The present invention relates generally to the field of machines that form rims of containers. In particular, the present invention relates to the field of a single machine rim curling and rim flattening device.
Rims of containers are often curled to provide the container with a smooth and stronger upper edge. However, curled upper edges provide only a limited amount of surface area (the crown) against which the sealing panel may be secured. As a result, the curls are often flattened to provide a larger surface area against which a sealing panel may be secured. The flattened curl itself is also sealed as a result of the typical thermosplastic coating being melted as the curl is flattened.
Two apparatus are commonly used to curl and flatten the upper edges of paperboard containers. These apparatuses include a two-machine apparatus and a single machine apparatus. A conventional two-machine apparatus generally includes a pocket having an upper perimeter bounded by a concave groove or semi-spherical groove. To curl the rim, a series of tools that have a concave groove or semi-spherical groove are linearly moved towards the pocket so as to deform and curl the upper edge of the paperboard container. The paperboard container is then removed and loaded on to a second flattening machine having a pocket bounded by a flat surface and having a die ring providing an opposing flat surface. The die ring is linearly moved towards the flat surface of the pocket to flatten the curl therebetween. Although conventional, this two-machine apparatus is expensive, space consuming and slow.
A conventional single machine employs a pocket and die ring similar to the pocket and die ring employed by the two-machine process for curling the upper edge of the paperboard container. However, instead of requiring that the paperboard container with a curled rim be removed and reloaded on a separate machine for flattening, the single machine has a series of two heating stations, two curling stations and a flattening station where the machine lifts the container out of the pocket and into the flattener station as four flattening anvils are extended towards one another and about the container under the rim to form a solid ring. A generally flat member is then moved against the anvils to compress and flatten the curled rim therebetween. The order of operation is then reversed to discharge the cup. Although eliminating the need for two separate machines to curl and flatten the paperboard upper edge, such single machine apparatus are still slow since the flattening step requires that the cup be raised and lowered relative to the pocket and also requires that four flattening anvils be extended toward the rim and retracted away from the rim. These additional steps increase process time and costs. The requirement of four stations to rim the container also adds complexity and cost to the machine.
A machine and a method for forming a rim of a paperboard container having a bottom and a sidewall terminating at a rim are disclosed in U.S. Patent Application Publication No. 2002/0111260 published Aug. 15, 2002, the disclosure of which is herein incorporated by reference in entirety. The machine includes a frame, a turret rotatably coupled to the frame, a plurality of circumferentially spaced pockets supported by the turret and a plurality of workstations about the turret. Each pocket includes a shell having a cavity with a mouth configured to receive the container along an axis and a first member about the cavity and including a first surface. The first surface is one of a flat surface and a concave surface and is actuatable along the axis from a retracted position below the mouth to an extended position adjacent the mouth. The plurality of workstations includes a first station and a second station. The first station has a first tool with a second surface, wherein the second surface is one of a flat surface and a concave surface. The first tool is adapted to move along the axis so as to engage and form the paperboard rim between the first and second surfaces. The second station includes a second tool having a third surface, wherein the third surface is the other of a flat surface and a concave surface. The second station further includes a plurality of die segments about the second tool. Each segment has a fourth surface, wherein the fourth surface is the other of a flat surface and a concave surface. The die segments are adapted to move along the axis and to pivot between a closed position in which the fourth surface engages and forms a rim and an opened position.
One embodiment of the invention relates to an apparatus for forming an upper edge of a paperboard container having a bottom and a sidewall terminating at a rim at the upper edge. The apparatus includes a pocket having a shell provided with a cavity with a mouth configured to receive the container along an axis such that the rim extends beyond the mouth. A workstation includes a forming member separate from the pocket having a first forming surface being one of a flat surface and a concave surface. The first forming surface is actuatable along the axis from a retracted position spaced from the rim to an extended position lying adjacent an upper end of the rim. A forming segment has a second forming surface being one of a flat surface and a concave surface. The forming segment is actuatable towards the axis and the forming member in response to axial movement thereof such that the second forming surface is positioned spaced from a lower end of the rim. The second forming surface is actuatable along the axis towards the first forming surface to form the rim therebetween.
Another embodiment of the invention relates to an apparatus for forming an upper edge of a paperboard container having a bottom and a sidewall terminating at a rim. The apparatus includes a pocket having a shell provided with a cavity with a mouth configured to receive the container such that the rim extends beyond the mouth and the container is centered along an axis of the pocket, the rim being formed with a curl thereon. A flattening station is configured to provide compression and flattening of the curl formed on the rim. The flattening station includes a cam coupled to a forming member having a first forming surface. The cam and the forming member are movable back and forth relative to a support along the axis of the pocket. A set of forming arms is pivotally coupled to the support and is positioned outside the forming member for movement relative thereto. The forming arms are axially movable together with the cam and the forming member. Each of the forming arms has a cam follower engaged with the cam, and a forming segment having a second forming surface facing the first forming surface. The forming member is moved to position the first forming surface on an upper end of the curl on the rim, and the forming arms are pivoted to position each second forming surface spaced from a lower end of the curl on the rim in response to axial movement of the cam and the forming member, and each second forming surface is moved towards the first forming surface to form a flattened rim on the container.
Another embodiment of the invention relates to a method for forming an upper edge of a paperboard container including a bottom and a sidewall terminating in a rim. The method includes the steps of a) positioning the container in a pocket having a mouth such that the rim extends beyond the mouth and such that the container is centered along an axis; b) actuating a forming member having a first forming surface axially along the axis towards and adjacent an upper end of the rim; c) pivoting a forming segment having a second forming surface facing the first forming surface such that the second forming surface lies spaced from a lower end of the rim; and d) actuating at least one of the first forming surface and the second forming surface towards each other to form the rim therebetween.
An additional embodiment of the invention relates to a method of forming an upper edge of a paperboard container including a bottom and a sidewall terminating in a rim. The method includes the steps of a) providing a pocket including a shell having a cavity with a mouth configured to moveably receive the container such that the rim extends beyond the mouth and the container is centered along an axis of the pocket, the rim being formed with a curl thereon; b) providing a cam coupled to a forming member having a first forming surface, the cam and the forming member being axially moveable back and forth relative to a support along the axis of the pocket; c) providing a set of forming arms pivotally coupled to the support and positioned outside the forming member for movement relative thereto, each of the forming arms having a cam follower engaged with the cam, and a forming segment having a second forming surface facing the first forming surface; d) moving the container along the axis in the pocket to advance the rim towards the forming member; e) moving the forming member and each forming segment along the axis towards the pocket until each second forming surface is positioned outside of and beyond a lower end of the rim; f) further moving the forming member along the axis such that the first forming surface lies adjacent an upper end of the rim, such further movement of the forming member enabling each cam follower to move along the respective cam and causing the forming arms to pivot towards the axis and move the forming segments towards the forming member such that the second forming surfaces are positioned spaced from the lower end of the rim and in alignment with the first forming surface; and g) moving the second forming surfaces towards the first forming surface to flatten and compress the curl and form a flattened rim.
The drawings illustrate the best mode presently contemplated of carrying out the disclosure. In the drawings:
Pockets 24 are coupled to turret 22 so as to be rotatably driven about axis 32 by turret 22. In the exemplary embodiment, apparatus 10 includes seven pockets 24 circumferentially and equidistantly spaced about turret 22. Alternatively, apparatus 10 may he provided with any of a number of pockets 24 depending upon the number of stations required to form rim 18 of container 12 as well as to possibly form additional portions of container 12. Pockets 24 are each configured to receive and carry an individual container 12 as apparatus 10 is forming container 12. As a result, rim 18 of container 12 may be formed in fewer steps, in less time and with simpler and less expensive equipment.
Heating station 26, curling station 28 and flattening station 30 are circumferentially positioned about turret 22 and pockets 24 and are configured to engage rim 18 of container 12 to form rim 18. In operation, containers 12 having unformed rims 18 are individually loaded into pockets 24 at loading station 38, as indicated by arrow 40. Turret 22 thereafter rotates to position container 12 across from heating station 26. Heating station 26 directs hot air at rim 18 to melt the thermoplastic coating on rim 18, to render it more pliable for deformation and to allow the flattened rim to seal. Turret 22 then rotates to position pocket 24 and its container 12 across from curling station 28. Curling station 28 forms rim 18 by curling rim 18. Turret 22 then rotates to position pocket 24 and its container 12 across from flattening station 30. Flattening station 30 further forms the curled rim 18 by compressing and flattening rim 18. Thereafter, turret 22 rotates to position pocket 24 and formed container 12 at discharge station 42 where container 12 and its completed rim 18 are ejected, such as by a blower, or otherwise removed from apparatus 10 as indicated by arrow 44.
Shell 52 is supported by shell support 50 and includes bottom 56 defining cavity 60. Cavity 60 forms a mouth 62 and is configured to receive container 12. As shown in
Cam follower 76 (as shown in
Eccentric shaft 100 is pivotably coupled to link 102 and link 102 is pivotably coupled to support 104 through axes 110 and 112. Support 104 is coupled to nozzle support 106 which is coupled to nozzle 122. Support 104 is also slidably supported by linear bearing 118 relative to rim heater base 128. Eccentric shaft 100, link 102, support 104 and linear bearing 118 make up a slider-crank mechanism whereby rotational motion of eccentric shaft 100 causes support 104, support 106 and nozzle 122 to reciprocate in the directions indicated by arrows 114 and 116 in a timed relationship with the rotation of turret 22, supporting pockets 24.
Heater assembly 108 is mounted upon rim heater base 128 and generally includes heater 120. Heater 120 is conventionally known and is configured to heat surrounding air which is supplied by a compressor (not shown). The heated air is blown through the internal passageways 124 in the direction indicated by arrows 126 to nozzle 122. As shown by
Cam follower 137 is coupled to inner support 140 which is in turn coupled to support 142. Support 142 is coupled to support 144 which is in turn coupled to supports 146. Support 144 is coupled to forming member 148. In the exemplary embodiment, support 140 is mounted to support 142. Support 142 comprises an elongate cylinder slidably supported by bushing 166 relative to outer support 152. Support 142 is mounted to support 144. Alternatively, each support 140, 142, 144 and 146 may be fixedly secured to one another by any of a variety of mounting mechanisms. Moreover, one or more of supports 140, 142, 144 and 146, as well as a forming member 148, may alternatively be integrally formed with one another to reduce the number of parts or may be provided by a greater number of individual components secured to one another. Springs (not shown) act against support 140 to maintain cam follower 137 against cam 133 during rotation of shaft 130.
Forming member 148 is mounted to support member 144 and includes an annular forming surface 174 (
Cam followers 136 and 138 are rotatably coupled to supports 150 and 151 which are coupled to support 152. Support 152 is coupled to support 154 which is coupled to supports 156. Supports 156 are pivotably coupled to each of fingers 160 which are in turn pivotably coupled to each of forming segments 162. Forming segments 162 are also pivotably coupled to supports 146. As shown by
Fingers 160 extend between support 156 and forming segments 162 and are pivotably coupled to support 156 about axes 176 and also pivotably coupled to forming segments 162 about axes 178. As best shown by
Each forming segment 162 comprises a generally arcuate segment having a forming surface 184. Forming segments 162 circumscribe generally the entire perimeter of forming member 148 and are pivotably coupled to fingers 160 about axes 178 and are further pivotably coupled to support members 146 about axes 182. Actuation of fingers 160 towards and away from pocket 24 by cam followers 136 and 138 pivots each of forming segments 162 in unison between an open position (shown in
Cam follower 210 is coupled to inner support 240 which is in turn coupled to support 242. Support 242 is coupled to support 244 which is in turn coupled to support 246. Support 246 is coupled to cam 206. Cam 206 is coupled to forming member 248. In the exemplary embodiment, support 240 is mounted to support 242. Support 242 is mounted to support 244. Support 244 is mounted to support 246. Support 246 comprises an elongate cylinder slidably supported by bushing 266 relative to outer support 258. Support 246 is mounted to cam 206. Cam 206 is mounted to a forming member 248. Alternatively, each support 240, 242, 244 and 246 may he fixedly secured to one another by any of a variety of mounting mechanisms. Moreover, one or more of supports 240, 242, 244 and 246, as well as cam 206 and forming member 248, may alternatively be integrally formed with one another to reduce the number of parts or may be provided by a greater number of individual components secured to one another. Springs (not shown) act against support 242 to maintain cam follower 210 against cam 203 during rotation of shaft 230.
Forming member 248 is mounted to cam 206 and includes an annular forming surface 280 that generally faces pocket 24 when pocket 24 is opposite flattening station 30. In the exemplary embodiment, forming surface 280 comprises a flat surface to facilitate flattening of rim 18 of container 12. Although forming surface 280 preferably is flat in shape, forming surface 280 may alternatively have other continuous shapes depending upon the shape of the container and the rim being formed. For example, surface 280 may have round shapes or noncircular shapes such as oval.
Cam followers 208 and 212 are rotatably coupled to supports 250 and 252 which are coupled to supports 254 and 256 which are coupled to support 258. Support 258 is pivotably coupled to each of the forming arms 260. Forming segments 262 are coupled to forming arms 260. As shown by
Cam followers 214 are rotatably coupled to forming arms 260. Cam 206 interacts with cam followers 214 to pivot forming arms 260 about axis 278. Springs 276 act against forming arms 260 to maintain cam followers 214 against cam 206 during activation of cam 206. As best shown by
Each forming segment 262 comprises a generally flat segment having a forming surface 284. Forming segments 262 circumscribe generally the entire perimeter of forming member 248 and are coupled to forming arms 260 which are pivotably coupled to support 258 about axes 278. Actuation of forming arms 260 towards and away from pocket 24 by cam followers 208 and 212 and the reciprocation of cam 206 acting on cam follower 214, pivots each of forming segments 262 in unison between an open position (shown in
Although the present invention has been described with reference to preferred embodiments, workers skilled in the art will recognize that changes may be made in form and detail without departing from the spirit and scope of the invention as set forth in the appended claims.
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Number | Date | Country | |
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20180111346 A1 | Apr 2018 | US |