1. Field of the Invention
This invention pertains to two-piece buttons having coplanar shell flanges, and also to apparatus for manufacturing such buttons.
2. Description of the Prior Art
The word “button” traditionally has included three different types of items: upholstery buttons, apparel buttons, and novelty buttons. The present invention is directed only to novelty buttons, and the word “buttons” as used herein means novelty buttons.
Buttons and machines for manufacturing them are well known and have been in widespread use for many years. Buttons are commercially available in numerous sizes and in several shapes such as round, rectangular, and oval. Buttons may be of one-piece or two-piece construction. In a one-piece button, a flexible graphic is overlaid on a shell. The edge of the graphic is captured between the main portion of a shell wall and a margin of the shell wall that is bent outward and upward to hold the edge or the graphic. A wide variety of one-piece buttons are marketed under the trademark LarLuLine.
Two-piece buttons are generally considered to be of superior quality to one-piece buttons. Referring to
The flat back 39 has a periphery 41. The skirt 15 of the laminate 7 is tucked around the shell wall free edge 17 and around the flat back periphery 41. Then the shell wall 19 is crimped to become frusto-conical in shape as shown at reference numeral 19A and to capture the laminate between the shell 3 and the flat back. My prior machines as disclosed in U.S. Pat. Nos. 6,038,944 and 6,393,686 are capable of efficiently manufacturing the flat back buttons 1.
Turning to
The round button 59 with the coplanar flange 71 is sometimes referred to as a button medallion. That term is used, for instance, in my prior U.S. Pat. Nos. 6,038,944 and 6,393,686 to identify the button 59. Those patents also describe in detail a manual machine and methods for manufacturing round buttons 59 with the coplanar flanges 71. Specifically, my two prior patents disclose a manual machine in which a ram cooperates with a pickup die and a crimp die in a three-stroke process to manufacture the buttons 59 with the coplanar flanges 71. That is, it was necessary to press the button 1 a third time to complete the coplanar button 59.
Buttons with flat backs are not limited to being round in shape. Looking at
Because of the angular margins 51A, the prior rectangular buttons 43 did not have a finished appearance. In addition, normal processing tolerances sometimes allowed the angular shell margins 51A to inadequately secure the back and graphic to the shell. As a result, the buttons had a tendency to come apart during handling and usage. The angular margins were also prone to snag on clothing and other objects. Some prior rectangular buttons had margins that were more closely parallel to the flat back 49 than is shown in
To achieve a secure assembly of rectangular buttons with straight line elements instead of angled margins, it is necessary to fully form the flanges into a coplanar configuration. When a round button 1 or rectangular button 43 is further processed to form buttons with flanges that are coplanar and parallel with the flat backs 39 and 49, respectively, a secure assembly is created that engages its ultimate use more desirably. That is, it is more readily adhered to a surface such as a plaque by adhesive or attached to a refrigerator or file cabinet by means of a magnet or simply worn on a garment by means of a safety pin.
A prior rectangular button 73 with coplanar shell flanges is shown in
Although my prior manual machines for manufacturing round buttons have met with success, it is desirable to make them even more productive, such as by reducing the number of strokes required to manufacture a button.
Thus, it is desirable to both increase the productivity of button making machines and to increase the variety of readily available buttons.
In accordance with the present invention, a machine for making round and rectangular buttons having coplanar shell flanges is provided. This is accomplished by apparatus that includes spring cells in a crimp die that enable the machine to operate in a two-stroke process.
The machine of the invention has a framework that includes a base and a pair of columns that support a crown. A ram is guided in and supported by the framework crown for reciprocating along a ram axis. Ram reciprocation is achieved by means of a handle pivotally connected to the framework crown and acting against rollers on the ram. The ram includes a carrier and a plug. The plug has a concave working face opposite the carrier. A ram frame is slidable on the plug parallel to the ram axis. Either the ram frame or the carrier has one or more ram pins that extend parallel to the ram axis. The other of the ram frame or carrier has clearance holes that correspond to the ram pins. One or more springs bias the ram upwardly against the frame crown.
A die table is rotatably indexable on the framework base between two positions. When the die table is in the first position, a pickup die is under the ram. When the die table is in the second position, a crimp die on the die table is under the ram. Indexing the die table also shifts the ram between a pickup mode and a crimp mode of operation. To shift the ram between the pickup and crimp modes, the machine comprises an actuator that acts on the ram in response to indexing the die table. The actuator comprises a shifter post upstanding from the die table and a pair of fingers on the ram. When the die table is indexed, the shifter post travels in an arc to contact one or the other of the fingers. Specifically, when the die table is indexed to position the pickup die under the ram, the shifter post contacts the first finger to shift the ram to the pickup mode. When the die table is indexed to position the crimp die under the ram, the shifter post contacts the second finger to shift the ram to the crimp mode. When the ram is in the pickup mode, the ram pins are misaligned with the corresponding clearance holes. When the ram is in the crimp mode, the ram pins and clearance holes are aligned.
The pickup die has a pickup die pedestal attached to the die table. An outer frame is slidable over the pickup die pedestal. The outer frame has a top surface with a recess in it. One or more pickup die resilient members bias the outer frame away from the die table and against a shoulder on the pickup die pedestal.
The crimp die has a crimp die pedestal attached to the die table. A crimp die outer frame has an inner surface that is slidable over the crimp die pedestal. The outer frame has a bevel between a recess and the inner surface. One or more first crimp die resilient members bias the crimp die outer frame away from the die table and into abutment with the crimp die pedestal. There also are one or more second crimp die resilient members between the crimp die outer frame and the die table.
To use the machine of the present invention to manufacture a round button, the ram, crimp, and pickup dies are round, and the actuator fingers are on the ram frame. The handle is pivoted to a ready position. In that position, the ram springs bias the ram against the frame crown. A round button shell is placed on the pickup die pedestal. A laminate that is to be assembled to the shell is placed in the recess of the pickup die outer frame above the shell. The pickup die outer frame centers the laminate and shell. The die table is indexed to position the pickup die under the ram and rotate the ram frame such that the ram pins misalign with the clearance holes, thereby shifting the ram to the pickup mode. The handle is pivoted in a pickup stroke and advances the carrier, plug, and ram frame together until the frame contacts the laminate on the pickup die outer frame.
Further pivoting of the handle is resisted by the pickup die resilient members. However, further pivoting of the handle causes the misaligned ram pins to push the ram frame and overcome the resistance of the pickup die resilient members such that the pickup die outer frame slides along the pickup die pedestal and bends the laminate over the shell wall.
At the end of the pickup stroke, the laminate is fully bent over the shell and is transferred to and is held, along with the shell, in the ram frame. There is a skirt of the laminate that overhangs the free edge of the shell. Reverse pivoting of the handle to its ready position causes the ram to retract, with the shell and laminate held in the ram frame.
A flat back is placed on the crimp die pedestal. The die table is indexed to position the crimp die under the ram. Indexing the die table causes the actuator shifter post to contact the other finger and rotate the ram frame to align the ram pins with the clearance holes, thereby shifting the ram to the crimp mode.
The handle is pivoted in a crimp stroke until the ram frame contacts the crimp die outer frame. Because of the upward bias of the crimp die resilient members, the ram frame and the crimp die outer frame remain stationary under further pivoting of the handle. That pivoting of the handle does advance the carrier and plug, however, because the ram pins enter the corresponding clearance holes, and the plug slides inside the frame. That action pushes the shell and laminate part way out of the ram frame and causes the laminate skirt to contact the bevel in the crimp die outer frame. The skirt bends inwardly over and unto the top of the flat back. That action continues until the laminate next to the shell wall free edge contacts the bevel in the pickup die outer frame.
Further pivoting of the handles causes the carrier to contact the ram frame. Because of the resistance of the shell wall to bending, further advancement of the ram slides the crimp die outer frame against the first crimp die resilient members. That action causes the shell and laminate to more closely approach the flat back on the crimp die pedestal and further bend the laminate skirt over the flat back. Ultimately, the crimp die first and second resilient members combine to produce a force that resists further movement of the crimp die outer frame. Continued handle pivoting then forces a margin of the shell wall to bend inwardly against the bevel on the crimp die outer frame and under the flat back, thereby capturing the laminate skirt between the shell wall bent-over margin and the flat back periphery. At that point, the bent shell margin is between the flat back and a relief surface of the crimp die pedestal and makes an acute angle with the flat back. An additional small amount of handle pivoting overcomes the combined force of the first and second crimp die resilient members and forces the crimp die outer frame downwardly a small distance enough to allow the ram plug to bend the shell margins against the crimp die pedestal into flanges that are flat and coplanar all around the shell and complete the button assembly. The handle is reversed to its ready position, thereby exposing the completed button for removal.
It is an important feature of the invention that both round and rectangular buttons with coplanar shell flanges are manufacturable on the same basic machine. To make the rectangular button of the invention, the ram plug and frame are rectangular in shape, as are the pickup die and crimp die. The actuator for the rectangular machine is composed of the shifter post on the die table. The carrier on the rectangular machine is in two parts: a guide bar, and a shifter cage that is rotatable on the guide bar. The ram pins and clearance holes may be in either the shifter cage or the outer ring. Indexing the die table to position the pickup die under the ram causes the actuator to shift the ram to the pickup mode of operation by contacting the shifter post with one of two fingers on the shifter cage and rotating the cage on the guide bar to misalign the clearance holes with the ram pins. Indexing the die table to position the crimp die under the ram causes the shifter post to contact the other shifter cage finger and rotate the cage to align the clearance holes with the ram pins. The same two-stroke operation is used whether the machine is used for making round or rectangular buttons.
The method and apparatus of the invention, using first and second resilient members on the crimp die, thus manufactures buttons with coplanar flanges on a production bases. Only two ram strokes are required to manufacture the buttons, even though both round and rectangular buttons are manufactured using the same basic machine and principles of operation.
Other advantages, benefits, and features of the present invention will become apparent to those skilled in the art upon reading the detailed description of the invention.
Although the disclosure hereof is detailed and exact to enable those skilled in the art to practice the invention, the physical embodiments herein disclosed merely exemplify the invention, which may be embodied in other specific structure. The scope of the invention is defined in the claims appended hereto.
General
To manufacture the rectangular button 73 with the coplanar shell flanges 91, the present invention includes a two-stroke manual machine 95,
Pivotally connected to the crown 105 is a handle 111. In the illustrated construction, the handle 111 has a pair of plates 113 that straddle the crown and that are pivotally connected to it by a pin 115. The plates 113 terminate in a hand grip 117. The plates have respective cam surfaces 118 opposite the grip 117. As shown in
Ram
A ram 121 is supported and guided by the crown 105 for reciprocating along a vertical ram axis 123. The ram 121 includes a carrier 125 and a ram die 127. For the particular machine 95 illustrated, the carrier 125 is made with a guide bar 129 and a shifter cage 131. The guide bar 129 has a pair of screws 141 threaded into it. The screws 141 pass through corresponding holes in the frame crown 105. Ram springs 143 between the heads 145 of the screws 141 and the crown bias the ram upwardly against the underside 147 of the crown. To guide the ram 121 during reciprocation, a pair of guide pins 149 are pressed into the guide bar 129. The guide pins 149 are slidable through associated holes in the crown.
There are a pair of steps 150 on the opposite ends of the guide bar 129 such that the guide bar has a foot section 155. Projecting oppositely from the ram plate guide bar 129 are a pair of rollers 151. The rollers 151 are so located as to be contactable by the cam surfaces 118 of the handle 111 when the handle is pivoted away from the ready position.
The ram die 127 is composed of a rectangular plug 133, a four-sided ram frame 135, and a pair of support blocks 137. One surface 154 of the ram plug 133 is immovably fastened to the foot section 155 of the guide bar 129 by a screw 153 and alignment elements such as roll pins, not illustrated in the drawings. A working surface 167 of the plug opposite the surface 154 has a rectangular peripheral lip 169 with a concave inner surface 171.
The ram frame 135 is free to slide on the plug 133 through a distance D in the directions of the ram axis 123. Sliding in the upward direction is limited by contact by the frame top surface 172 with the shifter cage 131. Sliding in the downward direction is limited by overhangs 174 of the support blocks 137, which are joined to the upper surface 172 of the ram frame by fasteners 175. The frame has a bottom surface 177, four inner surfaces 179, and an outer surface 181. As best shown in
The carrier shifter cage 131 is supported on the ram plug surface 154 and is free to rotate on it. For that purpose, the shifter cage has a center opening 152 that fits loosely over the guide bar foot section 155. A pair of center lugs 157 in the shifter cage opening 152 loosely straddle the guide bar foot section. One end 159 of the shifter cage is close to the frame end column 103. The other end 161 of the shifter cage has a cutout 163 that straddles the frame center column 101. The shifter cage has holes 164 through it that are at the same distance from the ram axis 123 as the pins 184 in the ram frame 135.
Pickup Die and Crimp Die
Rotatably supported on the frame base 99 is a die table 185. There is a hole in the die table 185 that fits over the frame center column 101. In the preferred embodiment, the die table is indexible through 180 degrees about the center column. The opposite ends of the die table are formed with first and second cutouts 187 and 189, respectively. The cutouts 187 and 189 are located such that they are contactable with the frame end column 103.
Mounted to the opposite ends of the die table 185 are a pickup die 197 and a crimp die 199. The pickup die 197 comprises a pedestal 201 fastened to the die table by one or more screws 203 and alignment elements not shown. The pickup die pedestal 201 has a flat top surface 205 and four external shoulders 207. Between the top surface 205 and the external shoulders 207 are four side surfaces 208, each having a slight upward draft. An outer frame 209 is slidable over the pedestal. The outer frame 209 is biased away from the die table such that internal shoulders 213 normally contact the pedestal external shoulders 207. For that purpose, one or more resilient members are interposed between the outer frame and the die table. For example, a ring of resilient polyurethane material may surround the outer frame and contact the die table. As shown, several pickup springs 211 are used as the resilient members. The outer frame has a recess 215 in the top surface with an internal surface 216, and another internal surface 218.
The crimp die 199 is composed of a crimp die pedestal 217 having a top surface 219. Multiple fasteners including a screw 221 hold the crimp die pedestal 217 to the die table 185. The crimp die pedestal has an external shoulder 223. A relief surface 220 is parallel to and spaced from the top surface 219. An outer frame 225 is slidable over the crimp die pedestal. One or more first crimp die resilient members bias the outer frame 225 such that an internal shoulder 227 thereof contacts the pedestal external shoulder 223. As illustrated, the first crimp die resilient members are crimp die springs 226. However, other resilient members, such as a ring of resilient polyurethane material, may be used instead of the springs 226. The crimp die outer frame has a top surface 228 with a recess 229. A bevel 231 is between the recess 229 and an inner surface 224. The bevel 231 may be flat, but I prefer a concave scalloped shape as is illustrated. The crimp die further has one or more second resilient members between the die table and the crimp die outer frame. For example, the second resilient member may be a second ring of resilient polyurethane material. According to the aspect of the invention that is illustrated, the second resilient members are a number of spring cells 232. The spring cells 232 are received in associated bores in the bottom of the crimp die outer frame and are held there by a plate 234 and fasteners 236. Each spring cell has a very stiff spring 238 and a plunger 241.
Actuator
The final major component of the machine 95 is an actuator 235. In the machine with the rectangular ram die 127, pickup die 197, and crimp die 199, the actuator 235 is comprised of a pair of fingers 165 and 166 on the shifter cage 131. The fingers 165 and 166 are on opposite sides of the cutout 163. The actuator further has a vertical shifter post 191 joined to the die table 185. As shown, the shifter post 191 includes a pad 193 that is held to the die table by a screw 195. The shifter post 191 is long enough to reach between the fingers 165 and 166 on the shifter cage 131 when the ram 121 is retracted against the framework crown 105.
Operation
The operation of the machine 95 of the present invention to manufacture a rectangular flat back button 73 begins by placing a shell 75 on the pickup die pedestal 201. See
The handle 111 is pivoted in the direction of arrow 237 in a pickup stroke. Doing so causes the cams 118 on the handle plates 113 to push against the ram rollers 151 and advance the ram 121. The carrier 125, plug 133, and ram frame 135 advance together until the frame bottom surface 177 contacts the laminate 85 in the pickup die 197. The handle continues to pivot, which causes further advancement of the carrier and the plug, but the springs 211 of the pickup die outer frame 209 resist further advancement of the ram frame. However, the carrier shifter cage 131 bears against the pins 184 in the ram frame, so the force from the handle is transferred through the laminate to the pickup die outer frame. The force applied to the handle is sufficient to compress the pickup die springs and force the pickup die outer frame downwardly toward the die table 185. That action takes up the clearance between the laminate and the shell 75 (
At the end of the pickup stroke, the grooves 212 in the ram frame inner surfaces 179 are located opposite the shell bent margins 79. The inherent elasticity of the shell material causes the bent margins and adjacent portions of laminate 85 to enter and press against the grooves such that the bent shell and laminate transfer to the ram. The handle 111 is pivoted in the reverse direction 239. The ram springs 143 urge the ram 121 upwardly against the framework crown 105. As the ram retracts, the bent laminate 85 and shell 75 remain inside the ram frame inner surfaces 179. The draft of the pickup die pedestal side surfaces 208 assist in the transfer of the shell and laminate to the ram.
A flat back 81 is placed on the crimp die pedestal 217. The die table 185 is then indexed in the direction of arrow 241,
The crimp stroke begins as shown in
Advancement of the ram plug 133 continues in a second movement in which the free edges 77 of the shell 75 approach the bevel 231 and becomes separated from it only by the laminate 85. With the plug 133 pushing on the shell and laminate, resistance to bending of the metal shell forces the crimp die outer frame 225 downwardly against the resistance of the springs 226. As a result, the shell and laminate approach the flat back 81. The laminate skirt 90 tucks between the shell margins 79 and the flat back periphery 83. The crimp die outer frame continues to move until the plungers 241 of the spring cells 232 abut the die table 185,
The stiffness of the spring cell springs 238 combine with the stiffness of the crimp die springs 226 to prevent further movement of the crimp die outer frame 225, so continued pivoting of the handle 111 and advancement of the ram plug 133 is not accompanied by any movement of the crimp die outer frame or the ram frame 135. Consequently, the ram plug 133 slides further inside the ram frame and further pushes the shell 75 and laminate 85 out of the ram frame. The force applied to the handle is sufficient, because of the scalloped bevel 231, to bend the shell margins 79 into angular flanges 243. The continuous surface between the bevel and the pedestal relief surface 220 guides the shell angular flanges 243 and laminate skirt 90 into a notch 244 under the flat back 81 as the ram plug approaches the crimp die pedestal 281, effectively forming the button slightly beyond that illustrated in
To complete the manufacture of the rectangular button 73, a final force is applied to the machine handle 111,
Round Button Machine
Further in accordance with the present invention, round buttons 59 with coplanar shell flanges 71 are also manufactured in a two-stroke process. Turning to
The ram 249 is composed of a carrier 257 with rollers 258 that are contactable by cams 118′ on the handle 111′. The carrier 257 is guided for reciprocation along the ram axis 123′ by screws 141′. Ram springs 143′ cooperate with the screws 141′ to bias the carrier against the crown 105′. The carrier has a pair of holes 164′ that are parallel to the ram axis 123′.
The ram 249 further comprises a cylindrical plug 259 fastened to the carrier 257. The plug 259 has a working surface 167′ with a circular lip 169′ having a concave surface 171′. The plug has an external shoulder 261.
Slidable and rotatable over the ram plug 259 is an annular ram frame 263. The ram frame 263 has an inner surface 307. In the inner surface 307 may be annular groove similar to the grooves 212 in the ram frame 135 of the rectangular machine 95 described previously. Sliding of the frame 263 in the downward direction is limited by an internal shoulder 265 that contacts the plug external shoulder 261. Alternately, sliding of the frame on the plug may be limited by one or more support blocks, not shown but joined to the frame 263 with overhangs that contact the plug in the same fashion as the support blocks 237 of the machine 95 described previously. A pair of pins 184′ are pressed in the frame top surface 172′. The pins 184′ are at the same distance from the ram axis 123′ as the holes 164′ in the carrier 257. The frame is able to slide on the plug 259 a distance D, which is limited in the upward direction by contact of the frame top surface 172′ with the carrier 257.
Actuator
The machine 247 of the invention further comprises an actuator 267. In the particular machine illustrated, the actuator 267 is a shifter post 191′ and pad 193′ upstanding from the die table 185′ and fastened to it by a screw 195′. The actuator also includes a pair of fingers 269 and 271 that jut from the ram frame 263. The fingers 269 and 271 are on opposite sides of the framework center column 101′. Indexing the die table 185′ causes the shifter post 191′ to travel in an arc about the framework center column 101′ and contact one or other of the fingers. Although not illustrated, the pins 184′ may be in the carrier 257 instead of in the ram frame 263. In that case, the holes 164′ would be in the ram frame.
Pickup Die And Crimp Die
The pickup die 251 of the machine 247 is comprised of a pickup die pedestal 273 fastened to the die table 185′. The pickup die pedestal 273 has a round side surface 274 with a slight upward draft. An outer frame 275 is slidable over the pickup die pedestal 273. Pickup die springs 277 or other resilient members bias the outer frame 275 against an external shoulder 276 on the pickup die pedestal. There is a recess 279 in the pickup die outer frame top surface 278, and an inner surface 280 next to the recess.
A crimp die 253 has a crimp die pedestal 281 with a top surface 284 and an external shoulder 285. A crimp die outer frame 287 is biased by resilient elements such as crimp die springs 289 such that an internal shoulder 291 contacts the crimp die pedestal external shoulder 285. The crimp die outer frame 287 has a recess 293 and a bevel 295 between the recess and an inner diameter 297. The crimp die outer frame further has a number of spring cells 299, each with a stiff spring 301 and a plunger 303.
Operation
The operation of the machine 247 to manufacture round buttons 59 is very similar to the operation of the machine 95 for manufacturing rectangular buttons 73. A shell 63 is placed on the pickup die pedestal 273. The shell is guided laterally by the pickup die outer frame inner surface 280 or by the pedestal side surface 274. A laminate 67 is placed in the recess 279 of the pickup die outer frame 275. The die table 185′ is indexed in the direction of arrow 233′ to position the pickup die 251 under the ram 249. Indexing the die table 185′ causes the shifter post 191′ of the actuator 267 to contact the finger 271 and rotate the ram frame 263 on the plug 259. When that occurs, the pins 184′ in the frame 263 become misaligned with the clearance holes 164′ in the carrier 257, FIG, 24.
The handle 111′ is pivoted in the direction of arrow 237′ in a pickup stroke. Doing so causes the handle cams 118′ to push against the ram rollers 258 and advance the ram 249. The carrier 257, plug 259, and ram frame 263 advance together until the frame bottom surface 304 contacts the laminate 67 in the pickup die 251. The handle continues to pivot, which causes further advancement of the carrier 257 and the plug 259. The springs 277 of the pickup die outer frame 275 resist further advancement of the ram frame 263. However, the carrier bears against the pins 184′ in the ram frame, so the force from the handle is transferred to the pickup die outer frame 275. The force applied to the handle is sufficient to compress the pickup die springs and force the pickup die outer frame downwardly toward the die table 185′. That action takes up the clearance between the laminate and the shell 63. Further ram advancement causes the ram frame bottom surface 304 and inner surface 307 to progressively bend the laminate 67 over the shell 63. A wrinkled skirt overhangs the shell free edge 69.
At the end of the pickup stroke, the internal groove, if present, in the inner surface 307 of the ram frame 263 is located opposite the shell margin 61. The shell and laminate transfer to the ram 249. The handle 111′ is pivoted in the reverse direction 239′. The ram springs 143′ urge the ram 249 upwardly against the frame crown 105′. As the ram retracts, the laminate 67 and shell 63 remain inside the ram frame inner surface 307. The draft of the pickup die side surface 274 assists in transferring the shell and laminate from the pickup die 251 to the ram 249.
A flat back 65 is placed on the crimp die pedestal 281. The die table 185′ is then indexed in the direction of arrow 241′,
The operation of the machine 247 during the crimp stroke is substantially identical to the operation of the machine 95 that manufactures the rectangular button 43 as was described previously. The crimp stroke begins as shown in
Although the handle 111′ continues to pivot, the springs 289 resist any downward motion of the crimp die outer frame 287 and also any further advancement of the ram frame 263. The pins 184′ enter the associated clearance holes 164′. Consequently, the ram plug 259 slides inside the ram frame 263. That action pushes the shell 63 and laminate 67 most of the way out of the ram frame inner surface 307 and also causes the laminate skirt to contact the bevel 295 of the crimp die outer frame 287 and bend inwardly on top of the flat back 65. Advancement of the plug 259 continues in a second movement in which the free edge 69 of the shell approaches the bevel 295 and becomes separated from it only by the laminate. With the plug 259 pushing on the shell, resistance to bending of the metal shell forces the crimp die outer frame downwardly against the resistance of the springs 289. As a result, the shell and laminate approach the flat back 65. The laminate skirt tucks between the shell margin 61 and the flat back periphery 68 in a manner substantially similar to that described previously in connection with
The crimp die outer frame 287 continues to move until the plungers 303 of the spring cells 299 abut the die table 185′. As a result, the shell 63 and laminate 67 further approach the flat back 65. The force of the spring cell springs 301 combine with the force of the crimp die springs 289 to prevent further movement of the crimp die outer frame, so continued pivoting of the handle 111′ and advancement of the ram plug 259 is not accompanied by any movement of the crimp die outer frame or the ram frame 263. Consequently, the ram plug slides further inside the ram frame and further pushes the shell and laminate out of the ram frame. Simultaneously, a force is applied to the handle that is sufficient, because of the bevel 295, to bend the shell wall into a frusto-conical shape. The shell frusto-conical wall and the laminate skirt enter a notch between the flat back and a crimp die pedestal relief surface 309. Refer to
To complete the manufacture of the round button 59, a final force is applied to the machine handle 111′. The final force is transferred through the ram carrier 257 to the ram plug 259. The final force advances the ram 249 in a third movement of the crimp stroke in which the ram plug working surface 167′ and lip 169′ force the shell frusto-conical wall to bend against the crimp die pedestal relief surface 309. As the shell frusto-conical wall is further bent against the crimp die pedestal relief surface, the line of contact between the laminate 67 and the crimp die outer frame bevel 295 moves slightly upwardly along the bevel. That causes the crimp die outer frame 287 to be forced downwardly slightly against the combined forces of the spring cells 299 and the crimp die springs 289 The shell frusto-conical wall thus bends into the flange 71 that is flat and that lies in a single plane 72,
In summary, the results and advantages of modern graphics can now be more fully realized. The machines 247 and 95 for manufacturing the round button 59 and rectangular button 73, respectively, provide both efficient two-stroke operation as well as commonality of parts. This desirable result comes from using the combined functions of the spring cells 232 and 299. The spring cells are stiff enough to enable the button shells 75 and 63 to bend in the crimp dies 199 and 253, respectively, but the spring cells yield under final pivoting of the handle 111 or 111′ to bend the shells to have respective coplanar flanges 91 and 71. The machine 95 for the rectangular button has a two-part carrier 125 including the shifter cage 131. The actuator shifter post 191 acts on the fingers 165 and 166 to shift the ram 121 between pickup and crimp modes of operation in response to indexing the die table 185. For the round button machine 247, the actuator shifter post 191′ acts on the fingers 269 and 271 to rotate the ram frame 263. For both machines, shifting the ram between pickup and crimp modes of operation align and misalign, respectively, pins and clearance holes in the ram. The two-strokes of the ram utilize the misaligned and aligned pins and clearance holes to enable the ram to cooperate with the pickup and crimp dies, respectively, to manufacture the buttons.
It will also be recognized that in addition to the superior performance of the machines 95 and 247, their construction is such as to cost little, if any, more than traditional button machines. In fact, the increased efficiency and productivity inherent in the two-stroke operation quickly pays for any increased cost of the machines.
Thus, it is apparent that there has been provided, in accordance with the invention, a two-stroke machine for making buttons having coplanar shell flanges that fully satisfies the aims and advantages set forth above. While the invention has been described in conjunction with specific embodiments thereof, it is evident that many alternatives, modifications, and variations will be apparent to those skilled in the art in light of the foregoing description. Accordingly, it is intended to embrace all such alternatives, modifications, and variations as fall within the spirit and broad scope of the appended claims.
Number | Name | Date | Kind |
---|---|---|---|
4867013 | Braunberger | Sep 1989 | A |
6038944 | Braunberger | Mar 2000 | A |