The present invention relates to a movable blade release mechanism for a cutting tool. More particularly, the present invention relates to a cutting tool having a spring member that stores energy during operation such that when the stored energy is released a movable blade is returned to its initial position. Still more particularly, the present invention relates to a cutting tool in which a pinion gear is movable between first and second positions, such that energy is stored in a spring member when the pinion gear is in the first position and energy stored in the spring member is released when the pinion gear is in the second position.
Conventional cutting tools rotate a movable blade relative to a fixed blade to cut a cable. The movable blade is rotated from an initial position toward the fixed blade to cut the cable positioned between the two blades. After the cable is cut, the movable blade is rotated back to the first position.
The cutting process includes those two movements: advancing the movable blade toward the fixed blade, and returning the movable blade to its initial position. An important performance feature of cutting tools is the speed at which the cutting process can be conducted. Conventional cutting tools neglect the speed at which the movable blade is returned to its initial position after cutting a cable such that another cutting process can be conducted. Accordingly, a need exists for a cutting tool in which the movable blade is quickly returned to its initial position after cutting a cable.
Accordingly, a primary objective of the present invention is to provide an improved cutting tool for cutting a cable.
A further objective of the present invention is to provide an improved cutting tool in which the movable blade is quickly returned to its initial position after cutting a cable.
The foregoing objectives are basically attained by a cutting tool including a fixed blade having a first cutting surface and a movable blade having a second cutting surface. The movable blade is rotatable between a first position in which the second cutting surface is spaced from the first cutting surface of the fixed blade and a second position in which a cable disposed between the fixed and movable blades is cut by the first and second cutting surfaces. A return spring member is connected to the movable blade. The return spring member stores energy when the movable blade is rotated from the first position to the second position. The return spring member returns the movable blade to the first position when the stored energy is released. Accordingly, the movable blade is quickly returned to the first position such that another cutting process can be performed.
The foregoing objectives are also basically attained by a cutting tool including a fixed blade and a movable blade having a plurality of teeth. The movable blade is rotatable between a first position spaced from the fixed blade to receive an object therebetween and a second position adjacent the fixed blade to cut the object disposed between the fixed and movable blades. A drive pinion gear is movable between a drive position engaging the plurality of teeth of the movable blade and a return position disengaged from the plurality of teeth. The drive pinion gear rotates the movable blade from the first position to the second position in the drive position. A return spring member is connected to the movable blade to store energy when the movable blade is rotated from the first position to the second position and to release the stored energy to return the movable blade when the drive pinion gear is moved to the return position, thereby rotating the movable blade back to the first position. Accordingly, the movable blade is quickly returned to the first position such that another cutting process can be performed.
The foregoing objectives are also basically attained by a method of operating a cutting tool. A movable blade is rotated from a first position to a second position to cut a cable. A drive pinion gear is disengaged from the movable blade. The movable blade is rotated back to the first position after disengaging the drive pinion gear from the movable blade. Accordingly, the movable blade is quickly returned to the first position such that another cutting process can be performed.
Other objects, advantages and salient features of the invention will become apparent from the following detailed description, which, taken in conjunction with the annexed drawings, discloses preferred embodiments of the invention.
As used in this application, the terms “front,” “rear,” “upper,” “lower,” “upwardly,” “downwardly,” and other orientational descriptors are intended to facilitate the description of the cutting tool, and are not intended to limit the structure of the cutting tool to any particular position or orientation.
The above aspects and features of the present invention will be more apparent from the description for exemplary embodiments of the present invention taken with reference to the accompanying drawing figures, in which:
Throughout the drawings, like reference numerals will be understood to refer to like parts, components and structures.
As shown in
The movable cutting blade 12 has an inner edge 15 and an outer edge 18, as shown in
The fixed cutting blade 13 has an inner edge 24 and an outer edge 25, as shown in
A drive pinion gear 29 is non-rotatably, but axially movably, mounted on a drive shaft 30, as shown in
A mounting plate 35 is fixedly connected to the motor 31 and has an opening 36 through which the motor shaft 32 rotatably extends. A frame 37 is connected to the mounting plate 35 and has first and second pairs of recesses 38 and 39. The first frame plate 20 is received by the first pair of recesses 38 and the second frame plate 21 is received by the second pair of recesses 39, as shown in
A first or drive spring member 40 is disposed on the drive shaft 30 on one side of the drive pinion gear 29, as shown in
A linkage assembly 42 is connected between a trigger 43 and the sleeve 41, as shown in
A return pinion gear 52 is non-rotatably mounted on a return shaft 53 to rotate with the return shaft, as shown in
The return pinion gear 52 is disposed between the first and second frame plates 20 and 21. The return pinion gear 52 engages the plurality of teeth 17 of the movable blade 12. The second or return spring member 14 is disposed on the return shaft 53 on an opposite side of the second frame plate 21 from the return pinion gear 52. A first end 55 of the second spring member 14 is received by a slot 54 in the return shaft 53. A second end 56 of the second spring member 14 is fixed to the second frame plate 21, such as to a pin 71. Preferably, the second spring member 14 is a torsion spring. Accordingly, rotation of the second spring member 14 causes rotational energy to be stored therein. A bearing member 73 is disposed in the fixed blade 13 to allow the return shaft 53 to pass therethrough while allowing the return shaft 53 to rotate relative to the fixed blade 13.
A plurality of snap rings 74, 75 and 76 are disposed on the return shaft 53 to prevent axial movement of the return shaft 53, as shown in
A blade guide 58 is connected to the fixed blade 13, as shown in
Operation
The cutting tool 11 in accordance with the first exemplary embodiment of the present invention provides a quick return of the movable cutting blade 12 to a first, or receiving, position after using the tool to cut an object, such as a cable. Accordingly, the movable blade 12 is quickly returned to the first position such that another cutting process can be performed.
The movable blade 12 is shown in a first, or receiving, position in
To cut an object positioned between the movable and fixed cutting blades 12 and 13, electrical power is supplied to the motor 31 to rotate the motor shaft 32. First and second bevel gears 33 and 34 translate the rotation of the motor shaft 32 ninety degrees to rotate the drive shaft 30. The drive pinion gear 29 rotates with the drive shaft 30. The plurality of teeth 17 of the movable cutting blade 12 are engaged with the first pinion gear 29, such that rotation of the pinion gear 29 rotates the movable cutting blade in a cutting direction from a first or receiving position in which the first cutting surface 23 is spaced from the second cutting surface 28 to a second or cutting position in which an object disposed between the first and second cutting surfaces 23 and 28 is cut. A first end 60 of the movable cutting blade 12 abuts the stop member 59 to prevent further rotation of the movable cutting blade in the cutting direction. A load limiter electrically connected to a wiring harness or circuit board electrically connected to the motor 31 prevents excess force from being exerted by the movable cutting blade 12 on the stop member 59 by stopping the supply of power to the motor 31.
The rotation of the movable cutting blade 12 rotates the return pinion gear 52. The rotation of the return pinion gear 52 rotates the return shaft 53 in a first direction. The first end 55 of the second spring member 14 is fixed to the return shaft 53 and the second end 56 is fixed to a pin 71 connected to the second frame plate 21, as shown in
When the object has been cut, the user presses an upper portion 63 of the trigger 43. The movement of the upper portion 63 of the trigger 43 moves the first linking arm 44 inwardly. The linear movement inwardly of the first linking arm 44 rotates the second linking arm 47 about its rotation axis 51, as shown in
When the drive pinion gear 29 is disengaged from the teeth 17 of the movable blade 12, the motor 31 no longer rotates the movable blade 12. Accordingly, the return shaft 53 is also no longer rotated. This allows the second spring member 14 to release the stored rotational energy, which rotates the return shaft 53 in a second direction opposite to the first direction in which the return shaft was rotated during the cutting process. The rotation of the return shaft 53 rotates the return pinion gear 52 in a direction opposite to the direction in which the return pinion gear rotates during the cutting process. The movable cutting blade 12 is rotated in a return direction (opposite to the cutting direction) to its first position. The second end 61 of the movable cutting blade 12 abuts the stop member 59, thereby preventing further rotation in the return direction. Accordingly, the second spring member 14 quickly returns the movable cutting blade 12 to its first position after cutting an object.
When the movable blade 12 has returned to the first position, the user manually presses the lower portion 64 of the trigger 43 to move the first linking arm 44 linearly outwardly. The second linking arm 47 rotates about the rotational axis to move the second end 49 away from the sleeve 41. The first spring member 40 expands to its initial position, thereby moving the drive pinion gear 29 and the sleeve 41 on the drive shaft 30 along the longitudinal axis. The sleeve 41 is moved on the drive shaft 30 until it abuts the second end 49 of the second linking arm 47. The drive pinion gear 29 engages the plurality of teeth 17 of the movable cutting blade 12. The cutting tool 11 is in position to perform another cutting operation.
A second exemplary embodiment of the cutting tool 111 of the present invention is shown in
The movable blade 112 is shown in a first, or receiving, position in
As shown in
A return spring member 114 is mounted on the cutting blade shaft 191, as shown in
Cutting an object positioned between the movable and fixed cutting blades 112 and 113 is substantially similar to the process described with respect to the cutting tool 11 of the first exemplary embodiment. Electrical power is supplied to the motor 131 to rotate the motor shaft 32 (
The rotation of the movable cutting blade 112 rotates the cutting blade shaft 191 on which the movable cutting blade 112 is fixedly mounted. The first end 155 of the return spring member 114 rotates with the cutting blade shaft 191 and with respect to the fixed second end 156 of the return spring member 114, thereby twisting the second spring member 114 tighter and storing energy therein.
When the object has been cut, the user presses an upper portion 163 of the trigger 143. The movement of the upper portion 163 of the trigger 143 moves the first linking arm 44 (
When the drive pinion gear 129 is disengaged from the teeth 117 of the movable blade 112, the motor 31 (
While advantageous embodiments have been chosen to illustrate the invention, it will be understood by those skilled in the art that various changes and modifications may be made therein without departing from the scope of the invention as defined in the appended claims.
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European Search Report issued in Application No. 13275047.2-1709 dated Jul. 3, 2013. |
Number | Date | Country | |
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20150224660 A1 | Aug 2015 | US |
Number | Date | Country | |
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Parent | 13412435 | Mar 2012 | US |
Child | 14691748 | US |