The present invention relates to knockout punches and, more particularly, to powered knockout drivers.
A knockout driver is generally used in combination with a punch and die set to form apertures within sheet material, such as sheet metal and the like. The punching process is accomplished by providing a large force between the die and punch, causing the punch to pierce the sheet material and form the desired aperture. The force can be produced in a number of ways, such as manually, hydraulically, and the like. Typically, manual embodiments are limited by the size of hole they can create, while most hydraulic powered systems can be bulky.
The invention provides, in one aspect, a hand-held knockout driver including a main housing having a handle portion, a motor positioned within the main housing, a hydraulic assembly driven by the motor and including a reservoir containing hydraulic fluid, a secondary housing coupled to the main housing and defining a bore therein, a working piston moveable within the bore between a rest position and an actuated position, and a work zone defined between the secondary housing and the working piston into which pressurized hydraulic fluid discharged from the hydraulic assembly is received. One unit of fluid is added to the work zone to move the working piston from the rest position to the actuated position. The reservoir has a fill capacity no greater than about 1.5 units of fluid.
The invention provides, in another aspect, a hand-held knockout driver including a main housing having a handle portion, a motor positioned within the main housing, a pump assembly driven by the motor, a secondary housing coupled to the main housing and defining a bore therein, a working piston moveable within the bore from a rest position to an actuated position to define a piston throw distance therebetween, a draw stud coupled to the working piston, and one of a punch or a die coupled to the draw stud opposite the working piston for movement therewith. The die includes a depth greater than the piston throw distance.
The invention provides, in yet another aspect, a hand-held knockout driver including a housing having a handle portion, a head unit defining a first hydraulic channel, a pump body coupled to the head unit, the pump body defining a second hydraulic channel therein, and an insert having a first end sized to be at least partially received within and form a seal with the first hydraulic channel and a second end sized to be at least partially received within and form a seal with the second hydraulic channel.
The invention provides, in a further aspect, a hand-held knockout driver including a housing having a handle portion, a motor positioned within the housing, a pump body positioned within the housing and defining a recess therein, and a dump valve positioned within the recess and having a seat, a piston, a plunger, and a return spring. The seat includes a side wall defining an output aperture. The side wall is spaced a distance radially inwardly from the interior of the recess.
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 embodiment 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.
Although the illustrated embodiment utilizes a DC electric motor 26 powered by an 18 volt rechargeable battery 15, in another embodiment, the driver 10 may be powered by a battery having a greater or lesser voltage or may include a power cord to be plugged into a power outlet. In still another embodiment, a pneumatic motor may be utilized.
Referring to
The third portion 50 of the bore 38 includes a seal groove 62 extending circumferentially thereabout. The seal groove 62 is sized to receive an O-ring 66 and a back-up ring 70 therein (
The bore 38 also includes an intermediate portion 82 extending between the second portion 46 and the third portion 50. When assembled, the walls of the intermediate portion 82 are spaced a distance from the piston 74 to provide clearance for the hydraulic fluid to enter the work zone 78.
The head unit 18 also includes a hydraulic channel 86 extending between the outside of the housing 30 and the intermediate portion 82 (e.g., the work zone 78) of the bore 38. When assembled, the channel 86 is configured to allow fluid to flow between the work zone 78 and an outlet 198 of a pump 182 (described below).
The head unit 18 also includes the piston 74, positioned and axially moveable within the bore 38 of the housing 30 along the axis 34. The piston 74 is movable between a rest position, where a bottom 90 of the piston 74 is proximate the contact surface 58 of the housing 30 (
In the illustrated embodiment, the piston 74 is substantially cylindrical in shape and includes a bottom portion 94, which has a first outer diameter substantially corresponding to the third portion 50 of the bore 38, and a flange 98 extending radially outwardly from the bottom portion 94, which has a second outer diameter substantially corresponding to the second portion 46 of the bore 38.
The piston 74 includes a seal groove 102 extending circumferentially around the flange 98 that is sized to receive an O-ring 66 and a back-up ring 70 therein (
The piston 74 also includes a recess 106, extending axially inward from the bottom 90 that is configured to receive a portion of a draw rod 378 therein (
The piston 74 also includes a spring seat 110 formed in the upper surface of the piston 74. When assembled, the spring seat 110 positions a return spring 114 on the piston 74. Dependent upon the size, orientation, and number of return springs present, one or more seats 110 may be used.
The head unit 18 also includes the retainer cup 118 coupled to the top of the housing 30 and configured to position the return spring 114 substantially co-axial with the central axis 34 (
In the illustrated embodiment, the return spring 114 extends between the piston 74 and the retainer cup 118 to bias the piston 74 toward the rest position. The return spring 114 provides sufficient force to bias the piston 74 toward the rest position when fluid is free to flow between the work zone 78 and the reservoir 142 (e.g., a dump valve 230 is open), but does not provide enough force to unseat the dump valve 230 by itself. In the illustrated embodiment, a pair of concentric return springs 114a, 114b, each formed from circular wire, may be used (
The driver 10 also includes a hydraulic assembly 22. The hydraulic assembly 22 includes a hydraulic body 146, first and second reservoir bladders 150a, 150b coupled to the hydraulic body 146, and a pump assembly 154. During operation, the hydraulic assembly 22 provides hydraulic fluid, under pressure, to the head unit 18 to bias the piston 74 toward the actuated position.
Illustrated in
In the illustrated embodiment, the seal between the channel 86 and the aperture 170 is formed from a seal member 174. The seal member 174 is substantially cylindrical in shape having a fluid passage extending therethrough. The seal member 174 also includes a pair of O-rings, to seal with the interior surfaces of the channel 86 and aperture 170. In other embodiments, other forms of sealing may be used.
The hydraulic block 166 defines a substantially semi-cylindrical recess 178 (
The piston cylinder 182 also includes an inlet 194 and an outlet 198 (
The hydraulic block 166 also includes a first reservoir boss 206a extending from a first side wall and a second reservoir boss 206b extending from a second side wall opposite the first side wall. In the illustrated embodiment, each boss 206a, 206b is substantially circular and includes a groove 210 into which the corresponding reservoir bladder 150a, 150b can be attached.
The hydraulic block 166 also defines a plurality of hydraulic channels, each of which is drilled into or otherwise formed to provide fluid pathways between various areas of the head unit 18, the pump assembly 154 (when attached), and the reservoir 142. In the illustrated embodiment, the block 166 defines the first hydraulic channel 214 extending between and in fluid communication with the hydraulic aperture 170, the dump valve 230, and the outlet 198 or high pressure side of the pump 182 (
In the illustrated embodiment, the block 166 also includes a fill channel 226 extending between the second reservoir boss 206b and the outside of the block 166 to allow the user to add or remove the hydraulic fluid in the reservoir 142. The fill channel 226 may also be used for mounting sensors (e.g., a pressure sensor, and the like) or be used as an accumulator to accommodate for changes in the hydraulic fluid level in addition to the reservoir bladders themselves.
Illustrated in
As such, the reservoir bladders 150a, 150b are configured to allow a larger portion of the fluid contained within the bladders 150a, 150b to be used as working fluid. Stated differently, if a device requires 1 unit of fluid to operate (e.g., the working volume is 1 unit of fluid), the reservoir is designed to contain no greater than about 1.5 units of fluid. In another embodiment, the reservoir is designed to contain no more than about 1.4 units of fluid. In still another embodiment, the combined volume of the first reservoir bladder and the second reservoir bladder is designed to contain no more than about 1.1 units of volume. In another embodiment, the combined volume of the first reservoir bladder and the second reservoir bladder is designed to contain no more than about 1.011 units of fluid.
In the present invention, the working volume is defined as the volume of fluid that must be added to the work zone 78 (e.g., by the pump assembly 154) to move the working piston 110 from the rest position (
The hydraulic assembly 22 also includes a dump valve 230 (
Illustrated in
The plunger 246 of the dump valve 230 is substantially disk shaped, and includes an aperture 266 proximate its center and defines an annular groove 270 along its perimeter. During operation, the plunger 246 moves axially along axis 231 within the recess 234 and along the actuation rod 242 between a first position (
Illustrated in
During operation, the dump valve 230 generally remains in the closed configuration where no fluid can flow between the first hydraulic channel 214 (e.g., the working volume 78) and the cross channel 218 (e.g., the reservoir 142). More specifically, when the dump valve 230 is in the closed configuration the spring 278 biases the plunger 246 toward the first position, which in turn causes the needle point 287 of the activation rod 242 to form a seal with the seat 294, sealing the recess 234 from the first hydraulic channel 214 (
When the user wishes to return the piston 74 to the rest position, the user presses the return button 250, biasing the rod in a direction C along axis 231. As the activation rod 242 moves in the direction C, the radially extending wall 290 contacts the bottom of the plunger 246 biasing it in the first direction against the spring 278 and into the second position, leaving an output aperture 298 uncovered (
In the illustrated embodiment, the spring 278 is configured to produce a force that is sufficiently strong to keep the needle point 287 engaged with the seat 294 as pressure builds within the first hydraulic channel 214, but sufficiently weak to allow the plunger 246 to move toward the second position once the needle point 287 has been unseated. More specifically, it takes a first, smaller force to overcome the hydraulic pressure acting against the smaller surface area of the needle point 287 and a second, larger force to overcome the hydraulic pressure acting on the larger surface area of the plunger 246. As such, the spring 278 typically is preloaded to produce a force greater than the first, smaller force required for the needle point 287, but less than the second, larger force required for the plunger 246.
As the fluid leaves the work zone 78, the return spring 114 is able to bias the piston 74 toward the rest position. As the piston 74 moves toward the rest position, the pressure of the fluid within the recess 234 of the dump valve 230 is created by the energy stored within the return spring 114. As such, as the piston 74 continues to move toward the rest position, energy is released from the return spring 114 causing the pressure of the fluid in the dump valve 230 to drop. As the pressure of the fluid contained within the dump valve 230 drops, the plunger 246, biased by the spring 278, moves toward the first position.
Once the pressure within the volume has decreased to a given level, the plunger 246 will have moved to where it will begin to cover or block the outlet aperture 298. At this time, the aperture 298 becomes aligned with annular groove 270 forcing the working fluid to flow through the flow control aperture 282 formed in the bottom of the plunger 246. As this happens, a pressure differential is formed forcing the plunger 246 toward the first position and causing the needle point 287 to fully seal with the seat 294.
In the illustrated embodiment, the seat 294 of the dump valve 230 includes a flat contact surface with a generally vertical channel (
Furthermore, the seat 294 has an outer diameter defining an axially extending wall that is less than the diameter of the recess 234, creating a gap 306 therebetween. During operation, fluid that flows out the outlet aperture 298 flows into the cross channel 218 via the gap 306.
Although the illustrated embodiment shows the head unit 18 permanently joined to the hydraulic body 146, in other embodiments, the head unit 18 may be detachable from the body 146. In still other embodiments, the head unit 18 may be rotatably or pivotably mounted to the body 146 to provide greater adaptability for tight or restricted working conditions.
Illustrated in
Referring to
The pump housing 310 also includes mounting provisions (not shown) within the recess 326 to allow the instillation of the gear drive 314 and the motor 26. When assembled, the mounting provisions axially align the gear drive 314 and motor 26 with the drive axis 322.
Referring to
During operation of the pump assembly 154, the piston 318 moves (e.g., oscillates) along the pump axis 319 and within the piston cylinder 182 to alter the working volume therein; the working volume being defined as the volume within the piston cylinder 182 where the working fluid may be present. More specifically, when the piston 318 moves toward the distal end 186 of the piston cylinder 182, the working volume decreases, and when the piston 318 moves away from the distal end 186 of the piston cylinder 182, the working volume increases.
During operation, the torque provided by the motor 26 is transmitted to the piston 318 by way of a yoke 334. The motor 26 rotates the gear train 314, which in turn rotates an eccentrically positioned crank pin 338 (
More specifically, the crank pin 338 is supported between a first eccentric bushing 346 and a second eccentric bushing 350 (
As the motor 26 rotates, the piston 318 oscillates within the piston cylinder 182 causing the working volume to increase and decrease in repetition. As such, each time the working volume increases, working fluid is drawn through the inlet 194 and into the piston cylinder 182. In contrast, each time the working volume begins to decrease, the fluid is forced out the outlet 198 and into the working volume 78.
Referring to
An opposing end 382 of the draw rod 378 is coupled to the piston 74 of the driver 10. The contact surface 58 of the driver 10 should rest against the die 370 and a user adjusts the position of the punch 366 so that the punch rests snuggly against the sheet material 362.
With the setup complete, the user activates the driver 10 by depressing the trigger 386 or other activation device (not shown), and thereby closing an electrical circuit and causing the motor 26 to produce torque. As the motor 26 rotates, the motor 26 causes the crank pin 338 to rotate eccentrically. As described above, eccentric rotation of the crank pin 338 is converted into linear, reciprocating motion of the piston 318 by way of the yoke 334. The reciprocating motion of the piston 318 within the piston cylinder 182 causes the pump assembly 154 to draw fluid from the reservoir 142 by way of the cross channel 218 and output fluid through the first hydraulic channel 214 and into the work zone 78. As the fluid accumulates within the work zone 78, the piston 74 is biased toward the actuated position, which in turn imparts tension on the draw rod 378.
As tension on the draw rod 378 increases (e.g., fluid continues to accumulate in the work zone 78), the punch 366 is drawn toward the die 370 until enough force is created to physically cut (e.g., punch) the sheet material 362 and create the desired aperture (
With the hole created, the user can return the piston 74 to the rest position (e.g., reset the system) by actuating the dump valve 230 as described above. With the dump valve 230 activated, the fluid within the work zone 78 is evacuated to the reservoir 142 causing the piston 74 to return to the rest position. Once there, the dump valve 230 returns to the closed configuration.
In the instances where operating pressures within the work zone 78 exceed the pressure within the reservoir 142 beyond the predetermined value (e.g., the material is too thick, the punch is too large, or the piston 74 has reached the end of its travel limit), the dump valve 230 will automatically open, causing the piston 74 to return to the rest position as described above.
Referring to
The pump housing 496 also includes a piston cylinder 464 extending from a side wall 468 of the pump housing 406 that is substantially perpendicular the pump axis 426 to produce a distal end 472. In the illustrated embodiment, the piston cylinder 464 intersects and is in fluid communication with both the inlet channel 446 and the outlet channel 454 (
Referring to
Referring to
During operation of the pump assembly 400, the piston 418 moves (e.g., oscillates) within the piston cylinder 464 to alter the working volume of the pump housing 406; the working volume being defined as the volume within the pump housing 496 where hydraulic fluid may be present. More specifically, when the piston 418 moves toward the distal end 472 of the piston cylinder 464, the working volume decreases, and when the piston 418 moves away from the distal end 472 of the piston cylinder 464, the working volume increases. The pump assembly 400 also includes a return spring 480 positioned within the piston cylinder 464 and extending between the distal end 472 and the piston 418 (
Referring to
During operation of the pump assembly 400, the cam 422 rotates with respect to the pump housing 406. As the cam 422 rotates, a point of contact 497 between the piston 418 and cam 422 moves circumferentially along the interior cam surface 295 varying the radial distance of the contact point 497 from the pump axis 426 in response to the contour of the cam wall 499. Variations in radial position of the contact point 497 cause the piston 497 to move within the piston cylinder 464, which changes the working volume of the pump housing 406.
More specifically, as the radial distance between the interior cam surface 495 and the pump axis 426 decreases, the piston 418 moves toward the distal end 472 of the piston cylinder 464 and the working volume decreases. In contrast, as the radial distance between the interior cam surface 495 and the pump axis 426 increases, the piston 418 moves away from the distal end 472 of the piston cylinder 464 (aided by the return spring 480) and the working volume increases. As such, the contour of the interior cam surface 495 may be altered to customize the speed and extent of the oscillating motion of the piston 418, and ultimately, the performance characteristics of the pump assembly 400.
As the cam 422 rotates, the piston 418 oscillates within the piston cylinder 464 (as described above) causing the working volume of the pump housing 406 to increase and decrease in repetition. As such, each time the working volume increases, working fluid is drawn through the first check valve 410, along the inlet channel 446, and into the piston cylinder 464. In contrast, each time the working volume begins to decrease, the fluid is forced out along the outlet channel 454 and through the second check valve 414.
In the above described configuration, direct contact with the interior cam surface 495 forces the piston 418 toward the distal end 472 (e.g., forcing the fluid out of the pump assembly 400), while the return spring is responsible biasing the piston 418 away from the distal end 472 (e.g., drawing the fluid into the pump assembly 400). This configuration is desirable since larger forces can be applied by the cam 422 (e.g., via the motor) than by the spring 480, thereby increasing the capabilities of the pump assembly 400. The above described pump stages are repeated as long as the cam 422 rotates.
Referring to
The pump housing 506 also includes a piston cylinder 564 extending through the housing substantially perpendicular the axis 526 and open on both ends. In the illustrated embodiment, the piston cylinder 564 includes a first portion 572 having a first diameter and a second portion 568 having a second diameter smaller than the first diameter. The piston cylinder 564 intersects and is in fluid communication with both the inlet channel 546 and the outlet channel 554 (
Referring to
Referring to
During operation, the piston 518 moves (e.g., oscillates) within the piston cylinder 564 to alter the working volume of the pump housing 506; the working volume being defined as the volume within the pump housing 596 where hydraulic fluid may be present. More specifically, when the piston 518 moves to the left or toward first portion 572, the working volume increases, and when the piston 518 moves to the right or toward the second portion 568, the working volume decreases.
Referring to
During operation of the pump assembly 500, the cam 522 rotates with respect to the pump housing 506. As the cam 522 rotates, the bearings 576, 580, in contact with the cam surface 595, move along cam surface 595 as it varies in radial distance from the pump axis 526. As described above, variations in radial position of the contact points cause the piston 518 to move or reciprocate within the piston cylinder 564, which in turn causes the working volume of the pump housing 506 to vary. In the illustrated construction, both ends of the piston 518 contact the cam surface 595 so both directions of movement (e.g., to the right and to the left) are driven by the motor instead of relying on a return spring.
Referring to
The ring 714′ of the pump side attachment 708′ is substantially annular in shape and includes a groove 728′ extending circumferentially along the outer surface of the ring 714′. In the illustrated embodiment, the groove 728′ extends radially inwardly to form a substantially radiused contour corresponding to the shape of locking balls 768′ that are part of the tool side attachment 704′ (described below).
Best illustrated in
The second end 744′ also includes a plurality (e.g., four) of flats 752′ (
The tool side attachment 704′ also includes an output shaft 756′ rotatably coupled to the body 732′ and driven by the motor 26′. When assembled, the output shaft 756′ is configured to transmit torque between the motor 26′ and the cam 222′. More specifically, the output shaft 756′ includes a splined end 760′ that, when the tool side attachment 704′ is coupled to the pump side attachment 708′, meshes with a splined portion 764′ of the cam 222′ to transmit torque therebetween.
The tool side attachment 704′ also includes locking balls 768′, which are spaced equally around the circumference of the body 732′ and radially moveable between a radially inward or locked position (
The tool side attachment 704′ also includes a substantially annular locking collar 776′. The locking collar 776′ is slideably coupled to the body 732′, being axially moveable between a rested position (
Referring to
The tool side attachment 704′ also includes a sleeve 796′ positioned within and axially moveable within the annular channel 748′ between a rested position, wherein the sleeve 796′ is axially aligned with the locking balls 768′ (
To attach the head unit 18′ to the main housing 14′, a user first rotates the head unit 18′ into the desired orientation with respect to the main hosing 14′ making sure to align the flats of the outer housing 712′ with the flats 752′ of the body 732′. The user then axially introduces the ring 714′ of the pump side attachment 708′ into the annular channel 748′ of the tool side assembly 704′.
As the user continues to axially introduce the ring 714′ into the annular channel 748′, the ring 714′ contacts the sleeve 796′, urging it out of axial alignment with the locking balls 768′. The user continues to introduce the ring 714′ until the groove 728′ of the ring 714′ aligns with the locking balls 768′, thereby allowing the locking balls 768′ to move radially inwardly into engagement with the groove 728′ and into the locked position. As a result, the locking collar 776′ is able to move forward into the rested position, causing the first portion 792′ of the inner surface 784′ to become aligned with the locking balls 768′ and maintaining the balls 768′ in the locked position and securing the head unit 18′ to the main housing 14′.
To remove the head unit 18′ from the main housing 14′, the user manually biases the locking collar 776′ into the actuated position, causing the second portion 788′ of the inner surface 784′ to become aligned with the locking balls 768′. As a result, the locking balls 768′ are free to move radially outwardly from the locked position and out of engagement with the groove 728′ of the ring 714′. The user can then axially remove the pump side assembly 708′ from the annular channel 748′. With the ring 714′ removed, the sleeve 796′ returns to the rested position (e.g., blocking the locking balls 768′ from moving into the locked position) causing the locking collar 776′ to remain in the actuated position, as described above.
The piston 810″ also includes a travel limit poppet valve 867″ for providing selective fluid communication between the work zone 838″ and the reservoir 842″, and which is at least partially dependent upon the position of the piston 810″ within the bore 850″ of the head unit. More specifically, the travel limit poppet valve 867″ is configured to open, or allow the flow of fluid between the work zone 838″ and the reservoir 850″, when the piston 810″ has reached a pre-determined travel limit within the bore 850″.
Illustrated in
The head unit 18″ also includes a fill tube 906″ coupled to the piston 810″ and in fluid communication with the reservoir 842″. In the illustrated embodiment, the fill tube 906″ moves with the piston 810″ and includes a plunger 910″ positioned within and axially moveable within the fill tube 906″. When assembled, the volume produced by the fill tube 906″ and plunger 910″ is in fluid communication with the reservoir 842″ via a set of notches 914″ cut into the piston 810″. As such, any variations in fluid level of the reservoir 842″ (e.g., via movement of the piston 810″ within the bore 850″ or working fluid temperature changes) will bias the plunger 910″ axially along the tube 906″ to compensate. More specifically, if the volume of fluid within the reservoir 842″ increases, the plunger 910″ will move toward the open end of the tube 906″, while if the volume of fluid within the reservoir 842″ decreases, the plunger 910″ will move toward the piston 810″. In the illustrated construction, the piston 810″ moves within the fill tube 906″ by way of hydraulic forces only; however in alternate constructions, additional forces may be employed (e.g., via springs, stops, check valves, and the like).
Furthermore, if the fluid level within the reservoir 842″ exceeds a maximum allowable limit, the plunger 910″ can eject from the far end of the fill tube 906″ allowing the excess fluid to drain harmlessly. In situations where the plunger 910″ is ejected, all the user must do to resume working with the head unit 18″ is top off the any working fluid that may have been lost and re-insert the plunger 910″ in the fill tube 906″ via the open portion of the retainer cup 876″, no replacement parts are needed. In some embodiments, a rod or handle (not shown) may be attached to the plunger 910″ so the user can manually remove the plunger 910″ from the tube 906″.
Although the invention has been described in detail with reference to certain preferred embodiments, variations and modifications exist within the scope and spirit of one or more independent aspects of the invention as described.
The present application is a divisional of U.S. patent application Ser. No. 16/254,169, filed on Jan. 22, 2019 now U.S. Pat. No. 11,148,312, which is a continuation of U.S. patent application Ser. No. 14/921,474, filed Oct. 23, 2015, now U.S. Pat. No. 10,195,755, which is a continuation of U.S. patent application Ser. No. 13/444,784, filed Apr. 11, 2012, now U.S. Pat. No. 9,199,389, which claims the benefit of and priority to U.S. Provisional Patent Application No. 61/596,548, filed Feb. 8, 2012, U.S. Provisional Patent Application No. 61/523,691, filed Aug. 15, 2011, U.S. Provisional Patent Application No. 61/489,186, filed May 23, 2011, and U.S. Provisional Patent Application No. 61/474,156, filed Apr. 11, 2011, each of which is incorporated herein by reference in its entirety.
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20220032486 A1 | Feb 2022 | US |
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Parent | 16254169 | Jan 2019 | US |
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Parent | 13444784 | Apr 2012 | US |
Child | 14921474 | US |