CUTTER ADAPTED FOR USE WITH A POWER TOOL

Abstract

A cutter includes a main body, a cog assembly, and a blade. The main body is provided with an anvil. The cog assembly includes a drive shaft and a first and a second cog. The drive shaft is rotatably connected to the main body. The drive shaft has a first end configured to detachably connect which a power tool. The first cog moves synchronously with the drive shaft. The second cog is rotatably connected to the main body and rotates upon rotation of the first cog. The blade is rotatably connected to the main body and connected to the second cog. The blade is rotatable between a deployment position and a cutting position and has a cutting edge. The cutting edge is disposed away from the anvil when the blade is in the deployment position, but is adjacent to the anvil when the blade is in the cutting position.

Claims

1. A cutter adapted for use with a power tool comprising: a main body including an anvil; a cog assembly including a drive shaft and a first and a second cog, wherein the drive shaft is rotatably connected to the main body, wherein the drive shaft has a first end configured to detachably connect which the power tool, wherein the first cog is disposed on the drive shaft and moves synchronously with the drive shaft, and wherein the second cog is rotatably connected to the main body and rotates upon rotation of the first cog; and a blade connected to the cog assembly, wherein the blade is rotatably connected to the main body and connected to the second cog in a manner that rotates synchronously with the second cog, wherein the blade has a cutting edge selectively cutting the object to be cut by the cutter, wherein the blade is rotatable between a deployment position and a cutting position with respect to the object, and wherein the cutting edge is disposed away from the anvil when the blade is in the deployment position, but is adjacent to the anvil when the blade is in the cutting position.

2. The cutter as claimed in claim 1 further comprising a clamping device configured to selectively clamp and release the object, wherein the clamping device is rotatably connected to the main body and being rotatable between a clamping position and a release position with respect to the object, wherein the clamping device is adjacent to the blade, wherein the clamping device is rotatable about a rotation axis and has a holding portion at a first end and an operating portion at a second end, and wherein the holding portion is disposed adjacent to the anvil when the clamping device is in the clamping position, but is away from the anvil when the clamping device is in the release position.

3. The cutter as claimed in claim 2, wherein the clamping device is attached to a resilient member, wherein the resilient member applies a force opposite to a force causing rotation of the clamping device, and wherein the resilient member has a first end connected to the clamping device and a second end connected to the anvil.

4. The cutter as claimed in claim 1, wherein the cog assembly includes a pawl selectively engaged with and disengaged from the second cog, wherein the pawl is rotatably connected to the main body and being rotatable between an engaged position and a disengaged position with respect to the second cog, wherein when the pawl is in the engaged position, the second cog is rotatable in a first direction and unrotatable in a second direction opposite the first direction such that the blade is limited to be rotatable from the deployment position to the cutting position, wherein when the pawl is in the disengaged position, the second cog is rotatable in the first and the second directions, and wherein the pawl is operably connected to a switch, and wherein the switch is movably connected to and protrudes out of the main body.

5. The cutter as claimed in in claim 4, wherein the cog assembly includes a first spring configured to bias the pawl between the engaged position and the disengaged position with respect to the second cog, and wherein the first spring has a first end supported on the pawl and a second end supported on the main body.

6. The cutter as claimed in claim 1 further comprising a rotatable shaft rotatably and detachably connected to the main body, wherein the second cog and the blade are connected to the rotatable shaft such that when the rotatable shaft rotates, the second cog and the blade rotate synchronously with and about the rotatable shaft, wherein the second cog has a first hole configured for receiving the rotatable shaft, wherein the blade has a perforation configured for receiving the rotatable shaft, wherein when the rotatable shaft is connected to the main body and inserted into the first hole and the perforation, the second cog and the blade rotate synchronously with the rotatable shaft in response to rotation of the rotatable shaft, and wherein when the rotatable shaft is disconnected from the main body, the blade is adapted to be disconnected from the rotatable shaft and removed in a radial direction from the main body.

7. The cutter as claimed in claim 6 further comprising a cover detachably connected to the main body and adapted to prevent detachment of the rotatable shaft from the main body, wherein when the cover is connected to the main body, it abuts the rotatable shaft and disposed opposite to the second cog, and wherein when the over is disconnected from the main body, the rotatable shaft is adapted to be detached from the main body.

8. The cutter as claimed in claim 6, wherein the cog assembly includes a reset mechanism configured to provide a driving force to cause the blade to move to the deployment position, wherein the reset mechanism includes a reset member and a second spring configured to bias the reset member, wherein the reset member is connected to the second cog in a manner that rotates synchronously with the second cog, wherein the second cog has a flange protruding on a side thereof in a direction along an axial direction of the rotatable shaft and surrounding the first hole, wherein the reset member has a second hole configured for receiving the flange, wherein the flange is inserted into the second hole for allowing the reset member to rotate synchronously with the second cog, wherein the reset member is connected between the second cog and the blade, wherein the second spring has a first end supported on the reset member and a second end supported on the main body, and wherein the second spring is adapted to provide a resilient pulling force to cause the blade to move to the deployment position.

9. The cutter as claimed in claim 1, wherein the cog assembly includes a first intermediate cog, a second intermediate cog and a third intermediate cog, wherein the first and the second intermediate cogs are rotatably connected to the main body in a manner that rotate synchronously about a same axis, wherein the first intermediate cog and the first cog are engaged with each other, wherein the first cog and the first intermediate cog are helical gears, wherein the second cog and the second intermediate cog are interlinked with each other by the third intermediate cog such that the second intermediate cog is not in contact with the second cog and the third intermediate cog is engaged between the second cog and the second intermediate cog, wherein the second cog, the second intermediate cog, and the third intermediate cog are spur gears, and wherein the second intermediate cog and the first cog are arranged at opposite sides of the first intermediate cog.

10. The cutter as claimed in claim 1, wherein the cutting edge includes a first length and a second length extending obliquely to the first length.

11. The cutter as claimed in claim 2, wherein the cog assembly includes a pawl selectively engaged with and disengaged from the second cog, wherein the pawl is rotatably connected to the main body and being rotatable between an engaged position and a disengaged position with respect to the second cog, wherein when the pawl is in the engaged position, the second cog is rotatable in a first direction and unrotatable in a second direction opposite the first direction such that the blade is limited to be rotatable from the deployment position to the cutting position, wherein when the pawl is in the disengaged position, the second cog is rotatable in the first and the second directions, and wherein the pawl is operably connected to a switch, and wherein the switch is movably connected to and protrudes out of the main body.

12. The cutter as claimed in claim 11 further comprising a rotatable shaft rotatably and detachably connected to the main body, wherein the second cog and the blade are connected to the rotatable shaft such that when the rotatable shaft rotates, the second cog and the blade rotate synchronously with and about the rotatable shaft, wherein the second cog has a first hole configured for receiving the rotatable shaft, wherein the blade has a perforation configured for receiving the rotatable shaft, wherein when the rotatable shaft is connected to the main body and inserted into the first hole and the perforation, the second cog and the blade rotate synchronously with the rotatable shaft in response to rotation of the rotatable shaft, and wherein when the rotatable shaft is disconnected from the main body, the blade is adapted to be disconnected from the rotatable shaft and removed in a radial direction from the main body.

13. The cutter as claimed in claim 12, wherein the cog assembly includes a reset mechanism configured to provide a driving force to cause the blade to move to the deployment position, wherein the reset mechanism includes a reset member and a second spring configured to bias the reset member, wherein the reset member is connected to the second cog in a manner that rotates synchronously with the second cog, wherein the second cog has a flange protruding on a side thereof in a direction along an axial direction of the rotatable shaft and surrounding the first hole, wherein the reset member has a second hole configured for receiving the flange, wherein the flange is inserted into the second hole for allowing the reset member to rotate synchronously with the second cog, wherein the reset member is connected between the second cog and the blade, wherein the second spring has a first end supported on the reset member and a second end supported on the main body, and wherein the second spring is adapted to provide a resilient pulling force to cause the blade to move to the deployment position.

14. The cutter as claimed in claim 13, wherein the cog assembly includes a first intermediate cog, a second intermediate cog and a third intermediate cog, wherein the first and the second intermediate cogs are rotatably connected to the main body in a manner that rotate synchronously about a same axis, wherein the first intermediate cog and the first cog are engaged with each other, wherein the first cog and the first intermediate cog are helical gears, wherein the second cog and the second intermediate cog are interlinked with each other by the third intermediate cog such that the second intermediate cog is not in contact with the second cog and the third intermediate cog is engaged between the second cog and the second intermediate cog, wherein the second cog, the second intermediate cog, and the third intermediate cog are spur gears, and wherein the second intermediate cog and the first cog are arranged at opposite sides of the first intermediate cog.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0010] FIG. 1 is a perspective view of a cutter adapted for use with a power tool in accordance with the present invention.

[0011] FIG. 2 is an exploded perspective view of the cutter of FIG. 1.

[0012] FIG. 3 is another exploded perspective view of the cutter of FIG. 1.

[0013] FIG. 4 is an exploded perspective view of a clamping device of the cutter of FIG. 1.

[0014] FIG. 5 is a cross-sectional view of the cutter of FIG. 1.

[0015] FIG. 6 is another cross-sectional view of the cutter of FIG. 1 and in which a second cog of the cutter in a radial direction thereof is shown.

[0016] FIG. 7 is yet another cross-sectional structural view of the cutter of FIG. 1 and in which a first cog of the cutter in an axial direction thereof is shown.

[0017] FIG. 8 is yet another cross-sectional view of the cutter of FIG. 1 and in which the second cog of the cutter in an axial direction thereof is shown.

[0018] FIG. 9 is yet another cross-sectional view of the clamping device of the cutter of FIG. 1.

[0019] FIG. 10 is yet another cross-sectional view of the cutter of FIG. 1 and illustrates the clamping device holding a pipe.

[0020] FIG. 11 is yet another cross-sectional view of the cutter of FIG. 1 and illustrates a blade of the cutter in a cutting position.

DETAILED DESCRIPTION OF THE INVENTION

[0021] FIGS. 1 through 11 show a cutter 10 adapted for use with a power tool 90 in accordance with the present invention includes a main body 20, a cog assembly 30, and a blade 40. The cog assembly 30 is arranged on the main body 20. The blade 40 is connected to and operably moved by the cog assembly 30.

[0022] The main body 20 includes an anvil 21.

[0023] The cog assembly 30 includes a drive shaft 31 and a first and a second cog 32 and 33. The drive shaft 31 is rotatably connected to the main body 20. The drive shaft 31 has a first end configured to detachably connect which the power tool 90. The first cog 32 is disposed on the drive shaft 31 and moves synchronously with the drive shaft 31. The second cog 33 is rotatably connected to the main body 20 and rotates upon rotation of the first cog 32.

[0024] The blade 40 is rotatably connected to the main body 20 and connected to the second cog 33 in a manner that rotates synchronously with the second cog 33. The blade 40 has a cutting edge 41 selectively cutting the object to be cut by the cutter 10. The cutting edge 41 includes a first length and a second length extending obliquely to the first length. Therefore, the object can be cut along a straight line or an oblique line. The blade 40 is rotatable between a deployment position and a cutting position with respect to the object. The cutting edge 41 is disposed away from the anvil 21 when the blade 40 is in the deployment position, but is adjacent to the anvil 21 when the blade 40 is in the cutting position.

[0025] The cutter 10 also includes a rotatable shaft 23 rotatably and detachably connected to the main body 20. The second cog 33 and the blade 40 are connected to the rotatable shaft 23 such that when the rotatable shaft 23 rotates, the second cog 33 and the blade 40 rotate synchronously with and about the rotatable shaft 23. The second cog 33 has a first hole 331 configured for receiving the rotatable shaft 23. The blade 40 has a perforation 42 configured for receiving the rotatable shaft 23. When the rotatable shaft 23 is connected to the main body 20 and inserted into the first hole 331 and the perforation 42, the second cog 33 and the blade 40 rotate synchronously with the rotatable shaft 23 in response to rotation of the rotatable shaft 23. When the rotatable shaft 23 is disconnected from the main body 20, the blade 40 is adapted to be disconnected from the rotatable shaft 23 and removed in a radial direction from the main body 20.

[0026] The cog assembly 30 also includes a pawl 34 selectively engaged with and disengaged from the second cog 33. The pawl 34 is rotatably connected to the main body 20 and being rotatable between an engaged position and a disengaged position with respect to the second cog 33. When the pawl 34 is in the engaged position, the second cog 33 is rotatable in a first direction and unrotatable in a second direction opposite the first direction such that the blade 40 is limited to be rotatable from the deployment position to the cutting position. When the pawl 34 is in the disengaged position, the second cog 33 is rotatable in the first and the second directions. The pawl 34 is operably connected to a switch 341. The switch 341 is movably connected to and protrudes out of the main body 20. The cog assembly 30 includes a first spring 342 configured to bias the pawl 34 between the engaged position and the disengaged position with respect to the second cog 33. The first spring 342 has a first end supported on the pawl 34 and a second end supported on the main body 20.

[0027] The cog assembly 30 further includes a reset mechanism configured to provide a driving force to cause the blade 40 to move to the deployment position. The reset mechanism includes a reset member 35 and a second spring 36 configured to bias the reset member 35. The reset member 35 is connected to the second cog 33 in a manner that rotates synchronously with the second cog 33. In the embodiment, the second cog 33 has a flange 332 protruding on a side thereof in a direction along an axial direction of the rotatable shaft 23 and surrounding the first hole 331, the reset member 35 has a second hole 351 configured for receiving the flange 332, and the flange 332 is inserted into the second hole 351 for allowing the reset member 35 to rotate synchronously with the second cog 33. The reset member 35 is connected between the second cog 33 and the blade 40. The second spring 36 has a first end supported on the reset member 35 and a second end supported on the main body 20. The second spring 36 is adapted to provide a resilient pulling force to cause the blade 40 to move to the deployment position. The reset member 35 is connected to the rotatable shaft 23 such that when the rotatable shaft 23 rotates, the reset member 35 rotates synchronously with and about the rotatable shaft 23. The reset member 35 includes the second hole 351 adapted to receive the rotatable shaft 23.

[0028] The cog assembly 30 further includes a first intermediate cog 37, a second intermediate cog 38 and a third intermediate cog 39. The first and the second intermediate cogs 37 and 38 are rotatably connected to the main body 20 in a manner that rotate synchronously about a same axis. The first intermediate cog 37 and the first cog 32 are engaged with each other. The first cog 32 and the first intermediate cog 37 are helical gears. The second cog 33 and the second intermediate cog 38 are interlinked with each other by the third intermediate cog 39 such that the second intermediate cog 38 is not in contact with the second cog 33 and the third intermediate cog 39 is engaged between the second cog 33 and the second intermediate cog 38. The second cog 33, the second intermediate cog 38, and the third intermediate cog 39 are spur gears. The second intermediate cog 38 and the first cog 32 are arranged at opposite sides of the first intermediate cog 37.

[0029] The cutter 10 also includes a clamping device 22 configured to selectively clamp and release the object. The clamping device 22 is rotatably connected to the main body 20 and being rotatable between a clamping position and a release position with respect to the object. The clamping device 22 is adjacent to the blade 40. The clamping device 22 is rotatable about a rotation axis and has a holding portion 221 at a first end and an operating portion 222 at a second end. The holding portion 221 is disposed adjacent to the anvil 21 when the clamping device 22 is in the clamping position, but is away from the anvil 21 when the clamping device 22 is in the release position. The clamping device 22 is attached to a resilient member 223. The resilient member 223 applies a force opposite to a force causing rotation of the clamping device 22. The resilient member 223 has a first end connected to the clamping device 22 and a second end connected to the anvil 21.

[0030] The cutter 10 further includes a cover 231 detachably connected to the main body 20 and adapted to prevent detachment of the rotatable shaft 23 from the main body 20. When the cover 231 is connected to the main body 20, it abuts the rotatable shaft 23 and disposed opposite to the second cog 33. When the over 231 is disconnected from the main body 20, the rotatable shaft 23 is adapted to be detached from the main body 20.

[0031] In view of the foregoing, the cutter 10 with set forth design can connect to the power tool 90 and power tool 90 can drive the cutter 10 to cut an object, so that a user can perform a cutting operation in a labor-saving and stable-output manner. Also, the clamping device 22 can clamp the object before shearing and therefore, it is convenient for the user to align the blade 40 with the position to be cut.

[0032] The foregoing is merely illustrative of the principles of this invention and various modifications can be made by those skilled in the art without departing from the scope and spirit of the invention.