaw faces forming an angle of about 120 degrees relative to each other, each of the first and second jaw faces defining a planar surface portion along a longitudinal axis thereof; and a guide connected to the frame and the movable jaw to control movement of the movable jaw along a line forming an angle of one of about 19.1 and about 40.9 degrees with respect to an intersection of the line and the planar portion of the fixed jaw face, the guide including an elongate shaft including a first end engaged with the frame, and a second end at an end opposite the first end, the second end including a standard extension socket that includes a square shaped socket; the planar surface portion of the first jaw face remaining parallel to the planar surface portion of the fixed jaw face as the movable jaw is moved, the fixed, first, and second jaw faces defining a mutually intersecting plane, there being a part of the device lying upon the plane between the first jaw face and the fixed jaw face which is open to admit passage of the fastener along the plane.
In a variation thereof, the shaft is threadably engaged with the frame; and/or the rotatable shaft is rotatable in a first direction to move the movable jaw away from the fixed jaw and to extend the shaft away from the frame to thereby increase an overall length of the device.
A more complete understanding of the present disclosure, and the attendant advantages and features thereof, will be more readily understood by reference to the following detailed description when considered in conjunction with the accompanying drawings wherein:
As required, detailed embodiments are disclosed herein; however, it is to be understood that the disclosed embodiments are merely examples and that the systems and methods described below can be embodied in various forms. Therefore, specific structural and functional details disclosed herein are not to be interpreted as limiting, but merely as a basis for the claims and as a representative basis for teaching one skilled in the art to variously employ the present subject matter in virtually any appropriately detailed structure and function. Further, the terms and phrases used herein are not intended to be limiting, but rather, to provide an understandable description of the concepts.
The terms “a” or “an”, as used herein, are defined as one or more than one. The term plurality, as used herein, is defined as two or more than two. The term another, as used herein, is defined as at least a second or more. The terms “including” and “having,” as used herein, are defined as comprising (i.e., open language). The term “coupled,” as used herein, is defined as “connected,” although not necessarily directly, and not necessarily mechanically.
The disclosure relates to wrenches which grasp and turn the head of a nut, bolt, other fastener, or any other object graspable by the various embodiments herein, hereinafter simply fastener 300. The wrenches being referred to herein generally as 100, and in variations distinguished with a letter suffix. While the various embodiments are designated with a letter suffix for clarity, it should be understood that among the various embodiments, like numbers refer to like elements, and that the various embodiments of wrench 100 contain common features, as will be understood with reference to the drawings and the accompanying description.
With reference to
Movable jaw 120 includes two faces 122, 124 forming an angle of about 120 degrees between them, when wrench 100A is configured for a hex head bolt, as illustrated. The term ‘about’ is used to indicate that manufacturing tolerances can produce variations in angle, and in consideration that variances of plus or minus a few degrees will still produce a working result, although a substantial deviation from 120 degrees will result in a less satisfactory device in terms of fit and performance. It should be understood that this angle will differ for a five or eight sided head, for example. In this embodiment, as movable jaw 120 slides within channel 144, face 122 maintains a parallel disposition with respect to face 148 of fixed jaw 142. To do so, an angular disposition of faces 122 and 124 with respect to axis “A” is defined by an angular disposition of face 148 with respect to such axis. In the embodiment shown, the angle is about 48 degrees, although this angle can be different. For example, a steeper angle which is more perpendicular to the movement axis, or a shallower angle can be used. Each has potential trade-offs in terms of the size and shape of frame 140, and the bending forces exerted upon frame 140, and thus a compromise or particular angle can be established for the intended purpose of the wrench, which is determinable by one skilled in the art.
As can be seen in the figures, movable jaw 120 and fixed jaw 142 maintain a contact along three sides of a six-sided fastener when adjusted to grip the fastener head 302. A first ‘flat’ of the fastener head 302 (or any other object with engagement faces, such as a nut or plate) is engaged by face 148 of fixed jaw 142, and a second flat, directly opposite the first flat is engaged by face 122 of movable jaw 120. The third flat, adjacent to the second flat, is contacted by face 124 of movable jaw 120, and a shared corner of the fastener head 302 is engaged at an intersection of faces 122 and 124.
As can be seen in
Movement of movable jaw 120 is carried out by an engagement between threads 182 of an adjusting shaft 180 and corresponding threads 150 of a bore 152 passing through frame 140. A distal end of shaft 180 passes into a bore 128 within moveable jaw 120, and is rotatably secured by an engagement 184 of shaft 180 and movable jaw 120, which permits rotation of shaft 180 with respect to movable jaw 120. In this embodiment, engagement 184 includes a pin 186 passing through movable jaw 120, pin 186 slidably retained within a groove 188. It should be understood, however, that engagement 184 can be accomplished by any other known or hereinafter developed method, such as a press fit, or axial screw. In an embodiment, dimensional tolerances of pin 186, groove 188, and shaft 180 enable a leading end 194 of shaft 180 to bear upon an interior blind end of bore 128 of moveable jaw 120, as shaft 180 is rotated and moveable jaw 120 is tightened against nut or fastener 300. In this manner, tightening stress is not transferred to pin 186. The pitch of threads 182 can be selected to balance precision and accuracy for a fine pitch against, for example, considerations of manufacturing tolerance and speed of adjustment for a courser/steeper pitch.
In the embodiment of
In an embodiment, grip 192 is affixed to shaft 180, whereby rotation of grip 192 causes a corresponding rotation of shaft 180, and a corresponding movement along axis “A”. In this manner, as handle 190 is moved radially with respect to a rotational axis of nut or fastener 300, grip 192 can be simultaneously rotated about axis “B” to maintain a firm and secure engagement with the nut or bolt head by maintaining pressure of an engagement of movable jaw 120 against the first, second, and third flats and the shared corner. Moreover, the tightening force exerted by rotation of the grip drives the distal end of shaft 180 directly and linearly towards fastener 300, in turn driving the nut or bolt head directly and linearly into fixed jaw 142, resulting in an efficient transfer of tightening energy. Accordingly, a smooth coordinated motion can both tighten or loosen a nut or bolt, while at the same time maintaining pressure on a grip of the fastener 300.
With reference to
In an alternative embodiment, shown in
It should be understood that a configuration providing for bolt 154 or frame brace 162 is not needed in all applications, and that sufficient strength can be obtained by a choice of sufficiently strong materials and part thickness.
As can be seen in
With respect to installing movable jaw 120 within frame 140, it should be understood that movable jaw can be installed prior to, or during formation of frame 140, and therefore guide rail 146A can be longer than illustrated. Additionally, brace elements can have a shape or location which would not be possible in a configuration where movable jaw 120 must be installed after formation of frame 140.
In the embodiment of
In
In
Referring now to
In
In the closed and partially closed end configurations of wrench 100, the two faces 122, 124 of movable jaw 120 are positioned on an opposite side of bolt 300 with respect to engagement of faces 148, 204. In all embodiments, including open ended wrenches 100 such as are shown in
More particularly, as can be seen in
Thus, movable jaw is guided by shaft 180 and/or guide rails 146, or is otherwise guided to follow a path along line “A” that lies at an angle of about 19 degrees with respect to a plane formed by either fixed face 148 or 204. Thus, if the 19 degree angle is formed between fixed face 148 and line “A”, movable jaw face 124 will lie at an angle of 120 degrees relative to adjacent fixed face 148. Likewise, if the 19 degree angle is formed between fixed face 204 and line “A”, movable jaw face 124 will lie at an angle of 120 degrees relative to adjacent fixed face 204. Line “A” additionally intersects a corner formed by faces 122 and 124 of movable jaw 120.
A model of movement of movable jaw 120 with respect to faces 148 and 204 is illustrated in
It is desired that fixed jaw 142 and movable jaw 120 ‘land’ against and fully engage with pressure against the faces of bolt 300, subjecting bolt head 302 to a pinching or wedging force. The wedging force is exerted along the entire surface of the contacted faces of bolt head 302 with continuously increasing pressure, as pressure applied by movable jaw 120 is increased, and as the wrench is rotated to tighten bolt 300.
It should be understood that forming an angle between line “A” and either of the fixed jaw faces 148, 204 need not be exactly 19.1 degrees for wrench 100 to function. As a practical matter, to control costs, parts of wrench may be fabricated using manufacturing methods which may not produce movement along an angle of exactly 19.1 degrees, particularly in light of tolerance stackup amount several parts. Provided there is an ability for movable jaw 120 to wobble or displace along its guide path, it may still be possible to fully engage bolt 300 if the angle is merely about 19 degrees, for example it may be varied to any extent plus or minus up to 6 or more degrees, for example by several tenths or several degrees, but the range of bolt 300 sizes that can be accommodated may be reduced, as well as the reliability and strength of wrench 100, as the deviation from an angle of 19.1 degrees increases.
Likewise, the 60 degree angle formed between fixed faces 148 and 204 can vary, as can the 120 degree angle formed between the faces 122, 124 of movable jaw 120. An angle of about 60 degrees or about 120 degrees, respectively, may be sufficient. For example these 60 and 120 degree angles could be increased or decreased to any extent up to 6 or more degrees, for example several tenths or several degrees, but with progressively diminished wrench performance as the angle deviates.
As shown in
Because wrench 100 does not engage opposite points of bolt head 302, movement of movable jaw 120 along line “A” is not aligned through opposed points of bolt head 302. The geometry of an optimized wrench of the disclosure is illustrated in
For open ended wrenches, such as are shown in
The angular orientation of jaw movement along line “A” with respect to faces 148 and 204 is governed by angle θ, which can be derived as follows. If a length of a face of bolt head 302 is taken to be x, then an adjacent side of triangle 176 is formed by an equilateral triangle having all sides equal to x, a side of bolt head 302 which is equal to x, and a side of a 30-60-90 degree right triangle. It is known that the relationship of the sides of a 30-60-90 right triangle are 1:sqrt(3):2, which gives us a length of 0.5x for the last portion of the adjacent leg of triangle 176. Once we have the adjacent and opposite lengths of triangle 176, we can calculate θ as:
tan(θ)=0.866/2.5, or θ=tan−1(0.3464)=19.1 degrees.
Alternatively, we can calculate the hypotenuse using the Pythagorean theorem and calculate θ as:
sin(θ)=0.866/2.64574, or θ=sin−1(0.3273)=19.1 degrees.
The particular engagement of bolt head 302 described above enables an open ended wrench, as compared with engaging opposing corners of bolt head 302, in that an open ended wrench of the disclosure is practical and secure, and is particularly so with large bolts (e.g. as illustrated in
More particularly, frame 140J includes a closed end 198J including closed ended jaw 148J which is connected to a U-shaped base portion 210 of frame 140J at pivot 212. A movable pivot 214 connects closed ended jaw 148J, at an opposite end with respect to pivot 212, to a sliding latch portion 216. Movement of sliding latch portion 216 is confined to a path defined by a rail 218 extending from U-shaped base portion 210 which mates with a corresponding channel 220 within sliding latch portion 216. Channel 220 can be formed on opposite sides of sliding latch portion 216, and rail 218 can be formed on both inner sides of base portion 210, which forms a channel within which sliding latch portion 216 moves. As with other rail/channel engagements herein, it should be understood that the relative locations of the rail and channel can be reversed; in this instance, for example, rail 218 can be formed in sliding latch portion 216 and channel 220 can be formed in base portion 210.
A spring 224 connects sliding latch portion 216 and handle 190J, urging sliding latch portion 216 into mating engagement with pivotable latch portion 232 which extends from handle 190J. Spring 224 can alternatively be connected between sliding latch portion 216 and U-shaped base portion 210. While spring 224 is illustrated as a tension spring, it should be understood that sliding latch portion 216 can be biased into mating engagement with pivotable latch portion 232 by other spring types as would be understood within the art. For example, a torsion or clock spring can be associated with pivot 212.
Sliding latch portion 216 includes a catch 230, and pivotable latch portion 226 includes a hook 234 which matingly engage when sliding latch portion 216 and pivotable latch portion are in mating contact. To disengage catch 230 and hook 234, handle 190J is pushed in an upwards direction as viewed in the figures, to rotate handle 190J counter-clockwise about handle pivot 226. A torsion or clock spring 228 can be connected to base portion 210 and handle 190J to bias handle 190J to rotate clockwise to engage catch 230 and hook 234. A ledge 254 is formed within U-shaped frame portion 210 braces handle 190J and forms a limit to clockwise rotation of handle 190J with respect to frame 140P. Ledge 254 cooperates with pivot 228 when tightening fastener 300 to brace handle 190J when applying torque to frame 140P. A stop 256 formed as a protrusion upon frame 140J limits rotation of handle 190J with respect to frame 140J during release of fastener 300. For the embodiment of
To use wrench 190J to tighten a fastener 300, bolt head 302 is positioned within frame 140J and is contacted by frame faces 148, 204 and movable jaw faces 122, 124, as described elsewhere herein. End grip 192 is grasped by a hand of the user and wrench 100J is rotated clockwise along the plane of the page, as viewed in the figures, to move wrench 100J through a tightening stroke. Due to engagement of catch 230 and hook 234, sliding latch portion 216 is unable to move, and wrench 100J functions in the manner of fixed wrench 140E of
With reference to
When the relative rotation of wrench 100J and fastener 300 is sufficient to realign faces of bolt head 302 with frame faces 148, 204 and movable jaw faces 122, 124, bolt faces no longer push against close ended jaw 148J. As such, an interior dimension of the enclosed portion of frame 140J can once again be reduced in size as spring 224 pulls sliding latch portion 216 back into latched engagement with pivotable latch portion 232. Once reengaged, frame handle 190J can once again be rotated in a clockwise direction to continue turning or tightening fastener 300 as described above.
With reference to
Referring now to FIGS.
Frame 140P pivotally supports handle 190P at pivot 226, as described with respect to
When handle 190P is moved counter-clockwise about pivot 226, as viewed in
A biasing element 260 of any type, in this example a spring, connects between frame 140P or handle 190P and fixed jaw 142P, to urge fixed jaw 142P to rotate about pivot 214P, clearing a space under of fixed jaw 142P so that block 252 can slide under fixed jaw 142P. When it is desired to locked fixed jaw 142P, handle 190P is pulled back to contact ledge 254, while causing block 248 to slide under lock jaw 142P, thereby locking jaw 142P in position for a subsequent tightening or loosening operation.
Wrenches 100J and 1001P can be flipped over vertically, as viewed in the Figures, and re-engaged with a fastener 300, whereby fastener 300 can be tightened or loosened in an opposite rotational direction. As in
With reference to
Socket 400 includes analogous parts to the various forms of wrench 100 described herein, and which have analogous functions. This includes movable jaw 120S, adjusting shaft 180, end grip 192S, frame 140S, fixed engagement faces 148, 204, movable engagement faces 124, 122 and threaded bore 152S. For compactness, bore 128S is oriented to be adjacent to movable jaw faces 122 and 124, repositioning shaft bore 152S adjacent to movable and fixed jaws 120S and 142S. A recess 272 is formed within the socket frame 140S, so that fingers can rotate grip 192S to rotate shaft 180 and change a position of movable jaw 120S. Rotation of grip 192S causes movable jaw to move towards or away from fixed engagement faces 148, 204, to engage a bolt head 302 as described elsewhere herein.
A slot 274 is formed within socket frame 140S, and guides movement, and prevents rotation, of movable jaw 120S. Shaft 180 prevents tilting of movable jaw 120S. Threads 182 can be formed to limit axial movement of movable jaw 120S, or a land or other obstruction can be formed within frame 140S.
For compactness, it may be seen that shaft 180 is positioned alongside or side-by-side with movable jaw 120S, instead of in-line behind movable jaw 120S as in other embodiments herein. It should be noted, however, that this side-by-side arrangement can be carried out in the other embodiments, as well.
Referring now to
In the embodiment shown in
In
As mentioned above, any known method can be used to maintain shaft 180 in rotatable connection to moveable jaw 120. An additional example is illustrated in
With further reference to
In
By using a standard extension socket 320 on a prior art wrench head 328 or a wrench 100 of the disclosure, a toolkit can save space by including multiple wrench heads, each with a substantially shorter handle than would otherwise be needed for many applications requiring the leverage a longer handle would afford. However, the toolkit need only include a single standard socket extension 350, or socket extensions 350 of varying sizes, which can be used with a plurality of wrench heads. In addition, the various forms of socket extensions can be used to access locations which would otherwise be difficult, including swiveling socket extensions, for example of the type including a u-joint, or extensions including a dog-leg or offset portion.
Wrenches of the disclosure can be made of any material with sufficient hardness, durability, and strength for a particular application, as well as resistance to damage due to liquids or other substances found within a particular use context. Materials can include metal or plastic, or a composite material, for example. Some or all of a wrench of the disclosure can be made by casting, forging, machining, molding, stamping, grinding, 3D printing, extrusion, welding, brazing, or any other manufacturing method appropriate to the shapes shown and described, with consideration to hardness, durability, and strength, as well as attractiveness and precision. Some or all of the components shown and described can be provided with an attractive and durable finish, such as by chroming, painting, coating, knurling or stamping.
All references cited herein are expressly incorporated by reference in their entirety. It will be appreciated by persons skilled in the art that the present disclosure is not limited to what has been particularly shown and described herein above. In addition, unless mention was made above to the contrary, it should be noted that all of the accompanying drawings are not to scale. There are many different features to the present disclosure and it is contemplated that these features may be used together or separately. Thus, the disclosure should not be limited to any particular combination of features or to a particular application of the disclosure. Further, it should be understood that variations and modifications within the spirit and scope of the disclosure might occur to those skilled in the art to which the disclosure pertains. Accordingly, all expedient modifications readily attainable by one versed in the art from the disclosure set forth herein that are within the scope and spirit of the present disclosure are to be included as further embodiments of the present disclosure.
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Number | Date | Country | |
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20210023683 A1 | Jan 2021 | US |
Number | Date | Country | |
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Parent | 15718569 | Sep 2017 | US |
Child | 17034097 | US |
Number | Date | Country | |
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Parent | PCT/US2017/031508 | May 2017 | US |
Child | 15718569 | US | |
Parent | 15149227 | May 2016 | US |
Child | PCT/US2017/031508 | US |