The present invention relates to a heavy duty stapler, and more particularly to a heavy duty stapler having an effort-saving linkage member.
Accordingly, the object is achieved by providing a heavy duty stapler. The heavy duty stapler comprises a base member; a magazine member, which has a first end pivotally connected to the base member and a second end opposite to the first end, including a firing device provided at the second end thereof, with a firing portion formed from an end of the firing device; a lever arm, which has first and second end, including first and second pivotal sections defined at the first end thereof and a pressing section defined at the second end thereof opposite to the first and second pivotal sections, with the first pivotal section pivotally connected to the base member; a linkage member having a first end pivotally connected to the second pivotal section of the lever arm and a second end opposite to the first end thereof, with the whole length of the linkage member being able to be perpendicular to a direction of the first end of the lever arm from the first pivotal section to the second pivotal section; and a driven member including a first pivotal portion pivotally connected to the base member, a second pivotal portion pivotally connected to the second end of the linkage member and a driven portion, with a direction of the driven member from the first pivotal portion to the second pivotal portion being able to be perpendicular to the whole length of the linkage member.
Other advantages and features of the present invention will become apparent from the following descriptions referring to the drawings.
The present invention will be described through detailed illustration of the preferred embodiment referring to the drawings.
With reference to
The magazine member 20 includes a main body 21, a staple pusher 22 and a firing device 23. The staple pusher 22 is disposed in the main body 21 and adapted for pushing staples which are provided in the main body 21 to slide transversely toward the firing device 23. The main body 21 has first and second ends and includes first and second apertures 211 and 212 respectively formed at the first and second ends thereof. The staple pusher 22 is installed to the first end of the main body 21 and adjacent to the first aperture 211. The third pivotal hole 15 and the first aperture 211 are engaged with each other via the second pivotal element 151. The firing device 23 is slideably installed to the second end of the main body 21 in a longitudinal direction and includes first and second ends. A hole 231 is formed at the first end of the firing device 23 and a shaft 232 provided to insert through the hole 231. A firing portion 233 is formed at the second end of the firing device 23 and a sliding rail 234 is defined between the first and second ends of the firing device 23. A shaft 213 is provided to engaged the second aperture 212 with the sliding rail 234 and the firing device 23 is able to slide longitudinally with respect the shaft 213 via the sliding rail 234.
The lever arm 30 which has first and second ends includes first and second pivotal sections 31 and 32 defined at the distal of the first end thereof and a pressing section 33 defined at the second end thereof opposite to the first and second pivotal sections 31 and 32. First and second pivots 311 and 321 are respectively provided at the first and second pivotal sections 31 and 32. The first pivotal section 31 is engaged with the second pivotal hole 14 of the base member 10 via the first pivot 311. The first pivot 311 is inserted through the second elastic element 17 in the meanwhile. The lever arm 30 further consists of two spaced lateral walls and an intermediate plate sandwiched by the two lateral walls. The second leg 172 of the second elastic element 17 is abutted against the bottom surface of the intermediate plate of the lever arm 30.
The linkage member 40 which has a first end 401 and a second end 402 includes first and second pivotal orifices 41 and 42 respectively provided at the first and second ends 401 and 402 thereof. The first pivotal orifice 41 is joined to the second pivotal section 32 of the lever arm 30 via the second pivot 312. A linkage pivot 421 is inserted through the second end 402 of the linkage member 40 and adapted to pivotally couple the second end 402 of the linkage member 40 to the driven member 50. A direction of the whole length of the linkage member 40 is adjustable to be approximately perpendicular to a direction of the first end of the lever arm 30 from the first pivotal section 31 to the second pivotal section 32.
The driven member 50 is preferably L-shaped and includes first and second pivotal portions 51 and 52 and a driven portion 53. In this case, the driven portion 53 is preferably in form of a slot. The first pivotal portion 51, the second pivotal portion 52 and a center of the driven portion 53 preferably constitute a triangle form. The first pivotal portion 51 is joined to the first pivotal hole 13 of the base member 10 via the first pivotal element 131. The second pivotal portion 52 is pivotally couple to the second pivotal orifice 42 of the linkage 40 via the linkage pivot 421. A direction of the driven member 50 from the first pivotal portion 51 to the second pivotal portion 52 is adjustable to be approximately perpendicular to a direction of the whole length of the linkage member 40. The driven portion 53 corresponds to and is engaged with the hole 231 of the firing device 23 via the shaft 232 of the firing device 23. Hence, while the shaft 232 slides along the driven portion 53, the driven member 50 is driven to slide with respect to the shaft 232.
Referring to
The third pivotal hole 15 of the base member 10 is pivotally joined to the first aperture 211 of the magazine member 20. The second pivotal section 32 of the lever arm 30 is pivotally joined to the first pivotal orifice 41 of the linkage member 40. The second pivotal orifice 42 of the linkage member 40 is pivotally joined to the second pivotal portion 52 of the driven member 50. The first pivotal portion 51 of the driven member 50 is pivotally joined to the first pivotal hole 13 of the base member 10. The driven portion 53 of the driven member 50 is slideably joined to the hole 231 of the firing device 23. The driven member 50 is able to change position with respect to the firing device 23 and further the firing device 23 is able to move longitudinally with respect to the main body 21 of the magazine member 20.
Referring to
The lever arm 30 and the driven member 50 are coupled to each other via the linkage member 40. Thus, the force FA forms an angle θ1 with respect to the linkage member 40. The angle θ1 is preferably an acute angle and the force FA is divided into two component forces FX1 and FY1. The component force FX1 is exactly defined through the longitudinal direction of the linkage device 40.
The value of component force FX1 can be calculated by the following formula:
FX1=COS θ1*FA
Because the angle θ1 is an acute angle and the value of COS θ1 should be less than 1. Hence, the value of the component force FX1 must be smaller than that of the force FA. And the component force FX1 can be transmitted to the linkage pivot 421 of the linkage member 40 to which the driven member 50 is coupled to.
A second effort arm F2 is defined by a distance between the linkage pivot 421 of the linkage member 40 and the first pivotal portion 51 of the driven member 50 to which the base member 10 is coupled to. A second resistance arm P2 is defined by a distance between the first pivotal portion 51 of the driven member 50 and the first pivotal section 31 of the lever arm 30 and the shaft 232 which is slideably disposed in the driven portion 53 of the driven member 50. A force FB whose direction is perpendicular to a direction of the second effort arm F2 is generated at the linkage pivot 421 of the linkage member 40 and forms an angle θ2 with respect to the component force FX1. The angle θ2 is preferably an acute angle and the component force FX1 is divided into the force FB and a force FY2.
The value of the force FB can be calculated by the following formula:
FB=COS θ2*FX1
Because the angle θ2 is an acute angle and the value of COS θ2 should be less than 1. Hence, the value of the force FB must be smaller than that of the component force FX1 which is consumed during transmission.
Referring to
While the staple which is hit by the firing portion 233 and the legs of the staple are inserted through papers completely and in contact with the anvil portion 11, a direction of the force FA is perpendicular to that of the first resistance arm P1 and the force FA will not be divided into two component forces. A direction of the force FB is perpendicular to that of the second resistance arm P2 and the force FB will not be divided into two component forces. Thus, the force FA is completely transmitted to the force FB and the force FB is completely transmitted to the force P. In the other words, while the legs of staple are bent by the anvil portion 11, the whole length of the lever arm 40 is perpendicular to the direction of the first end of the lever arm 30 from the first pivotal section 31 to the second pivotal section 32 and also perpendicular to the direction of the first end of the driven member 50 from the first pivotal portion 51 to the second pivotal portion 52. The application of force F can be completely transmitted to the force P to fire staples without any force consumption for effort-saving.
The greatest value of the force F is happened while the legs of staple are bent to press themselves against papers by the anvil portion 11. Because the force FA and FB will not be divided into any component forces, the application of force F can be transmitted to the force P completely without any force consumption.
The ratio of the force P to the force F can be can be calculated by the following formula:
P/F=(F1*F2)/(P1*P2)
The relationship between the values of F1, F2, P1 and P2 can represent how much effort would be saved during operation of the heavy duty stapler.
While several embodiments of the invention have been shown and described, it will be apparent to those skilled in the art that modifications may be made therein without departing from the scope and spirit of the present invention.
Number | Date | Country | Kind |
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98119550 A | Jun 2009 | TW | national |
Number | Name | Date | Kind |
---|---|---|---|
5356063 | Perez | Oct 1994 | A |
5364000 | Fealey | Nov 1994 | A |
6776321 | Jairam et al. | Aug 2004 | B2 |
7404507 | Marks | Jul 2008 | B2 |
7681771 | Kandasamy et al. | Mar 2010 | B2 |
7703652 | Shen | Apr 2010 | B2 |
Number | Date | Country | |
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20100314431 A1 | Dec 2010 | US |