The present disclosure relates to powered-fastener-driving tools. Generally, powered-fastener-driving tools use one of several types of power sources to carry out a fastener-driving cycle to drive a fastener (such as a nail or a staple) into a workpiece. More specifically, a powered-fastener-driving tool uses a power source to force a driving assembly, such as a piston carrying a driving element including a driver blade, through a cylinder from a pre-firing position to a firing position. As the driving assembly moves to the firing position, the driver blade travels through a nosepiece, which guides the driver blade to contact a fastener housed in the nosepiece. Continued movement of the driving assembly through the cylinder toward the firing position forces the driver blade to drive the fastener from the nosepiece into the workpiece. The driving assembly is then forced back to the pre-firing position in a way that depends on the tool's construction and power source. A fastener-advancing device forces another fastener from a magazine into the nosepiece, and the tool is ready to fire again.
Pneumatic-powered-fastener-driving tools use a compressed air power source. To operate a typical pneumatic-powered-fastener-driving tool, an operator depresses a workpiece-contact element of the tool onto a workpiece to move the workpiece-contact element from an extended position to a retracted position and then pulls the trigger to actuate a control valve and start the fastener-driving cycle. Actuation of the control valve causes compressed air to act on the top of the piston and force the driving assembly to move through the cylinder from the pre-firing position to the firing position, thereby causing the driver blade to contact a fastener housed in the nosepiece and drive the fastener from the nosepiece into the workpiece.
As the driving assembly moves toward the firing position, the piston drives air inside the cylinder through several vents defined in the cylinder into a return chamber, thereby increasing the air pressure in the return chamber. As the driving assembly reaches the firing position, the volume above the piston is exposed to atmosphere, and the compressed air stops acting on the top of the piston. After the driving assembly reaches the firing position, the air in the return chamber reenters the cylinder through the vents and pushes on the bottom of the piston to force the driving assembly back to its pre-firing position. The piston forces any air above it out of the tool to atmosphere while the driving assembly returns to the pre-firing position. This completes the fastener-driving cycle.
Combustion-powered-fastener-driving tools use a small internal combustion assembly as their power source. To operate a typical combustion-powered-fastener-driving tool, an operator depresses a workpiece-contact element of the tool onto a workpiece. This moves the workpiece-contact element from an extended position to a retracted position, which causes one or more mechanical linkages to cause: (1) a valve sleeve to move to a sealed position to seal a combustion chamber that is in fluid communication with the cylinder; and (2) a fuel delivery system to dispense fuel from a fuel canister into the (now sealed) combustion chamber.
The operator then pulls the trigger to actuate a trigger switch, thereby causing a spark plug to deliver a spark and ignite the fuel/air mixture in the combustion chamber and start the fastener-driving cycle. This generates high-pressure combustion gases that expand and act on the piston to force the driving assembly to move through the cylinder from the pre-firing position to the firing position, thereby causing the driver blade to contact a fastener housed in the nosepiece and drive the fastener from the nosepiece into the workpiece.
Just before the driving assembly reaches the firing position, the piston passes exhaust check valves defined through the cylinder, and some of the combustion gases that propel the cylinder exhaust through the check valves to atmosphere. This combined with heat exchange to the atmosphere and the fact that the combustion chamber remains sealed during the fastener-driving cycle generates a vacuum pressure above the piston, which causes the driving assembly to retract to the pre-firing position to complete the fastener-driving cycle. When the operator removes the workpiece-contact element from the workpiece, a spring biases the workpiece-contact element from the retracted position to the extended position, causing the one or more mechanical linkages to move the valve sleeve to an unsealed position to unseal the combustion chamber.
Some known or proposed combustion-powered-fastener-driving tools also include a return chamber similar to that of a pneumatic-powered-fastener-driving tool to help the piston return to the pre-firing position.
As explained below with respect to
The driver blade 106 has a longitudinal axis APA and a length LPA. Moving from the flange 104 to the free end 106a along the longitudinal axis APA, the driver blade: (1) tapers toward the longitudinal axis APA to a width WPA1 along a distance DPA1; (2) maintains the width WPA1 along a distance DPA2; and (3) tapers toward the longitudinal axis APA to a width WPA3 along a distance DPA3. Although not shown, the transverse cross-section of the driver blade 106 (taken along a horizontal plane perpendicular to the longitudinal axis APA) along the distance DPA2 is generally rectangular shaped, and its size and shape do not change. Put differently, the transverse cross-section of the driver blade 106 is generally uniform along the distance DPA2.
When installed, the driver blade 106 is slidably received in the driver blade receiving opening 190a of the driver blade seal 190. The driver blade 106 and the driver blade seal 190 are positioned such that some part of the driver blade 106 along the distance DPA2 always occupies a portion of the driver blade receiving opening 190a when the driving assembly is in the firing position, the pre-firing position, or anywhere in between. Since the transverse cross-section of the driver blade 106 along the distance DPA2 is uniform, the driver blade 106 always occupies the same portion of the driver blade receiving opening 190a regardless of the position of the piston 24.
If the air pressure in the return chamber is excessively high when the driving assembly reaches the firing position, the piston will impact the top of the cylinder with excessive force when the driving assembly reaches the pre-firing position. This could damage the piston, the cylinder, or other tool components, especially with repeated use. Also, if the piston impacts the top of the cylinder with too much force, it could bounce off of the cylinder and cause the driving assembly to end up between the pre-firing and the firing position upon completion of the fastener-driving cycle. Improper positioning of the driving assembly could result in a misfire the next time the operator tries to drive a fastener.
There is a need for a powered-fastener-driving tool that solves these problems.
Various embodiments of the present disclosure provide a powered-fastener-driving tool including driver blade that has a varying cross-section that solves the above problems.
In one embodiment, the powered-fastener-driving tool includes a cylinder, a return chamber in fluid communication with the cylinder, a driver blade seal that defines a driver blade receiving opening, a driving element including a driver blade, and a piston within and movable relative to the cylinder and the driver blade seal. The piston is attached to the driving element such that the driver blade is slidably received in the driver blade receiving opening. To drive a fastener, the piston is driven to move from a pre-firing position to a firing position. This movement forces air beneath the piston from the cylinder into the return chamber. Once the piston reaches the firing position and the air pressure in the return chamber has reached its maximum, the pressurized air flows from the return chamber back into the cylinder to force the piston from the firing position back to the pre-firing position.
The non-uniform cross-section of the driver blade is sized and shaped such that a portion of the driver blade receiving opening occupied by the driver blade changes as the piston moves between a pre-firing position and a firing position. This solves the above problems by reducing the impact force of the piston on the upper end of the cylinder when returning to the pre-firing position as compared to an identical prior art tool with a uniform cross-section driver blade. Specifically, since more air can leak through the driver blade receiving opening as the piston moves from the pre-firing position to the firing position, the return chamber is less pressurized following fastener driving than the return chamber of the prior art tool. This combined with the fact that more air can leak through the driver blade receiving opening as the piston moves from the firing position to the pre-firing position results in less force acting on the piston to return it to the pre-firing position as compared to the prior art tool. The varying cross-section of the driver blade thus precisely controls the amount of air leakage through the driver blade seal to achieve a desired piston return.
Other objects, features, and advantages of the present disclosure will be apparent from the detailed description and the drawings.
Various embodiments of the present disclosure provide a powered-fastener-driving tool including driver blade that has a varying cross-section.
As best shown in
One or more, and in this illustrated embodiment multiple, circumferentially spaced return ports 56 are defined through the cylinder 14 near an upper edge 58 of the bumper 20. The quantity and location of the return ports 56 may vary. The portion of this example cylinder 14 that extends between the upper end 18 and the return ports 56 does not define any openings therethrough. But in other embodiments, the portion of the cylinder that extends between the upper end and the return ports defines one or more openings therethrough.
The driving assembly 16 includes a piston 24 threadably engaged to a driving element 200. The piston 24 has an upper surface 76, an underside 54, and an outer cylindrical surface (not labeled). A sealing element (such as an o-ring) is attached to the outer surface and sealingly engages the inner cylindrical surface of the cylinder 14 to prevent the volume of the cylinder 14 below the piston 24 from fluidly communicating with the volume of the cylinder 14 above the piston 24.
As best shown in
The driver blade 206 has a longitudinal axis AA and a length LA. Moving from the flange 204 to the free end 206a along the longitudinal axis AA, the driver blade 206: (1) tapers toward the longitudinal axis AA to a width WA1 along a distance DA1; (2) maintains the width WA1 along a distance DA2; (3) tapers toward the longitudinal axis AA to a width WA2 along a distance DA3; (4) maintains the width WA2 along a distance DA4; (5) tapers away from the longitudinal axis AA to a width WA3 along a distance DA5; (6) maintains the width WA3 along a distance DA6; and (7) tapers toward the longitudinal axis AA to a width WA4 along a distance DA7.
Although not shown, the transverse cross-section of the driver blade 206 (taken along a horizontal plane perpendicular to the longitudinal axis AA): (1) along the distance DA2 is generally rectangular shaped, and its size and shape do not change; (2) along the distance DA4 is generally rectangular shaped, and its size and shape do not change; and (3) along the distance DA6 is generally rectangular shaped, and its size and shape do not change. Put differently, the transverse cross-section of the driver blade 206 is generally uniform along the distance DA2, along the distance DA4, and along the distance DA6. The transverse cross-section of the driver blade 206 along the distance DA2 and the transverse cross-section of the driver blade 206 along the distance DA4 are different. The transverse cross-section of the driver blade 206 along the distance DA4 and the transverse cross-section of the driver blade 206 along the distance DA6 are different. The transverse cross-section of the driver blade 206 along the distance DA2 and the transverse cross-section of the driver blade 206 along the distance DA6 may be the same or different.
The driving assembly 16 is movable within and relative to the cylinder 14 between a pre-firing position (
When installed, the driver blade 206 is slidably received in the driver blade receiving opening 90a of the driver blade seal 90. The driver blade 206 and the driver blade seal 90 are positioned such that: (1) when the driving assembly 16 is in the pre-firing position (
Since the transverse cross-section of the driver blade 206 differs along the distances DA2, DA3, and DA4, the driver blade 206 occupies different portions of the driver blade receiving opening 90a (depending on the position of the driving assembly 16) throughout the fastener-driving cycle. Put differently, the unoccupied portion of the driver blade receiving opening 90a varies throughout the fastener-driving cycle. This means that the amount of air that can escape the cylinder 14 during the fastener-driving cycle through the portion of the driver blade receiving opening 90a unoccupied by the driver blade 206 changes as the driving assembly 16 moves, as described below with respect to
The following components of the tool 10 collectively define a combustion chamber: the cylinder head 44, the combustion chamber housing 30 that includes a generally cylindrical outer wall 32 and a floor 34, and the upper surface 76 of the piston 24 (when the driving assembly 16 is in the pre-firing position). This is merely one example combustion chamber, and in other embodiments the combustion chamber may be differently shaped and/or sized and may be defined by any suitable components.
The combustion chamber is in fluid communication with the cylinder 14 via an opening 36 defined through the combustion chamber housing 30 and an opening defined in the upper end 18 of the cylinder 14. Unlike in conventional combustion-powered-fastener-driving tools, the outer wall 32 of the combustion chamber housing 30 is fixed relative to the cylinder 14 during the entire fastener-driving cycle.
As best shown in
One or more, and in this embodiment multiple, biasing elements 42 (such as springs) bias the valve element 40 to the open position. In this embodiment, to move the valve element 40 to the closed position, an operator depresses the nosepiece 28 of the tool 10—and more particularly a workpiece contact element (not shown) at the end of the nosepiece 28 as is known in the art—against a workpiece with enough force to cause a linkage (not shown) that connects the nosepiece 28 to the valve element 40 to impose a force on the valve element 40 that overcomes the collective biasing force of the biasing elements 42. This causes the valve 40 to move relative to the outer wall 32 and toward the cylinder head 44 to the closed position, thereby sealing the combustion chamber by blocking the ports 38.
Although not shown, as is known in the art, depressing the nosepiece 28 of the tool against the workpiece also causes, such as via actuation of one or more mechanical or electromechanical switches: (1) a fuel canister (not shown) to dispense fuel into the combustion chamber via a fuel delivery system (not shown); and (2) a motor 50 attached to the cylinder head 44 to drive a fan blade 48 at least partially disposed within the combustion chamber for a designated period of time that spans the fastener-driving cycle and enables enhanced mixing of air and fuel within the combustion chamber before ignition and also facilitates exchanging combustion gases for fresh air after ignition.
As best shown in
In operation, after ignition of the fuel/air mixture in the combustion chamber and movement of the driving assembly 16 to the firing position, the driving assembly 16 returns to the pre-firing position through action of pressurized air stored in the return chamber 52 simultaneously with exhaustion of the combustion gases from the combustion chamber. Specifically, as the driving assembly 16 moves relative to the cylinder 14 from the pre-firing position to the firing position under the force generated by ignition of the fuel/air mixture in the combustion chamber, the piston 24 compresses and forces the air below the underside 54 of the piston 24 through the return ports 56 and into the return chamber 52.
Once the driving assembly 16 reaches the firing position, recoil forces created by the action of driving a fastener cause the nosepiece 28 of the tool 10, which an operator is holding, to disengage the workpiece. This movement removes the forces opposing the collective biasing force of the biasing elements 42, which causes the biasing elements 42 to move the valve element 40 to the open position. This unseals the combustion chamber and fluidically connects it to atmosphere outside tool 10 (via the ports 38 and 70), enabling the combustion gases to exhaust from the combustion chamber and fresh air to enter the combustion chamber. This is contrary to conventional combustion-powered-fastener-driving tools in which the combustion chamber must remain closed until the piston returns to the pre-firing position to ensure that the differential pressure required to return the piston to the pre-firing position is maintained.
After the driving assembly 16 reaches the firing position and contacts the bumper 20, the air pressure in the return chamber 52 is greater than the air pressure in the cylinder 14. This causes the pressurized air in the return chamber 52 to flow back through the return ports 56 into the cylinder 14. Some of that air acts on the underside 54 of the piston 24 to force the driving assembly 16 back to the pre-firing position while the remainder escapes through the unoccupied portion of the driver blade receiving opening 90a to atmosphere.
So as the driving assembly 16 moves from the pre-firing position to the firing position, the driver blade 206 switches from occupying the first, smaller portion of the driver blade receiving opening 90a along the distance DA2 to the second, larger portion of the driver blade receiving opening 90a along the distance DA4. Since the first portion is smaller than the second portion, more air escapes to atmosphere through the unoccupied portion of the driver blade receiving opening 90a when the driver blade 206 occupies the first portion of the driver blade receiving opening 90a than when the driver blade 206 occupies the second portion of the driver blade receiving opening 90a.
Additionally, the varying cross-section of the driver blade 206 results in a lower maximum air pressure in the return chamber 52 as compared to a driver blade with a uniform cross-section identical to the cross-section along DA2. Since the portion of the driver blade 206 along the distance DA4 occupies less of the driver blade receiving opening 90a as compared to the cross-section along DA2, it enables comparatively more air to escape through the (larger) unoccupied portion of the driver blade receiving opening 90a to atmosphere and comparatively less air to enter the return chamber 52.
So as the driving assembly 16 moves from the firing position to the pre-firing position, the driver blade 206 switches from occupying the second, larger portion of the driver blade receiving opening 90a along the distance DA2 to the first, smaller portion of the driver blade receiving opening 90a along the distance DA4. Since the second portion is larger than the first portion, less air escapes to atmosphere through the unoccupied portion of the driver blade receiving opening 90a when the driver blade 206 occupies the second portion of the driver blade receiving opening 90a than when the driver blade 206 occupies the first portion of the driver blade receiving opening 90a. This means that the air entering the cylinder 14 from the return chamber 52 applies comparatively more force on the underside 54 of the piston 24 when the driver blade 206 occupies the second portion of the driver blade receiving opening 90a than when the driver blade 206 occupies the first portion of the driver blade receiving opening 90a.
Additionally, the varying cross-section of the driver blade 206 results in a reduced impact force of the piston 24 on the upper end 18 of the cylinder 14 upon return to the pre-firing position as compared to a driver blade with a uniform cross-section identical to the cross-section along DA2. Since the portion of the driver blade 206 along the distance DA4 occupies less of the driver blade receiving opening 90a as compared to the cross-section along DA2, more air to escape through the (larger) unoccupied portion of the driver blade receiving opening 90a to atmosphere and there is less air pressure forcing the piston 24 to the pre-firing position. The varying cross-section of the driver blade thus precisely controls the amount of air leakage through the driver blade seal to achieve a desired piston return.
In one example embodiment: WA1 and WA3 are 0.425 inches, WA2 is 0.250 inches, WA4 is 0.375 inches, DA1 is 0.125 inches; DA2 is 2.45 inches; DA3 and DA5 are 0.100 inches, DA4 is 2.6 inches, DA6 is 0.080 inches, DA7 is 0.140 inches, the thickness of the driver blade 206 along its length LA is 0.105 inches. In one example embodiment, the cylinder volume is about 16 cubic inches and the return chamber volume is about 32 cubic inches, though these may vary in other embodiments.
The driver blade 306 has a longitudinal axis AB and a length LB. Moving from the flange 304 to the free end 306a along the longitudinal axis AB, the driver blade 306: (1) tapers toward the longitudinal axis AB to a width WB1 along a distance DB1; (2) maintains the width WB1 along a distance DB2; (3) tapers toward the longitudinal axis AB to a width WB2 along a distance DB3; and (4) maintains the width WB2 along a distance DB4.
Although not shown, the transverse cross-section of the driver blade 306 (taken along a horizontal plane perpendicular to the longitudinal axis AB): (1) along the distance DB2 is generally rectangular shaped, and its size and shape do not change; and (2) along the distance DB4 is generally rectangular shaped, and its size and shape do not change. Put differently, the transverse cross-section of the driver blade 306 is generally uniform along the distance DB2 and along the distance DB4. The transverse cross-section of the driver blade 306 along the distance DB2 and the transverse cross-section of the driver blade 306 along the distance DB4 are different.
Since DB2 is larger than DA2, assuming all other factors are held constant, the pressure in the return chamber would be higher for the driving element 300 than for the driving element 200.
The driver blade 406 has a longitudinal axis AC and a length LC. Moving from the flange 404 to the free end 406a along the longitudinal axis AC, the driver blade 406: (1) tapers toward the longitudinal axis AC to a width WC1 along a distance DC1; (2) maintains the width WC1 along a distance DC2, (3) tapers toward the longitudinal axis AC to a width WC2 along a distance DC3; and (4) maintains the width WC2 along a distance DC4.
Although not shown, the transverse cross-section of the driver blade 406 (taken along a horizontal plane perpendicular to the longitudinal axis AC): (1) along the distance DC2 is generally rectangular shaped, and its size and shape do not change; and (2) along the distance DC4 is generally rectangular shaped, and its size and shape do not change. Put differently, the transverse cross-section of the driver blade 406 is generally uniform along the distance DC2 and along the distance DC4. The transverse cross-section of the driver blade 406 along the distance DC2 and the transverse cross-section of the driver blade 406 along the distance DC4 are different.
Since DC2 is the same as DA2, assuming all other factors are held constant, the pressure in the return chamber would be the same for the driving elements 200 and 400.
The driver blade 506 has a longitudinal axis AD and a length LD. Moving from the flange 504 to the free end 506a along the longitudinal axis AD, the driver blade 5060: (1) tapers toward the longitudinal axis AD to a width WD1 along a distance DD1; (2) maintains the width WD1 along a distance DD2, (3) tapers toward the longitudinal axis AD to a width WD2 along a distance DD3; (4) maintains the width WD2 along a distance DD4; (5) tapers away from the longitudinal axis AD to a width WD3 along a distance DD5; (6) maintains the width WD3 along a distance DD6; (7) tapers toward the longitudinal axis AD to a width WD4 along a distance DD7; (8) maintains the width WD4 along a distance DD8, (9) tapers away from the longitudinal axis AD to a width WD5 along a distance DD9; (10) maintains the width WD5 along a distance DD10; (11) tapers toward the longitudinal axis AD to a width WD6 along a distance DD11; and (12) maintains the width WD6 along a distance DD12.
Although not shown, the transverse cross-section of the driver blade 506 (taken along a horizontal plane perpendicular to the longitudinal axis AD): (1) along the distance DD2 is generally rectangular shaped, and its size and shape do not change; (2) along the distance DD4 is generally rectangular shaped, and its size and shape do not change; (3) along the distance DD6 is generally rectangular shaped, and its size and shape do not change; (4) along the distance DD8 is generally rectangular shaped, and its size and shape do not change; (5) along the distance DD10 is generally rectangular shaped, and its size and shape do not change; and (6) along the distance DD12 is generally rectangular shaped, and its size and shape do not change. Put differently, the transverse cross-section of the driver blade 506 is generally uniform along the distances DD2, DD4, DD6, DD8, DD10, and DD12. The transverse cross-sections of the driver blade 506 along the distances DD2, DD6, and DD10 are different form the transverse cross-sections of the driver blade 506 along the distance distances DD4, DD8, and DD12. The transverse cross-sections of the driver blade 506 along the distances DD2, DD6, and DD10 may be the same or different. The transverse cross-sections of the driver blade 506 along the distances DD4, DD8, and DD12 may be the same or different.
These are merely example driver blades with cross-sections that vary in terms of their width to ensure the unoccupied portion of the driver blade receiving opening changes during the fastener-driving cycle. The cross-section of the driver blade may vary in any suitable manner to ensure the unoccupied portion of the driver blade receiving opening changes during the fastener-driving cycle. For instance, in another embodiment the driver blade's width remains constant along its length but its thickness varies to ensure the unoccupied portion of the driver blade receiving opening changes during the fastener-driving cycle. In another embodiment the driver blade's width and thickness change along its length to ensure the unoccupied portion of the driver blade receiving opening changes during the fastener-driving cycle. In another embodiment the shape of the driver blade's transverse cross-section changes along its length to ensure the unoccupied portion of the driver blade receiving opening changes during the fastener-driving cycle.
While the above-described example tool is a combustion-powered-fastener-driving tool, the features described above can apply to other types of powered-fastener-driving tools, including tools powered pneumatically, electrically, or by powder cartridges.
It should be appreciated from the above that in various embodiments the present disclosure provides a fastener-driving tool comprising: a cylinder; a driver blade seal that defines a driver blade receiving opening; a driving element including a driver blade; and a piston within the cylinder and attached to the driving element such that the driver blade is slidably received in the driver blade receiving opening, wherein the piston is movable relative to the cylinder and the driver blade seal between: (1) a first position in which a first part of the driver blade occupies a first portion of the driver blade receiving opening; and (2) a second position in which a second part of the driver blade occupies a second portion of the driver blade receiving opening that is larger than the first portion.
In various such embodiments of the fastener-driving tool, the first position is a pre-firing position near an upper end of the cylinder and the second position is a firing position near a lower end of the cylinder.
In various such embodiments of the fastener-driving tool, an interior volume of the cylinder between the piston and the driver blade seal is in fluid communication with atmosphere at least in part via a portion of the driver blade receiving opening not occupied by the driver blade.
In various such embodiments of the fastener-driving tool, a first unoccupied portion of the driver blade receiving opening is not occupied by the driver blade when the driver blade is in the first position and a second unoccupied portion of the driver blade receiving opening that is smaller than the first unoccupied portion is not occupied by the driver blade when the driver blade is in the second position.
In various such embodiments of the fastener-driving tool, the first part of the driver blade has a first width and the second part of the driver blade has a second width that is larger than the first width.
In various such embodiments of the fastener-driving tool, the first part of the driver blade has a first thickness and the second part of the driver blade has a second thickness that is larger than the first thickness.
In various such embodiments of the fastener-driving tool, the cylinder defines one or more openings there through, and the fastener-driving tool further comprises a return chamber in fluid communication with the cylinder via the one or more openings.
In various such embodiments of the fastener-driving tool, the return chamber is in fluid communication with atmosphere at least in part via the one or more openings and via a portion of the driver blade receiving opening not occupied by the driver blade.
In various such embodiments, the fastener-driving tool further comprises one of: (1) an internal combustion engine assembly; and (2) an air inlet attachable to a compressed air source.
It should also be appreciated from the above that in various embodiments the present disclosure provides a fastener-driving tool comprising: a cylinder; a driver blade seal that defines a driver blade receiving opening; a driving element including a driver blade; and a piston within and movable relative to the cylinder and the driver blade seal and that is attached to the driving element such that the driver blade is slidably received in the driver blade receiving opening, wherein the driver blade has a non-uniform cross-section such that a portion of the driver blade receiving opening occupied by the driver blade changes as the piston moves relative to the cylinder from a first position to a second position.
In various such embodiments of the fastener-driving tool, a first part of the driver blade occupies a first portion of the driver blade receiving opening when the piston is in the first position and second part of the driver blade occupies a second portion of the driver blade receiving opening that is larger than the first portion when the piston is in the second position.
In various such embodiments of the fastener-driving tool, the first position is a pre-firing position near an upper end of the cylinder and the second position is a firing position near a lower end of the cylinder.
In various such embodiments of the fastener-driving tool, the first part of the driver blade has a first width and the second part of the driver blade has a second width that is larger than the first width.
In various such embodiments of the fastener-driving tool, the first part of the driver blade has a first thickness and the second part of the driver blade has a second thickness that is larger than the first thickness.
In various such embodiments of the fastener-driving tool, an interior volume of the cylinder between the piston and the driver blade seal is in fluid communication with atmosphere at least in part via a portion of the driver blade receiving opening not occupied by the driver blade.
In various such embodiments of the fastener-driving tool, a first unoccupied portion of the driver blade receiving opening is not occupied by the driver blade when the driver blade is in the first position and a second unoccupied portion of the driver blade receiving opening that is smaller than the first unoccupied portion is not occupied by the driver blade when the driver blade is in the second position.
In various such embodiments of the fastener-driving tool, the cylinder defines one or more openings there through, and the fastener-driving tool further comprises a return chamber in fluid communication with the cylinder via the one or more openings.
In various such embodiments of the fastener-driving tool, the return chamber is in fluid communication with atmosphere at least in part via the one or more openings and via a portion of the driver blade receiving opening not occupied by the driver blade.
In various such embodiments, the fastener-driving tool further comprises one of: (1) an internal combustion engine assembly; and (2) an air inlet attachable to a compressed air source.
Various changes and modifications to the above-described embodiments described herein will be apparent to those skilled in the art. These changes and modifications can be made without departing from the spirit and scope of this present subject matter and without diminishing its intended advantages. Not all of the depicted components described in this disclosure may be required, and some implementations may include additional, different, or fewer components from those expressly described in this disclosure. Variations in the arrangement and type of the components; the shapes, sizes, and materials of the components; and the manners of attachment and connections of the components may be made without departing from the spirit or scope of the claims as set forth herein. Also, unless otherwise indicated, any directions referred to herein reflect the orientations of the components shown in the corresponding drawings and do not limit the scope of the present disclosure. This specification is intended to be taken as a whole and interpreted in accordance with the principles of the invention as taught herein and understood by one of ordinary skill in the art.
This application claims priority to and the benefit of U.S. Provisional Patent Application Ser. No. 62/456,954, filed Feb. 9, 2017, the entire contents of which are incorporated by reference herein.
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