The invention relates generally to a tool handle for holding rotary tools and more particularly to an improved multi-function, reconfigurable tool handle for holding taps and extractors and other fastener tools such as screwdriver bits, sockets and the like.
Taps and extractors are rotary tools for making threaded holes and removing stripped fasteners, respectively. In order to generate sufficient torque, taps and extractors are typically used with a handle that can be rotated by hand. The taps and extractors are releasably connected to the handle such that the handle can be used with different taps and extractors. Typically the taps and extractors include male connector portions that engage a female receptacle formed on the handle.
Existing tap and extractor handles are specifically designed to engage taps and extractors such that they are not useable with other fastener tools such as sockets and screwdriver bits. Moreover, known handles do not offer sufficient flexibility in the configuration of the handle for different applications. Known handles also do not provide a reconfigurable design that is easy to use yet can adequately transfer high torque.
A multi-purpose tool handle that can be connected to a wide variety of tools and that is easily reconfigurable for different applications is desired.
The tool handle of the invention includes a shank connected via a ratcheting mechanism to a male square drive. A pair of handle wings are pivotally connected to the shank at a transverse pivot hinge such that the handle wings can be changed between a screwdriver-type configuration, an L-shape configuration, a T-shape configuration and other configurations. When the handle wings are in the fully open position, the handle wings bear against the shank to create a mechanism for transferring power between the handle wings and the tool shank without the need for a separate lock. A quick change adapter having a female drive can be connected to the male square drive such that the tool handle can be used with a wide variety of tools including taps and extractors, sockets, screwdriver bits and the like.
Referring more particularly to
Referring more particularly to
Handle wing 10 includes a handle portion 40 that terminates in outer flanges 42 and 44 and inner flange 46 that define apertures 48, 50 and 52, respectively. The apertures are coaxially aligned with one another and are dimensioned to closely but rotatably receive hinge pin 54. Handle wing 12 may be identical to handle wing 10 and includes a handle portion 56 that terminates in outer flanges 60 and 62 and inner flange 64. Flanges 60 and 62 define apertures 68 and 72, respectively. Flange 62 also defines an aperture (not shown) similar to aperture 48 defined by flange 42. The apertures formed on flanges 60, 62 and 64 are dimensioned to closely but rotatably receive hinge pin 54 and are coaxially aligned with one another and with apertures 48, 50 and 52 of handle wing 10 in the assembled tool handle.
These components can be made by metal injection molding, or die cast zinc-aluminum alloy fabrications. A secondary material such as TPR can be overmolded on the handles to improve the grip and comfort of the tool.
Inner flange 46 of handle wing 10 and inner flange 64 of handle wing 12 are dimensioned to closely but rotatably fit between flanges 16 and 18 of shank 10. Inner flange 46 and inner flange 64 each include a flat face that abut one another when the flanges are located between the flanges 16 and 18. Moreover, each of inner flanges 46 and 64 include detents 76 spaced about the periphery thereof such that the detents on inner flange 46 may be aligned with the detents on inner flange 64 to define recesses for receiving ball 36. The detents are spaced about the periphery of the flanges 46 and 64 so that they are aligned with ball 36 when the wing handles 10 and 12 are in any of the desired configurations described with reference to
Outer flange 44 is spaced from inner flange 46 so as to be positioned outside of and in abutting contact with flange 18. Outer flange 62 is spaced from flange 64 so as to be positioned outside of and in abutting contact with flange 44. Outer flange 60 is spaced from inner flange 64 so as to be positioned outside of and in abutting contact with flange 16. Outer flange 42 is spaced from inner flange 46 so as to be positioned outside of and in abutting contact with outer flange 60. Hinge pin 54 passes through the apertures defined by the interdigitated flanges to complete the pivot hinge 14. In this manner the flanges of the handle wings 10 and 12 and the shank 2 are interdigitated to create a strong connection at pivot hinge 14 to maximize the amount of torque that can be transferred through the wing handles 10 and 12 to the shank 2. In one embodiment the flanges are tapered from the inner flange to the outermost flange to create a streamlined profile as best shown in
A hinge pin cover 80 is friction fit into aperture 53 of hinge pin 54 to lock the hinge pin in place. The handle wings 10 and 12 are free to rotate relative to one another and relative to the shank 2 such that the handle wings can be rotated independently or together as a unit. The engagement of ball 36 with detents 76 locks the handles in the desired position. It is to be understood that the engagement of ball 36 and detents 76 can be overcome by manually applying a rotational force to either of the handle wings sufficient to depress spring 34 and release ball 36 from detents 76. The spring is preferably selected such that this force can be overcome by the force applied by a typical user with one hand. In this manner the tool handle can be reconfigured very easily by the user.
The inner face 40a of handle wing 10 is positioned substantially on the centerline of the apertures formed on flanges 42, 44 and 46. Likewise, the inner face 56a of handle wing 12 is positioned substantially on the centerline of the apertures formed on flanges 60, 62 and 64. As a result, when the handles are in the closed position of
Because it may be necessary to exert a significant force toward square tool drive 4 when using the tool handle, the handle wings 10 and 12 are designed such that a portion 82 of the handle wings 10 and 12 abuts shank 2 when the handle wings are in the fully opened position. Portion 82 is the area of the handle wings between and adjacent to the flanges that contacts shank 2. In one embodiment portion 82 may be configured to conform to the outer shape of shank 2. In this manner, forces exerted on the handle wings 10 and 12 are transferred by direct load bearing contact from the handle wings to shank 2. This arrangement provides strong support for the handle wings and an effective force transference between the handle wings and the shank without the use of additional locking or load transferring mechanisms.
The opposite end of shank 2 is formed with a first extension 86 that meets with the shank to create a shoulder 88. A second semi-circular extension 90 extends from the base of the first extension to create a semi-circular recessed area 94 (the recessed area 94 is identical to area identified by reference numeral 294 in
The square tool drive 4 includes a ball detent 116 on the square drive connector 115 to releasably engage a tool having a female connector portion such as a socket. In one embodiment, square drive connector 115 is a ⅜ inch male connector that will fit most standard ⅜ inch drive sockets. The square drive also can be connected to a quick change adapter 120 that includes a cavity 122 for releasably receiving square drive connector 115. Cavity 122 includes a recess 124 for receiving ball detent 116 to lock the adapter on the square drive. A chuck 125 for connecting the quick change adapter 120 to a tap, extractor or other tool having a male connector portion is provided on the distal end of the quick change adapter. The ratchet, square drive and adapter may be made of powdered metal or cold or hot forged metal.
Referring more particularly to
Handle wings 210 and 212 are identical and include a handle portion 240 that terminates in flanges 242 and 244 and that define apertures 248 and 250, respectively. The apertures are coaxially aligned with one another and are dimensioned to closely but rotatably receive hinge pins 255. Hinge pins 255 are inserted through the axially aligned apertures to create a pivot hinge connection between the handle wings 210 and 212 and the shank 202. A hinge pin cover 280 is friction fit into an aperture (not shown) on shank 202 to lock the hinge pins 255 in place. The handle wings 210 and 212 are free to rotate relative to one another and relative to the shank 202 such that the handle wings can be rotated independently.
These components can be made by metal injection molding or die cast zinc-aluminum alloy fabrications. A secondary material such as TPR can be overmolded on the handles to improve the grip and comfort of the tool.
The flanges 242 and 244 of handles 210 and 212 are dimensioned to closely but movably fit between flanges 216 and 218 of shank 202. Moreover, handle wings 210 and 212 include apertures 274 and 276 for receiving the protrusions 227 and 229 extending from latch pin head 232. Release button 230 is used to move latch pin 226 into and out of engagement with the apertures on handles 210 and 212. When the latch pin is engaged with the apertures handles 210 and 212 are prevented from moving relative to the shank 202, when the latch pin is removed from the apertures 274 and/or 276, the handle wings can be pivoted between the closed position shown by handle wing 210 and the open position shown by handle wing 212.
The opposite end of shank 202 is formed with a first extension 286 that meets with the shank to create a shoulder 288. A second semi-circular extension 290 having a smaller diameter than the first extension 286 extends from the base of the first extension to create a semi-circular recessed area 294. Positioned in the recessed areas 294 are a pair of pawls 296 that have gear teeth 298 that engage with mating gear teeth 307 on square drive 4 as will hereinafter be described. A ratchet spring 300 is disposed in aperture 301 between the free ends of pawls 296 to exert a force on the pawls tending to urge the ends of pawls away from one another. The pawls are formed with pivots 302 that fit into mating cavities 303 formed in recessed area 294 such that the pawls 296 rotate about pivots 302 in cavities 303. A ratchet ring 304 fits over pawls 296 and rotatably receives the annular portion 306 of square drive. A shaft 308 extends from square drive into a longitudinally extending bore (not shown) formed in shank 202. The shaft has an annular groove 309 formed therein. A pin 310 is inserted through a transverse bore formed in shank 202 such that the pin engages groove 309 to retain the square drive in the shank but allow it to rotate relative to the shank. A ratchet detent ball 311 is biased into engagement with recesses 312 by ratchet detent spring 314 to hold the ratchet ring in the desired position. The ratchet ring includes a camming surface 315 can be rotated between one of three positions as described with reference to the embodiment shown in
Referring more particularly to
Handle wing 410 includes a handle portion 440 that terminates in flanges 442 and 444 and that define apertures 448 and 450, respectively. The apertures are coaxially aligned with one another and are dimensioned to closely but rotatably receive hinge pin 454. Likewise handle wing 412 may be identical to handle wing 410 and includes a handle portion 456 that terminates in flanges 460 and 462 that define apertures 468 and 470, respectively. The apertures are coaxially aligned with one another and are dimensioned to closely but rotatably receive hinge pin 454. The flanges 442 and 460 are dimensioned to closely but movably fit between over flange 416. Flanges 444 and 462 are dimensioned to closely but movably fit over flanges 460 and 442, respectively. Hinge pin 454 is inserted through the axially aligned apertures to create a pivot hinge connection between the handle wings 410 and 412 and the shank 402, respectively.
These components can be made by metal injection molding or die cast zinc-aluminum alloy fabrications. A secondary material such as TPR can be overmolded on the handles to improve the grip and comfort of the tool.
The locking mechanism for locking the handles in the desired position is the same on both sides of the shank, for explanatory purposes only one side will be described. The locking mechanism comprises locking pin 480 slidably received in bore 420 and biased so as to extend out of the bore 420 by spring 482. The pin is located on flange 416 such that in the normal locked position it can engage detents 484 formed about the periphery of aperture 448 in flange 442. A release ring 486 is slidably positioned on pin 454 such that it contacts pin 480. A pin retainer 488 covers the release ring and a release button 490 is connected to hinge pin 455. To release the locking mechanism, release button 490 is depressed causing release ring 486 to depress pin 480 until the pin no longer engages detent 484. The handle can then be rotated. When release button is released, spring 482 extends pin 480 back into engagement with detents 484. Because the locking mechanism may be formed on both sides of flange 416, a user will typically squeeze both release buttons simultaneously to release both handles at the same time.
A ratchet assembly 490 as previously described with reference to
In operation the tool handle is connected to a tool either by direct connection to the square tool drive or via the quick change adapter. The tool handle can then be reconfigured to the desired grip configuration based on the amount of torque required and the space available to access the workpiece. The ergonomic design also provides an advantage for people with disabilities such as arthritis. By providing the opposing wings, it is possible to use the strength of both hands and arms to turn the tool.
Specific embodiments of an invention are disclosed herein. One of ordinary skill in the computing and financial arts will quickly recognize that the invention has other applications in other environments. Many embodiments are possible. The following claims are in no way intended to limit the scope of the invention to the specific embodiments described above.
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Number | Date | Country | |
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20070000097 A1 | Jan 2007 | US |