EP1944131B1 - Stapler - Google Patents
Stapler Download PDFInfo
- Publication number
- EP1944131B1 EP1944131B1 EP08103713A EP08103713A EP1944131B1 EP 1944131 B1 EP1944131 B1 EP 1944131B1 EP 08103713 A EP08103713 A EP 08103713A EP 08103713 A EP08103713 A EP 08103713A EP 1944131 B1 EP1944131 B1 EP 1944131B1
- Authority
- EP
- European Patent Office
- Prior art keywords
- stapler
- magazine
- cover
- elastic member
- driver blade
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
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- 238000005381 potential energy Methods 0.000 claims abstract description 20
- 238000010276 construction Methods 0.000 description 66
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- 238000004146 energy storage Methods 0.000 description 1
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- 230000036316 preload Effects 0.000 description 1
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Images
Classifications
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B25—HAND TOOLS; PORTABLE POWER-DRIVEN TOOLS; MANIPULATORS
- B25C—HAND-HELD NAILING OR STAPLING TOOLS; MANUALLY OPERATED PORTABLE STAPLING TOOLS
- B25C5/00—Manually operated portable stapling tools; Hand-held power-operated stapling tools; Staple feeding devices therefor
- B25C5/02—Manually operated portable stapling tools; Hand-held power-operated stapling tools; Staple feeding devices therefor with provision for bending the ends of the staples on to the work
- B25C5/0221—Stapling tools of the table model type, i.e. tools supported by a table or the work during operation
- B25C5/0242—Stapling tools of the table model type, i.e. tools supported by a table or the work during operation having a pivoting upper leg and a leg provided with an anvil supported by the table or work
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B25—HAND TOOLS; PORTABLE POWER-DRIVEN TOOLS; MANIPULATORS
- B25C—HAND-HELD NAILING OR STAPLING TOOLS; MANUALLY OPERATED PORTABLE STAPLING TOOLS
- B25C5/00—Manually operated portable stapling tools; Hand-held power-operated stapling tools; Staple feeding devices therefor
- B25C5/16—Staple-feeding devices, e.g. with feeding means, supports for staples or accessories concerning feeding devices
- B25C5/1696—Staple support displaceable relative to the tool to allow re-loading
Definitions
- the invention relates to staplers, and more particularly, to staplers utilizing potential energy to assist in operating the staple drive mechanism.
- Potential energy or spring assisted office staplers have traditionally been of two types; either a stationary adaptation of powerful tacker-type models or a stationary stapler whose spring assist cannot achieve full power to drive and clinch the required sheet capacity without additional user applied force.
- a tacker-type stapler typically, the staples are driven into the target object but the leg of staples are not bent.
- the strong force that is required for driving the staples is obtained by releasing the pressure that is accumulated in a spring or elastic member.
- this structure that stores pressure in the spring can be of many different types but all are typically structured such that when the stapler is not in operation, the blade is located in front of the staples and when the blade is lifted, the staples move forward in the magazine. The blade is then lowered to drive one of the staples that has been pushed forward. This entire series of operations are executed in one instant with a powerful flow of force.
- Such a tacker is illustrated in U.S. Patent No. 6,145,728 .
- a stationary stapler adaptation of a similar mechanism is illustrated in U.S. Patent No. 6,918,525 .
- Both known types utilize locking mechanisms which act directly on the driver blade. These locking mechanisms intermittently experience functional problems including reduced power transmission to the driver, premature component failure, unreliable actuation and difficulty in returning to the rest position.
- US Patent No. 535,063 discloses a hand-operated stapler, including a base plate having two opposite ends and side parts disposed at one of the ends. A die plate is disposed at the other of the ends. A body is pivotably supported by the side parts. The body has a magazine with a centre channel for receiving and guiding a strip of staples and guide ribs disposed substantially at right angles to the centre channel. A push blade is guided by the guide ribs for sliding up and down to release and drive in the staples. A top part partly covers the body and acts as an operating arm. A locking release device for the push plate is operated by the top part.
- the locking and release device has a pivotable latch being disposed between the top part and the body and is releasably joined to the push plate for intermittently locking the push plate in a locked postion relative to a staple in the strip and for releasing the push plate in an unlocked position.
- the locking and release device has a spring supported on the push plate and is tensed when the unlocked position is attained for effecting sudden release of the push plate.
- This invention is a stapler having the features of claim 1, that is used for binding together the target objects by driving the staples utilizing the force that has been accumulated in an elastic member, that force being released all at once.
- the invention is also related to a stapler where the driver blade is not positioned in front of the staples but rather above the staples when the stapler is not in use. Further, this invention fully automates the function of the stapler while achieving adequate power and maintaining the preferred loading method.
- the invention could be utilized in a desktop-type stapler, where the staple legs are bent to bind together the target objects, or a tacker-type stapler where the staple legs are not bent.
- the desktop-type stapler of this invention reduces the possibility of the staples flying out by mistake and aims to obtain a stapling action that staples with a lot of power. Further, this is a stapler that is used for binding together papers and the like.
- the force that has been accumulated in the elastic object material is fed into the structure of the tacker from the viewpoint of releasing the force that has been stored up in the elastic member all at once and, as mentioned, it does not have a composition that is usually seen in tackers wherein the blade is located in front of the staples, but rather a structure where the blade is positioned above the staples.
- the invention also aims to achieve a structure whereby there is no need for a large rotation or movement of the base or the frame when the staples are being reloaded.
- the invention also aims to have a function where not only will the staples not be ejected by mistake, but further the structure will be simple and the stapling operation can be performed with a light force.
- the invention provides a stapler movable between a rest position and a stapling position.
- the stapler has a front end adjacent a staple ejection location and a rear end.
- the stapler includes a base, a staple magazine coupled to the base and configured to hold staples, and a driver blade operable to drive staples out of the staple magazine during stapling operations.
- the stapler further includes an elastic member coupled to the driver blade and operable to move the driver blade during stapling operations.
- the elastic member utilizes potential energy to move the driver blade during stapling operations.
- the driver blade is positioned above the staple magazine when the stapler is in the rest position and the magazine is extendable from the front end of the stapler to allow a user to load staples in the magazine.
- the stapler is configured such that only the potential energy of the elastic member can operate the driver blade during stapling operations.
- the elastic member is released by a triggering mechanism that does not directly contact the driver blade, thereby eliminating many of the triggering mechanism and locking mechanism problems of prior art staplers.
- the invention provides a stapler movable between a rest position and a stapling position.
- the stapler includes a staple magazine configured to hold staples, a driver operable to drive staples out of the staple magazine during stapling operations, and a drive mechanism coupled to the driver and operable to move the driver during stapling operations.
- the drive mechanism includes an elastic member for storing energy therein.
- the stapler further includes an activation member configured to engage the drive mechanism such that when a staple jam occurs, a user can manually reset the stapler to the rest position.
- an engagement part of the elastic member is engaged with a support member in the form of a slider, and as the cover and the frame come closer together due to the force input on the cover, the engagement part moves along the upper surface of the slider relatively until the engagement between the elastic member and the slider is released with the engagement part passing through the front end of the top surface of the slider.
- the slider is movable relative to the magazine in the forward and backward directions (i.e., longitudinally).
- the support member can take the form of a pivoting member attached in the frame and rotatable about a pivot axis.
- the slider includes a taper or arcuate surface in the front end of the slider, and the upper surface angle protrudes even farther out than a lower surface angle.
- the engagement part provides force such that the slider's upper surface front end is moved, leading to a disengagement of the elastic member and the slider.
- the cover rises upwards and the engagement part of the elastic member rises along the taper or arcuate surface.
- the engagement part is engaged with the upper surface of the slider and with the help of the slider spring, the engagement portion of the engagement part and the slider are tilted in the direction that pushes the slider in the backward direction. With the engagement part pushing the upper surface of the slider back, the elastic member returns to the configuration that exists when the stapler is not in use.
- the stapler includes a means that helps in disengaging the elastic member and the slider.
- the slider is pushed back with respect to the frame due to engagement between the cover and the slider.
- the elastic member is part of a drive mechanism coupled to the driver blade by a drive linkage that is in continuous contact with the driver blade during stapling operations.
- the drive linkage includes a driver link and an over-center link.
- the drive link has a first end connected to the driver blade, a second end coupled with the elastic member, and a pivot point intermediate the first and second ends.
- the over-center link is coupled with the driver link and is movable between a first position to prevent the drive link from pivoting about the pivot point, and a second position to allow the drive link to pivot about the pivot point to drive the driver blade
- Typical potential energy stapler technology utilizes a portion of the frame to prevent the driver blade from extending out of the bottom of the magazine. Preventing the driver blade from extending out of the magazine reduces the stapling power and can generate a considerable amount of noise. The stapling force is reduced because the driver blade is suddenly stopped during stapling. Therefore, more force needs to be generated by the stapler than the actual force that is required for stapling because energy is consumed to prevent the driver blade from extending out of the magazine.
- the driver blade of the stapler of the present invention is allowed to extend out of the magazine during stapling. Thus, there is generally no need to stop the blade from extending past the bottom of the magazine. As a result, less force needs to be generated by the stapler of the present invention versus typical potential energy staplers because energy is not consumed to stop the driver blade. Therefore, comparing the stapler of the present invention with typical potential energy staplers, the current stapler can staple the same amount of sheets or other items with less force. In addition, the stapler of the present invention generates less noise than typical potentially energy staplers because the driver blade is not suddenly stopped.
- the stapler of the present invention provides a stapler with potential energy technology while only slightly increasing the number of component parts from non-potential energy type staplers.
- the elastic member coupled to the underside of the cover creates a compact design such that the space required for the working components is less than staplers with other types of potential energy technology.
- this feature is added to the fact that the number of parts is less, the freedom in the design is greatly enhanced and it is easy to construct this device such that it is more compact than staplers with other types ofpotential energy technology.
- a stapler with other potential energy technology needs to have various safety measures and features to facilitate reloading the staples.
- the driver blade in the present invention is initially at rest above the staples and there is no spring force in the blade. Therefore, it is easy to obtain the same level of safety as a conventional stapler when reloading the staples.
- Fig. 1 is an external view of the stapler not embodying the present invention.
- Fig. 2 is a cutaway view of the stapler of Fig. 1 , illustrating the internal configuration of the stapler when the stapler is not in us.
- Fig. 3 is an exploded view of a portion of the stapler of Fig. 2 .
- Fig. 3a is an enlarged view of an elastic member of the stapler illustrated in Fig. 3 .
- Fig. 4 is a perspective view of a staple magazine of the stapler of Fig. 1 when the magazine of the stapler is pulled out.
- Figs. 5a - 5e illustrate the operation of the stapler of Fig. 1 .
- Figs. 5a' - 5e' relate to Figs. 5a - 5e respectively and illustrate a portion of the stapler of Fig. 1 during the operation of the stapler.
- Fig. 6 illustrates the internal configuration of the stapler of Fig. 1 when the stapler is being operated just before a staple is driven from the stapler.
- Fig. 7 illustrates the internal configuration of the stapler of Fig. 1 when the stapler is being operated after the staple is driven from the stapler.
- Fig. 8 illustrates the internal configuration of the stapler of Fig. 1 when the stapler is being operated as the cover begins to rise with respect to the staple magazine.
- Fig. 9 illustrates the internal configuration of the stapler of Fig. 1 when the stapler is being operated as the cover continues to rise with respect to the staple magazine.
- Fig. 10 illustrates the internal configuration of the stapler of Fig. 1 when the stapler has returned to the rest or start position.
- Fig. 11 illustrates the inner configuration of the stapler of Fig. 1 when the magazine of the stapler is pulled out to extend from the stapler
- Fig. 12 is an alternative arrangement of the stapler of Fig. 1 illustrating the inner configuration of the stapler and a driver spring.
- Fig. 12a illustrates the driver spring of the stapler of Fig. 12 .
- Fig. 13 is another alternative arrangement of the stapler of Fig. 1 illustrating the inner configuration of the stapler and a driver spring.
- Fig. 13b illustrates the driver spring of the stapler of Fig. 13 .
- Fig. 14 is yet another alternative arrangement of the stapler of Fig. 1 illustrating the internal configuration of the stapler.
- Fig. 15 is yet another alternative arrangement of the stapler of Fig. 1 illustrating the inner configuration of the stapler when the stapler is in the rest or start position.
- Fig. 16 illustrates the stapler of Fig. 15 when the stapler is being operated just before a staple is driven from the stapler.
- Fig. 17 illustrates an elastic member of the stapler of Fig. 15 .
- Fig. 18 illustrates a support member of the stapler of Fig. 15 .
- Fig. 19 is an enlarged view of a front portion of the stapler of Fig. 15 with a portion of the stapler removed.
- Fig. 20 is yet another alternative arrangement of the stapler of Fig. 1 illustrating the inner configuration of the stapler when the stapler is in the rest or starting position.
- Fig. 21 illustrates the stapler of Fig. 20 when the stapler is being operated just after a staple has been driven from the stapler.
- Fig. 22 illustrates the stapler of Fig. 20 when the stapler is being operated as the cover rises back to the starting position.
- Fig. 23 is yet another alternative embodiment of the stapler of Fig. 1 illustrating the inner configuration of the stapler when the stapler is in the rest or starting position.
- Fig. 24 is yet another alternative embodiment of the stapler of Fig. 1 illustrating a cutaway perspective view with the staple magazine in the staple loading position.
- Fig. 25 is a cutaway perspective view of a portion of the stapler of Fig. 24 .
- Fig. 26 is a side view of a drive mechanism of the stapler of Fig. 24 .
- Fig. 27 is a perspective view of the drive mechanism of the stapler of Fig. 24 .
- Fig. 28 is a top view of the drive mechanism of the stapler of Fig. 24 .
- Fig. 29 is a section view of the stapler of Fig. 24 in the rest position.
- Fig. 30 is a section view of the stapler of Fig. 24 in a partially actuated position.
- Fig. 31 is a section view of the stapler of Fig. 24 in a fully actuated position.
- a first stapler 1 is illustrated in Figs. 1-11 .
- the external appearance of the stapler 1 is as seen in Fig. 1 .
- the stapler 1 defines a front end 6, adjacent a staple ejection location 7, and a rear end 8 opposite the front end 6.
- the stapler 1 includes a base 2, a frame 3 that is coupled to the base 2, and a handle or cover 5 that is coupled to the frame 3 near the rear end 8 of the stapler 1.
- the illustrated base 2 includes an anvil 9. As is understood by one of skill in the art, the anvil 9 facilities clinching or bending staples.
- the base 2 supports the stapler 1 on a support surface, such as a desk, table, countertop, and the like.
- Fig. 2 illustrates the internal configuration of the stapler 1 when the stapler 1 is not in operation.
- Fig. 3 is an exploded view that illustrates several of parts of the stapler 1. For clarity, Fig. 3 is a cross-sectional view along a longitudinal axis of the stapler 1 illustrating generally half of several parts of the stapler 1.
- the illustrated stapler 1 further includes a cover biasing member 14 between the cover 5 and the frame 3 that biases the cover 5 away from the frame 3.
- the illustrated cover biasing member 14 is a coil spring, in other constructions the cover biasing member can be any suitable spring, such as torsion springs, leaf springs, and the like, or other suitable biasing members.
- the illustrated cover 5 includes a trigger member 12 that extends from an inside surface of the cover 5. While the illustrated trigger member 12 includes two projections, in other constructions the trigger member can include only a single projection or may take other suitable forms.
- the cover 5 further includes a spring or elastic member receiver portion 11 that extends from the inside surface of the cover 5, adjacent the trigger member 12.
- the stapler 1 further includes a driver member or elastic member 20, which is a leaf spring in the illustrated construction.
- the elastic member 20 is positioned between the cover 5 and the magazine 50.
- the elastic member 20 includes a first or free end portion 15, a second or fixed end portion 16, and a body portion 17 that extends between the free and fixed end portions 15, 16.
- the fixed end portion 16 of the illustrated elastic member 20 includes a substrate or base portion 21 that is utilized to couple the elastic member 20 to the receiver portion 11 of the cover 5.
- the elastic member 20 is coupled to the cover 5 using fasteners that extend into apertures 13 formed in the cover 5.
- a slit can be provided in the receiver portion 11, or at any suitable location within the cover 5, and at least a portion of the base portion 21 of the elastic member 20 can be bent to form a tab such that the tab can be press-fitted into the slit of the cover.
- Such a tab and slit configuration construction can be used alone or in combination with fasteners and the apertures 13.
- the free end 15 of the elastic member 20 includes a blade engagement portion 24 and a slider or support member engagement portion 22 that extends in a lateral direction from the blade engagement portion 24 to form a T-shaped engagement portion of the elastic member 20 in the illustrated embodiment.
- a driver blade 27 is coupled to the elastic member 20 at the blade engagement portion 24.
- the blade engagement portion 24 of the elastic member 20 extends through a slit 28 formed in the driver blade 27 to couple or engage the elastic member 20 to the driver blade 27.
- the slit 28 of the driver blade 27 is sized such that the blade engagement portion 24 of the elastic member 20 is free to move with respect to the driver blade 27 in the forward and rearward directions.
- the elastic member 20 is a leaf spring.
- the elastic member 20 can be any suitable biasing member.
- the leaf spring defines an angle ⁇ that is measured from the blade engagement portion 24 to the body portion 17 of the elastic member 20 with the stapler 1 in a resting or starting position (i.e., the cover 5 has not been pushed down).
- the angle ⁇ is approximately 160 degrees.
- the angle ⁇ can be more or less than 160 degree depending on the application of the stapler 1. For example, if the stapler 1 is designed for relatively large staples and/or to staple through a relatively large amount of paper and the like, the angle ⁇ can be less than 160 degrees.
- the stapler 1 further includes a support member 30, which is a slider in the illustrated construction.
- the support member 30 includes cut out portions 31 that define trigger guide surfaces 32, and support surfaces 34 that slidably support the support member engagement portions 22 of the elastic member 20.
- the support member 30 further includes spring guide openings or slots 33 that extend transversely through the support member 30 and front tapered portions or surfaces 35 that are spaced a distance apart in order to engage the support member engagement portions 22 of the elastic member 20.
- the illustrated support member 30 is coupled to the frame 3 using hubs or bosses 38 (only one visible in Fig. 3 ) that are received by the slots 33 of the support member 30.
- the illustrated support member 30 is able to slide with respect to the frame 3, and the slots 33 define the maximum forward and rearward positions of the support member 30 with respect to the frame 3.
- the support member 30 slides is a direction generally parallel to a longitudinal axis 53 defined by the magazine 50 of the stapler 1.
- a biasing member 40 which is a coil spring in the illustrated construction, biases the support member 30 toward the front end 6 of the stapler 1.
- the support member engagement portion 22 of the elastic member 20 is positioned on or above the spring gliding part or support surface 34 of the slider 30.
- the slider 30 moves with respect to the frame 3 in the forward and the rearward directions, the movement of the slider 30 is limited due to the engagement between the hub 38 of the frame 3 and the spring guide opening or slot 33 of the slider 30.
- the slider spring or biasing member 40 moves or biases the slider 30 in the forward direction (i.e. toward the front end 6 of the stapler 1).
- the stapler 1 includes the magazine 50 that is housed in the area 4 of the frame 3.
- the magazine 50 stores or houses staples 51.
- the magazine 50 is located with respect to the frame 3 such that a driver blade slot 56 formed in the magazine 50 is aligned with a driver blade slot 57 formed in the frame 3.
- the drive blade slots 56, 57 of the magazine 50 and the frame 3 are aligned such that the driver blade 27 can pass freely through both of the slots 56, 57.
- the illustrated magazine 50 includes a feeder or staple pusher 48 and a guide rod 55.
- the staple pusher 48 moves along the guide rod 55 to move or push Attorney Docket No. 010398-9349-01 staples 51 toward the front end 6 of the stapler 1.
- the magazine 50 can include a biasing member, such as a coil spring disposed around the guide rod 55 and coupled to the guide rod 55 and staple pusher 48 to bias the staple pusher 48 toward the front end 6 of the stapler 1.
- Other configurations can also be used to bias the staple pusher 48 toward the front end 6.
- the magazine 50 further includes a hook or latch 43 and a cut out 49.
- the latch 43 includes mounting bosses 44 (only one visible in Fig. 3 ) that couple the latch 43 to the frame 3 using the apertures 39 (only one visible in Fig. 3 ) formed within the frame 3.
- the bosses 39, 43 facilitate a pivoting connection of the latch 43 to the frame 3.
- a biasing member such as a spring, can be used to bias the latch 43 into an engaged position, such that the latch 43 is engaged with the cut out 49.
- the magazine 50 further includes a magazine biasing member, such as a spring, that biases magazine 50 toward an open position ( Fig. 11 ) or from the rear end 8 of the stapler 1 toward the front end 6.
- a magazine biasing member such as a spring
- the stapler 1 can be configured such that user can depress or push a rear portion of the latch 43 to eject the magazine 50 from the frame 3.
- Figs. 5a - 5c illustrate the operation of the stapler 1 and the passage or ejection of the staples 51 ( Fig. 4 ).
- the stapler 1 By pushing the cover 5 downward, toward the magazine 50, the stapler 1 is operated in the order illustrated in the order Fig. 5a ⁇ Fig. 5b ⁇ Fig. 5c .
- the stapling operation is completed when the state shown in Fig. 5c is reached.
- the stapler 1 returns to the state that existed (i.e., original or starting position) before stapling by carrying out the operations illustrated in the order Fig.5d ⁇ Fig. 5e ⁇ Fig. 5a .
- Figs. 5a'-Fig. 5e' Details of the position illustrated in Fig. 5a are shown in Fig. 2 while the details of the position illustrated in Fig. 5b are shown in Fig. 6.
- Figs. 7 , 9 and 10 indicate the details of the positions illustrated in Figs. 5c, 5d and 5e respectively.
- the engagement portion 22 of the elastic member 20 will fall downward after detaching or disengaging from the support surface 34 of the support member 30.
- the elastic member 20 passes through a portion of the support member 30 between upstanding portions that define the support surfaces 34.
- the driver blade 27 that is engaged with blade engagement portion 24 of the elastic member 20 is driven downward. The force that is accumulated in the elastic member 20 will be released instantly and the force driving the blade 27 will be sufficient to drive the staples effectively.
- the trigger member 12 is lowered along with the cover 5, and the trigger member 12 is engaged with the trigger guide 32 while the trigger member 12 is fed into the cut out 31 of the support member 30.
- the trigger member 12 contacts the trigger guide surfaces 32 of the support member 30 and guides or pushes the support member 30 backward while the cover 5 moves down.
- the user continues to push down on the cover 5 to overcome the force of the biasing member 40 to slide the support member 30 toward the rear end 8 of the stapler 1.
- the trigger 12 facilitates disengaging the engagement portion 22 of the elastic member 20 from the tip or front edge of the support member 30.
- the elastic member 20 is a plate or leaf spring, there is a small amount of bending of the elastic member 20 based on the timing or speed of the stapling action. Due to this bending, the distance from the base 21 of the elastic member 20 to the engagement portion 22 becomes shorter causing cases when the disengagement of the engagement portion 22 with the support member 30 does not occur properly.
- the support member 30 is then pushed backward or toward the rear end 8 of the stapler 1 by the trigger member 12 to ensure that the engagement portion 22 of the elastic member 20 is disengaged from the support member 30 and that the driver blade 27 falls.
- Figs. 5c and 7 illustrate the cover 5 of the stapler 1 in the furthest downward (i.e., lowered) position.
- the elastic member 20 extends through the slit 28 in the driver blade 27 ( Fig. 3 ) to remain in continuous contact with the driver blade 27.
- the cover 5 does not contact the driver blade 27 when the cover 5 is in the lowered position. Therefore, when the cover 5 is the lowered position, the cover 5 generally does not tend to push the driver blade 27 further downward.
- the maximum achievable stapling power of the stapler 1 is generated by the elastic member 20, and the user cannot push down further or harder on the cover 5 to force the driver blade 27 down further.
- the cover 5 After stapling, when the force used to push the cover 5 is released, the cover 5 returns to the original position ( Fig. 5a ) by rising immediately with the help of the cover biasing member 14. As shown in Fig. 5c' , in the illustrated construction, the trigger member 12 and the support member 30 are engaged only above the cut out 31 of the support member 30 when the cover 5 is in the lowered position. As the cover 5 rises, disengagement between the trigger member 12 and the support member 30 can take place easily and there is no longer any impact of the trigger member 12 on the support member 30.
- the engagement portion 22 of the elastic member 20 reaches the peak of the front taper portions 35 of the support member 30.
- the engagement portion 22 is detached from the front taper portion 35 of the support member 30 and the engagement portion 22 of the elastic member 20 re-engages with the support surface 34 of the support member 30.
- the support member 30 is pushed forward by the biasing member 40 while the engagement portion 22 slides along the support surface 34 of the support member 30 to return the support member 30 and elastic member 20 to the original or starting position as illustrated in Fig. 5a .
- Figs. 12 and 12a illustrate a second stapler.
- the elastic member 58 includes a rearwardly-extending plate spring portion 59 that functions as the cover biasing member (i.e., in place of the cover biasing member 14 of Figs. 1-11 ).
- the illustrated plate spring portion 59 is integrally formed with the elastic member 58, however could be a separate piece.
- the other mechanisms of the stapler and operation of the stapler are similar to the first arrangement of Figs. 1-11 .
- Figs. 13 and 13a illustrate a third arrangement.
- the elastic member 60 includes a plate spring portion 61 that operates as the cover biasing member (i.e., in place of the cover biasing 14 of Figs. 1-11 ).
- the elastic member 60 includes support member biasing members or slider springs 62 that can replace or supplement the biasing spring 40 of Figs. 1-11 .
- the illustrated slider springs 62 and plate spring 61 are integrally formed with the elastic member 60 but alternatively could be separate components.
- the other mechanisms of the stapler and operation of the stapler are similar to the first arrangement.
- Fig. 14 illustrates a fourth arrangement in which the support member 30 is replaced by a cam 63 that guides the engagement part of the elastic member.
- the cam 63 rotates with the help of the cam spring 65 about the axis 64.
- the other mechanisms are similar to the first arrangement.
- Figs. 15 - 19 illustrate yet another alternative arrangement of the stapler 1 of Figs. 1 - 11 .
- the stapler 101 of Figs. 15-19 is similar to the stapler 1 of Figs. 1-11 . Therefore, like components have been given like reference numbers in the one-hundred series, and only the general differences will be discussed below.
- Fig. 15 illustrates the stapler 101 that includes the base 102, the frame 103 coupled to the base 102, and the cover 105 that is coupled to the frame 103.
- the elastic member 120 is positioned between the cover 105 and the magazine 150.
- the illustrated elastic member 120 defines the angle between the body portion 117 and the driver blade engagement portion 124 that is approximately 140 degrees. As discussed above, the angle can be virtually any angle depending on the application of the stapler 101, including the angle that is approximately 160 degrees as illustrated in the stapler 1 of Figs. 1-11 .
- the elastic member 120 is illustrated in more detail in Fig. 17 .
- the illustrated elastic member 120 is a leaf spring that includes the free or first end portion 115 and the fixed or second end portion 116.
- the second end portion 116 of the elastic member 120 includes a first layer 166 and a second layer 167.
- the first layer 166 and the second layer 167 are formed to define a loop 168.
- the illustrated first layer 167 of the elastic member 120 is bent generally upwards at one end to form a tab 170.
- the tab 170 is received within a slot 169 formed in the cover 105 to facilitate coupling the elastic member 120 to the cover 105.
- the second end portion 116 of the illustrated elastic member 120 further includes an aperture 171 that extends through the elastic member 120.
- the aperture 171 receives a fastener 172 to couple the elastic member 120 to the cover 105.
- the illustrated aperture 171 includes a first aperture 171 a formed through the first layer 166 and a second aperture 171 b formed through the second layer 167 that is smaller than the first aperture 171a that extends through the first layer 166.
- the first and second apertures 171 a, b are sized such that the second aperture 171b that extends through the second layer 167 is utilized to generally fix or secure the elastic member 120 to the cover 105 while the first aperture 171 a that extends through the first layer 166 is larger than a head of the fastener 172.
- the first aperture 171a and the first layer 166 are able to move with respect to the fastener 172 and the second layer 167.
- Such a configuration increases the effective length of the elastic member 120 as compared to the elastic member 20 of Figs. 1- 11 to include the first layer 166, the loop 168, and the portion of the second layer 167 between the loop 168 and the aperture 171b.
- any of the embodiments of the stapler described herein can include either the single layer elastic member or the dual layer elastic member.
- the first end portion 115 of the elastic member 120 includes the support member engagement portions 122.
- the illustrated support member engagement portions 122 define a generally T-shaped portion of the elastic member 120 and includes tabs 173 that are somewhat rounded. The tabs 173 facilitate sliding of the elastic member 120 along the front portions 135 of the support member 130 ( Fig. 18 ).
- the stapler 101 further includes the support member 130 that supports the elastic member 120. Similar to the support member 30 of Figs. 1-11 , the illustrated support member 130 of Figs. 15 and 18 is a slider movable in a direction parallel to the longitudinal axis 153 of the magazine 150.
- the illustrated support member 130 includes support surfaces 134 that support the elastic member 120 and front end portions 135 that are both tapered and radiused. The radius of the front end portions 120 has been found to more effectively allow the elastic member 120 to move along the front end portions 135 to return to the support surfaces 134 of the support member 130 as the cover 105 rises after stapling.
- the illustrated magazine 150 of the stapler 101 includes the inner rails 152 that include swaged out end portions 173.
- the swaged out end portions 173 provide support surfaces 174 that stabilize or support the back of the staple when the staple is driven.
- the support surface 174 can be particularly beneficial for high speed and high sheet capacity staple driving applications.
- the magazine 150 further includes a boss 175 formed inside of the inner rails 152.
- the staple pusher 148 which is biased toward the driver blade 127, contacts the boss 175 when there are no staples remaining in the magazine in order to prevent the staple pusher 148 from being located directly underneath the driver blade 127. Therefore, if the user pushes the cover 105 to eject or push out a staple when there are no staples in the magazine 150 without generally contacting the staple pusher 148.
- the boss 175 is an upstanding flange, in other constructions the boss 175 can be any suitable member, such as a protrusion formed on the inside of the inner rail 152. Such a construction is illustrated in Figs. 20 - 23 .
- Figs. 20-22 illustrate yet another alternative arrangement of the stapler 1 of Figs. 1 - 11 .
- the stapler 201 of Figs. 20 - 22 is similar to the stapler 1 of Figs: 1-11 . Therefore, like components have been given like reference numbers in the two-hundred series, and only the general differences will be discussed below.
- the illustrated cover biasing member 214 of the stapler 201 is a torsion spring that contacts the cover 205 at a position closer to the front end 206 of the stapler 201 than the cover biasing member 14 of the stapler 1 of Figs. 1 - 11 .
- Increasing the distance from the point that the cover biasing member 214 contacts the cover 205 to the point about which the cover rotates increase the effective length of a lever created between the point that the cover biasing member 214 contacts the cover 205 to the point about which the cover 205 rotates.
- the longer lever reduces the spring force needed to raise the cover 205.
- the support member 230 of the stapler 201 is a cam that pivots or rotates about the axis 264.
- the illustrated support member 230 includes a slider member 276 and a biasing member 277 between the support member 230 and the slider member 276.
- the biasing member 277 biases the slider member 276 toward the front end 206 of the stapler 201. While the illustrated biasing member 277 is a coil spring, it should be understood that the biasing member can be any suitable biasing member, such as other types of springs, an elastomer, and the like.
- the stapler 201 includes a support member biasing member that biases the support member 230 about the axis 264 in the direction indicated by an arrow 278a.
- the support biasing member can be a torsion spring or other suitable devices.
- the stapler 201 further includes a support member release mechanism 279.
- the illustrated support member release mechanism 279 includes a release member 280 and an activation member 281.
- the illustrated release member 280 includes an elongated portion 286 that extends through an aperture 282 formed in the frame 203 and an enlarged portion 288 formed on an end of the elongated portion 286.
- the activation member 281 is located between the frame 203 and the enlarged portion 288 of the release member 280, and in the illustrated embodiment has a wedge-shaped configuration.
- the illustrated support member 230 includes a release member engagement portion 290.
- the engagement portion 290 engages the elongated portion 286 of the release member 280 to retain the support member 230 in the position illustrated in Fig. 20 .
- the release member engagement portion 290 of the support member 230 is a ledge portion of the support member 230, in other constructions the engagement portion 290 can be any suitable member, such as an aperture, surface, and the like.
- the operation of the stapler 201 is generally the same as the operation of the stapler 1, discussed above. Therefore, only the general differences in the operation will be discussed below.
- Fig. 20 illustrates the stapler 201 in the starting or original position when the stapler 201 is not being used.
- the engagement portion 222 of the elastic member 220 moves forward or toward the front end 206 of the stapler 201.
- the elastic member 220 will move far enough forward that the elastic member 220 disengages from the support surface 234 of the support member 230, or the trigger mechanism 212, which is a cam in the illustrated construction, will activate the support member release mechanism 279 to release the support member 230 to ensure that the driver blade 229 and elastic member 230 will fall and drive a staple ( Fig. 21 ).
- the trigger member 212 contacts the activation member 281 of the support member release mechanism 279. As the cover 205 is pushed down even farther the trigger member 212 pushes the activation member 281 downward between the frame 203 and the enlarged portion 288 of the release member 280 causing the release member 280 to slide toward the rear end 208 of the stapler 201. As illustrated in Fig. 21 , when the elongated portion 286 of the release member 280 moves rearward to a predetermined point, the release member 280 is removed from contact with the engagement portion 290 (e.g., an aperture, surface, etc.) of support member 230.
- the engagement portion 290 e.g., an aperture, surface, etc.
- the support member 230 With the release member 280 no longer contacting the support member 230, the support member 230 is free to rotate about the axis 264.
- the downward force of the elastic member 220 acting on the slider 276 of the support member 230 ( Fig. 20 ) rotates the support member 230 about the axis 264 in the direction indicated by the arrow 278b, thereby ensuring that the elastic member 220 and the driver blade 229 will fall and push a staple from the magazine 250.
- the illustrated stapler 201 is constructed such that a portion 284 of the driver blade 227 extends from the magazine 250 after the driver blade 227 has been lowered to drive a staple. While only the stapler 201 of Figs. 20 - 22 has been shown with the portion 275 extending from the magazine 250 after the driver blade 227 has been lowered, it should be understood that any of the staplers described herein can include such a feature.
- the slider 276 of the support member 230 facilitates returning the elastic member 220 to its starting or original position.
- the cover biasing member 214 forces the cover 205 and elastic member 220 upward, the cover biasing member 214 overcomes the force of the slider biasing member 277 and the elastic member 230 forces the slider 276 to slide into the support member 230 along a slider axis 285.
- the support member 230 is constructed such that the slider axis 285 is positioned at an angle ⁇ with respect to the magazine axis 253. In the illustrated construction, the angle ⁇ is approximately 20 degrees and in other constructions, the angle ⁇ can be any suitable angle.
- Fig. 23 illustrates an alternative construction of the stapler 201 of Figs. 20 - 22 .
- the stapler 301 of Fig. 23 is similar to the stapler 201 of Figs. 20 - 22 . Therefore, like components have been given like reference numbers in the three hundred series, and only the general differences will be discussed below.
- the support member 330 of the stapler 301 omits the slider 276 of the stapler 201 of Figs. 20 - 22 .
- the support member 330 further includes a boss 387 that is coupled to the support member 330.
- the boss 387 is positioned in a slot 389 that is formed in the frame 303.
- the ends of the slot 389 define the maximum rotational positions of the support member 330.
- the illustrated support member biasing member 340 is located around the boss 387 and biases the support member 330 in the direction indicated by the arrow 378 about the axis 364. In other constructions, the support member biasing member 340 can be located at other suitable locations or in other suitable configurations.
- the operation of the stapler 301 is generally the same as the operation of the stapler 201 of Figs. 20 - 22 with the exception that the stapler 301 omits the slider 276 of the stapler 201.
- Figs. 24-31 illustrate an alternative embodiment of the staplers of Figs. 1- 23 .
- the stapler 420 is a manual desktop-type stapler.
- the invention can be practiced with substantially any type of stapler, including, but not limited to, manual hand-held or upright staplers, manual heavy-duty staplers, and all forms of electric staplers, including desktop-type, heavy-duty, and hand-held electric staplers.
- the illustrated stapler 420 includes a base 424 having a front end 428 and a rear end 432.
- a bottom 43 6 of the base can be at least partially covered by a slipper or pad that helps stabilize and minimize sliding movement of the stapler 420 on a support surface (not shown).
- the slipper also makes gripping the stapler 420 more comfortable to the user, as well as facilitates gripping of the stapler 420 by the user by preventing the user's hand from slipping along the surface of the stapler 420.
- the base 424 further includes a top surface 444 for receiving and supporting a stack of sheets to be stapled. An anvil 448 is supported by the top surface 444 for clinching staples driven through the stack of sheets.
- a magazine assembly 452 is pivotally connected to the rear end 432 of the base 424 about a pivot axis 456, as is understood in the art.
- the magazine assembly 452 includes left and right side plates 453 (only one side plate 453 illustrated in Fig. 24 ) that are pivotally coupled to the base about the pivot axis 456, and a staple magazine 455 that is slidably connected to the side plates 453. Additional aspects of the side plates 453 will be discussed in detail below.
- the magazine 455 includes a nose piece 460 that wraps around the front end of the magazine 455. While the nose piece 460 of the illustrated embodiment is a separate component from the magazine 455, the nose piece 460 could also be integrally formed as part of the magazine 455, and thereby still define a nose piece 460 coupled to the magazine 455.
- the magazine 455 has a length M. In one construction, the length M of the magazine ranges from about 140mm to about 146mm, and in other constructions, the length M of the magazine can be any suitable length.
- a cover 464 is also pivotally connected to the base 424 about the pivot axis 456, and is capable of pivoting both with the magazine 455 and with respect to the magazine 455 during stapling operations.
- the cover 464 includes an input portion 467 located an input length F from the pivot axis 456 of the cover 464.
- the input portion 467 is defined as the point of force input by the user into the cover 464.
- the input length F ranges from about 153mm to about 155mm, and in other constructions the input length F can be any suitable length.
- An output length G extends from the pivot axis 456 to the point at which the energy input to the cover 464 is input into the stapling mechanism, as will be discussed in detail below.
- the length G ranges from about 30mm to about 37mm, and in other constructions can be any suitable length.
- the cover 464 includes a front end 465 and a rear end 466.
- the cover 464 includes the input portion 467 near the front end 465 of the cover 464 for receiving manual force input into the stapler 420 by a user.
- a lever portion 470 is defined by the cover 464 between the input portion 467 and the pivot axis 456.
- the lever portion 470 has a length equal to the input length F. Because the cover 464 pivots about the same pivot axis 456 as the magazine 455, the length of the lever portion 470 (i.e., the input length F) is maximized, thus maximizing the leverage available to the user. Maximizing the leverage by the user reduces the amount of force that must be input by the user to effectively operate the stapler 420. In the one embodiment, the ratio between input length F and the length M of the magazine 455 is between about 80% and 120%. Further aspects of the mechanical advantage of the stapler 420 will be described in detail below.
- the stapler 420 also includes a driver blade 468 coupled to a drive mechanism 472 to drive the staples out of the stapler 420 into the stack of sheets.
- the elements of the drive mechanism 472 will be described in more detail below.
- the front surface of the driver blade 468 defines a plane of movement in which the driver blade 468 moves downwardly to drive staples out of the stapler 420.
- the driver 468 moves downwardly through the magazine 455 to drive out a staple, the driver 468 is supported by the nose piece 460 and prevented from moving out of alignment with the staple to be driven.
- a stiffening plate 476 is coupled to the rear surface of the driver 468 and includes a slot or aperture 480 therein for receiving a portion of the drive mechanism 472, as will be discussed in detail below.
- aperture 480 can be omitted, and the drive mechanism 472 can be coupled to the stiffening plate 476 or driver blade 468 by welding, brazing, gluing, bonding, bolting, and the like.
- the stiffening plate 476 can be coupled to the driver blade 468 via a rivet, embossment, welding, gluing, bolting, and the like.
- the plate 476 and the driver blade 468 may be integrally formed as one piece. It is also understood that in other embodiments, no stiffening plate is used, and thus the drive mechanism 472 interacts directly with the driver 468.
- each side plate 453 wraps around the front surface of the driver blade 468 and includes slots 500 therein that receive the edges of the driver 468 to help guide the driver 468 during the stapling action.
- Rear portions 508 of each plate 453 enclose a portion of the drive mechanism 472, and are coupled together along the pivot axis 456.
- Each plate 453 also includes a rib 510 that extends along at least a portion of the plate.
- the stapler 420 includes a magazine release mechanism 520.
- the magazine release mechanism 520 includes a pivoting lever 524 that is actuated by the user to release the magazine 455 such that the magazine 455 can be ejected out the front of the stapler 420 into a staple loading position.
- the illustrated pivoting lever 524 includes a generally vertical surface 528 and a generally horizontal surface 532.
- a biasing member 536 is utilized to hold the magazine 455 in the locked position, as illustrated in Fig. 29 .
- the biasing member 536 is a torsion spring that is coupled to the pivoting lever 524 to hold the magazine 455 in the locked position.
- any suitable mechanism or biasing member can be utilized to bias the pivoting lever 524 into the engaged or locked position.
- the magazine 455 includes a staple pusher spring therein that functions to push or pull staples within the magazine 455 toward the front of the magazine 455 such that the forwardmost staple is in position to be driven out of the stapler 420 by the driver blade 468.
- the forward bias of the staple pusher spring also functions to bias the magazine 455 toward the front of the stapler 420 such that when the magazine 455 is released, the staple pusher spring pushes the magazine 455 forward to facilitate ejecting the magazine 455 out of the front of the stapler 420 and into the staple loading position.
- the release mechanism 520 also includes a braking spring (not illustrated).
- a braking spring (not illustrated).
- the force of the staple pusher spring ejects the magazine 455 out of the front of the stapler 420 as discussed above.
- the more the staple pusher spring is compressed the greater the ejecting bias of the staple pusher spring.
- the staple pusher spring force is at a minimum.
- the braking spring is configured to interact with the magazine 455 to slow the ejection of the magazine 455 out of the stapler 420.
- the braking spring is coupled to the magazine 455 such that the braking spring moves with the magazine 455.
- the braking spring moves forward with the movement of the magazine 455 and engages the rib 510 on the side plate 453.
- the engagement between the braking spring and the rib 510 causes friction, slowing the forward movement of the magazine 455.
- the stiffness of the braking spring, and thus the amount of friction created during magazine ejection should be optimized to ensure a controlled ejection of the magazine 455 when the staple pusher spring is highly compressed, but also ensuring that when the magazine 455 is empty (and thus the staple pusher spring is only lightly compressed), the magazine 455 can be drawn out of the stapler 420 by the user with little difficulty. While one braking spring configuration is described herein, it should be understood that other braking spring configurations are contemplated and would fall within the scope of the present invention.
- the magazine 455 also includes a u-shaped channel 548 therein that receives a locking shaft 552 of the magazine release mechanism 520.
- the biasing member 536 biases the locking shaft 552 into the channel 548 of the magazine 455 to lock the magazine 455 within the stapler 420.
- the channel 548 also includes a rear cam surface 554.
- the user pushes on the vertical surface 528 of the pivoting lever 524, either directly or via a button 549 coupled with the cover 464, which causes the horizontal surface 532 to rotate in the clockwise direction.
- the rotation lifts the locking shaft 552 out of the channel 548.
- the magazine 455 unlocks and the bias of the staple pusher spring ejects the magazine 455 out of the front of the stapler 420, subject to the forces of the braking spring described above.
- the magazine 455 may be only partially ejected from the stapler 420, and the user may need to manually move the magazine 455 into the final refilling position.
- the user pushes the magazine 455 back into the stapler 420 against the bias of the staple pusher spring.
- the locking shaft 552 engages the rear cam surface 554 of the magazine 455 and cams against the surface until the locking shaft 552 travels over the rear cam surface 554 and falls back into the channel 548 to hold the magazine 455 in the locked position.
- the drive mechanism 472 includes a drive linkage 556 that includes a drive link 560, a spring link 561, and an over-center linkage 562 having a trip link 564 and a pivot link 566.
- the drive link 560 includes a front end 572 that engages the aperture 480 in the stiffening plate 476 that is coupled to the driver blade 468, and a rear end 576.
- the front end 572 continuously engages the aperture 480 during all stages of stapling operations.
- the rear end 576 is somewhat wedge-shaped in configuration.
- the drive link 560 pivots about a pivot point 580.
- the geometry of the drive link 560 is configured to take advantage of residual energy within the drive mechanism 472 after the stapling operation to return the stapler 420 to the rest position, as will be discussed in more detail below.
- the drive link 560 includes an input portion having a length H. In one construction the length H ranges from about 29mm to about 33mm, and in other constructions can be any suitable length.
- the drive link 560 further includes an output portion having a length I that is approximately 27mm in one construction, and can be any suitable length in other constructions.
- the input portion H is the portion of the drive link 560 between the rear end 576 that receives energy to the pivot point 580
- the output portion I is the portion of the drive link 560 between the pivot point 580 and the front end 572 that directs energy into the driver blade 468.
- the trip link 564 of the over-center linkage 562 is pivotably coupled to the pivot link 566 of the over-center linkage 562.
- the trip link 564 is biased by a torsion spring 592 into an over-center position.
- the trip link 564 is configured to cooperate with the cover 464 of the stapler 420 to trigger stapling operation, as will be discussed in detail below.
- the pivot link 566 is coupled to the drive link 560 via a shaft 600.
- the trip link 564 pivots with respect to the pivot link 566 about a pivot shaft 604.
- the trip link 564 is supported between the side plates 453 on shaft 606 ( Fig. 25 ).
- the spring 592 is positioned about the shaft 606. As best illustrated in Fig. 26 , in the over-center position, the pivots shafts 600, 604, 606 of the over-center linkage 562 are generally aligned, the function of which will be described below.
- the spring link 561 includes a cam end 608 that engages the rear end 576 of the drive link 560, and a rear end 612.
- the cam end 608 includes an integral cam surface or cam member 614.
- the spring link 561 includes an input portion having a length J that ranges from about 23mm to about 32mm in one construction, and an output portion having a length K of approximately 36mm in one construction. In other constructions, the lengths J and K can be any suitable length.
- the input portion of the spring link 561 is the portion between the rear end 612 and a shaft 624 about which the spring link 561 pivots that receives energy from the cover 464, and the output portion is the portion between the shaft 624 and the cam end 608 that transmits energy to the drive link 560.
- the rear end 612 of the spring link 561 includes cam surfaces 625 and 626, the function of which will be described in detail below. While the illustrated spring link 561 is formed from a single piece, in other constructions, the spring link 561 can be formed of multiple part halves that are fastened together via rivets, bonding, gluing, welding, etc. The spring link 561 pivots about the shaft 624 supported by the rear portions 504 of the side plates 453.
- the drive mechanism 472 also includes an elastic member or energy storage device, shown in the illustrated embodiments as dual torsion springs 628, housed between the rear portions 504 of the side plates 453. It should be understood that while two torsion springs 628 are shown in the illustrated embodiments, a single torsion spring could also be used and would fall within the scope of the present invention.
- Each of the torsion springs 628 includes a first end 632 and a second end 636.
- the first ends 632 contact the underside of the rear end 576 of the drive link 560, biasing the rear end 576 upwardly.
- the second ends 636 rest on top of the cam end 608 of the spring link 561, biasing the cam member 614 into contact with the rear end 576 of the drive link 560.
- Neither the ends 632, 636 of the springs 628 are fixed, with the second ends 636 being charged during a first portion of the stapling operations (i.e., a first stapler condition), and with the first ends 632 releasing energy into the drive mechanism 472 during a second portion of the stapling operations (i.e., a second stapler condition).
- Figs. 25 - 26 illustrate the springs 628 in a preloaded position. In the preloaded position, some energy is stored in the springs 628 at all times.
- the cover 464 of the stapler 420 includes an activation member 644.
- the illustrated activation member 644 is supported by a chassis 645 that supports a roller 647.
- the chassis 645 is coupled to the inside of the cover 464. While the illustrated activation member 644 is support by the chassis 645, in other constructions the activation member could be integrally formed with the cover, or could be the inside surface of the cover 464 itself.
- the activation member 644 is configured to cooperate with the rear end 612 of the spring link 561 during the stapling operation. The activation member 644 engages the spring link 561 to allow the user to lift the cover 464 in order to manually reset the stapler, discussed in more detail below.
- the activation member is a pin
- the activation member can be a substantially hook shaped member that depends downwardly from the inside surface of the cover 464.
- the activation member can be any suitable member, such as a post coupled to the spring link that moves within a slot.
- Figs. 29-31 illustrate the stapler 420 during various phases of the stapling operation and illustrate the method of operating the drive mechanism 472 described above.
- Fig. 29 illustrates the stapler 420 in the rest position.
- the driver 468 remains above the magazine 455 (i.e., in the up position) when the stapler is at rest due to the over-center arrangement of the over-center linkage 562, which in the illustrated construction includes the trip link 564 and the pivot link 566.
- This allows the magazine 455 to be ejected out of the front of the stapler 420 if the user wishes to place additional staples within the magazine 455.
- the torsion springs 628 are in the preloaded position within the stapler 420.
- the first ends 632 of the springs 628 bias the rear end 576 of the drive link 560 upwardly into the cam end 608 of the spring link 561.
- the second ends 636 of the springs 628 biases the cam end 608 into the rear end 576 of the drive link 560 such that the cam member 614 cams against the rear end 576 of the drive link 560.
- the cam surface 626 on the rear end 612 of the spring link 561 is in contact with the roller 647 coupled to the cover 464 via the chassis 645.
- the trip link 564 of the over-center linkage 562 is biased into the over-center position by the torsion spring 592 maintaining the pivot link 566 in its over-center position as well.
- the cover 464 is in the extended position when the stapler 420 is in the rest position.
- the cover 464 defines a vertical distance W between the top of the front end 465 and the top surface 444 of the base. In one construction, the vertical distance W ranges from about 73mm to about 87mm, and in other constructions can be any suitable distance.
- the driver 468 defines a vertical distance X between the top of the plate 453 and the midpoint of the front end 572 of the drive link 560. In one construction, the vertical distance X ranges from about 10mm to about 13mm, and in other constructions can be any suitable distance.
- the cover 464 and the magazine 455 pivot downwardly with respect to the base 424 such that the cover 464 moves from the extended position toward the depressed position.
- Inputting force into the stapler 420 charges the stapler, resulting in the first, charged stapler condition.
- the roller 647 coupled to the cover 464 near the rear end 612 of the spring link 561 rolls along the cam or support surface 626 of the spring link 561, causing the front end 608 of the spring link 561 to pivot upwardly against the bias of the second ends 636 of the torsion springs 628, charging the springs 628.
- the movement of the spring link 561 causes the torsion springs 628 to fully deflect, storing more potential energy within the springs 628.
- the rear end 576 of the drive link 560 remains in the rest position due to the over-center bias of the trip link 564 overcoming the upward bias of the first ends 632 of the springs 628 and the alignment of the pivot shafts 600, 604, and 606 of the over-center linkage 562.
- Fig. 30 illustrates the stapler 420 after the manual force inputted by the user has caused the cover 464 to pivot toward the trip link 564 of the over-center linkage 562.
- a tab or protrusion 597 integrally formed on the inside surface of the cover 464 will contact with an outer end 648 of the trip link 564.
- the drive link 560 and the trip link 564 have not yet moved from the rest position and the pivot shafts 600, 604, and 606 of the over-center linkage 562 remain aligned.
- the protrusion 597 could be a separate part coupled to the cover, trip link, or the cover could be configured such that no protrusion is necessary.
- the interaction between the cover 464 and the outer end 648 of the trip link 564 moves the trip link 564 with respect to the pivot link 566 to move the pivot shaft 604 out of the over-center position (i.e., out of alignment with the pivot shafts 600 and 606), overcoming the bias of the torsion spring 592.
- the pivot shafts 600, 604, and 606 of the over-center linkage 562 are no longer aligned and there is no longer any force opposing the upward bias of the first ends 632 of the springs 628 on the rear end 576 of the drive link 560.
- the release of potential energy from the spring 628 drives the driver 468 downwardly through a driver stroke, causing the driver 468 to drive a staple within the magazine 455 out of the stapler 420 (in the stapling direction) and into a waiting stack of sheets.
- the triggering mechanism of the stapler 420 e.g., the over-center linkage 562 in the illustrated embodiment
- the cover 464 moves into the depressed position as the stapler is in the stapling position.
- the cover 464 defines a vertical distance Y between the top of the front end 465 and the top surface 444 of the base 424
- the driver 468 defines a vertical distance Z between the top of the plate 453 and the midpoint of the front end 572 of the drive link 560.
- the vertical distance Y ranges from about 53mm to about 57mm
- the vertical distance Z ranges from about 19mm to about 25mm. In other constructions the vertical distances Y and Z can be any suitable length.
- the driver 468 moves vertically through the driver stroke.
- the driver stroke represents the vertical movement of the driver 468 upon actuation by the drive linkage 556, and has a length calculated by subtracting the vertical distances of the driver 468 identified above (i.e., Z-X).
- Z-X the vertical distances of the driver 468 identified above
- the downward force of the driver 468 also assists in the clinching of the staple legs as the staple legs pass through the stack of sheets into the anvil 448. Similar to the stapler 201 of Fig. 21 , and as illustrated in Fig. 31 , a bottom portion of the driver 468 extends through and out of the magazine 455 after the staple has been driven. The driver 468 is not mechanically stopped during the stapling operation such that the continued movement of the driver 468 through the bottom of the magazine 455 imparts additional force to the staple as the staple enters the stack of sheets and is clinched.
- the total vertical movement in the stapling direction of the front end 465 of the cover 464 as compared with the total vertical movement of the driver 468 during the driver stroke represents the mechanical advantage realized in the stapler 420.
- the total vertical movement of the front end 465 of the cover 464 i.e., a first vertical distance
- the first vertical distance ranges from about 16mm to about 34mm.
- the total vertical movement of the driver 468 during the driver stroke i.e., a second vertical distance is calculated as described above, subtracting X from Z.
- the second vertical distance ranges from about 9mm to about 12mm.
- the mechanical advantage of the stapler 420 ranges from about 1.8:1 to about 4:1. In other embodiments, the mechanical advantage ranges from about 3:1 to about 8:1. The greater the vertical distance traveled by the cover 464 with respect to the distance traveled by the driver 468 during the driver stroke, the greater the mechanical advantage in the stapler.
- FIG. 24 , 26 , and 29 another method of determining or quantifying the mechanical advantage of the stapler is to calculate the mechanical advantage through the input and output lengths of the cover 464 and the drive linkage 556.
- the cover 464 acts as a link in the drive linkage 556.
- the mechanical advantage in the drive link 560 is calculated by dividing the input length H of the drive link 560 by the output length 1.
- the mechanical advantage of the drive link 560 ranges from about 2.8 to about 5.4.
- the mechanical advantage in the drive link is equal to 33mm/27mm (H/I), or approximately 1.2.
- the mechanical advantage of the spring link 561, in one construction is 32mm/36mm (J/K), or approximately 0.88.
- the mechanical advantage of the cover 464 is equal to the input length F of the cover 464 divided by the output length G. In one construction, the mechanical advantage of the cover 464 is 153mzn130rnm (F/G), or approximately 5.1.
- the mechanical advantage of the cover 464 is multiplied by the mechanical advantage of the drive link 560 and the mechanical advantage of the spring link 561. Therefore, using the construction described above, the stapler 420 has a mechanical advantage of 1.2*0.88*5.1, or approximately 5.4. Using this formula, changing the geometry of any of the cover 464, the drive link 560, or the spring link 561, such as changing the length of the input and/or output portions, would directly affect the mechanical advantage of the stapler.
- the method described above results in a stapler 420 with improved stapling function requiring less force input by the user due to the use of the potential energy that naturally builds within the drive mechanism 472 to drive the staples out of the stapler 420.
- the configuration of the cover 464 and the drive linkage 556 increases the leverage available to the user such that the amount of force needed from the user to deflect the torsion springs 628 and store energy in the springs 628 is reduced, as discussed in detail above.
- the torsion springs 628 are preloaded, a residual amount of potential energy remains in the drive mechanism 472 at all times such that even after staple driving, the residual potential energy can assist with completing the staple clinch and returning the stapler 420 to the rest position, due in part to the geometry of the drive link 560.
- the geometry of the over-center linkage 562, which includes the trip link 564 and the pivot link 566, (i.e., the over-center arrangement) maintains the driver 468 above the magazine 455 in the stapler rest position to allow for front loading of the staples.
- the drive linkage 556 When there is no staple jam, the drive linkage 556 will naturally want to reset itself due to the residual energy in the springs 628.
- Prior art staplers required a user to manually reset the stapler to rest, or utilized an additional spring for the express purpose of resetting the stapler to rest.
- the geometry of the drive mechanism 472, including the drive linkage 556, of the stapler 420 automatically resets the stapler 420 to the rest position.
- the shape of the rear end 576 of the drive link 560 and the cam end 614 of the spring link 561 maintain a large gap (i.e., the difference in height) between the first and second ends 432, 436 of the springs 628. The gap imparts additional potential energy into the springs 628.
- the drive mechanism 472 allows the user to manually lift the cover 464 to reset the stapler and the drive mechanism 472 to the rest position.
- the actuation member or pin 644 moves upwardly with the cover 464 and into engagement with the cam surface 625 on the bottom of the spring link 561.
- the actuation member 644 raises the rear end 612 of the spring link 561 back to the position shown in Fig. 29 , allow the rest of the linkages in the drive mechanism 472 to reset to the rest position shown in Fig. 29 .
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Abstract
Description
- The invention relates to staplers, and more particularly, to staplers utilizing potential energy to assist in operating the staple drive mechanism. Potential energy or spring assisted office staplers have traditionally been of two types; either a stationary adaptation of powerful tacker-type models or a stationary stapler whose spring assist cannot achieve full power to drive and clinch the required sheet capacity without additional user applied force.
- Typically, in a tacker-type stapler the staples are driven into the target object but the leg of staples are not bent. The strong force that is required for driving the staples is obtained by releasing the pressure that is accumulated in a spring or elastic member. Further, this structure that stores pressure in the spring can be of many different types but all are typically structured such that when the stapler is not in operation, the blade is located in front of the staples and when the blade is lifted, the staples move forward in the magazine. The blade is then lowered to drive one of the staples that has been pushed forward. This entire series of operations are executed in one instant with a powerful flow of force. Such a tacker is illustrated in
U.S. Patent No. 6,145,728 . A stationary stapler adaptation of a similar mechanism is illustrated inU.S. Patent No. 6,918,525 . - In this type of tacker-type stapler configuration, when nothing is being stapled, there is a danger of staples flying out of the tacker inadvertently and it was necessary to develop a more complex structure in order to prevent such erroneous operations. Further, what is then seen in the tacker-type is a stationary configuration which requires loading the stapler from the rear due to the driver being in front of the staples and not lifted except during stapler operation. As a result, when the staples are reloaded, either the base or the magazine frame would have to be rotated and opened and the staples would then be fed. As such, more complex structures were adopted for each of inadvertent operation and staple reloading.
- In the second type, spring assisted power has been applied within stationary staplers with a raised driver and without rear staple loading. However, previous approaches achieved very limited power gain given the limitations of known spring trigger mechanisms, known driver engagement mechanisms or other related linkages. These constructions only partly automate the function of the stapler and require additional manual force be applied to the driver when a stapler is operated at its sheet capacity, otherwise the staple would not be fully clinched under the paper. A stationary stapler adaptation of such an assist mechanism is illustrated in
U.S. Patent No.5,356,063 , which discloses the preamble ofclaim 1. - Both known types utilize locking mechanisms which act directly on the driver blade. These locking mechanisms intermittently experience functional problems including reduced power transmission to the driver, premature component failure, unreliable actuation and difficulty in returning to the rest position.
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US Patent No. 535,063 discloses a hand-operated stapler, including a base plate having two opposite ends and side parts disposed at one of the ends. A die plate is disposed at the other of the ends. A body is pivotably supported by the side parts. The body has a magazine with a centre channel for receiving and guiding a strip of staples and guide ribs disposed substantially at right angles to the centre channel. A push blade is guided by the guide ribs for sliding up and down to release and drive in the staples. A top part partly covers the body and acts as an operating arm. A locking release device for the push plate is operated by the top part. The locking and release device has a pivotable latch being disposed between the top part and the body and is releasably joined to the push plate for intermittently locking the push plate in a locked postion relative to a staple in the strip and for releasing the push plate in an unlocked position. The locking and release device has a spring supported on the push plate and is tensed when the unlocked position is attained for effecting sudden release of the push plate. - This invention is a stapler having the features of
claim 1, that is used for binding together the target objects by driving the staples utilizing the force that has been accumulated in an elastic member, that force being released all at once. The invention is also related to a stapler where the driver blade is not positioned in front of the staples but rather above the staples when the stapler is not in use. Further, this invention fully automates the function of the stapler while achieving adequate power and maintaining the preferred loading method. - The invention could be utilized in a desktop-type stapler, where the staple legs are bent to bind together the target objects, or a tacker-type stapler where the staple legs are not bent. The desktop-type stapler of this invention reduces the possibility of the staples flying out by mistake and aims to obtain a stapling action that staples with a lot of power. Further, this is a stapler that is used for binding together papers and the like. The force that has been accumulated in the elastic object material is fed into the structure of the tacker from the viewpoint of releasing the force that has been stored up in the elastic member all at once and, as mentioned, it does not have a composition that is usually seen in tackers wherein the blade is located in front of the staples, but rather a structure where the blade is positioned above the staples.
- Further the invention also aims to achieve a structure whereby there is no need for a large rotation or movement of the base or the frame when the staples are being reloaded. The invention also aims to have a function where not only will the staples not be ejected by mistake, but further the structure will be simple and the stapling operation can be performed with a light force.
- In one embodiment, the invention provides a stapler movable between a rest position and a stapling position. The stapler has a front end adjacent a staple ejection location and a rear end. The stapler includes a base, a staple magazine coupled to the base and configured to hold staples, and a driver blade operable to drive staples out of the staple magazine during stapling operations. The stapler further includes an elastic member coupled to the driver blade and operable to move the driver blade during stapling operations. The elastic member utilizes potential energy to move the driver blade during stapling operations. The driver blade is positioned above the staple magazine when the stapler is in the rest position and the magazine is extendable from the front end of the stapler to allow a user to load staples in the magazine. The stapler is configured such that only the potential energy of the elastic member can operate the driver blade during stapling operations. In one embodiment, the elastic member is released by a triggering mechanism that does not directly contact the driver blade, thereby eliminating many of the triggering mechanism and locking mechanism problems of prior art staplers.
- In another embodiment, the invention provides a stapler movable between a rest position and a stapling position. The stapler includes a staple magazine configured to hold staples, a driver operable to drive staples out of the staple magazine during stapling operations, and a drive mechanism coupled to the driver and operable to move the driver during stapling operations. The drive mechanism includes an elastic member for storing energy therein. The stapler further includes an activation member configured to engage the drive mechanism such that when a staple jam occurs, a user can manually reset the stapler to the rest position.
- In some embodiments of the invention, an engagement part of the elastic member is engaged with a support member in the form of a slider, and as the cover and the frame come closer together due to the force input on the cover, the engagement part moves along the upper surface of the slider relatively until the engagement between the elastic member and the slider is released with the engagement part passing through the front end of the top surface of the slider. The slider is movable relative to the magazine in the forward and backward directions (i.e., longitudinally). In other configurations, the support member can take the form of a pivoting member attached in the frame and rotatable about a pivot axis.
- In other embodiments of the invention, the slider includes a taper or arcuate surface in the front end of the slider, and the upper surface angle protrudes even farther out than a lower surface angle. With the cover and the frame coming closer together, the engagement part provides force such that the slider's upper surface front end is moved, leading to a disengagement of the elastic member and the slider. With a release of the force that is applied in a direction that brings the cover and the frame close together, the cover rises upwards and the engagement part of the elastic member rises along the taper or arcuate surface. Once the rising has been completed, the engagement part is engaged with the upper surface of the slider and with the help of the slider spring, the engagement portion of the engagement part and the slider are tilted in the direction that pushes the slider in the backward direction. With the engagement part pushing the upper surface of the slider back, the elastic member returns to the configuration that exists when the stapler is not in use.
- In some embodiments of the invention, the stapler includes a means that helps in disengaging the elastic member and the slider. The slider is pushed back with respect to the frame due to engagement between the cover and the slider.
- In yet other embodiments the elastic member is part of a drive mechanism coupled to the driver blade by a drive linkage that is in continuous contact with the driver blade during stapling operations. In one embodiment the drive linkage includes a driver link and an over-center link. The drive link has a first end connected to the driver blade, a second end coupled with the elastic member, and a pivot point intermediate the first and second ends. The over-center link is coupled with the driver link and is movable between a first position to prevent the drive link from pivoting about the pivot point, and a second position to allow the drive link to pivot about the pivot point to drive the driver blade
- Typical potential energy stapler technology utilizes a portion of the frame to prevent the driver blade from extending out of the bottom of the magazine. Preventing the driver blade from extending out of the magazine reduces the stapling power and can generate a considerable amount of noise. The stapling force is reduced because the driver blade is suddenly stopped during stapling. Therefore, more force needs to be generated by the stapler than the actual force that is required for stapling because energy is consumed to prevent the driver blade from extending out of the magazine.
- The driver blade of the stapler of the present invention is allowed to extend out of the magazine during stapling. Thus, there is generally no need to stop the blade from extending past the bottom of the magazine. As a result, less force needs to be generated by the stapler of the present invention versus typical potential energy staplers because energy is not consumed to stop the driver blade. Therefore, comparing the stapler of the present invention with typical potential energy staplers, the current stapler can staple the same amount of sheets or other items with less force. In addition, the stapler of the present invention generates less noise than typical potentially energy staplers because the driver blade is not suddenly stopped.
- Since the blade starts from above the staples, a front-loading mechanism or arrangement can still be used. Further the stapler of the present invention provides a stapler with potential energy technology while only slightly increasing the number of component parts from non-potential energy type staplers.
- The elastic member coupled to the underside of the cover creates a compact design such that the space required for the working components is less than staplers with other types of potential energy technology. When this feature is added to the fact that the number of parts is less, the freedom in the design is greatly enhanced and it is easy to construct this device such that it is more compact than staplers with other types ofpotential energy technology.
- Further, it is possible to change the force provided by the plate spring by making changes to the plate thickness and configuration, and has therefore becomes easier to apply this new technology over a wide range of devices starting from small staplers that require only minimal amount of force for stapling and extending to large staplers that need more force for the stapling action.
- A stapler with other potential energy technology needs to have various safety measures and features to facilitate reloading the staples. The driver blade in the present invention is initially at rest above the staples and there is no spring force in the blade. Therefore, it is easy to obtain the same level of safety as a conventional stapler when reloading the staples.
- Other features and advantages of the invention will become apparent to those skilled in the art upon review of the following detailed description, claims, and drawings.
-
Fig. 1 is an external view of the stapler not embodying the present invention. -
Fig. 2 is a cutaway view of the stapler ofFig. 1 , illustrating the internal configuration of the stapler when the stapler is not in us. -
Fig. 3 is an exploded view of a portion of the stapler ofFig. 2 . -
Fig. 3a is an enlarged view of an elastic member of the stapler illustrated inFig. 3 . -
Fig. 4 is a perspective view of a staple magazine of the stapler ofFig. 1 when the magazine of the stapler is pulled out. -
Figs. 5a - 5e illustrate the operation of the stapler ofFig. 1 . -
Figs. 5a' - 5e' relate to Figs. 5a - 5e respectively and illustrate a portion of the stapler ofFig. 1 during the operation of the stapler. -
Fig. 6 illustrates the internal configuration of the stapler ofFig. 1 when the stapler is being operated just before a staple is driven from the stapler. -
Fig. 7 illustrates the internal configuration of the stapler ofFig. 1 when the stapler is being operated after the staple is driven from the stapler. -
Fig. 8 illustrates the internal configuration of the stapler ofFig. 1 when the stapler is being operated as the cover begins to rise with respect to the staple magazine. -
Fig. 9 illustrates the internal configuration of the stapler ofFig. 1 when the stapler is being operated as the cover continues to rise with respect to the staple magazine. -
Fig. 10 illustrates the internal configuration of the stapler ofFig. 1 when the stapler has returned to the rest or start position. -
Fig. 11 illustrates the inner configuration of the stapler ofFig. 1 when the magazine of the stapler is pulled out to extend from the stapler -
Fig. 12 is an alternative arrangement of the stapler ofFig. 1 illustrating the inner configuration of the stapler and a driver spring. -
Fig. 12a illustrates the driver spring of the stapler ofFig. 12 . -
Fig. 13 is another alternative arrangement of the stapler ofFig. 1 illustrating the inner configuration of the stapler and a driver spring. - Fig. 13b illustrates the driver spring of the stapler of
Fig. 13 . -
Fig. 14 is yet another alternative arrangement of the stapler ofFig. 1 illustrating the internal configuration of the stapler. -
Fig. 15 is yet another alternative arrangement of the stapler ofFig. 1 illustrating the inner configuration of the stapler when the stapler is in the rest or start position. -
Fig. 16 illustrates the stapler ofFig. 15 when the stapler is being operated just before a staple is driven from the stapler. -
Fig. 17 illustrates an elastic member of the stapler ofFig. 15 . -
Fig. 18 illustrates a support member of the stapler ofFig. 15 . -
Fig. 19 is an enlarged view of a front portion of the stapler ofFig. 15 with a portion of the stapler removed. -
Fig. 20 is yet another alternative arrangement of the stapler ofFig. 1 illustrating the inner configuration of the stapler when the stapler is in the rest or starting position. -
Fig. 21 illustrates the stapler ofFig. 20 when the stapler is being operated just after a staple has been driven from the stapler. -
Fig. 22 illustrates the stapler ofFig. 20 when the stapler is being operated as the cover rises back to the starting position. -
Fig. 23 is yet another alternative embodiment of the stapler ofFig. 1 illustrating the inner configuration of the stapler when the stapler is in the rest or starting position. -
Fig. 24 is yet another alternative embodiment of the stapler ofFig. 1 illustrating a cutaway perspective view with the staple magazine in the staple loading position. -
Fig. 25 is a cutaway perspective view of a portion of the stapler ofFig. 24 . -
Fig. 26 is a side view of a drive mechanism of the stapler ofFig. 24 . -
Fig. 27 is a perspective view of the drive mechanism of the stapler ofFig. 24 . -
Fig. 28 is a top view of the drive mechanism of the stapler ofFig. 24 . -
Fig. 29 is a section view of the stapler ofFig. 24 in the rest position. -
Fig. 30 is a section view of the stapler ofFig. 24 in a partially actuated position. -
Fig. 31 is a section view of the stapler ofFig. 24 in a fully actuated position. - Before any embodiments of the invention are explained in detail, it is to be understood that the invention is not limited in its application to the details of construction and the arrangement of components set forth in the following description or illustrated in the following drawings. The invention is capable of other embodiments and of being practiced or of being carried out in various ways. Also, it is to be understood that the phraseology and terminology used herein is for the purpose of description and should not be regarded as limiting. The use of "including," "comprising," or "having" and variations thereof herein is meant to encompass the items listed thereafter and equivalents thereof as well as additional items. Unless specified or limited otherwise, the terms "mounted," "connected," "supported," and "coupled" and variations thereof are used broadly and encompass both direct and indirect mountings, connections, supports, and couplings. Further, "connected" and "coupled" are not restricted to physical or mechanical connections or couplings.
- The present invention will be described with reference to the accompanying drawing figures wherein like numbers represent like elements throughout. Certain terminology, for example, "top", "bottom", "upper", "lower", "front", "rear". "up", "down", "right", "left", "clockwise", "counterclockwise" is used in the following description for relative descriptive clarity only and is not intended to be limiting.
- A
first stapler 1 is illustrated inFigs. 1-11 . The external appearance of thestapler 1 is as seen inFig. 1 . Referring toFig. 1 and 2 , thestapler 1 defines a front end 6, adjacent astaple ejection location 7, and arear end 8 opposite the front end 6. Thestapler 1 includes a base 2, aframe 3 that is coupled to the base 2, and a handle or cover 5 that is coupled to theframe 3 near therear end 8 of thestapler 1. - The illustrated base 2 includes an
anvil 9. As is understood by one of skill in the art, theanvil 9 facilities clinching or bending staples. The base 2 supports thestapler 1 on a support surface, such as a desk, table, countertop, and the like. -
Fig. 2 illustrates the internal configuration of thestapler 1 when thestapler 1 is not in operation.Fig. 3 is an exploded view that illustrates several of parts of thestapler 1. For clarity,Fig. 3 is a cross-sectional view along a longitudinal axis of thestapler 1 illustrating generally half of several parts of thestapler 1. - Referring to
Figs. 1-3 , the illustratedstapler 1 further includes acover biasing member 14 between thecover 5 and theframe 3 that biases thecover 5 away from theframe 3. While, the illustratedcover biasing member 14 is a coil spring, in other constructions the cover biasing member can be any suitable spring, such as torsion springs, leaf springs, and the like, or other suitable biasing members. - The illustrated
cover 5 includes atrigger member 12 that extends from an inside surface of thecover 5. While the illustratedtrigger member 12 includes two projections, in other constructions the trigger member can include only a single projection or may take other suitable forms. Thecover 5 further includes a spring or elasticmember receiver portion 11 that extends from the inside surface of thecover 5, adjacent thetrigger member 12. - The
stapler 1 further includes a driver member orelastic member 20, which is a leaf spring in the illustrated construction. Theelastic member 20 is positioned between thecover 5 and themagazine 50. Theelastic member 20 includes a first orfree end portion 15, a second or fixedend portion 16, and abody portion 17 that extends between the free andfixed end portions fixed end portion 16 of the illustratedelastic member 20 includes a substrate orbase portion 21 that is utilized to couple theelastic member 20 to thereceiver portion 11 of thecover 5. In the illustrated construction, theelastic member 20 is coupled to thecover 5 using fasteners that extend intoapertures 13 formed in thecover 5. In other constructions, a slit can be provided in thereceiver portion 11, or at any suitable location within thecover 5, and at least a portion of thebase portion 21 of theelastic member 20 can be bent to form a tab such that the tab can be press-fitted into the slit of the cover. Such a tab and slit configuration construction can be used alone or in combination with fasteners and theapertures 13. - Referring to
Figs. 3 and3a , thefree end 15 of theelastic member 20 includes ablade engagement portion 24 and a slider or supportmember engagement portion 22 that extends in a lateral direction from theblade engagement portion 24 to form a T-shaped engagement portion of theelastic member 20 in the illustrated embodiment. Adriver blade 27 is coupled to theelastic member 20 at theblade engagement portion 24. Theblade engagement portion 24 of theelastic member 20 extends through aslit 28 formed in thedriver blade 27 to couple or engage theelastic member 20 to thedriver blade 27. Theslit 28 of thedriver blade 27 is sized such that theblade engagement portion 24 of theelastic member 20 is free to move with respect to thedriver blade 27 in the forward and rearward directions. - Referring to
Fig. 2 , in the illustrated construction theelastic member 20 is a leaf spring. In other constructions, theelastic member 20 can be any suitable biasing member. The leaf spring defines an angle θ that is measured from theblade engagement portion 24 to thebody portion 17 of theelastic member 20 with thestapler 1 in a resting or starting position (i.e., thecover 5 has not been pushed down). In the illustrated construction, the angle θ is approximately 160 degrees. In other constructions, the angle θ can be more or less than 160 degree depending on the application of thestapler 1. For example, if thestapler 1 is designed for relatively large staples and/or to staple through a relatively large amount of paper and the like, the angle θ can be less than 160 degrees. - Referring to
Figs. 2 and3 , thestapler 1 further includes asupport member 30, which is a slider in the illustrated construction. Thesupport member 30 includes cut outportions 31 that define trigger guide surfaces 32, and support surfaces 34 that slidably support the supportmember engagement portions 22 of theelastic member 20. Thesupport member 30 further includes spring guide openings orslots 33 that extend transversely through thesupport member 30 and front tapered portions orsurfaces 35 that are spaced a distance apart in order to engage the supportmember engagement portions 22 of theelastic member 20. - The illustrated
support member 30 is coupled to theframe 3 using hubs or bosses 38 (only one visible inFig. 3 ) that are received by theslots 33 of thesupport member 30. The illustratedsupport member 30 is able to slide with respect to theframe 3, and theslots 33 define the maximum forward and rearward positions of thesupport member 30 with respect to theframe 3. In the illustrated construction, thesupport member 30 slides is a direction generally parallel to alongitudinal axis 53 defined by themagazine 50 of thestapler 1. As best illustrated inFig. 2 , a biasingmember 40, which is a coil spring in the illustrated construction, biases thesupport member 30 toward the front end 6 of thestapler 1. - Referring to
Figs. 5 a and 5a', when thestapler 1 is not in operation, the supportmember engagement portion 22 of theelastic member 20 is positioned on or above the spring gliding part orsupport surface 34 of theslider 30. Although theslider 30 moves with respect to theframe 3 in the forward and the rearward directions, the movement of theslider 30 is limited due to the engagement between thehub 38 of theframe 3 and the spring guide opening or slot 33 of theslider 30. Referring toFig. 5a , the slider spring or biasingmember 40 moves or biases theslider 30 in the forward direction (i.e. toward the front end 6 of the stapler 1). - Referring to
Figs. 2 - 4 , thestapler 1 includes themagazine 50 that is housed in the area 4 of theframe 3. Themagazine 50 stores orhouses staples 51. Themagazine 50 is located with respect to theframe 3 such that adriver blade slot 56 formed in themagazine 50 is aligned with adriver blade slot 57 formed in theframe 3. Thedrive blade slots magazine 50 and theframe 3 are aligned such that thedriver blade 27 can pass freely through both of theslots - Referring to
Fig. 3 , the illustratedmagazine 50 includes a feeder orstaple pusher 48 and aguide rod 55. Thestaple pusher 48 moves along theguide rod 55 to move or push Attorney Docket No. 010398-9349-01staples 51 toward the front end 6 of thestapler 1. While not illustrated, themagazine 50 can include a biasing member, such as a coil spring disposed around theguide rod 55 and coupled to theguide rod 55 andstaple pusher 48 to bias thestaple pusher 48 toward the front end 6 of thestapler 1. Other configurations can also be used to bias thestaple pusher 48 toward the front end 6. - The
magazine 50 further includes a hook or latch 43 and a cut out 49. Thelatch 43 includes mounting bosses 44 (only one visible inFig. 3 ) that couple thelatch 43 to theframe 3 using the apertures 39 (only one visible inFig. 3 ) formed within theframe 3. Thebosses latch 43 to theframe 3. While not illustrated a biasing member, such as a spring, can be used to bias thelatch 43 into an engaged position, such that thelatch 43 is engaged with the cut out 49. - While not illustrated, the
magazine 50 further includes a magazine biasing member, such as a spring, thatbiases magazine 50 toward an open position (Fig. 11 ) or from therear end 8 of thestapler 1 toward the front end 6. By disengaging thelatch 43 from the cut out 49, it is possible to draw out or eject themagazine 50 forward for reloadingstaples 51 into the magazine 50 (Fig. 4 ). The user can disengage thelatch 43 from the cut out 49 with a button, lever, or other suitable actuator interconnected to latch 43. In other constructions, thestapler 1 can be configured such that user can depress or push a rear portion of thelatch 43 to eject themagazine 50 from theframe 3. -
Figs. 5a - 5c illustrate the operation of thestapler 1 and the passage or ejection of the staples 51 (Fig. 4 ). By pushing thecover 5 downward, toward themagazine 50, thestapler 1 is operated in the order illustrated in the orderFig. 5a →Fig. 5b →Fig. 5c . The stapling operation is completed when the state shown inFig. 5c is reached. To continue, when the user stops pushing thecover 5 downward, thestapler 1 returns to the state that existed (i.e., original or starting position) before stapling by carrying out the operations illustrated in the orderFig.5d →Fig. 5e →Fig. 5a . The engagement of theelastic member 20, thesupport member 30 and thetrigger member 12 is shown in the steps illustrated inFigs. 5a'-Fig. 5e' . Details of the position illustrated inFig. 5a are shown inFig. 2 while the details of the position illustrated inFig. 5b are shown inFig. 6. Figs. 7 ,9 and10 indicate the details of the positions illustrated inFigs. 5c, 5d and 5e respectively. - As illustrated in
Figs. 5a and 5a' , when the user starts to push thecover 5 downward, toward themagazine 50, theengagement portion 22 of theelastic member 20 is in contact with the top surface orsupport surface 34 of thesupport member 30. When thecover 5 is pushed down further, the angle θ (Fig. 2 ) between theblade engagement portion 24 and thebody portion 17 of theelastic member 20 is opened or the angle θ increases and theengagement portion 22 of theelastic member 20 moves forward along thesupport surface 34 of thesupport member 30. - As illustrated in
Figs. 5b and 5b' , if thecover 5 is pushed further down, theengagement portion 22 of theelastic member 20 will slide along thesupport surface 34 of thesupport member 30 right up to the front edge of thesupport surface 34. At this time, a large amount of force or energy to return to the original state (Fig. 5a ) is accumulated in theelastic member 20. - As illustrated in
Figs. 5c and 5c' , should thecover 5 be pushed further down, theengagement portion 22 of theelastic member 20 will fall downward after detaching or disengaging from thesupport surface 34 of thesupport member 30. In the illustrated construction, theelastic member 20 passes through a portion of thesupport member 30 between upstanding portions that define the support surfaces 34. When theengagement portion 22 of theelastic member 20 disengages thesupport surface 34 of thesupport member 30, thedriver blade 27 that is engaged withblade engagement portion 24 of theelastic member 20 is driven downward. The force that is accumulated in theelastic member 20 will be released instantly and the force driving theblade 27 will be sufficient to drive the staples effectively. - As illustrated in
Fig. 5b and 5b' and inFig. 5c and 5c' , thetrigger member 12 is lowered along with thecover 5, and thetrigger member 12 is engaged with thetrigger guide 32 while thetrigger member 12 is fed into the cut out 31 of thesupport member 30. Thetrigger member 12 contacts the trigger guide surfaces 32 of thesupport member 30 and guides or pushes thesupport member 30 backward while thecover 5 moves down. In the illustrated construction, when thetrigger member 12 contacts thesupport member 30 the user continues to push down on thecover 5 to overcome the force of the biasingmember 40 to slide thesupport member 30 toward therear end 8 of thestapler 1. - The
trigger 12 facilitates disengaging theengagement portion 22 of theelastic member 20 from the tip or front edge of thesupport member 30. In other words, since theelastic member 20 is a plate or leaf spring, there is a small amount of bending of theelastic member 20 based on the timing or speed of the stapling action. Due to this bending, the distance from thebase 21 of theelastic member 20 to theengagement portion 22 becomes shorter causing cases when the disengagement of theengagement portion 22 with thesupport member 30 does not occur properly. Thesupport member 30 is then pushed backward or toward therear end 8 of thestapler 1 by thetrigger member 12 to ensure that theengagement portion 22 of theelastic member 20 is disengaged from thesupport member 30 and that thedriver blade 27 falls. -
Figs. 5c and7 illustrate thecover 5 of thestapler 1 in the furthest downward (i.e., lowered) position. As illustrated inFigs. 5a - 5c , as thecover 5 travels from the starting position (Fig. 5a ) to the lowered position (Fig. 5c ), theelastic member 20 extends through theslit 28 in the driver blade 27 (Fig. 3 ) to remain in continuous contact with thedriver blade 27. - As illustrated in
Figs. 5c and7 , in the illustrated construction, thecover 5 does not contact thedriver blade 27 when thecover 5 is in the lowered position. Therefore, when thecover 5 is the lowered position, thecover 5 generally does not tend to push thedriver blade 27 further downward. Thus, the maximum achievable stapling power of thestapler 1 is generated by theelastic member 20, and the user cannot push down further or harder on thecover 5 to force thedriver blade 27 down further. - After stapling, when the force used to push the
cover 5 is released, thecover 5 returns to the original position (Fig. 5a ) by rising immediately with the help of thecover biasing member 14. As shown inFig. 5c' , in the illustrated construction, thetrigger member 12 and thesupport member 30 are engaged only above the cut out 31 of thesupport member 30 when thecover 5 is in the lowered position. As thecover 5 rises, disengagement between thetrigger member 12 and thesupport member 30 can take place easily and there is no longer any impact of thetrigger member 12 on thesupport member 30. - As illustrated in
Fig. 5d and 5d' , as thecover biasing member 14 raises thecover 5, theengagement portion 22 of theelastic member 20 rises upward and is guided by thefront taper portions 35 of thesupport member 30. At this time, the spring force of thecover biasing member 14, which forces thecover 5 andelastic member 20 to rise, is greater than the spring force of the biasingmember 40 of thesupport member 30 that biases thesupport member 30 toward the front end 6 of thestapler 1. Because thefront taper 35 angles forward, as theelastic member 20 rises, theengagement portion 22 not only slides along thefront taper 35 of thesupport member 30, but also guides or pushes thesupport member 30 backward or toward therear end 8 of thestapler 1. - As illustrated in
Fig. 5e and 5e' , as thecover 5 and theelastic member 20 rise further, theengagement portion 22 of theelastic member 20 reaches the peak of thefront taper portions 35 of thesupport member 30. When thecover 5 andelastic member 20 rise slightly more, theengagement portion 22 is detached from thefront taper portion 35 of thesupport member 30 and theengagement portion 22 of theelastic member 20 re-engages with thesupport surface 34 of thesupport member 30. When theengagement portion 22 is detached from thefront taper portion 35 of thesupport member 30, thesupport member 30 is pushed forward by the biasingmember 40 while theengagement portion 22 slides along thesupport surface 34 of thesupport member 30 to return thesupport member 30 andelastic member 20 to the original or starting position as illustrated inFig. 5a . -
Figs. 12 and 12a illustrate a second stapler. In the arrangement illustrated inFig. 12 , theelastic member 58 includes a rearwardly-extendingplate spring portion 59 that functions as the cover biasing member (i.e., in place of thecover biasing member 14 ofFigs. 1-11 ). The illustratedplate spring portion 59 is integrally formed with theelastic member 58, however could be a separate piece. The other mechanisms of the stapler and operation of the stapler are similar to the first arrangement ofFigs. 1-11 . -
Figs. 13 and 13a illustrate a third arrangement. Theelastic member 60 includes aplate spring portion 61 that operates as the cover biasing member (i.e., in place of the cover biasing 14 ofFigs. 1-11 ). Furthermore, theelastic member 60 includes support member biasing members or slider springs 62 that can replace or supplement the biasingspring 40 ofFigs. 1-11 . The illustrated slider springs 62 andplate spring 61 are integrally formed with theelastic member 60 but alternatively could be separate components. The other mechanisms of the stapler and operation of the stapler are similar to the first arrangement. -
Fig. 14 illustrates a fourth arrangement in which thesupport member 30 is replaced by acam 63 that guides the engagement part of the elastic member. Thecam 63 rotates with the help of thecam spring 65 about theaxis 64. The other mechanisms are similar to the first arrangement. -
Figs. 15 - 19 illustrate yet another alternative arrangement of thestapler 1 ofFigs. 1 - 11 . Thestapler 101 ofFigs. 15-19 is similar to thestapler 1 ofFigs. 1-11 . Therefore, like components have been given like reference numbers in the one-hundred series, and only the general differences will be discussed below. -
Fig. 15 illustrates thestapler 101 that includes thebase 102, theframe 103 coupled to thebase 102, and thecover 105 that is coupled to theframe 103. - The
elastic member 120 is positioned between thecover 105 and themagazine 150. The illustratedelastic member 120 defines the angle between thebody portion 117 and the driverblade engagement portion 124 that is approximately 140 degrees. As discussed above, the angle can be virtually any angle depending on the application of thestapler 101, including the angle that is approximately 160 degrees as illustrated in thestapler 1 ofFigs. 1-11 . - The
elastic member 120 is illustrated in more detail inFig. 17 . The illustratedelastic member 120 is a leaf spring that includes the free orfirst end portion 115 and the fixed orsecond end portion 116. Thesecond end portion 116 of theelastic member 120 includes afirst layer 166 and asecond layer 167. Thefirst layer 166 and thesecond layer 167 are formed to define aloop 168. The illustratedfirst layer 167 of theelastic member 120 is bent generally upwards at one end to form atab 170. Thetab 170 is received within aslot 169 formed in thecover 105 to facilitate coupling theelastic member 120 to thecover 105. - Referring to
Figs. 15 and17 , thesecond end portion 116 of the illustratedelastic member 120 further includes anaperture 171 that extends through theelastic member 120. Theaperture 171 receives afastener 172 to couple theelastic member 120 to thecover 105. The illustratedaperture 171 includes afirst aperture 171 a formed through thefirst layer 166 and asecond aperture 171 b formed through thesecond layer 167 that is smaller than thefirst aperture 171a that extends through thefirst layer 166. The first andsecond apertures 171 a, b are sized such that thesecond aperture 171b that extends through thesecond layer 167 is utilized to generally fix or secure theelastic member 120 to thecover 105 while thefirst aperture 171 a that extends through thefirst layer 166 is larger than a head of thefastener 172. - Therefore, the
first aperture 171a and thefirst layer 166 are able to move with respect to thefastener 172 and thesecond layer 167. Such a configuration increases the effective length of theelastic member 120 as compared to theelastic member 20 ofFigs. 1- 11 to include thefirst layer 166, theloop 168, and the portion of thesecond layer 167 between theloop 168 and theaperture 171b. However, it should be understood that any of the embodiments of the stapler described herein can include either the single layer elastic member or the dual layer elastic member. - Referring to
Fig. 17 , thefirst end portion 115 of theelastic member 120 includes the supportmember engagement portions 122. The illustrated supportmember engagement portions 122 define a generally T-shaped portion of theelastic member 120 and includestabs 173 that are somewhat rounded. Thetabs 173 facilitate sliding of theelastic member 120 along thefront portions 135 of the support member 130 (Fig. 18 ). - Referring to
Figs. 15 and18 , thestapler 101 further includes thesupport member 130 that supports theelastic member 120. Similar to thesupport member 30 ofFigs. 1-11 , the illustratedsupport member 130 ofFigs. 15 and18 is a slider movable in a direction parallel to thelongitudinal axis 153 of themagazine 150. The illustratedsupport member 130 includes support surfaces 134 that support theelastic member 120 andfront end portions 135 that are both tapered and radiused. The radius of thefront end portions 120 has been found to more effectively allow theelastic member 120 to move along thefront end portions 135 to return to the support surfaces 134 of thesupport member 130 as thecover 105 rises after stapling. - Referring to
Fig. 19 , the illustratedmagazine 150 of thestapler 101 includes theinner rails 152 that include swaged outend portions 173. The swaged outend portions 173 providesupport surfaces 174 that stabilize or support the back of the staple when the staple is driven. Thesupport surface 174 can be particularly beneficial for high speed and high sheet capacity staple driving applications. - Referring to
Fig. 15 , themagazine 150 further includes aboss 175 formed inside of theinner rails 152. Thestaple pusher 148, which is biased toward thedriver blade 127, contacts theboss 175 when there are no staples remaining in the magazine in order to prevent thestaple pusher 148 from being located directly underneath thedriver blade 127. Therefore, if the user pushes thecover 105 to eject or push out a staple when there are no staples in themagazine 150 without generally contacting thestaple pusher 148. While theboss 175 is an upstanding flange, in other constructions theboss 175 can be any suitable member, such as a protrusion formed on the inside of theinner rail 152. Such a construction is illustrated inFigs. 20 - 23 . - Operation of the
stapler 101 ofFigs. 15-19 is generally the same as thestapler 1 ofFigs. 1-11 . -
Figs. 20-22 illustrate yet another alternative arrangement of thestapler 1 ofFigs. 1 - 11 . Thestapler 201 ofFigs. 20 - 22 is similar to thestapler 1 ofFigs: 1-11 . Therefore, like components have been given like reference numbers in the two-hundred series, and only the general differences will be discussed below. - Referring to
Fig. 20 , the illustratedcover biasing member 214 of thestapler 201 is a torsion spring that contacts thecover 205 at a position closer to thefront end 206 of thestapler 201 than thecover biasing member 14 of thestapler 1 ofFigs. 1 - 11 . Increasing the distance from the point that thecover biasing member 214 contacts thecover 205 to the point about which the cover rotates increase the effective length of a lever created between the point that thecover biasing member 214 contacts thecover 205 to the point about which thecover 205 rotates. As understood by one of skill in the art, the longer lever reduces the spring force needed to raise thecover 205. - The
support member 230 of thestapler 201 is a cam that pivots or rotates about theaxis 264. The illustratedsupport member 230 includes aslider member 276 and a biasingmember 277 between thesupport member 230 and theslider member 276. The biasingmember 277 biases theslider member 276 toward thefront end 206 of thestapler 201. While the illustrated biasingmember 277 is a coil spring, it should be understood that the biasing member can be any suitable biasing member, such as other types of springs, an elastomer, and the like. - While not visible in
Fig. 20 , thestapler 201 includes a support member biasing member that biases thesupport member 230 about theaxis 264 in the direction indicated by anarrow 278a. The support biasing member can be a torsion spring or other suitable devices. - The
stapler 201 further includes a supportmember release mechanism 279. The illustrated supportmember release mechanism 279 includes arelease member 280 and anactivation member 281. The illustratedrelease member 280 includes anelongated portion 286 that extends through anaperture 282 formed in theframe 203 and anenlarged portion 288 formed on an end of theelongated portion 286. Theactivation member 281 is located between theframe 203 and theenlarged portion 288 of therelease member 280, and in the illustrated embodiment has a wedge-shaped configuration. A biasingmember 283, which is a coil spring in the illustrated construction, surrounds a portion of theelongated portion 286 of therelease member 280 and biases therelease member 280 toward thefront end 206 of thestapler 1, into engagement with thesupport member 230. - The illustrated
support member 230 includes a releasemember engagement portion 290. Theengagement portion 290 engages theelongated portion 286 of therelease member 280 to retain thesupport member 230 in the position illustrated inFig. 20 . While the releasemember engagement portion 290 of thesupport member 230 is a ledge portion of thesupport member 230, in other constructions theengagement portion 290 can be any suitable member, such as an aperture, surface, and the like. - The operation of the
stapler 201 is generally the same as the operation of thestapler 1, discussed above. Therefore, only the general differences in the operation will be discussed below. -
Fig. 20 illustrates thestapler 201 in the starting or original position when thestapler 201 is not being used. As discussed above with regard toFigs. 5a - 5c , as the user pushes down on thecover 205, theengagement portion 222 of theelastic member 220 moves forward or toward thefront end 206 of thestapler 201. Eventually theelastic member 220 will move far enough forward that theelastic member 220 disengages from thesupport surface 234 of thesupport member 230, or thetrigger mechanism 212, which is a cam in the illustrated construction, will activate the supportmember release mechanism 279 to release thesupport member 230 to ensure that the driver blade 229 andelastic member 230 will fall and drive a staple (Fig. 21 ). - Referring to
Fig. 21 , in the illustrated construction, whencover 205 is pushed down far enough thetrigger member 212 contacts theactivation member 281 of the supportmember release mechanism 279. As thecover 205 is pushed down even farther thetrigger member 212 pushes theactivation member 281 downward between theframe 203 and theenlarged portion 288 of therelease member 280 causing therelease member 280 to slide toward therear end 208 of thestapler 201. As illustrated inFig. 21 , when theelongated portion 286 of therelease member 280 moves rearward to a predetermined point, therelease member 280 is removed from contact with the engagement portion 290 (e.g., an aperture, surface, etc.) ofsupport member 230. With therelease member 280 no longer contacting thesupport member 230, thesupport member 230 is free to rotate about theaxis 264. The downward force of theelastic member 220 acting on theslider 276 of the support member 230 (Fig. 20 ) rotates thesupport member 230 about theaxis 264 in the direction indicated by thearrow 278b, thereby ensuring that theelastic member 220 and the driver blade 229 will fall and push a staple from themagazine 250. - As illustrated in
Fig. 21 , the illustratedstapler 201 is constructed such that aportion 284 of thedriver blade 227 extends from themagazine 250 after thedriver blade 227 has been lowered to drive a staple. While only thestapler 201 ofFigs. 20 - 22 has been shown with theportion 275 extending from themagazine 250 after thedriver blade 227 has been lowered, it should be understood that any of the staplers described herein can include such a feature. - As illustrated in
Fig. 22 , theslider 276 of thesupport member 230 facilitates returning theelastic member 220 to its starting or original position. As thecover biasing member 214 forces thecover 205 andelastic member 220 upward, thecover biasing member 214 overcomes the force of theslider biasing member 277 and theelastic member 230 forces theslider 276 to slide into thesupport member 230 along aslider axis 285. Thesupport member 230 is constructed such that theslider axis 285 is positioned at an angle α with respect to themagazine axis 253. In the illustrated construction, the angle α is approximately 20 degrees and in other constructions, the angle α can be any suitable angle. -
Fig. 23 illustrates an alternative construction of thestapler 201 ofFigs. 20 - 22 . Thestapler 301 ofFig. 23 is similar to thestapler 201 ofFigs. 20 - 22 . Therefore, like components have been given like reference numbers in the three hundred series, and only the general differences will be discussed below. - The
support member 330 of thestapler 301 omits theslider 276 of thestapler 201 ofFigs. 20 - 22 . Thesupport member 330 further includes aboss 387 that is coupled to thesupport member 330. Theboss 387 is positioned in aslot 389 that is formed in theframe 303. The ends of theslot 389 define the maximum rotational positions of thesupport member 330. The illustrated supportmember biasing member 340 is located around theboss 387 and biases thesupport member 330 in the direction indicated by thearrow 378 about theaxis 364. In other constructions, the supportmember biasing member 340 can be located at other suitable locations or in other suitable configurations. - The operation of the
stapler 301 is generally the same as the operation of thestapler 201 ofFigs. 20 - 22 with the exception that thestapler 301 omits theslider 276 of thestapler 201. -
Figs. 24-31 illustrate an alternative embodiment of the staplers ofFigs. 1- 23 . In the embodiment illustrated inFig. 24 , thestapler 420 is a manual desktop-type stapler. However, the invention can be practiced with substantially any type of stapler, including, but not limited to, manual hand-held or upright staplers, manual heavy-duty staplers, and all forms of electric staplers, including desktop-type, heavy-duty, and hand-held electric staplers. - The illustrated
stapler 420 includes a base 424 having afront end 428 and arear end 432. A bottom 43 6 of the base can be at least partially covered by a slipper or pad that helps stabilize and minimize sliding movement of thestapler 420 on a support surface (not shown). Should a user grasp thestapler 420 to perform the stapling operation as a hand-held stapler, the slipper also makes gripping thestapler 420 more comfortable to the user, as well as facilitates gripping of thestapler 420 by the user by preventing the user's hand from slipping along the surface of thestapler 420. The base 424 further includes atop surface 444 for receiving and supporting a stack of sheets to be stapled. Ananvil 448 is supported by thetop surface 444 for clinching staples driven through the stack of sheets. - A
magazine assembly 452 is pivotally connected to therear end 432 of the base 424 about apivot axis 456, as is understood in the art. Themagazine assembly 452 includes left and right side plates 453 (only oneside plate 453 illustrated inFig. 24 ) that are pivotally coupled to the base about thepivot axis 456, and astaple magazine 455 that is slidably connected to theside plates 453. Additional aspects of theside plates 453 will be discussed in detail below. - The
magazine 455 includes anose piece 460 that wraps around the front end of themagazine 455. While thenose piece 460 of the illustrated embodiment is a separate component from themagazine 455, thenose piece 460 could also be integrally formed as part of themagazine 455, and thereby still define anose piece 460 coupled to themagazine 455. Themagazine 455 has a length M. In one construction, the length M of the magazine ranges from about 140mm to about 146mm, and in other constructions, the length M of the magazine can be any suitable length. - Referring to
Figs. 24 and29 , acover 464 is also pivotally connected to the base 424 about thepivot axis 456, and is capable of pivoting both with themagazine 455 and with respect to themagazine 455 during stapling operations. Thecover 464 includes aninput portion 467 located an input length F from thepivot axis 456 of thecover 464. Theinput portion 467 is defined as the point of force input by the user into thecover 464. In one construction the input length F ranges from about 153mm to about 155mm, and in other constructions the input length F can be any suitable length. An output length G extends from thepivot axis 456 to the point at which the energy input to thecover 464 is input into the stapling mechanism, as will be discussed in detail below. In one construction the length G ranges from about 30mm to about 37mm, and in other constructions can be any suitable length. - Referring to
Fig. 24 , thecover 464 includes afront end 465 and arear end 466. Thecover 464 includes theinput portion 467 near thefront end 465 of thecover 464 for receiving manual force input into thestapler 420 by a user. Alever portion 470 is defined by thecover 464 between theinput portion 467 and thepivot axis 456. Thelever portion 470 has a length equal to the input length F. Because thecover 464 pivots about thesame pivot axis 456 as themagazine 455, the length of the lever portion 470 (i.e., the input length F) is maximized, thus maximizing the leverage available to the user. Maximizing the leverage by the user reduces the amount of force that must be input by the user to effectively operate thestapler 420. In the one embodiment, the ratio between input length F and the length M of themagazine 455 is between about 80% and 120%. Further aspects of the mechanical advantage of thestapler 420 will be described in detail below. - The
stapler 420 also includes adriver blade 468 coupled to adrive mechanism 472 to drive the staples out of thestapler 420 into the stack of sheets. The elements of thedrive mechanism 472 will be described in more detail below. The front surface of thedriver blade 468 defines a plane of movement in which thedriver blade 468 moves downwardly to drive staples out of thestapler 420. As thedriver 468 moves downwardly through themagazine 455 to drive out a staple, thedriver 468 is supported by thenose piece 460 and prevented from moving out of alignment with the staple to be driven. - As best illustrated in
Fig. 25 , astiffening plate 476 is coupled to the rear surface of thedriver 468 and includes a slot oraperture 480 therein for receiving a portion of thedrive mechanism 472, as will be discussed in detail below. In other constructions,aperture 480 can be omitted, and thedrive mechanism 472 can be coupled to thestiffening plate 476 ordriver blade 468 by welding, brazing, gluing, bonding, bolting, and the like. Thestiffening plate 476 can be coupled to thedriver blade 468 via a rivet, embossment, welding, gluing, bolting, and the like. In other constructions, theplate 476 and thedriver blade 468 may be integrally formed as one piece. It is also understood that in other embodiments, no stiffening plate is used, and thus thedrive mechanism 472 interacts directly with thedriver 468. - With continued reference to
Fig. 25 , afront portion 492 of each side plate 453 (only oneside plate 453 is illustrated inFig. 25 ) wraps around the front surface of thedriver blade 468 and includesslots 500 therein that receive the edges of thedriver 468 to help guide thedriver 468 during the stapling action. Rear portions 508 of eachplate 453 enclose a portion of thedrive mechanism 472, and are coupled together along thepivot axis 456. Eachplate 453 also includes arib 510 that extends along at least a portion of the plate. - With reference to
Figs. 25 and29 , thestapler 420 includes amagazine release mechanism 520. Themagazine release mechanism 520 includes a pivotinglever 524 that is actuated by the user to release themagazine 455 such that themagazine 455 can be ejected out the front of thestapler 420 into a staple loading position. The illustratedpivoting lever 524 includes a generallyvertical surface 528 and a generallyhorizontal surface 532. - A biasing
member 536 is utilized to hold themagazine 455 in the locked position, as illustrated inFig. 29 . In the illustrated construction, the biasingmember 536 is a torsion spring that is coupled to the pivotinglever 524 to hold themagazine 455 in the locked position. In other constructions, any suitable mechanism or biasing member can be utilized to bias the pivotinglever 524 into the engaged or locked position. - While not illustrated, the
magazine 455 includes a staple pusher spring therein that functions to push or pull staples within themagazine 455 toward the front of themagazine 455 such that the forwardmost staple is in position to be driven out of thestapler 420 by thedriver blade 468. The forward bias of the staple pusher spring also functions to bias themagazine 455 toward the front of thestapler 420 such that when themagazine 455 is released, the staple pusher spring pushes themagazine 455 forward to facilitate ejecting themagazine 455 out of the front of thestapler 420 and into the staple loading position. - In one embodiment, the
release mechanism 520 also includes a braking spring (not illustrated). When themagazine 455 is released due to actuation of the pivotinglever 524, the force of the staple pusher spring ejects themagazine 455 out of the front of thestapler 420 as discussed above. The more the staple pusher spring is compressed, the greater the ejecting bias of the staple pusher spring. When there are no staples remaining in themagazine 455, the staple pusher spring force is at a minimum. The greater the number of staples remaining in themagazine 455, the greater the staple pusher spring compression and thus the greater the ejecting bias of the staple pusher spring. To maintain control of the ejection of themagazine 455 when the staple pusher spring is compressed, the braking spring is configured to interact with themagazine 455 to slow the ejection of themagazine 455 out of thestapler 420. - In one construction, the braking spring is coupled to the
magazine 455 such that the braking spring moves with themagazine 455. When themagazine 455 is released, the braking spring moves forward with the movement of themagazine 455 and engages therib 510 on theside plate 453. The engagement between the braking spring and therib 510 causes friction, slowing the forward movement of themagazine 455. The stiffness of the braking spring, and thus the amount of friction created during magazine ejection, should be optimized to ensure a controlled ejection of themagazine 455 when the staple pusher spring is highly compressed, but also ensuring that when themagazine 455 is empty (and thus the staple pusher spring is only lightly compressed), themagazine 455 can be drawn out of thestapler 420 by the user with little difficulty. While one braking spring configuration is described herein, it should be understood that other braking spring configurations are contemplated and would fall within the scope of the present invention. - Referring to
Figs. 24 and25 , themagazine 455 also includes au-shaped channel 548 therein that receives a lockingshaft 552 of themagazine release mechanism 520. The biasingmember 536 biases the lockingshaft 552 into thechannel 548 of themagazine 455 to lock themagazine 455 within thestapler 420. Thechannel 548 also includes arear cam surface 554. - To release the
magazine 455, the user pushes on thevertical surface 528 of the pivotinglever 524, either directly or via abutton 549 coupled with thecover 464, which causes thehorizontal surface 532 to rotate in the clockwise direction. The rotation lifts thelocking shaft 552 out of thechannel 548. Once the lockingshaft 552 exits thechannel 548, themagazine 455 unlocks and the bias of the staple pusher spring ejects themagazine 455 out of the front of thestapler 420, subject to the forces of the braking spring described above. In situations where themagazine 455 is empty upon disengagement of the lockingshaft 552 from thechannel 548, themagazine 455 may be only partially ejected from thestapler 420, and the user may need to manually move themagazine 455 into the final refilling position. - Once the user has refilled the
magazine 455 with staples, the user then pushes themagazine 455 back into thestapler 420 against the bias of the staple pusher spring. As themagazine 455 is pushed back into thestapler 420, the lockingshaft 552 engages therear cam surface 554 of themagazine 455 and cams against the surface until the lockingshaft 552 travels over therear cam surface 554 and falls back into thechannel 548 to hold themagazine 455 in the locked position. - As best shown in
Figs. 26 and27 , thedrive mechanism 472 includes adrive linkage 556 that includes adrive link 560, aspring link 561, and anover-center linkage 562 having atrip link 564 and apivot link 566. - The
drive link 560 includes afront end 572 that engages theaperture 480 in thestiffening plate 476 that is coupled to thedriver blade 468, and arear end 576. Thefront end 572 continuously engages theaperture 480 during all stages of stapling operations. In one construction, therear end 576 is somewhat wedge-shaped in configuration. Thedrive link 560 pivots about apivot point 580. The geometry of thedrive link 560 is configured to take advantage of residual energy within thedrive mechanism 472 after the stapling operation to return thestapler 420 to the rest position, as will be discussed in more detail below. Thedrive link 560 includes an input portion having a length H. In one construction the length H ranges from about 29mm to about 33mm, and in other constructions can be any suitable length. Thedrive link 560 further includes an output portion having a length I that is approximately 27mm in one construction, and can be any suitable length in other constructions. The input portion H is the portion of thedrive link 560 between therear end 576 that receives energy to thepivot point 580, and the output portion I is the portion of thedrive link 560 between thepivot point 580 and thefront end 572 that directs energy into thedriver blade 468. - The trip link 564 of the
over-center linkage 562 is pivotably coupled to thepivot link 566 of theover-center linkage 562. The trip link 564 is biased by atorsion spring 592 into an over-center position. The trip link 564 is configured to cooperate with thecover 464 of thestapler 420 to trigger stapling operation, as will be discussed in detail below. Thepivot link 566 is coupled to thedrive link 560 via ashaft 600. The trip link 564 pivots with respect to thepivot link 566 about apivot shaft 604. The trip link 564 is supported between theside plates 453 on shaft 606 (Fig. 25 ). Thespring 592 is positioned about theshaft 606. As best illustrated inFig. 26 , in the over-center position, thepivots shafts over-center linkage 562 are generally aligned, the function of which will be described below. - Referring to
Figs. 25 - 27 , thespring link 561 includes acam end 608 that engages therear end 576 of thedrive link 560, and arear end 612. Thecam end 608 includes an integral cam surface orcam member 614. It should be understood that while thecam member 614 of the illustrated embodiment is an integrally formed and fixed cam member, movable cam members, such as a roller, can be used and still fall within the scope of the present invention. Thespring link 561 includes an input portion having a length J that ranges from about 23mm to about 32mm in one construction, and an output portion having a length K of approximately 36mm in one construction. In other constructions, the lengths J and K can be any suitable length. The input portion of thespring link 561 is the portion between therear end 612 and ashaft 624 about which thespring link 561 pivots that receives energy from thecover 464, and the output portion is the portion between theshaft 624 and thecam end 608 that transmits energy to thedrive link 560. - The
rear end 612 of thespring link 561 includes cam surfaces 625 and 626, the function of which will be described in detail below. While the illustratedspring link 561 is formed from a single piece, in other constructions, thespring link 561 can be formed of multiple part halves that are fastened together via rivets, bonding, gluing, welding, etc. Thespring link 561 pivots about theshaft 624 supported by therear portions 504 of theside plates 453. - The
drive mechanism 472 also includes an elastic member or energy storage device, shown in the illustrated embodiments as dual torsion springs 628, housed between therear portions 504 of theside plates 453. It should be understood that while two torsion springs 628 are shown in the illustrated embodiments, a single torsion spring could also be used and would fall within the scope of the present invention. - Each of the torsion springs 628 includes a
first end 632 and asecond end 636. The first ends 632 contact the underside of therear end 576 of thedrive link 560, biasing therear end 576 upwardly. The second ends 636 rest on top of thecam end 608 of thespring link 561, biasing thecam member 614 into contact with therear end 576 of thedrive link 560. Neither theends springs 628 are fixed, with the second ends 636 being charged during a first portion of the stapling operations (i.e., a first stapler condition), and with the first ends 632 releasing energy into thedrive mechanism 472 during a second portion of the stapling operations (i.e., a second stapler condition). - It should be understood that
Figs. 25 - 26 illustrate thesprings 628 in a preloaded position. In the preloaded position, some energy is stored in thesprings 628 at all times. - Referring to
Figs. 24 ,26 , and27 , thecover 464 of thestapler 420 includes anactivation member 644. The illustratedactivation member 644 is supported by achassis 645 that supports aroller 647. Thechassis 645 is coupled to the inside of thecover 464. While the illustratedactivation member 644 is support by thechassis 645, in other constructions the activation member could be integrally formed with the cover, or could be the inside surface of thecover 464 itself. Theactivation member 644 is configured to cooperate with therear end 612 of thespring link 561 during the stapling operation. Theactivation member 644 engages thespring link 561 to allow the user to lift thecover 464 in order to manually reset the stapler, discussed in more detail below. While the illustrated activation member is a pin, in other constructions the activation member can be a substantially hook shaped member that depends downwardly from the inside surface of thecover 464. In yet other constructions, the activation member can be any suitable member, such as a post coupled to the spring link that moves within a slot. -
Figs. 29-31 illustrate thestapler 420 during various phases of the stapling operation and illustrate the method of operating thedrive mechanism 472 described above. -
Fig. 29 illustrates thestapler 420 in the rest position. Thedriver 468 remains above the magazine 455 (i.e., in the up position) when the stapler is at rest due to the over-center arrangement of theover-center linkage 562, which in the illustrated construction includes thetrip link 564 and thepivot link 566. This allows themagazine 455 to be ejected out of the front of thestapler 420 if the user wishes to place additional staples within themagazine 455. The torsion springs 628 are in the preloaded position within thestapler 420. The first ends 632 of thesprings 628 bias therear end 576 of thedrive link 560 upwardly into thecam end 608 of thespring link 561. Likewise, the second ends 636 of thesprings 628 biases thecam end 608 into therear end 576 of thedrive link 560 such that thecam member 614 cams against therear end 576 of thedrive link 560. Thecam surface 626 on therear end 612 of thespring link 561 is in contact with theroller 647 coupled to thecover 464 via thechassis 645. The trip link 564 of theover-center linkage 562 is biased into the over-center position by thetorsion spring 592 maintaining thepivot link 566 in its over-center position as well. Thecover 464 is in the extended position when thestapler 420 is in the rest position. - In the rest position, the
cover 464 defines a vertical distance W between the top of thefront end 465 and thetop surface 444 of the base. In one construction, the vertical distance W ranges from about 73mm to about 87mm, and in other constructions can be any suitable distance. Thedriver 468 defines a vertical distance X between the top of theplate 453 and the midpoint of thefront end 572 of thedrive link 560. In one construction, the vertical distance X ranges from about 10mm to about 13mm, and in other constructions can be any suitable distance. - As the user inputs manual force into the
stapler 420 by pressing on theinput portion 467 of thecover 464, thecover 464 and themagazine 455 pivot downwardly with respect to the base 424 such that thecover 464 moves from the extended position toward the depressed position. Inputting force into thestapler 420 charges the stapler, resulting in the first, charged stapler condition. As thecover 464 pivots, theroller 647 coupled to thecover 464 near therear end 612 of thespring link 561 rolls along the cam orsupport surface 626 of thespring link 561, causing thefront end 608 of thespring link 561 to pivot upwardly against the bias of the second ends 636 of the torsion springs 628, charging thesprings 628. The movement of thespring link 561 causes the torsion springs 628 to fully deflect, storing more potential energy within thesprings 628. Therear end 576 of thedrive link 560 remains in the rest position due to the over-center bias of thetrip link 564 overcoming the upward bias of the first ends 632 of thesprings 628 and the alignment of thepivot shafts over-center linkage 562. -
Fig. 30 illustrates thestapler 420 after the manual force inputted by the user has caused thecover 464 to pivot toward the trip link 564 of theover-center linkage 562. At the point ofdriver 468 release, a tab orprotrusion 597 integrally formed on the inside surface of thecover 464 will contact with anouter end 648 of thetrip link 564. As illustrated inFig. 30 , thedrive link 560 and thetrip link 564 have not yet moved from the rest position and thepivot shafts over-center linkage 562 remain aligned. Of course theprotrusion 597 could be a separate part coupled to the cover, trip link, or the cover could be configured such that no protrusion is necessary. - Referring to
Fig. 31 , the interaction between thecover 464 and theouter end 648 of thetrip link 564 moves thetrip link 564 with respect to thepivot link 566 to move thepivot shaft 604 out of the over-center position (i.e., out of alignment with thepivot shafts 600 and 606), overcoming the bias of thetorsion spring 592. As the trip link 564 snaps out of the over-center position thepivot shafts over-center linkage 562 are no longer aligned and there is no longer any force opposing the upward bias of the first ends 632 of thesprings 628 on therear end 576 of thedrive link 560. This allows thesprings 628 to snap back to the preload position, releasing the charged energy within thesprings 628 into thedrive linkage 556 through the first ends 632 of thespring 628 forcing therear end 576 of thedrive link 560 upwardly, which in turn drives thefront end 572 of thedrive link 560 downwardly. This is the second, released stapler condition. - Because the
front end 572 of thedrive link 560 is continuously engaged with thedriver 468 via theaperture 480 in thestiffening plate 476, the release of potential energy from thespring 628 drives thedriver 468 downwardly through a driver stroke, causing thedriver 468 to drive a staple within themagazine 455 out of the stapler 420 (in the stapling direction) and into a waiting stack of sheets. As mentioned above, the triggering mechanism of the stapler 420 (e.g., theover-center linkage 562 in the illustrated embodiment) does not directly engage and hold thedriver blade 468, thereby eliminating many of the triggering mechanism and locking mechanism problems associated with prior art staplers. - Moving from
Fig. 30 to Fig. 31 , thecover 464 moves into the depressed position as the stapler is in the stapling position. In the stapling position, thecover 464 defines a vertical distance Y between the top of thefront end 465 and thetop surface 444 of thebase 424, and thedriver 468 defines a vertical distance Z between the top of theplate 453 and the midpoint of thefront end 572 of thedrive link 560. In one construction, the vertical distance Y ranges from about 53mm to about 57mm, and the vertical distance Z ranges from about 19mm to about 25mm. In other constructions the vertical distances Y and Z can be any suitable length. - Referring to
Figs. 29 and31 , during the stapling operation, thedriver 468 moves vertically through the driver stroke. The driver stroke represents the vertical movement of thedriver 468 upon actuation by thedrive linkage 556, and has a length calculated by subtracting the vertical distances of thedriver 468 identified above (i.e., Z-X). At the point of release of thedriver 468, no additional manual force input from the user is required to perform the stapling operation, and any additional manual force directed into thecover 464 will not be translated to thedriver 468 as there is no contact between thecover 464 and thedriver 468 once thedriver 468 is released. Thus, thestapler 420 achieves full power and is fully automated for as many sheets as can be received by thestapler 420. - The downward force of the
driver 468 also assists in the clinching of the staple legs as the staple legs pass through the stack of sheets into theanvil 448. Similar to thestapler 201 ofFig. 21 , and as illustrated inFig. 31 , a bottom portion of thedriver 468 extends through and out of themagazine 455 after the staple has been driven. Thedriver 468 is not mechanically stopped during the stapling operation such that the continued movement of thedriver 468 through the bottom of themagazine 455 imparts additional force to the staple as the staple enters the stack of sheets and is clinched. The continued movement of thedriver 468 and the residual force remaining in thedrive mechanism 472 after stapling due to the preloading of thesprings 628 help to complete the staple clinch and returns thestapler 420 to the rest position, as will be described in more detail below. - Referring to
Figs. 29 - 31 , the total vertical movement in the stapling direction of thefront end 465 of thecover 464 as compared with the total vertical movement of thedriver 468 during the driver stroke represents the mechanical advantage realized in thestapler 420. The total vertical movement of thefront end 465 of the cover 464 (i.e., a first vertical distance) can be calculated by taking the vertical distance W in the stapler rest position minus the vertical distance Y in the stapling position. In one construction of the stapler, the first vertical distance ranges from about 16mm to about 34mm. Similarly, the total vertical movement of thedriver 468 during the driver stroke (i.e., a second vertical distance) is calculated as described above, subtracting X from Z. In one construction, the second vertical distance ranges from about 9mm to about 12mm. In one embodiment, the mechanical advantage of thestapler 420 ranges from about 1.8:1 to about 4:1. In other embodiments, the mechanical advantage ranges from about 3:1 to about 8:1. The greater the vertical distance traveled by thecover 464 with respect to the distance traveled by thedriver 468 during the driver stroke, the greater the mechanical advantage in the stapler. - Referring to
Figs. 24 ,26 , and29 another method of determining or quantifying the mechanical advantage of the stapler is to calculate the mechanical advantage through the input and output lengths of thecover 464 and thedrive linkage 556. With respect to the calculation of mechanical advantage in thestapler 420, thecover 464 acts as a link in thedrive linkage 556. - Some amount of mechanical advantage is generated by the geometry of the
cover 464, the geometry of thedrive link 560, and the geometry of thespring link 561. The mechanical advantage in thedrive link 560 is calculated by dividing the input length H of thedrive link 560 by theoutput length 1. Thus, in one construction, the mechanical advantage of thedrive link 560 ranges from about 2.8 to about 5.4. In the illustrated embodiment, the mechanical advantage in the drive link is equal to 33mm/27mm (H/I), or approximately 1.2. Similarly, the mechanical advantage of thespring link 561, in one construction is 32mm/36mm (J/K), or approximately 0.88. The mechanical advantage of thecover 464 is equal to the input length F of thecover 464 divided by the output length G. In one construction, the mechanical advantage of thecover 464 is 153mzn130rnm (F/G), or approximately 5.1. - To calculate the total mechanical advantage from the examples above for the
stapler 420, the mechanical advantage of thecover 464 is multiplied by the mechanical advantage of thedrive link 560 and the mechanical advantage of thespring link 561. Therefore, using the construction described above, thestapler 420 has a mechanical advantage of 1.2*0.88*5.1, or approximately 5.4. Using this formula, changing the geometry of any of thecover 464, thedrive link 560, or thespring link 561, such as changing the length of the input and/or output portions, would directly affect the mechanical advantage of the stapler. - The method described above results in a
stapler 420 with improved stapling function requiring less force input by the user due to the use of the potential energy that naturally builds within thedrive mechanism 472 to drive the staples out of thestapler 420. The configuration of thecover 464 and thedrive linkage 556 increases the leverage available to the user such that the amount of force needed from the user to deflect the torsion springs 628 and store energy in thesprings 628 is reduced, as discussed in detail above. - Because the torsion springs 628 are preloaded, a residual amount of potential energy remains in the
drive mechanism 472 at all times such that even after staple driving, the residual potential energy can assist with completing the staple clinch and returning thestapler 420 to the rest position, due in part to the geometry of thedrive link 560. The geometry of theover-center linkage 562, which includes thetrip link 564 and thepivot link 566, (i.e., the over-center arrangement) maintains thedriver 468 above themagazine 455 in the stapler rest position to allow for front loading of the staples. - When there is no staple jam, the
drive linkage 556 will naturally want to reset itself due to the residual energy in thesprings 628. Prior art staplers required a user to manually reset the stapler to rest, or utilized an additional spring for the express purpose of resetting the stapler to rest. The geometry of thedrive mechanism 472, including thedrive linkage 556, of thestapler 420 automatically resets thestapler 420 to the rest position. The shape of therear end 576 of thedrive link 560 and thecam end 614 of thespring link 561 maintain a large gap (i.e., the difference in height) between the first and second ends 432, 436 of thesprings 628. The gap imparts additional potential energy into thesprings 628. The gap naturally tends toward closure to release energy built up within thesprings 628. This tendency to close lifts up on therear end 576 of thedrive link 560, and pushes downwardly on thecam end 608 of thespring link 561 such that theroller 647 engages thecam surface 626 of the of therear end 612 of thespring link 561. All of this movement described above works to automatically reset thestapler 420 to the rest position after a staple is driven out of thestapler 420. - Further, in a staple jam situation, the
drive mechanism 472 allows the user to manually lift thecover 464 to reset the stapler and thedrive mechanism 472 to the rest position. When thecover 464 is lifted, the actuation member or pin 644 moves upwardly with thecover 464 and into engagement with thecam surface 625 on the bottom of thespring link 561. Continued upward movement of theactuation member 644 raises therear end 612 of thespring link 561 back to the position shown inFig. 29 , allow the rest of the linkages in thedrive mechanism 472 to reset to the rest position shown inFig. 29 . - It should be understood that the specific component measurements discussed above, such as the specific vertical distances, the link input lengths, the link output lengths, etc., are illustrative of a specific embodiment of a stapler according to the invention. It is understood that the lengths, measurements, and specific geometries of the components of the stapler described above can be adjusted or changed, and will still fall within the scope of the present invention.
- Various features of the invention can be found in the following claims.
When used in this specification and claims, the terms "comprises" and "comprising" and variations thereof mean that the specified features, steps or integers are included. The terms are not to be interpreted to exclude the presence of other features, steps or components.
The features disclosed in the foregoing description, or the following claims, or the accompanying drawings, expressed in their specific forms or in terms of a means for performing the disclosed function, or a method or process for attaining the disclosed result, as appropriate, may, separately, or in any combination of such features, be utilised for realising the invention in diverse forms thereof.
Claims (7)
- A stapler (420) movable between a rest position and a stapling position, the stapler (420) having a front end (428) adjacent a staple ejection location and a rear end (432), the stapler (420) comprising:a base (424);a staple magazine (455) coupled to the base (424) and configured to hold staples;a driver blade (468) operable to drive staples out of the staple magazine (455) during stapling operations; andan elastic member (628) coupled to the driver blade (468) and operable tomove the driver blade (468) during stapling operations, the elastic member (628) utilising potential energy to move the driver blade (468) during stapling operations;
characterized by an over-center linkage (562) having a trip link (564) which is pivotably coupled to a pivot link (566), the over-center linkage (562) being moveable between a first position in which the driver blade (468) is prevented from driving a staple out of the staple magazine (455), and a second position in which the driver blade (468) may drive a staple out of the staple magazine (455). - The stapler (420) of claim 1, further comprising:a drive link (560) coupled with the driver blade (468) and the elastic member (628), and having a pivot point (580) about which the drive link (560) pivots; andwherein the over-center linkage (562) is coupled with the drive link (560) such that, when the over-center linkage (562) is in the second position, the drive link (560) is allowed to pivot about the pivot point (580) to drive the driver blade (468).
- The stapler (420) of claim 1 or 2, wherein the over-center linkage (562) moves from the first position to the second position upon engagement with a cover (464) of the stapler (420).
- The stapler (420) of claim 1,
wherein the trip link (564) and pivot link (566) are pivotally connected about a first pivot (604), the pivot link (566) is pivotally connected to a drive link (560) about a second pivot (600), and the trip link (564) is pivotally supported between side plates (453) of the stapler (420) about a third pivot (562); and
wherein the first, second and third pivots (604,600,606) are generally aligned when the over-center linkage (562) is in the first position, and are not aligned when the over-center linkage (562) is in the second position - The stapler (420) of claim 1, wherein a spring (592) biases the over-center linkage (562) into the first position.
- The stapler (420) of claim 1, wherein the driver blade (468) is positioned above staples housed in the staple magazine (455) when the stapler (420) is in the rest position and the magazine (455) is extendible from the front end (428) of the stapler (420) to allow a user to load staples in the magazine (455).
- The stapler (420) of claim 1, further comprising a drive link (560) coupled with the driver blade (468) and the elastic member (628), and wherein the drive link (560) is in continuous engagement with the driver blade (468) during stapling operations.
Applications Claiming Priority (3)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP2005177441A JP4608375B2 (en) | 2005-06-17 | 2005-06-17 | Stapler |
US70522505P | 2005-08-03 | 2005-08-03 | |
EP06012294A EP1733848A1 (en) | 2005-06-17 | 2006-06-14 | Stapler |
Related Parent Applications (2)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
EP06012294.2 Division | 2006-06-14 | ||
EP06012294A Division EP1733848A1 (en) | 2005-06-17 | 2006-06-14 | Stapler |
Publications (3)
Publication Number | Publication Date |
---|---|
EP1944131A2 EP1944131A2 (en) | 2008-07-16 |
EP1944131A3 EP1944131A3 (en) | 2008-07-23 |
EP1944131B1 true EP1944131B1 (en) | 2010-10-27 |
Family
ID=37020662
Family Applications (2)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
EP06012294A Withdrawn EP1733848A1 (en) | 2005-06-17 | 2006-06-14 | Stapler |
EP08103713A Active EP1944131B1 (en) | 2005-06-17 | 2006-06-14 | Stapler |
Family Applications Before (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
EP06012294A Withdrawn EP1733848A1 (en) | 2005-06-17 | 2006-06-14 | Stapler |
Country Status (4)
Country | Link |
---|---|
EP (2) | EP1733848A1 (en) |
AT (1) | ATE485922T1 (en) |
AU (1) | AU2006202591A1 (en) |
CA (1) | CA2550386A1 (en) |
Families Citing this family (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
FR2925381B1 (en) * | 2007-12-19 | 2010-09-24 | Maped | PUNCH TOOL SUCH AS STAGPER WITH STRESS DEMULTIPLICATION |
US9415494B2 (en) * | 2013-03-15 | 2016-08-16 | Arrow Fastener Co., Llc | Fastening tool assembly |
US11524397B2 (en) | 2020-02-05 | 2022-12-13 | Worklife Brands Llc | Stapler with moveable strike plate and integrated accessibility features |
Family Cites Families (11)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
GB540611A (en) * | 1939-07-22 | 1941-10-23 | Belle Linsky | Improvements in or relating to tackers |
SE456660B (en) * | 1987-03-03 | 1988-10-24 | Isaberg Ab | DEVICE FOR A TOOL FOR THE RECOVERY OF A MIXTURE, EXAMPLE OF A staple, IN A PURPOSE |
GB2229129A (en) * | 1989-03-15 | 1990-09-19 | Ted Szu Chang | Hand-operated stapler |
US5356063A (en) * | 1990-12-05 | 1994-10-18 | Erwin Muller GmbH Co. | Hand-operated stapler |
US5315448A (en) | 1993-03-18 | 1994-05-24 | Macrovision Corporation | Copy protection for hybrid digital video tape recording and unprotected source material |
US5497932A (en) * | 1994-08-12 | 1996-03-12 | Emhart Inc. | Manually operated fastening device |
SE9501965L (en) * | 1995-05-30 | 1996-05-13 | Isaberg Ab | Hand tools with a frame, a handle means pivotally mounted thereon and a working member movable relative to the body between an initial position and a turning position |
US6145728A (en) * | 1999-04-26 | 2000-11-14 | Worktools, Inc. | Compact simplified staple gun mechanism |
US6918525B2 (en) * | 2003-05-23 | 2005-07-19 | Worktools, Inc. | Spring energized desktop stapler |
JP2005177441A (en) | 2003-11-26 | 2005-07-07 | Neoshisu:Kk | Suitable temperature cart for meal serving |
US7681771B2 (en) | 2005-06-17 | 2010-03-23 | Acco Brands Usa Llc | Stapler |
-
2006
- 2006-06-14 EP EP06012294A patent/EP1733848A1/en not_active Withdrawn
- 2006-06-14 EP EP08103713A patent/EP1944131B1/en active Active
- 2006-06-14 AT AT08103713T patent/ATE485922T1/en not_active IP Right Cessation
- 2006-06-16 AU AU2006202591A patent/AU2006202591A1/en not_active Abandoned
- 2006-06-16 CA CA002550386A patent/CA2550386A1/en not_active Abandoned
Also Published As
Publication number | Publication date |
---|---|
EP1944131A2 (en) | 2008-07-16 |
EP1733848A1 (en) | 2006-12-20 |
ATE485922T1 (en) | 2010-11-15 |
EP1944131A3 (en) | 2008-07-23 |
CA2550386A1 (en) | 2006-12-17 |
AU2006202591A1 (en) | 2007-01-11 |
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