This disclosure relates generally to machine tools, and specifically to punch assemblies for metal working. In particular, the disclosure relates to punch tool assemblies suitable for use in punch press machines, including, but not limited to, high speed punch presses used in fabrication and manufacturing.
Industrial tooling machines including turret and rail-type punch presses are widely used in the fabrication of sheet metal workpieces and other sheet components (e.g., metal, plastic, leather, etc.). Automated punch presses are commonly employed in manufacturing applications, including single and multi-station presses, press brakes, sheet and coil feed systems, rail-type machine tool systems, and other fabrication equipment adapted for pressing, bending and punching sheet metal components, used to fabricate sheet metal and other workpieces into a wide range of useful products.
Punch presses in particular have found wide use in sheet metal hole punching and forming applications. Turret presses typically have an upper and lower turret sections that hold a series of punches and dies, spaced circumferentially at different locations around the periphery of the turret. The turret press can then be rotated about a vertical axis to bring a desired punch and die set into vertical alignment with a work station, or to bring a series of different punch and die sets sequentially into alignment for performing a series of different pressing operations. Rail-type and single-tool punch presses are also widely used.
The workpiece itself is commonly formed of a piece of sheet metal, disposed between selected punch and die combinations. The punches can be operated under computer control, when the selected punch and die assemblies are aligned across the workpiece. The punch is driven through the workpiece and into the die, forming a hole or other desired feature.
Punch systems typically include an outer punch guide with a punch member reciprocating in a longitudinal bore, or a punch ram assembly with a bushing to hold the punch. The punch itself typically includes a shank or body portion and a punch point or other forming tool on the working end, facing the sheet metal component or workpiece. The punch point engages the workpiece in the punch stroke, forming a hole by driving a slug out of the workpiece metal and through the die. A return spring or punch clamp can be used to urge the punch back into its original position, in a stripping action following the punch stroke.
A high number of repeated strokes are typical in automated machine tool applications. The punch point may thus become worn, and require sharpening or replacement. There is a constant need to make the replacement process less complex and more efficient, with less downtime and reduced replacement cost.
A punch or punch device assembly is provided, suitable for use in a punch press or similar tooling machine. The assembly includes a replaceable punch tip configured for selective engagement and disengagement with a punch body. Punch press systems using the punch assembly are also encompassed, along with corresponding methods of assembly and operation.
Depending on configuration, the punch body and punch tip can be coupled by axial engagement between an insert or stem and a corresponding axial cavity. Various manual and tool-less coupling mechanisms may be utilized e.g., with a transverse coupling pin engagement between the punch body and stem.
Punch press apparatus 20 includes upper turret 18 and lower turret 22. Die 24 is mounted in lower turret 22, opposite punch tip 14 across workpiece 25, for example a sheet metal component or other material to be tooled.
In operation of punch assembly (or punch) 10, punch point 15 of punch tip 14 is driven through an aperture in stripper 26 on the bottom surface of punch guide 16, extending through workpiece 25 and into die 24. Punch point 15 separates a slug from workpiece 25 during the punching process, and the slug is received into die 24. Stripper 26 is disposed on the bottom surface of punch guide 16, and holds workpiece 25 in place as punch point 15 is withdrawn from die 24. Alternatively, press apparatus 20 and die 24 may be configured for notching, slitting, shearing, or blanking workpiece 25, or for other metal forming processes.
A threaded connection or other mechanical coupling 28 couples punch body 12 to punch canister assembly 30, with punch head 32, punch driver 34 and stripping spring 36. A ram component of punch press apparatus 20 imparts an axial (e.g., downward) force onto punch head 32, driving punch driver 34 through an aperture in spring retainer plate 38 by a distance sufficient for punch point 15 to penetrate workpiece 25 into die 24, as described above. When the ram is retracted (or the driving force on the ram is removed), stripping spring 36 acts between spring retainer plate 38 and punch head 32, moving punch driver 34 back (e.g., upward) to its original position. Punch tip 14 is withdrawn from die 24 and workpiece 25 back into punch guide 16, with punch point 15 positioned within (and no longer extending from) the aperture in stripper member 26, as shown in
Depending on embodiment, a pushbutton or other mechanism 40 may be provided to adjust punch length of punch assembly 10, as measured to punch tip 14 and punch point 15. Additional features suitable for application in punch press apparatus 20 are disclosed in U.S. Pat. Nos. 5,839,341, 5,884,544, and 7,975,587, currently assigned to Mate Precision Tooling of Anoka, Minn., each of which is incorporated by reference herein, in the entirety and for all purposes.
In one particular example, punch tip 14 is secured to punch body 12 using a pin-connected configuration, as shown in
In punching operation, press ram 11 is actuated to drive the working end of the punch tip or insert 14 through the workpiece, and into engagement with die 24 in die holder 23. In the rail-type configuration of
In one particular example, punch tip 14 is secured to punch body 12 using coupling pin 42, as shown in
Removable tip punch assembly 10 is configured for punch press tooling, and includes a removable lower punch tip 14 for a punch press machine, held into an upper portion or punch body 12 by a manually operable lateral sliding pin 42. Replaceable punch tip 14 is locked in place securely without elastic or cam features, and pin 42 is easily operated without tools. A variety of small, removable and replaceable punch tips 14 can be made from high performance tool steel and other suitable materials, at comparatively low cost.
This design incorporates a number of useful features, not previously found in the punch press industry. These features include radial sliding pin 42, which is configured to engage tang or stem portion 44 of punch tip 14 and the lower portion of punch body 12, extending through radially aligned (e.g., cylindrical) walls of cavities 48. Pin 42 is aligned with and positioned through radial cavities or bores 48 and 49 (see
Punch assembly or device 10 includes a removable punch tip 14 attached to a specially configured “holder” or punch body 12, which makes up the remainder of what would otherwise be a complete punch (or punch assembly) 10, which in turn is used in a punch press. Such a removable punch tip 14 is desirable in the industry, because, for example, if punch tip 14 is very small (or relatively small, as compared to the other components of punch assembly 10), punch tip 14 can be made of high performance material at a reasonable cost, while lower-cost materials are used for other components (e.g., punch body 12), whereas making the entire punch 10 of such high-performance materials could be cost-prohibitive.
Punch device or assembly 10 includes three working elements. These are punch tip 14, punch body 12, and the punch tip retention mechanism of coupling pin 42.
Punch Tip
In preferred embodiments, punch tip 14 encompasses the removable lower portion of punch assembly 10, and has a cylindrical shank, tang or stem 44 extending at top end 14T, opposite working end 14W of punch tip 14 (e.g., punch point 15, see
In additional embodiments, an alignment pin 64 in punch body 12 and mating alignment slot 65 in the flange or top end 14T of punch tip 14 allow for precision orientation of punch tip 14 with respect to punch body 12, suitable for practical application in a punch press apparatus (see, e.g.,
Alternately, it may be desirable to include both mechanisms, in a redundant centering system with both constraints. Precision centering is desired to reduce damage to the die, e.g., when punching thin materials that require a tight fit between the punch and die sizes.
Punch Body
In preferred embodiments, punch body 12 (
Punch body 12 has an axial (e.g., cylindrical) pocket or cavity 54 on lower end 56, configured for receiving the axial tang or stem 44 of punch tip 14. Pocket or axial cavity 54 can be precisely centered to facilitate accurate location of punch tip 14. An alignment pin 64 may also be provided at the bottom end of punch body 12, oriented parallel to punch axis A but centered near the outer diameter, and configured to angularly orient punch tip 14 with respect to punch body 12 by engaging a precision key-slot 65 in punch tip 14.
For tool-less manual operation of coupling pin 42, a relief cavity 60 (
Further enhancements encompass ergonomic knurls or grooves configured to facilitate gripping and manipulation of pin 42. A ball plunger 45 may also be pressed or screwed into a hole in punch body 12, e.g., substantially perpendicular to radial axis S of pin 42 (
Sliding Pin
In preferred embodiments (e.g., as shown in
Radial grooves, detents, or other engagement features 62 can also be provided on sliding pin 42, e.g., positioned towards opposite ends 42A and 42B, as shown in
Installation of Punch Tip into Punch Body
In preferred embodiments, punch assembly 10 encompasses a premium adjustable-length punch system with a threaded engagement or similar coupling feature 28 in top portion 55 of punch body 12, and a vertical hole or axial cavity 54 in the lower end or bottom portion 56 (see
Pin 42 can be manipulated laterally inward to fit into a locked position within receiving cavities 48 and 49 of punch body 12 and punch tip 14, constraining punch body 12 and punch tip 14 to move slidably together within the punch guide or bushing. Pin 42 can also be manipulated into a laterally outward or open position in which stem 44 of punch tip 14 can move vertically or axially past pin 42, facilitating installation or removal of punch tip 14.
Punch tip 14 is resiliently locked in place for punching operation when pin 42 is fully inserted through cavities or channels 48, 49, positioned within or at least flush with the outside diameter of punch body 42. Pin 42 can be further secured in the locked position when punch assembly 10 is installed within the walls of a punch guide, bushing, or similar component, where the walls constrain pin 42 in the axial direction and prevent or do not allow for pin 42 to slip out of (or extend beyond the sides of) punch body 12. Pin 42 can further be constrained by a resilient or secured coupling or other various mechanical features, as described in the examples below, in order for pin 42 to remain in either the locked or open positions, and to facilitate or ease manual operation of the sliding pin mechanism.
Once punch tip 14 is completely pushed into the axial cavity in punch body 12, radial sliding pin 42 can be pushed or manipulated by hand from its “open” position through the corresponding radial cavity or channel 49 in punch tip (or insert) stem 44. Pin 42 can then be snapped into place in the “closed” position, when the corresponding radial groove or other engagement feature 62 meets ball plunger 45. Punch tip 14 can thus be alternately retained and released by manually operable pin 42.
Punch tip 14 may also be provided with keying for angular orientation. For example, an axially oriented pin or key can be provided at a radial distance from punch body axis A, which fits into a slot or cavity in punch tip 14. This positions punch tip 14 angularly, in a predetermined or selected rotational alignment with respect to punch body 12.
Removal of Punch Tip from Punch Body
To remove punch tip 14 from punch body 12, punch assembly 10 can be removed from the punch guide and separated into two or more parts by moving pin 42 to the open or disengaged position. This can be performed in a two-part process, in which a first end of pin 42 is first pushed into a relief cavity 60 on one side of punch body 12, allowing pin 42 to move into punch body 12 enough for the second (opposite) end of pin 42 to protrude from the outside diameter of punch body 12 on the opposite side. Then, pin 42 can be manually grabbed or manipulated on the second end (e.g., with a finger and a thumb), and pulled outward from punch body 12 until the second end of pin 42 reaches an outer lateral location and the groove or engagement feature 62 on the first end of pin engages ball plunger 45.
When the second end of pin 42 reaches the proper location, pin 42 snaps or locks in the open position, allowing punch tip 14 to be manually removed or pulled out of punch body 12 (e.g., using the other hand to slide tip stem 44 or punch tip 14 axially, out of cavity 54 in punch body 12). Depending on design, pin 42 may also be configured for manipulation past the open position, and removal from punch body 12.
As can be seen in the various section views of punch assembly 10, stem or tang 44 of punch tip 14 may have radial cavity or channel 49 (e.g., cylindrical and perpendicular to the punch axis), which accepts pin 42 to secure punch tip 14 to punch body 12.
When pin 42 is completely inserted into punch body 12, with pin 42 fully engaged with the corresponding cavity or channel 49 in the punch tip or punch insert (e.g., in tang 44), pin 42 is in the installed or closed and locked position. When pin 42 is manipulated to extend from the outer circumference of punch body 12 at one end, with the other end radially outside cavity or channel 49 in punch tip 14 and positioned to engage with ball plunger 45 via a groove or similar feature, pin 42 is considered to be in the open or assembly (unlocked) position. This mechanism allows employment of a relatively small punch tip 14, which can be easily installed onto or removed from punch body 12 manually, without the need for specialized tools, and without necessarily requiring tools of any kind.
As shown in
To avoid damage or deformation of coupling pin 42 during the punch stroke, the compressive loading may be directed to the contact surfaces defined between punch body 12 and punch tip 14, for example by maintaining clearance between the coupling pin and pin cavity, or other relevant coupling structures. Thus, the load may be directed to the interface between the top surface of the flange or ledge 47, extending circumferentially about stem 44 on punch tip 14, and on the bottom surface of punch body 12, extending around the axial cavity in which stem 44 is engaged. Note that there may be some gaps along the load-bearing surfaces (e.g., due to the alignment features), but these are typically small in relation to the load-bearing surface area, in order to maintain the strength and integrity of punch device 10.
There is also loading during the stripping operation, due to punch point 15 sticking in the sheet when punch tip 14 is retracted due to the material around the circumference of the punch hole tending to grip punch point 15. This results in a tension load T on punch body 12 and sliding pin connector 42, rather than a compressive load and the magnitude of tension load T (upward arrows) during the stripping operation is typically several times less than that of compressive loading C during the punch stroke. Nonetheless, the stripping loads can be extensive, and the corresponding tension forces must be transferred through the coupling between punch tip stem 44 and pin 42, as shown in
To address these very different punching and stripping loads, punch 10 must provide a combination of compressive loading surfaces defined across punch axis A, along the contact interface between punch body 12 and punch tip 14, and a coupling mechanism with sufficient strength to withstand the smaller but still very substantial tension loads introduced along axis A, when punch point 15 is withdrawn from the sheet metal workpiece. In this particular embodiment, this means that coupling pin 42 and punch tip stem 44 are configured to maintain the coupling between punch body 12 and punch tip 14 under a tension loading on the order of at least a few tons, or more. The coupling and load-transfer structures should also be configured to withstand these different compression and tension loads over extended period of operation, including many thousands or even millions of punch cycles, executed over weeks and months of continuous operation, and years of accumulated service time.
In additional embodiments, pin 42 can be resiliently held in place with one or more rubber or polymer rings 70 (e.g., O-rings or other resilient members), disposed in radial grooves extending circumferentially about pin 42. Additional grooves can be added to the axial holes in punch body 12 (or to the radial grooves or channels extending through stem 72, and/or the outer walls of punch tip 14), in order to provide additional resistance for retaining pin 42 by engaging resilient ring members 70 in the open and closed positions, respectively.
As shown in
In additional embodiments, rather than providing an axial alignment slot 65 in punch tip 14 and an axially located alignment pin 64 in punch body 12, as described above, the configuration could also be substantially reversed in order to have an axially located pin alignment 64 in punch tip 14 and a precision alignment slot 65 in punch body 12 (see
As shown in
For example, head 43 may have a greater outer radius R than the longitudinal body (center portion 42C) of pin 42 (and the corresponding longitudinal cavity extending through punch body 12 and punch tip stem 44). If installed correctly, this configuration prevents the operator from pushing pin 42 too far into punch body 12, by seating head 43 of pin 42 in the correct stop position inside a fitted pocket 61 recessed within the outer diameter of punch body 12, as shown in Detail D (opposite relief feature 60, as configured for manual access to the opposite end of pin 42). A groove 62 can also be provided to retain pin 42 in position within the fitted pocket, e.g., by engagement with ball plunger 45 or other biasing component.
One or more grooves 86 may also be formed around punch tip 14, in an optional geometry. Punch body 12 may also be provided with additional features such as a relief cavity 60 and an alignment key 68, as described above.
In any of the embodiments and examples herein, the sliding pin can be resiliently urged into its open or unlocked and closed or locked positions with one or more rubber rings fitting into radial grooves.
The end geometries of the punch tip and punch body can also be reversed, such that the punch body has a protruding axial tang or stem and the punch tip has an axial cavity to receive the punch body tang.
Rather than angular keying being achieved via a key in the side of the punch body, in combination with a pin and slot connection to the punch tip, a punch key which keys to the punch guide body or bushing could be put directly into the punch tip.
Rather than providing a key alignment slot in the punch tip and an axially located pin in the punch body, the configuration could be reversed to have an axially located pin in the punch tip and a precision angular alignment slot in the punch body.
Instead of using an alignment pin and slot to orient the punch tip with respect to the punch body, the fit of the coupling pin could provide sufficiently precise angular orientation without additional keying means.
The following examples are provided to illustrate the potential scope of various embodiments of the invention. Each of these examples may be provided in any combination with any of the other examples and embodiments described herein.
1. A removable lower portion punch tip can be provided for punch press tooling, held into a punch body upper portion by a manually operable slide-in or sliding pin, which is pushed or pulled into either an open position for installation or removal of a punch tip, or a locked position for secured operation in a punch press. The punch body has a lower portion with an axial cavity, and the punch tip has an upper portion with an axial stem or protrusion with fits into the cavity in the punch body.
The punch tip stem has a radial cavity with geometry which corresponds to the geometry of the pin, so that in one radial position the pin is not engaged with the radial cavity of the punch tip, and the punch tip can be removed from the assembly. In another radial position the pin is fully engaged with the radial cavity of the punch tip, the punch tip cannot be removed or inserted from the punch body but is secured for operation in a punch press, where the assembly of the punch body and punch tip can slidably operate in a punch guide or bushing as a hybrid replacement punch.
2. The punch tip can have an upper portion which is an axial protrusion configured to engage into a pocket in the lower portion of the punch body for axial affixing thereto.
3. The pin can alternately be held resiliently in an open or locked position with a ball plunger or rubber rings and grooves, preventing unwanted release of the punch tip during handling outside of the punching machine, punch guide, or bushing.
4. The task or function of the ball plunger could be achieved with a piece of urethane or other similar component, which presents sufficient resilient properties for urging and retaining the pin into alternate open or unlocked and engaged or locked positions.
5. The pin can have sufficient length to prevent disengagement from the punch tip when the assembly is installed in a punch guide or bushing, assuring the pin stays securely in the locked position while in operation within the punch guide or bushing.
6. The pin can be alternately held in an open or locked position with frictional means, preventing unwanted movement in a radial direction on the punch body.
7. The punch body can have a lower stem, tang or shank and the punch tip can have the cavity to receive the stem, tang or shank of the punch body.
8. The pin can have a head on one end and the punch body or driver r can have a fitted pocket for the head to prevent pushing the pin through the driver in the wrong direction.
Elastic Bumper Member
Bumper member 80 can be formed of an elastic material such as a plastic or rubberized polymer, or provided as a resilient (e.g., spring) bias element, which is positioned to dampen or reduce relative motion between punch body/driver 12 and removable punch tip or insert 14. Bumper member 80 is configured to provide sufficient resilient bias to reduce “jiggle,” shaking, wiggling, and other motion of punch insert 14 with respect to punch driver 12, e.g., due to vibration or during assembly of the punch assembly or apparatus 10. At the same time, bumper member 80 can also be substantially isolated from the punch and stripping load paths, as described above.
As shown in
Bumpers 80, 82 and 84 may be formed as an elongate, axially projecting member, a ball plunger, and an elastic ring (or resilient disk), respectively, each positioned between the upper surface of punch insert 14, where stem 44 is received within the axial cavity in the bottom of the punch driver (or punch body) 12. For example, bumper member 84 can be provided in the form of an O-ring positioned about axis A of punch assembly 10, as shown in
Lubrication
Punch body 12 of
In the alternate example of
As shown in
Alternatively, one or more spiral grooves 86 may also be formed around the punch tip or insert 14, in an optional geometry. In additional embodiments, one or more horizontal or radial lubrication channels or ports 92 may be provided for internal lubricant flow, e.g., connecting internal (axial) channel 90 to the external (OD) vertical grooves 88, and/or spiral grooves 86.
As shown in
The access window configuration
According to the various examples and embodiments herein, a punch assembly may comprise: a punch body configured for a punching operation in a punch press, the punch body having an axial cavity defined along an axis; a punch tip having a first end configured for the punching operation and a second end comprising a punch tip stem configured for selective engagement within the axial cavity in the punch body; and a coupling pin disposed transverse to the axis of the punch body, the coupling pin comprising a first end, a second end, and a middle portion between the first and second ends; wherein the first end of the coupling pin is configured for manipulation of the coupling pin transverse to the axis of the punch body to selectively engage and disengage the punch tip stem.
The punch assembly may comprise first and second openings in the punch body configured for selective engagement and disengagement with the first and second ends of the coupling pin, and further comprising a lateral cavity in the punch tip stem configured for selective engagement and disengagement with the middle portion of the coupling pin. The coupling pin may have a first position with the first and second ends engaged with the punch body and the middle portion engaged within the punch tip stem, and a second position with the middle portion disengaged from the punch tip stem.
The punch assembly may comprise a bias member configured to selectively bias the coupling pin in the first and second positions, wherein the bias member comprises a ball plunger, resilient O-ring, or frictional member. The punch assembly may further comprise at least one groove or detent on the coupling pin configured to selectively engage and disengage the bias member.
The punch assembly may comprise a cap or stop configured to seat the second end of the coupling pin against the punch body, wherein manipulation of the coupling pin to disengage the punch tip stem is allowed in a first direction transverse to the axis of the punch body and prevented in a second direction transverse to the axis of the punch body. The coupling pin may have sufficient length to prevent disengagement from the punch tip stem when the punch body is disposed within a punch guide or bushing of the punch press, the coupling pin being constrained substantially within an outer diameter of the punch body by the punch guide or bushing.
The punch assembly may comprise: a punch guide or bushing disposed about the punch body; and at least one access window in the bushing or punch guide, the access window configured for manipulation of the coupling pin to selectively engage and disengage the middle portion with a lateral channel in the punch tip stem, while the punch body is disposed within the bushing or punch guide. At least two of the access windows may be provided for access to the first and second ends of the coupling pin, respectively. Each access window may be configured to accommodate axial adjustment of the punch assembly within the bushing or punch guide, while maintaining access to the coupling pin for manipulation thereof.
The punch assembly may comprise an alignment pin disposed in one of the punch tip and the punch body, the alignment pin configured for angular alignment of the punch tip about the axis of the punch body by engagement with a complementary alignment slot disposed in another of the punch tip and punch body. The alignment pin may be configured for axial engagement with the alignment slot when the punch tip stem is disposed within the axial cavity of the punch body. The alignment pin may be configured for lateral or radial engagement within the alignment slot, transverse to the axis of the punch body. Alternatively, the coupling pin may be configured for angular orientation of the punch tip with respect to the punch body by lateral engagement of the middle portion of the coupling pin within a precision receiving slot defined in the punch tip stem, absent other pin and slot alignment features configured for relative angular alignment of the punch tip with respect to the punch body.
The punch assembly may comprise a flange on the punch tip, the flange configured to transfer a compressive load from a bottom surface of the punch body to a working end of the punch tip during the punching operation in the punch press, wherein the coupling pin is substantially isolated from the compressive load. The punch assembly may further comprise an elastic member disposed in biasing relationship between the punch body and the punch tip when the punch tip stem is engaged in the axial cavity. The elastic member may comprise one or more of an elastic bumper member, an O-ring, a spring and a ball plunger configured to reduce relative motion of the punch tip when engaged with the punch body. The one or more grooves or detents may define an asymmetric geometry at the first and second ends of the coupling pin, the asymmetric geometry adapted for increasing a force required to remove the coupling pin, as compared to manipulating the coupling pin between the first and second positions.
According to additional examples and embodiments herein, a punch system may comprise: a punch body having an axis; a punch tip having a first end configured for a punching operation and a second end configured for selective engagement and disengagement with the punch body along the axis; and a coupling pin disposed transverse to the axis, the coupling pin comprising a first end, a second end, and a middle portion therebetween, the first and second ends configured for manipulation of the coupling pin transverse to the axis of the punch body to selectively engage and disengage the middle portion with the punch body and the punch tip; wherein the coupling pin has a first position in which the punch tip and punch body are engaged with the first and second ends of the coupling pin disposed within an outer diameter thereof, and a second position in which the punch tip and punch body are disengaged with at least one of the first and second ends of the coupling pin disposed outside the outer diameter.
The punch system may comprise an axial cavity in the punch body and a stem extending from the second end of the punch tip, the stem having a lateral cavity configured for selective engagement and disengagement with the middle portion of the coupling pin when disposed within the axial cavity of the punch body. Alternatively, the punch system may comprise an axial cavity in the second end of the punch tip and a stem extending from the punch body, the stem having a lateral cavity configured for selective engagement and disengagement with the middle portion of the coupling pin when disposed within the axial cavity of the punch tip.
The punch system may comprise a bias member configured to selectively engage and disengage one or more grooves or detents in the coupling pin, in the first and second positions thereof. The punch system may further comprise an alignment slot disposed in one of the punch body and the punch tip and a complementary alignment pin disposed in another of the punch body and the punch tip, the alignment slot and pin configured for axial or radial engagement to maintain precision orientation of the punch tip with respect to the punch body. The alignment pin may be configured for radial engagement with a lateral alignment slot extending through the punch tip and the punch body, or for radial engagement with a top end of a stem extending from the second end of the punch tip into an axial cavity in the punch body.
The punch system may comprise a punch guide disposed about the punch body in a turret press apparatus, the punch guide having at least one access window configured for manipulation of the coupling pin between the first and second positions when the punch body is disposed within the punch guide. The punch system may also comprise a bushing disposed about the punch body in a rail-type press apparatus. An ejector may be configured to urge the punch tip from the punch body along the axis when the coupling pin is manipulated from the first position to the second position.
A pocket may be disposed in the punch body or punch tip proximate the first end of the coupling pin, wherein the pocket defines a straight or curved recess adapted for manual access to push or pull the first end of the coupling pin transverse to the axis of the punch body. Such straight or curved recesses may be defined in opposing positions on an outer diameter of the punch body or punch tip, the recesses adapted for manual access to push or pull each of the first and second ends of the coupling pin transverse to the axis of the punch body.
A method for any of the above punch assemblies and systems may comprise: engaging a punch tip with a punch body along an axis thereof, the punch tip configured for a punching operation in combination with the punch body; manipulating a coupling pin transverse to the axis into a first position in which the coupling pin engages a stem on the punch tip or punch body, wherein the coupling pin is disposed within an outer diameter thereof, in the first position; manipulating the coupling pin transverse to the axis into a second position in which the coupling pin is disengaged from the stem, wherein at least a portion of the coupling pin is disposed outside the outer diameter, in the second position; and disengaging the punch tip from the punch body along the axis.
Manipulating the coupling pin into the second position may comprise pushing the first end of the coupling pin into a curved or straight recess defined in an outer diameter of the punch tip or punch body; grabbing a second end of the coupling pin extending outside the outer diameter opposite the recess; and pulling the second end of the coupling pin transverse to the axis of the punch body. The method may also comprise installing the punch body in a punch guide or bushing of a punch press apparatus, and manipulating the coupling pin between the first and second positions via at least one access window provided in the punch guide or bushing.
While this invention has been described with reference to exemplary embodiments, it will be understood by those skilled in the art that various changes can be made and equivalents may be substituted without departing from the spirit and scope thereof. Modifications may also be made to adapt the teachings of the invention to particular problems, technologies, materials, applications and materials, without departing from the essential scope thereof. Thus, the invention is not limited to the particular examples that are disclosed herein, but encompasses all embodiments falling within the scope of the appended claims.
This application claims priority to U.S. Provisional Application No. 62/113,778, filed Feb. 9, 2015, entitled PUNCH ASSEMBLY WITH REPLACEABLE PUNCH TIP, which is incorporated by reference herein, in the entirety and for all purposes. This application is related to copending U.S. patent application Ser. No. 14/985,863, entitled PUNCH ASSEMBLY WITH REPLACEABLE PUNCH TIP, filed Dec. 31, 2015, which is incorporated by reference herein, in the entirety and for all purposes.
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