The present disclosure relates to case sealers, and more particularly to random case sealers configured to seal cases of different heights.
Every day, companies around the world pack millions of items in cases (such as boxes formed from corrugated) to prepare them for shipping. Case sealers partially automate this process by applying pressure-sensitive tape to cases already packed with items and (in certain instances) protective dunnage to seal those cases shut. Random case sealers are a subset of case sealers that automatically adjust to the height of the case to-be-sealed so they can seal cases of different heights.
A typical random case sealer includes a top-head assembly with a pressure switch at its front end. The top-head assembly moves vertically under control of two pneumatic cylinders to accommodate cases of different heights. The top-head assembly includes a tape cartridge configured to apply tape to the top surface of the case as it moves past the tape cartridge. One known tape cartridge includes a front roller assembly, a cutter assembly, a rear roller assembly, a tape-mounting assembly, and a tension-roller assembly. A roll of tape is mounted to the tape-mounting assembly. A free end of the tape is routed through several rollers of the tension-roller assembly until the free end of the tape is adjacent a front roller of the front roller assembly with its adhesive side facing outward (toward the incoming cases).
In operation, an operator moves a case into contact with the pressure switch. In response, pressurized air is introduced into the two pneumatic cylinders to pressurize the volumes below their respective pistons to a first pressure to begin raising the top-head assembly. Once the top-head assembly ascends above the case so the case stops contacting the pressure switch, the operator moves the case beneath the top-head assembly, and the air pressure in the pneumatic cylinders is reduced to a second, lower pressure. When pressurized at the second pressure, the pneumatic cylinders partially counter-balance the weight of the top-head assembly so the top-head assembly gently descends onto the top surface of the case.
A drive assembly of the case sealer moves the case relative to the tape cartridge. This movement causes the front roller of the front roller assembly to contact a leading surface of the case and apply the tape to the leading surface. Continued movement of the case relative to the tape cartridge forces the front roller assembly to retract against the force of a spring. This also causes the rear roller assembly to retract since the roller arm assemblies are linked. As the drive assembly continues to move the case relative to the tape cartridge, the spring forces the front roller to ride along the top surface of the case while applying the tape to the top surface. The spring also forces a rear roller of the rear roller assembly to ride along the top surface of the case (once the case reaches it).
As the drive assembly continues to move the case relative to the tape cartridge, the case contacts the cutter assembly and causes it to retract against the force of another spring, which leads to the cutter assembly riding along the top surface of the case. Once the drive assembly moves the case relative to the tape cartridge so the case's trailing surface passes the cutter assembly, the spring biases the cutter assembly back to its original position. Specifically, the spring biases an arm with a toothed blade downward to contact the tape and sever the tape from the roll, forming a free trailing end of the tape. At this point, the rear roller continues to ride along the top surface of the case, thereby maintaining the front and rear roller arm assemblies in their retracted positions.
Once the drive assembly moves the case relative to the tape cartridge so the case's trailing surface passes the rear roller, the spring forces the front and rear roller assemblies to return to their original positions. As the rear roller assembly does so, it contacts the trailing end of the severed tape and applies it to the trailing surface of the case to complete the sealing process.
One issue with this known random case sealer is that the construction and control of the top-head assembly limits throughput of cases through the machine. Attempting to increase throughput by causing the top-head assembly to ascend faster (via increasing the first pressure) results in the top-head assembly significantly overshooting the top surface of the case. This means that the time saved via the quicker ascent of the top-head assembly would be lost because afterwards the top-head assembly would have to to descend further to reach the top surface of the case and thus would take longer to do so.
Another issue is that the second pressure is not variable during operation of the case sealer. Setting the second pressure lower would enable the top-head assembly to descend quicker onto the top surface of the case, but could damage or crush the case. This is particularly likely in instances in which the case is under-filled (e.g., in which the case is not entirely filled with product or protective dunnage to support the top surface of the case) and/or formed from weak corrugated. To counteract this, operators could use cases formed from more robust corrugated or fill the cases with more protective dunnage, but this increases costs and waste.
Another issue is that the biasing force on the front roller assembly of the tape cartridge is strong enough to damage the leading edge of the case when the leading edge of the case initially contacts the front roller and forces the roller assemblies to retract. To counteract this, operators could use cases formed from more robust corrugated or fill the cases with more protective dunnage, but this would increase costs and waste.
Another issue is that the roller and cutter assemblies of the tape cartridge impart significant downward forces on the top surface of the case (via their respective springs) during taping, which can cause the top surface of the case to cave in or otherwise damage the case. Again, to counteract this, operators could use cases formed from more robust corrugated, but this would increase costs.
Another known issue is that extension springs of the tape cartridge that impart biasing forces on the roller and cutter assemblies can exhibit an uncontrollable varying force as they are extended. In particular, with respect to the cutter assembly, this can result in the blade inconsistently cutting the tape. The biasing elements (e.g., springs) can also degrade over time and at a certain point may no longer provide acceptable performance and require replacement. This increases down time and decreases throughput.
There is a continuing need for case sealers configured to seal under-filled or weak cases at high throughput without requiring stronger cases or more protective dunnage.
Various embodiments of the present disclosure provide a random case sealer. The case sealer includes a top-head-actuating assembly configured to vary the speed of the top-head assembly when ascending (to make room for the case beneath the top-head assembly) and when descending onto the case (to engage the top surface of the case during sealing). This maximizes the speed of the top-head assembly while limiting overshoot (when ascending) and preventing damage to the case (when descending). In certain embodiments the case sealer includes a tape cartridge configured to limit the forces imparted onto the leading and top surfaces of the case during sealing. These features result in increased throughput as compared to prior art random case sealers without requiring stronger cases or more protective dunnage.
While the systems, devices, and methods described herein may be embodied in various forms, the drawings show and the specification describes certain exemplary and non-limiting embodiments. Not all of the components shown in the drawings and described in the specification may be required, and certain implementations may include additional, different, or fewer components. Variations in the arrangement and type of the components; the shapes, sizes, and materials of the components; and the manners of connection of the components may be made without departing from the spirit or scope of the claims. Unless otherwise indicated, any directions referred to in the specification reflect the orientations of the components shown in the corresponding drawings and do not limit the scope of the present disclosure. Further, terms that refer to mounting methods, such as coupled, mounted, connected, etc., are not intended to be limited to direct mounting methods, but should be interpreted broadly to include indirect and operably coupled, mounted, connected, and like mounting methods. This specification is intended to be taken as a whole and interpreted in accordance with the principles of the present disclosure and as understood by one of ordinary skill in the art.
Various embodiments of the present disclosure provide a random case sealer. The case sealer includes a top-head-actuating assembly configured to vary the speed of the top-head assembly when ascending (to make room for the case beneath the top-head assembly) and when descending onto the case (to engage the top surface of the case during sealing). This maximizes the speed of the top-head assembly while limiting overshoot (when ascending) and preventing damage to the case (when descending). In certain embodiments the case sealer includes a tape cartridge configured to limit the forces imparted onto the leading and top surfaces of the case during sealing. These features result in increased throughput as compared to prior art random case sealers without requiring stronger cases or more protective dunnage.
A controller 90 is communicatively connected to the sensors S to send and receive signals to and from the sensors S. The controller 90 is operably connected to the actuating assemblies and the actuators to control the actuating assemblies and the actuators. The controller 90 may be any suitable type of controller (such as a programmable logic controller) that includes any suitable processing device(s) (such as a microprocessor, a microcontroller-based platform, an integrated circuit, or an application-specific integrated circuit) and any suitable memory device(s) (such as random access memory, read-only memory, or flash memory). The memory device(s) stores instructions executable by the processing device(s) to control operation of the case sealer 10.
The base assembly 100 is configured to align cases in preparation for sealing and to move the cases through the case sealer 10 while supporting the mast assembly 200 (which supports the top-head assembly 300). As best shown in
The base-assembly frame 111 is formed from any suitable combination of solid and/or tubular members and/or plates fastened together. The base-assembly frame 111 is configured to support the other components of the base assembly 100.
The infeed table 112 is mounted to the base-assembly frame 111 adjacent the infeed end IN of the case sealer 10. The infeed table 112 includes multiple rollers on which the operator can place and fill a case and then use to convey the filled case to the top-head assembly 300. The infeed table 112 includes an infeed-table sensor S1 (
The outfeed table 113 is mounted to the base-assembly frame 111 adjacent the outfeed end OUT of the case sealer 10. The outfeed table 113 includes multiple rollers onto which the case is ejected after taping.
The side-rail assembly 114 is supported by the base-assembly frame 111 adjacent the infeed table 112 and includes first and second side rails 114a and 114b and a side-rail-actuating assembly 117 (
The controller 90 is operably connected to the side-rail-actuating assembly 117 to control the side-rail-actuating assembly 117 to move the side rails 114a and 114b between the rest and centering configurations. Specifically: (1) when the side rails 114a and 114b are in the rest configuration, the controller 90 is configured to control the side-rail valve 117a to direct pressurized gas into the side-rail pneumatic cylinder 117b on the appropriate side of the piston to cause the side-rail pneumatic cylinder 117b to move the side rails 114a and 114b from the rest configuration to the centering configuration; and (2) when the side rails 114a and 114b are in the centering configuration, the controller 90 is configured to control the side-rail valve 117a to direct pressurized gas into the side-rail pneumatic cylinder 117b on the opposite side of the piston to cause the side-rail pneumatic cylinder 117b to move the side rails 114a and 114b from the centering configuration to the rest configuration.
The bottom-drive assembly 115 is supported by the base-assembly frame 111 and (along with a top-drive assembly 320, described below) configured to move cases in the direction D. The bottom-drive assembly 115 includes a bottom drive element and a bottom-drive-assembly actuator 118 (
The barrier assembly 116 includes four individually framed barriers (not labeled) that are formed from clear material, such as plastic or glass. The barriers are connected to the base-assembly frame 111 so one pair of barriers flanks the first top-head-mounting assembly 210 (described below) and the other pair of barriers flanks the second top-head-mounting assembly 250 (described below). When connected to the base-assembly frame 111, the barriers are laterally offset from the top-head assembly 300 to prevent undesired objects from entering the area surrounding the top-head assembly 300 from the sides.
The mast assembly 200 is configured to support and control vertical movement of the top-head assembly 300 relative to the base assembly 100. As best shown in
The first top-head-mounting assembly 210 includes an enclosure 220 that is connected to (via suitable fasteners or in any other suitable manner) and partially encloses part of a first top-head-actuating assembly 230. As best shown in
The first and second rail mounts 232a and 234a include elongated tubular members having a rectangular cross-section, and the first and second rails 232b and 234b are elongated solid (or in certain embodiments, tubular) members having a circular cross-section. The first rail 232b is mounted to the first rail mount 232a so the first rail 232b and the first rail mount 232a share the same longitudinal axis. The second rail 234b is mounted to the second rail mount 234a so the second rail 234b and the second rail mount 234a share the same longitudinal axis.
The carriage 240 includes a body 242 that includes a first pair of outwardly extending spaced-apart mounting wings 242a and 242b, a second pair of outwardly extending spaced-apart mounting wings 242c and 242d, a pair of upwardly extending mounting ears 242e and 242f, four linear bearings 244a-244d, and a shaft 246. Each mounting wing 242a-242f defines a mounting opening therethrough (not labeled). Each linear bearing 244a-244d defines a mounting bore therethrough (not labeled). The linear bearings 244a-244d are connected to the mounting wings 242a-242d, respectively, so the mounting openings of the mounting wings and the mounting bores of the linear bearings are aligned. The shaft 246 is received in the mounting openings of the mounting ears 242e and 242f so the shaft 246 extends between those mounting ears.
The first top-head-actuating-assembly pneumatic cylinder 248 includes a cylinder 248a, a piston rod 248b having an exposed end outside the cylinder 248a, and a piston 248c (
The first top-head-actuating-assembly upper valve 230uv (
The carriage 240 is slidably mounted to the first and second rails 232b and 234b via: (1) receiving the first rail 232b through the mounting openings in the mounting wings 242a and 242b and the mounting bores in the linear bearings 244a and 244b; and (2) receiving the second rail 234a through the mounting openings in the mounting wings 242c and 242d and the mounting bores in the linear bearings 244c and 244d. The first top-head-actuating-assembly pneumatic cylinder 248 is operably connected to the carriage 240 to move the carriage along and relative to the rails 232b and 234b. Specifically, a lower end of the cylinder 248a is connected to a plate (not labeled) that extends between the first and second rail supports 232a and 234a, and the exposed end of the piston rod 248b is connected to the shaft 246. In this configuration, extension of the piston rod 248b causes the carriage 240 to move upward along the rails 232b and 234b, and retraction of the piston rod 248b causes the carriage 240 to move downward along the rails 232b and 234b.
The second top-head-mounting assembly 250 includes an enclosure 260 that is connected to (via suitable fasteners or in any other suitable manner) and partially encloses part of a second top-head-actuating assembly 270 (
The first and second rail mounts 272a and 274a include elongated tubular members having a rectangular cross-section, and the first and second rails 272b and 274b are elongated solid (or in certain embodiments, tubular) members having a circular cross-section. The first rail 272b is mounted to the first rail mount 272a so the first rail 272b and the first rail mount 272a share the same longitudinal axis. The second rail 274b is mounted to the second rail mount 274a so the second rail 274b and the second rail mount 274a share the same longitudinal axis.
The carriage 280 includes a body 282 that includes a first pair of outwardly extending mounting wings 282a and 282b, a second pair of outwardly extending mounting wings 282c and 282d, a pair of upwardly extending mounting ears 282e and 282f, four linear bearings 284a-284d, and a shaft 286. Each mounting wing 282a-282f defines a mounting opening therethrough (not labeled). Each linear bearing 284a-284d defines a mounting bore therethrough (not labeled). The linear bearings 284a-284d are connected to the mounting wings 282a-282d, respectively, so the mounting openings of the mounting wings and the mounting bores of the linear bearings are aligned. The shaft 286 is received in the mounting openings of the mounting ears 282e and 282f so the shaft 286 extends between those mounting ears.
The second top-head-actuating-assembly pneumatic cylinder 288 includes a cylinder 288a, a piston rod 288b having an exposed end outside the cylinder 288a, and a piston 288c slidably disposed within the cylinder 288a and connected to the other end of the piston rod 288b. An upper port is in fluid communication with the interior of the cylinder 288a above the piston 288c to enable pressurized gas to be directed into the cylinder 288a above the piston 288c (as described below), and a lower port is in fluid communication with the interior of the cylinder 288a below the piston 288c to enable pressurized gas to be directed into the cylinder 288a below the piston 288c (as described below).
The second top-head-actuating-assembly upper valve 270uv (
The carriage 280 is slidably mounted to the first and second rails 272b and 274b via: (1) receiving the first rail 272b through the mounting openings in the mounting wings 282a and 282b and the mounting bores in the linear bearings 284a and 284b; and (2) receiving the second rail 274a through the mounting openings in the mounting wings 282c and 282d and the mounting bores in the linear bearings 284c and 284d. The second top-head-actuating-assembly pneumatic cylinder 288 is operably connected to the carriage 280 to move the carriage along and relative to the rails 272b and 274b. Specifically, a lower end of the cylinder 288a is connected to a plate (not labeled) that extends between the first and second rail supports 272a and 274a, and the exposed end of the piston rod 288b is connected to the shaft 286. In this configuration, extension of the piston rod 288b causes the carriage 280 to move upward along the rails 272b and 274b, and retraction of the piston rod 288b causes the carriage 280 to move downward along the rails 272b and 274b.
In other embodiments, the case sealer 10 includes: (1) a single top-head-actuating-assembly upper valve fluidly connectable to a pressurized gas source, the first top-head-actuating-assembly pneumatic cylinder 248, and the second top-head-actuating-assembly pneumatic cylinder 288 and configured to direct pressurized gas into the upper ports of their respective cylinders 248a and 288a; and (2) a single top-head-actuating-assembly lower valve fluidly connectable to the pressurized gas source, the first top-head-actuating-assembly pneumatic cylinder 248, and the second top-head-actuating-assembly pneumatic cylinder 288 and configured to direct pressurized gas into the lower ports of their respective cylinders 248a and 288a. For instance, in certain embodiments each of these valves includes a tee fitting to simultaneously direct pressurized air to the appropriate side (depending on the valve) of both cylinders.
In other embodiments, the case sealer includes a single top-head-actuating assembly configured to control the vertical movement of the top-head assembly.
The top-head assembly 300 is movably supported by the mast assembly 200 to adjust to cases of different heights and is configured to move the cases through the case sealer 10, engage the top surfaces of the cases while doing so, and support the tape cartridge 1000. As best shown in
The top-head-assembly frame 310 is configured to mount the top-head assembly 300 to the mast assembly 200 and to support the other components of the top-head assembly 300, and is formed from any suitable combination of solid or tubular members and/or plates fastened together. The top-head-assembly frame 310 includes laterally extending first and second mounting arms 312 and 314 that are connected to the carriages 240 and 280, respectively, of the first and second top-head-mounting assemblies 210 and 250 via suitable fasteners. A top-surface sensor mount (not labeled) carrying the top-surface sensor S3 is connected to the second mounting arm 314.
The top-drive assembly 320 is supported by the top-head-assembly frame 310 and (along with the bottom-drive assembly 115, described above) configured to move cases in the direction D. The top-drive assembly 320 includes a top-drive element and a top-drive-assembly actuator 322 (
The leading-surface sensor S2 includes a mechanical paddle switch (or any other suitable sensor, such as a proximity sensor) positioned at a front end of the top-head-assembly frame 310 and configured to detect when the leading surface of a case initially contacts (or is within a predetermined distance of) the top-head assembly 300. The leading-surface sensor S2 is communicatively connected to the controller 90 to send signals to the controller 90 responsive to actuation and de-actuation of the leading-surface sensor S2 (corresponding to the leading-surface sensor S2 detecting and no longer detecting the case).
The top-surface sensor S3 includes a proximity sensor (or any other suitable sensor) configured to detect the presence of a case. Here, although not shown, the top-surface sensor S3 is positioned at the front end of the top-head-assembly frame 310 and above at least part of the leading-surface sensor S2 so the top-surface sensor S3 can detect the top surface of the case C (as described below). The top-surface sensor S3 is communicatively connected to the controller 90 to send signals to the controller 90 responsive to detecting the case and no longer detecting the case.
The case-entry sensor S4 includes a proximity sensor (or any other suitable sensor) configured to detect the presence of a case. Here, although not shown, the top-surface sensor S4 is positioned on the underside of the top-head-assembly frame 310 near the front end of the top-head-assembly frame 310 so the case-entry sensor S4 can detect when a case enters the space below the top-head assembly 300. The case-entry sensor S4 is communicatively connected to the controller 90 to send signals to the controller 90 responsive to detecting the case and no longer detecting the case.
The retraction sensor S5 includes a proximity sensor (or any other suitable sensor) configured to detect the presence of a case. Here, although not shown, the retraction sensor S5 is positioned on the underside of the top-head-assembly frame 310 downstream of the case-entry sensor S4 so the retraction sensor S5 can detect when a case reaches a particular position underneath the top-head assembly 300 (here, a position just before the case contacts the front roller, as explained below). Here, “downstream” means in the direction of travel D, and “upstream” means the direction opposite the direction of travel D. The retraction sensor S5 is communicatively connected to the controller 90 to send signals to the controller 90 responsive to detecting the case and no longer detecting the case.
The case-exit sensor S6 includes a proximity sensor (or any other suitable sensor) configured to detect the presence of a case. Here, although not shown, the case-exit sensor S6 is positioned on the underside of the top-head-assembly frame 310 near the rear end of the top-head-assembly frame 310 (downstream of the case-entry and retraction sensors S4 and S5) so the case-exit sensor S6 can detect when a case exits from beneath the top-head assembly 300. The case-exit sensor S6 is communicatively connected to the controller 90 to send signals to the controller 90 responsive to detecting the case and no longer detecting the case.
The controller 90 is operably connected to (1) the first and second top-head-actuating assemblies 230 and 270 and configured to control the first and second top-head-actuating assemblies 230 and 270 to control vertical movement of the top-head assembly 300 responsive to signals received from the sensors S2-S4 and S6 and (2) the upper tape cartridge 1000 and configured to control the force-reduction functionality of the upper tape cartridge 1000 responsive to signals received from the sensor S5, as described in detail below in conjunction with
The upper tape cartridge 1000 is removably mounted to the top head assembly 300 and configured to apply tape to a leading surface, a top surface, and a trailing surface of a case. Although not separately described, the lower tape cartridge is removably mounted to the base assembly 100 and configured to apply tape to the leading surface, the bottom surface, and the trailing surface of the case. As best shown in
The front roller assembly 1100 includes a front roller arm 1110 and a front roller 1120. The front roller arm 1110 is pivotably mounted to the first mounting plate M1 via a front roller-arm-pivot shaft PSFRONT so the front roller arm 1110 can pivot relative to the mounting plate M1 about an axis AFRONT between a front roller arm extended position (
The rear roller assembly 1200 includes a rear roller arm 1210 and a rear roller 1220. The rear roller arm 1210 is pivotably mounted to the first mounting plate M1 via a rear roller-arm-pivot shaft PSREAR so the rear roller arm 1210 can pivot relative to the mounting plate M1 about an axis AREAR between a rear roller arm extended position (
A rigid first linking member 1020 is attached to and extends between the first roller arm 1110 and the second roller arm 1210. The first linking member 1020 links the front and rear roller assemblies 1100 and 1200 so: (1) moving the front roller arm 1110 from the front roller arm extended position to the front roller arm retracted position causes the first linking member 1020 to force the rear roller arm 1210 to move from the rear roller arm extended position to the rear roller arm retracted position (and vice-versa); and (2) moving the rear roller arm 1210 from the rear roller arm extended position to the rear roller arm retracted position causes the first linking member 1020 to force the front roller arm 1110 to move from the front roller arm extended position to the front roller arm retracted position (and vice-versa).
The tape-cartridge-actuating assembly 1600 (
The roller-arm-actuating assembly 1700 is configured to move the linked front and rear roller arms 1110 and 1210 between their respective extended and retracted positions. As best shown in
The piston 1712 is movable within the cylinder 1711 between: (1) a first position in which the piston 1712 is positioned near a first, bottom end of the cylinder 1711 and the piston rod 1713 is in an extended position; and (2) a second position in which the piston 1712 is positioned near a second, top end of the cylinder 1711 and the piston rod 1713 is in a retracted position. Introduction of pressurized gas into the first connector causes the piston 1712 to move to the second position to retract the piston rod 1713, and introduction of pressurized gas into the second connector 1714 causes the piston to move to the first position to extend the piston rod 1713. In other embodiments the roller-arm actuator may include any other actuator, such as a double-acting hydraulic cylinder or a motor.
The roller-arm actuator 1710 is operably connected to the front roller assembly 1100 to control movement of the front roller arm 1110 and the rear roller arm 1210 linked to the front roller arm 1110 between their respective extended and retracted positions. More specifically, the roller-arm actuator 1710 is coupled between the mounting plate M2 and the first roller arm assembly 1100 via attachment of the support plate 1702 to the mounting plate M2 and attachment of the end of the piston rod 1713 external to the cylinder 1711 to the shaft 1130 of the front roller assembly 1100. In this configuration, when the piston 1712 is in the first position and the piston rod 1713 is thus in the extended position, the front and rear roller arms 1110 and 1210 are in their respective extended positions. Movement of the piston 1712 from the first position to the second position retracts the piston rod 1713, which pulls the shaft 1130 toward the cylinder 1711 and in doing so causes the front roller arm 1110 and the rear roller arm 1210 (via the first linking member 1020) to move to their respective retracted positions.
The first tape-cartridge valve 1000v1 is in fluid communication with the first connector of the roller-arm actuator 1710, and the second tape-cartridge valve 1000v2 is in fluid communication with the second connector 1714 of the roller-arm actuator 1710. The controller 90 is operably connected to the first and second tape-cartridge valves 1000v1 and 1000v2 and configured to control the roller-arm actuator 1710 (and therefore the positions of the front and rear roller arms 1110 and 1210) by controlling air flow through the first and second tape-cartridge valves 1000v1 and 1000v2. Specifically, the controller 90 is configured to open the first tape-cartridge valve 1000v1 (while closing or maintaining closed the second tape-cartridge valve 1000v2) to direct pressurized gas into the cylinder 1711 via the first connector to cause the piston rod 1713 to retract, which causes the front roller arm 1110 and the rear roller arm 1210 (via the first linking member 1020) to move to their respective retracted positions. Conversely, the controller 90 is configured to open the second tape-cartridge valve 1000v2 (while closing or maintaining closed the first tape-cartridge valve 1000v1) to direct pressurized gas into the cylinder 1711 via the second connector 1714 to cause the piston rod 1713 to extend, which causes the front roller arm 1110 and the rear roller arm 1210 (via the first linking member 1020) to move to their respective extended positions.
As best shown in
The cutter arm 1301 includes a cylindrical surface 1301a that defines a cutter arm mounting opening. The cutter arm 1301 is pivotably mounted (via the cutter arm mounting opening) to the first mounting plate M1 via the front roller-arm-pivot shaft PSFRONT and bushings 1303a and 1303b so the cutter arm 1301 can pivot relative to the mounting plate M1 about the axis AFRONT between a cutter arm extended position (
The cutter-arm-actuator-coupling element 1310 includes a support plate 1312 and a coupling shaft 1314 extending transversely from the support plate 1312. The support plate 1312 is fixedly attached to the cutter arm 1301 via fasteners 1316 so the coupling shaft 1314 is generally parallel to and coplanar with the axis AFRONT.
The cutting-device-mounting assembly 1320 is fixedly mounted to the support arm 1310 (such as via welding) and is configured to removably receive the cutting device 1330. That is, the cutting-device-mounting assembly 1320 is configured so the cutting device can be removably mounted to the cutting-device-mounting assembly 1320. The cutting-device-mounting assembly 1320 is described in U.S. Pat. No. 8,079,395 (the entire contents of which are incorporated herein by reference), though any other suitable cutting-device-mounting assembly may be used to support the cutting device 1330.
The cutting-device cover 1340 includes a body 1342 and a finger 1344 extending from the body 1342. A pad 1350 is attached to the body 1342. The cutting-device cover 1340 is pivotably mounted to the support arm 1310 via mounting openings (not labeled) and the cutting-device cover pivot shaft 1306. Once attached, the cutting-device cover 1340 is pivotable about the axis ACOVER relative to the cutter arm 1301 and the cutting device mount 1320 from front to back and back to front between a closed position and an open position. A cutting-device cover biasing element 1346, which includes a torsion spring in this example embodiment, biases the cutting-device cover 1340 to the closed position. When in the closed position, the cutting-device cover 1340 generally encloses the cutting device 1330 so the pad 1350 contacts the toothed blade of the cutting device 1330. When in the open position, the cutting-device cover 1340 exposes the cutting device 1330 and its toothed blade.
The cutting-device cover pivot shaft 1306 is also attached to the rotation-control plate 1360. The rotation-control plate 1360 includes a slot-defining surface 1362 that defines a slot. The surface 1362 acts as a guide (not shown) for a bushing that is attached to the mounting plate M2. The bushing provides lateral support for the cutter assembly 1300 to generally prevent the cutter assembly from moving toward or away from the mounting plates M1 and M2 and interfering with other components of the tape cartridge 1000 when in use.
The cutter-arm-actuating assembly 1800 is configured to move the cutter arm 1301 between its retracted position and its extended position. As best shown in
The piston 1812 is movable within the cylinder 1811 between: (1) a first position in which the piston 1812 is positioned near a first, top end of the cylinder 1811 and the piston rod 1813 is in an extended position; and (2) a second position in which the piston 1812 is positioned near a second, bottom end of the cylinder 1811 and the piston rod 1813 is in a retracted position. Introduction of pressurized gas into the first connector 1814 causes the piston 1812 to move to the first position to extend the piston rod 1813, and introduction of pressurized gas into the second connector causes the piston to move to the second position to retract the piston rod. In other embodiments the cutter-arm actuator may include any other actuator, such as a double-acting hydraulic cylinder or a motor.
The cutter-arm actuator 1810 is operably connected to the cutter assembly 1300 to control movement of the cutter arm 1301 from its retracted position to its extended position. More specifically, the cutter-arm actuator 1810 is coupled between the mounting plate M1 and the cutter assembly 1300 via attachment of a block 1815 at the end of the piston rod 1813 opposite the piston to the shaft 1610 and attachment of a block 1816 on the opposite end of the cylinder 1811 to the coupling shaft 1314 of the cutter-arm-actuator-coupling element 1310. In this configuration, when the piston 1812 is in the first position and the piston rod 1813 is thus in the extended position, the cutter arm 1301 is in its retracted position. Movement of the piston 1812 from the first position to the second position retracts the piston rod 1813, which causes the cylinder 1811 to move toward the shaft 1610, and in doing so pulls the coupling shaft 1314 toward the shaft 1610 and thus causes the cutter arm 1301 to move to its extended position.
The first tape-cartridge valve 1000v1 is in fluid communication with the first connector 1812 of the cutter-arm actuator 1810, and the second tape-cartridge valve 1000v2 is in fluid communication with the second connector of the cutter—arm actuator 1810. The controller 90 is operably connected to the first and second tape-cartridge valves 1000v1 and 1000v2 and configured to control the cutter-arm actuator 1810 (and therefore the position of the cutter arm 1301) by controlling air flow through the first and second tape-cartridge valves 1000v1 and 1000v2. Specifically, the controller 90 is configured to open the first tape-cartridge valve 1000v1 (while closing or maintaining closed the second tape-cartridge valve 1000v2) to direct pressurized gas into the cylinder 1811 via the first connector 1814 to cause the piston rod 1813 to extend, which causes the cutter arm 1301 to move to its retracted position. Conversely, the controller 90 is configured to open the second tape-cartridge valve 1000v2 (while closing or maintaining closed the first tape-cartridge valve 1000v1) to direct pressurized gas into the cylinder 1811 via the second connector to cause the piston rod 1813 to retract, which causes the cutter arm 1301 to move to its extended position.
The tape-mounting assembly 1400 includes a tape-mounting plate 1410 and a tape-core-mounting assembly 1420 rotatably mounted to the tape-mounting plate 1410. The tape-core-mounting assembly 1420 is further described in U.S. Pat. No. 7,819,357, the entire contents of which are incorporated herein by reference (though other tape core mounting assemblies may be used in other embodiments). A roll R of tape is mountable to the tape-core-mounting assembly 1420.
The tension-roller assembly 1500 includes several rollers (not labeled) rotatably disposed on shafts that are supported by the first mounting plate M1. A free end of the roll R of tape mounted to the tape-core-mounting assembly 1420 is threadable through the rollers until the free end is adjacent the front roller 1120 of the front-roller assembly 1110 with its adhesive side facing outward in preparation for adhesion to a case. The tension-roller assembly 1500 is further described in U.S. Pat. No. 7,937,905, the entire contents of which are incorporated herein by reference (though other tension roller assemblies may be used in other embodiments).
Operation of the case sealer 10 to seal a case C is now described with reference to the flowchart shown in
Initially, the top-head assembly 300 is at its initial (lower) position, and the side rails 114a and 114b are in their rest configuration. The controller 90 controls the bottom-drive-assembly actuator 118 and the top-drive-assembly actuator 322 to drive the bottom drive element of the base assembly 100 and the top-drive element of the top-head assembly, respectively, as block 2002 indicates.
The operator positions the case C onto the infeed table 112, and the infeed-table sensor S1 detects the presence of the case C, as block 2004 indicates, and in response sends a corresponding signal to the controller 90. Responsive to receiving that signal, the controller 90 controls the side-rail valve 117a to direct pressurized gas into the side-rail pneumatic cylinder 117b on the appropriate side of the piston to cause the side-rail pneumatic cylinder 117b to move the side rails 114a and 114b from the rest configuration to the centering configuration so the side rails 114a and 114b move laterally inward to engage and center the case C on the infeed table 112, as block 2006 indicates and as shown in
The operator then moves the case C into contact with the leading-surface sensor S2. This causes the leading-surface sensor S2 (via the case C contacting and actuating the paddle switch of the leading-surface sensor S2) and the top-surface sensor S3 (via the case moving within a designated distance of the top-surface proximity sensor S3) to detect the case C, as block 2008 indicates, and in response send corresponding signals to the controller 90. Responsive to receiving those signals, the controller 90 controls the first and second top-head-actuating assemblies 230 and 270 to begin moving the top-head assembly 300 upward at a first speed, which is a maximum speed in this example embodiment. Specifically, the controller 90 is configured to control the first and second top-head-actuating-assembly lower valves 230lv and 270lv to direct pressurized gas into the lower ports of the cylinders 248a and 288a to pressurize the volumes below their respective pistons 248c and 288c to a first pressure to cause their respective pistons 248c and 288c to move upward and extend their respective piston rods 248b and 288b to move the top-head assembly 300 upward at the first speed, as block 2010 indicates and as shown in
The top-head assembly 300 continues moving upward at the first speed, and the top-surface sensor S3 eventually stops detecting the case C, as block 2012 indicates. This indicates that the top-surface sensor S3 has ascended above the top surface of the case C. At this point, the leading-surface sensor S2 continues to detect the case (i.e., the leading surface of the case C continues to actuate the paddle switch in this example embodiment). In response to no longer detecting the case C, the top-surface sensor S3 sends a corresponding signal to the controller 90. Responsive to receiving that signal, the controller 90 controls the first and second top-head-actuating assemblies 230 and 270 to begin slowing the upward movement of the top-head assembly 300. Specifically, the controller 90 controls the first and second top-head-actuating-assembly upper valves 230uv and 270uv to direct pressurized gas into the upper ports of the cylinders 248a and 288a, as block 2014 indicates and as shown in
The top-head assembly 300 continues moving upward at this slower second speed, and the leading-surface sensor S2 eventually stops detecting the case C, as block 2016 indicates. This indicates that the top-head assembly 300 has ascended above the top surface of the case C. In response to no longer detecting the case C, the leading-surface sensor S2 sends a corresponding signal to the controller 90. Responsive to receiving that signal, the controller 90 controls the first and second top-head-actuating assemblies 230 and 270 to enable the top-head assembly 300 to stop its ascent and begin descending under its own weight. Specifically, the controller 90 controls the first and second lower valves 230lv and 270lv and the first and second top-head-actuating-assembly upper valves 230uv and 270uv to close, as block 2018 indicates and as shown in
Once the top-head assembly 300 ascends above the top surface of the case C, the operator moves the case C beneath the top-head assembly 300 and into contact with the bottom-drive assembly 115. The case-entry sensor S4 detects the presence of the case C beneath the top-head assembly 300 and in response sends a corresponding signal to the controller 90, as block 2020 indicates. Responsive to receiving that signal, the controller 90 controls the first and second top-head-actuating assemblies 230 and 270 to begin to slow the descent of the top-head assembly 300 (which at this point is descending under its own weight). Specifically, the controller 90 controls the first and second top-head-actuating-assembly lower valves 230lv and 270lv to direct pressurized gas into the lower ports of the cylinders 248a and 288a to pressurize the volumes below their respective pistons 248c and 288c to a third pressure (that is less than the first pressure) to partially counter-balance the weight of the top-head assembly 300 and slow its descent onto the top surface of the case so as to not damage the case, as block 2022 indicates and as shown in
More generally, the controller 90 is configured to control the top-head-actuating-assembly actuators 248 and 288 to: (1) raise the top-head assembly 300 at a first speed responsive to the leading-surface sensor S2 and the top-surface sensor S3 detecting the case; (2) continue raising the top-head assembly 300 at a second slower speed responsive to the top-surface sensor S3 no longer detecting the case and the leading-surface sensor S2 still detecting the case; (3) enable gravity to stop and begin lowering the top-head assembly 300 responsive to the leading-surface sensor S2 no longer detecting the case; and (4) partially counter-balance the weight of the top-head assembly 300 responsive to the case-entry sensor S4 detecting the case.
The top- and bottom-drive assemblies 320 and 115 begin moving the case C in the direction D. The case C eventually moves off of the infeed table 112, at which point the infeed-table sensor S1 stops detecting the case C and sends a corresponding signal to the controller 90, as block 2024 indicates. Responsive to receiving that signal, the controller 90 controls the side-rail valve 117a to direct pressurized gas into the side-rail pneumatic cylinder 117b on the opposite side of the piston to cause the side-rail pneumatic cylinder 117b to move the side rails 114a and 114b from the centering configuration to the rest configuration to make space on the infeed table 112 for the next case to-be-sealed, as block 2026 indicates and as shown in
The top- and bottom-drive assemblies 320 and 115 continue moving the case C, and just before the leading surface of the case C contacts the front roller 1120 of the tape cartridge 1000 the retraction sensor S5 detects the presence of the case C and in response sends a corresponding signal to the controller 90, as block 2028 indicates. Responsive to receiving that signal, the controller 90 controls the roller-arm actuator 1710 and the cutter-arm actuator 1810 to move the first and second roller arms 1110 and 1120 and the cutter arm 1301 to their respective retracted positions, as blocks 2030a and 2030b indicate. Specifically, the controller 90 opens the first tape-cartridge valve 1000v1 (while closing or maintaining closed the second tape-cartridge valve 1000v2), which directs pressurized gas: (1) into the cylinder 1711 via the first connector and causes the piston rod 1713 to retract, which causes the front roller arm 1110 and the rear roller arm 1210 (via the first linking member 1020) to move to their respective retracted positions shown in
The leading surface of the case C contacts the front roller 1120 of the tape cartridge 1000 as the front roller arm 1110 is moving to its retracted position, which causes the tape positioned on the front roller 1120 to adhere to the leading surface of the case C. The fact that the front roller arm 1110 is moving toward its retracted position when the case C contacts the front roller 1120 reduces the force the front roller arm assembly 1100 imparts to the leading surface of the case C (compared to certain prior art case sealers), which reduces the likelihood that the roller arm assemblies will damage the case C during taping (compared to certain prior art tape cartridges that do not include actuators to retract the roller arms).
When the front and rear roller arms 1110 and 1210 are in their retracted positions, the front and rear rollers 1120 and 1220 are positioned so they apply enough pressure to the tape to adhere the tape to the top surface of the case C. When the cutter arm 1301 is in its retracted position, the cutter arm 1301 does not contact the top surface of the case C (though in certain embodiments it may do so). This significantly reduces the downward force applied to the top surface of the case C as compared to certain prior art tape cartridges that use biasing elements on their roller and/or cutter arms to pressure the arms against the top surface of the case C during taping. This reduces and virtually eliminates the possibility of the tape cartridges causing the top surface of the case to cave in and enables operators to use cases formed from weaker (and less expensive) corrugated and/or to fill cases with less protective dunnage (e.g., paper or bubble wrap) to save costs and reduce environmental waste without fear of the tape cartridge damaging the cases.
The controller 90 controls the first and second tape-cartridge valves 1000v1 and 1000v2 to remain open and closed, respectively, to retain the front and rear roller arms 1110 and 1210 and the cutter arm 1301 in their respective retracted positions as the top- and bottom-drive assemblies 320 and 115 move the case C past the tape cartridge 1000. At some point, the case-exit sensor S6 detects the presence of the case C, as block 2032 indicates (though this may occur after the retraction sensor S5 stops detecting the case C depending on the length of the case).
Once the retraction sensor S5 stops detecting the case (indicating that the case has moved past the retraction sensor S5), the retraction sensor S5 sends a corresponding signal to the controller 90, as block 2034 indicates. In response, the controller 90 controls the roller-arm actuator 1710 to return the first and second roller arms 1110 and 1120 to their respective extended positions to apply tape to the trailing surface of the case and controls the cutter-arm actuator 1810 to return the cutter arm 1301 to its extended position to cut the tape from the roll, as blocks 2036a and 2036b indicate. Specifically, the controller 90 closes the first tape-cartridge valve 1000v1 and opens the second tape-cartridge valve 1000v2, which directs pressurized gas: (1) into the cylinder 1711 via the second connector 1714 and causes the piston rod 1713 to extend, which causes the front roller arm 1110 and the rear roller arm 1210 (via the first linking member 1020) to move to their respective extended positions; and (2) into the cylinder 1811 via the second connector and causes the piston rod 1813 to retract, which causes the cutter arm 1301 to move to its extended position.
As this occurs, the finger 1344 of the cutting-device cover 1340 contacts the top surface of the case so the cutting-device cover 1340 pivots to the open position and exposes the cutting device 1330. Continued movement of the cutter arm 1301 brings the toothed blade of the cutting device 1330 into contact with the tape and severs the tape from the roll R. As the front and rear roller arms 1110 and 1210 move back to their extended positions, the rear roller arm 1210 moves so the rear roller 1220 contacts the severed end of the tape and applies the tape to the trailing surface of the case C to complete the taping process.
The top- and bottom-drive assemblies 320 and 115 continue to move the case C until it exits from beneath the top-head assembly 300 onto the outfeed table 113, at which point the case-exit sensor S6 stops detecting the case, as block 2038 indicates, and sends a corresponding signal to the controller 90. Responsive to receiving that signal, the controller 90 controls the first and second top-head-actuating assemblies 230 and 270 to enable the top-head assembly 300 to descend under its own weight. Specifically, the controller 90 controls the first and second top-head-actuating-assembly lower valves 230lv and 270lv to close, as block 2040 indicates and as shown in
If the operator moves another case (such as a shorter case) below the top-head assembly 300 as the top-head assembly 300 is descending and the case-entry sensor S4 detects the presence of that case beneath the top-head assembly 300, the process re-starts at block 2020 (with the case-entry sensor S4 sending an appropriate signal to the controller 90) to seal that case.
The case sealer of the present disclosure solves the above-described problems and can seal under-filled or weak cases at higher throughput than prior art ransom case sealers. The ability of the top-head-actuating assemblies to vary the speed of the top-head assembly when ascending to make room for the case beneath the top-head assembly and when descending onto the case maximizes the speed of the top-head assembly while also limiting overshoot, which maximizes the efficiency at which the top-head assembly moves. This means that the ascent/descent movement cycle of the top-head assembly of the case sealer of the present disclosure is (collectively) faster than those of prior art case sealers. Additionally, use of the tape-cartridge-actuating assembly significantly reduces the forces applied to the leading and top surfaces of the case as compared to prior art tape cartridges that use biasing elements on their roller and/or cutter arms. This reduces and virtually eliminates the possibility of the tape cartridges causing the top surface of the case to cave in and enables operators to use cases formed from weaker (and less expensive) corrugated and/or to fill cases with less protective dunnage (e.g., paper or bubble wrap) without fear of the tape cartridge damaging the cases.
The double-acting pneumatic cylinders described above may be configured and oriented in any suitable manner to move the roller and/or cutter arms as desired on either the extension or retraction stroke.
The case sealer may be powered in any suitable manner. In the above-described example embodiments, electrical couplings and compressed air power the case sealer.
In other embodiments, the controller is configured to control the cutter arm actuator to return the cutter arm to its retracted position after cutting the tape. That is, in these embodiments, the default position for the cutter arm is its retracted position, and the controller is configured to control the cutter arm actuator to move from this position to the extended position (and then back to the retracted position) responsive to receiving a signal from the retraction sensor that the retraction sensor no longer detects the presence of the case.
In various embodiments, the cutter-arm assembly is mechanically linked to the front- and/or rear-roller assembly such that retraction of the front- (and/or rear-) roller arm causes retraction of the cutter arm and extension of the front- (and/or rear-) roller arm causes extension of the cutter arm. In these embodiments, the roller-arm-actuating assembly is configured to control movement of both the roller- and cutter-arm-actuating assemblies between their respective extended and retracted positions.
In certain embodiments, the controller is separate from and in addition to the sensors. In other embodiments, the sensors act as their own controllers. For instance, in one embodiment, the retraction sensor is configured to directly control the cutter and roller arm actuators responsive to detecting the presence of and the absence of the case, the infeed-table sensor is configured to directly control the side rail actuator responsive to detecting the presence of and the absence of the case, and the leading-surface and top-surface sensors are configured to directly control the top head actuator responsive to detecting the presence of and the absence of the case (or contact with the case).
In certain embodiments, the controller is configured to prevent vertical movement of the top-head assembly while the case is underneath the top-head assembly. In one such embodiment, the controller is configured to prevent vertical movement of the top-head assembly (i.e., is configured not to actuate the first or second top-head-actuating assemblies) during a period starting with the case-entry sensor detecting the case and ending with the case-exit sensor no longer detecting the case.
In other embodiments, once the leading-surface sensor stops detecting the case, rather than close the top-head-actuating-assembly upper valves along with the top-head-actuating-assembly lower valves, the controller leaves the top-head-actuating-assembly upper valves open to more quickly stop the ascent of the top-head assembly and speed the descent of the top-head assembly back toward the case. In one such embodiment, the controller is configured to close the top-head-actuating-assembly upper valves responsive to the case-entry sensor detecting the case.
In further embodiments, once the leading-surface sensor stops detecting the case, rather than close the top-head-actuating-assembly lower valves along with the top-head-actuating-assembly upper valves, the controller reduces the pressure below the respective pistons to the second pressure.
While the top-head-actuating-assembly actuators are pneumatic cylinders controlled via valves and pressurized gas in the above-described example embodiment, these actuators may be any other suitable actuators that may be operably connected to the top-head assembly to control vertical movement of the top head assembly as described above. For instance, in one embodiment, the rails are linear gears (or “racks”) and the top-head-actuating-assembly actuators are electric motors operably connected to spur gears (or “pinions”) supported by the carriages and meshed with the linear gears. In this embodiment, the controller is configured to control output of the motor—and therefore rotation of the spur gears—to move the top-head assembly. In another embodiment, the mast assembly comprises pulleys driven by a motor-driven jack shaft. In this embodiment, the top-head assembly is attached it a chain, belt, or other suitable component driven by the pulleys to move the top-head assembly.
In various embodiments, the case sealer includes an active braking system operably connectable to the top-head assembly and configured to slow the vertical movement of the top-head assembly from the first speed to the second speed. For instance, in one such embodiment, the controller is configured to, responsive to the top-surface sensor no longer detecting the case, activate the active braking system so a component of the active braking system moves into contact with the top-head assembly to slow the vertical movement of the top-head assembly.
The example embodiment of the case sealer described above and shown in the Figures is a semiautomatic case sealer in which an operator feeds closed cases beneath the top-head assembly. This is merely one example embodiment, and the case sealer may be any other suitable type of case sealer, such as an automatic case sealer in which a machine automatically feeds closed cases beneath the top-head assembly.
In other embodiments, the case sealer includes a measuring device (such as a height sensor) configured to determine the height of a case to-be-sealed before the case contacts the leading-surface sensor. In these embodiments, the controller uses the determined height of the case to control the appropriate valves to move the top-head assembly as desired. In other words, in these embodiments, the controller does not use feedback from a top-surface sensor to detect the top surface of the case as the top-head assembly ascends.
Turning now to the additional components of the tape cartridge 3000, a first roller-arm-assembly-biasing element 3014a—here, an extension spring—has one end attached to a first roller-arm-assembly-biasing-element-attachment post 3014 attached to the first mounting plate M1 and another end attached to a connector 3016 pivotably attached to the rear roller arm 1210. The first roller-arm-assembly-biasing element 3014a biases the front and rear roller arms 1110 and 1210 (in part via the first linking member 1020) to their extended positions. This is one example manner of biasing the front and rear roller arms to their extended positions, and any other suitable arrangement of components and/or combination of components may be employed to do so.
A slide block 3030 is pivotably connected on one side to the first linking member 1020 and on the other side to a rigid second linking member 3040, which is attached to the front roller arm assembly 1100. A guide member 3050 is slidably received in an opening defined through the slide block 3030. One end of the guide member 3050 is attached to a connector 3060 pivotably attached to the rear roller arm 1210. A second roller-arm-assembly-biasing element 3050a—here, a compression spring—circumscribes the guide member 3050 and is constrained between the connector 3060 and the slide block 3030. As the front and rear roller arms 1110 and 1210 move from their extended positions to their retracted positions, the guide member 3050 slides further through the slide block 3030. As best shown in
The cutter assembly 1300 includes a cutter-arm-biasing element 3305. A mounting post 3302 extends from the end of the cutter arm 1301 opposite the cutting device 1330. The mounting post 3302 defines a circumferential groove (not labeled) sized to receive and retain a hook at one end of the cutter-arm-biasing element 3305, which is an extension spring in this example embodiment. The hook at the other end of the cutter-arm-biasing element 3305 is attached to a shaft 1610 that extends from the mounting plate M1. The cutter-arm-biasing element 3305 biases the cutter arm 1301 to the extended position best shown in
In some embodiments, the case sealer 10 with the tape cartridge 3000 operates as described above with respect to the flowchart in
In other embodiments, the case sealer 10 with the tape cartridge 3000 operates in accordance with the method 4000 identified by the flowchart shown in
Turning now to
The operator positions the case C onto the infeed table 112, and the infeed-table sensor S1 detects the presence of the case C, as block 4004 indicates, and in response sends a corresponding signal to the controller 90. Responsive to receiving that signal, the controller 90 controls the side-rail valve 117a to direct pressurized gas into the side-rail pneumatic cylinder 117b on the appropriate side of the piston to cause the side-rail pneumatic cylinder 117b to move the side rails 114a and 114b from the rest configuration to the centering configuration so the side rails 114a and 114b move laterally inward to engage and center the case C on the infeed table 112, as block 4006 indicates.
The operator then moves the case C into contact with the leading-surface sensor S2. This causes the leading-surface sensor S2 (via the case C contacting and actuating the paddle switch of the leading-surface sensor S2) and the top-surface sensor S3 (via the case moving within a designated distance of the top-surface proximity sensor S3) to detect the case C, as block 4008 indicates, and in response send corresponding signals to the controller 90. Responsive to receiving those signals, the controller 90 controls the first and second top-head-actuating assemblies 230 and 270 to begin moving the top-head assembly 300 upward at a first speed, which is a maximum speed in this example embodiment. Specifically, the controller 90 is configured to control the first and second top-head-actuating-assembly lower valves 230lv and 270lv to direct pressurized gas into the lower ports of the cylinders 248a and 288a to pressurize the volumes below their respective pistons 248c and 288c to a first pressure to cause their respective pistons 248c and 288c to move upward and extend their respective piston rods 248b and 288b to move the top-head assembly 300 upward at the first speed, as block 4010 indicates.
The top-head assembly 300 continues moving upward at the first speed, and the top-surface sensor S3 eventually stops detecting the case C, as block 4012 indicates. This indicates that the top-surface sensor S3 has ascended above the top surface of the case C. At this point, the leading-surface sensor S2 continues to detect the case (i.e., the leading surface of the case C continues to actuate the paddle switch). In response to no longer detecting the case C, the top-surface sensor S3 sends a corresponding signal to the controller 90. Responsive to receiving that signal, the controller 90 controls the first and second top-head-actuating assemblies 230 and 270 to begin slowing the upward movement of the top-head assembly 300. Specifically, the controller 90 controls the first and second top-head-actuating-assembly upper valves 230uv and 270uv to direct pressurized gas into the upper ports of the cylinders 248a and 288a, as block 4014 indicates, to pressurize the volumes above their respective pistons 248c and 288c to a second pressure that is less than the first pressure. The pressurized gas above the respective pistons 248c and 288c partially counteracts the upward force supplied by the pressurized gas below the pistons and therefore slows the upward movement of the top-head assembly 300 to a second speed that is lower than the first speed. That is, since the first pressure of the pressurized gas below the pistons is high enough to overcome both the weight of the top-head assembly 300 and the pressurized gas above the pistons, the top-head assembly 300 continues ascending (albeit at a slower speed).
The top-head assembly 300 continues moving upward at this slower second speed, and the leading-surface sensor S2 eventually stops detecting the case C, as block 4016 indicates. This indicates that the top-head assembly 300 has ascended above the top surface of the case C. In response to no longer detecting the case C, the leading-surface sensor S2 sends a corresponding signal to the controller 90. Responsive to receiving that signal, the controller 90 controls the first and second top-head-actuating assemblies 230 and 270 to enable the top-head assembly 300 to stop its ascent and begin descending under its own weight. Specifically, the controller 90 controls the first and second lower valves 230lv and 270lv and the first and second top-head-actuating-assembly upper valves 230uv and 270uv to close, as block 4018 indicates. This de-pressurizes the first and second top-head-assembly pneumatic cylinders 248 and 288 so the weight of the top-head assembly 300 causes the top-head assembly 300 to stop moving upward and to begin descending. Any gas remaining in the first and second top-head-assembly pneumatic cylinders below their respective pistons vents to atmosphere as the top-head assembly 300 descends.
Once the top-head assembly 300 ascends above the top surface of the case C, the operator moves the case C beneath the top-head assembly 300 and into contact with the bottom-drive assembly 115. The case-entry sensor S4 detects the presence of the case C beneath the top-head assembly 300 and in response sends a corresponding signal to the controller 90, as block 4020 indicates. Responsive to receiving that signal, the controller 90 controls the first and second top-head-actuating assemblies 230 and 270 to begin to slow the descent of the top-head assembly 300 (which at this point is descending under its own weight). Specifically, the controller 90 controls the first and second top-head-actuating-assembly lower valves 230lv and 270lv to direct pressurized gas into the lower ports of the cylinders 248a and 288a to pressurize the volumes below their respective pistons 248c and 288c to a third pressure (that is less than the first pressure) to partially counter-balance the weight of the top-head assembly 300 and slow its descent onto the top surface of the case so as to not damage the case, as block 4022 indicates. That is, since the third pressure of the pressurized gas below the pistons is too low to completely counteract the weight of the top-head assembly 300, the top-head assembly 300 continues descending (albeit at a slower speed).
More generally, the controller 90 is configured to control the top-head-actuating-assembly actuators 248 and 288 to: (1) raise the top-head assembly 300 at a first speed responsive to the leading-surface sensor S2 and the top-surface sensor S3 detecting the case; (2) continue raising the top-head assembly 300 at a second slower speed responsive to the top-surface sensor S3 no longer detecting the case and the leading-surface sensor S2 still detecting the case; (3) enable gravity to stop and begin lowering the top-head assembly 300 responsive to the leading-surface sensor S2 no longer detecting the case; and (4) partially counter-balance the weight of the top-head assembly 300 responsive to the case-entry sensor S4 detecting the case.
The top- and bottom-drive assemblies 320 and 115 begin moving the case C in the direction D. The case C eventually moves off of the infeed table 112, at which point the infeed-table sensor S1 stops detecting the case C and sends a corresponding signal to the controller 90, as block 4024 indicates. Responsive to receiving that signal, the controller 90 controls the side-rail valve 117a to direct pressurized gas into the side-rail pneumatic cylinder 117b on the opposite side of the piston to cause the side-rail pneumatic cylinder 117b to move the side rails 114a and 114b from the centering configuration to the rest configuration to make space on the infeed table 112 for the next case to-be-sealed, as block 4026 indicates.
The top- and bottom-drive assemblies 320 and 115 continue moving the case C, and just before the leading surface of the case C contacts the front roller 1120 of the tape cartridge 1000 the retraction sensor S5 detects the presence of the case C and in response sends a corresponding signal to the controller 90, as block 4028 indicates. Responsive to receiving that signal, the controller 90 controls the roller-arm actuator 1710 and the cutter-arm actuator 1810 to move the first and second roller arms 1110 and 1120 and the cutter arm 1301 to their respective retracted positions, as blocks 4030a and 4030b indicate. Specifically, the controller 90 opens the first tape-cartridge valve 1000v1, which directs pressurized gas: (1) into the cylinder 1711 via the first connector and causes the piston rod 1713 to retract, which causes the front roller arm 1110 and the rear roller arm 1210 (via the first linking member 1020) to move to their respective retracted positions shown in
The leading surface of the case C contacts the front roller 1120 of the tape cartridge 1000 as the front roller arm 1110 is moving to its retracted position, which causes the tape positioned on the front roller 1120 to adhere to the leading surface of the case C. The fact that the front roller arm 1110 is moving toward its retracted position when the case C contacts the front roller 1120 reduces the force the front roller arm assembly 1100 imparts to the leading surface of the case C (compared to certain prior art case sealers), which reduces the likelihood that the roller arm assemblies will damage the case C during taping (compared to certain prior art tape cartridges that do not include actuators to retract the roller arms).
When the front and rear roller arms 1110 and 1210 are in their retracted positions, the front and rear rollers 1120 and 1220 are positioned so they apply enough pressure to the tape to adhere the tape to the top surface of the case C. When the cutter arm 1301 is in its retracted position, the cutter arm 1301 does not contact the top surface of the case C (though in certain embodiments it may do so).
The controller 90 controls the first tape-cartridge valve 1000v1 to remain open to retain the front and rear roller arms 1110 and 1210 and the cutter arm 1301 in their respective retracted positions as the top- and bottom-drive assemblies 320 and 115 move the case C past the tape cartridge 1000. At some point, the case-exit sensor S6 detects the presence of the case C, as block 4032 indicates (though this may occur after the retraction sensor S5 stops detecting the case C depending on the length of the case).
Once the retraction sensor S5 stops detecting the case (indicating that the case has moved past the retraction sensor S5), the retraction sensor S5 sends a corresponding signal to the controller 90, as block 4034 indicates. In response, the controller 90 controls the roller-arm actuator 1710 to enable the first and second roller arms 1110 and 1120 to return to their respective extended positions to apply tape to the trailing surface of the case and controls the cutter-arm actuator 1810 to enable the cutter arm 1301 to return to its extended position to cut the tape from the roll, as blocks 4036a and 4036b indicate. Specifically, the controller 90 closes the first tape-cartridge valve 1000v1 to de-pressurize the corresponding sides of the cylinders 1711 and 1811. De-pressurization of the cylinders 1711 and 1811 enables the first and second roller-arm-assembly-biasing elements 3014a and 3050a to move the front roller arm 1110 and the rear roller arm 1210 (via the first linking member 1020) to their respective extended positions and enables the cutter-arm-biasing element 3305 to move the cutter arm 1301 to its extended position. As this occurs, the finger 1344 of the cutting-device cover 1340 contacts the top surface of the case so the cutting-device cover 1340 pivots to the open position and exposes the cutting device 1330. Continued movement of the cutter arm 1301 brings the toothed blade of the cutting device 1330 into contact with the tape and severs the tape from the roll R. As the front and rear roller arms 1110 and 1210 move back to their extended positions, the rear roller arm 1210 moves so the rear roller 1220 contacts the severed end of the tape and applies the tape to the trailing surface of the case C to complete the taping process.
The top- and bottom-drive assemblies 320 and 115 continue to move the case C until it exits from beneath the top-head assembly 300 onto the outfeed table 113, at which point the case-exit sensor S6 stops detecting the case, as block 4038 indicates, and sends a corresponding signal to the controller 90. Responsive to receiving that signal, the controller 90 controls the first and second top-head-actuating assemblies 230 and 270 to enable the top-head assembly 300 to descend under its own weight. Specifically, the controller 90 controls the first and second top-head-actuating-assembly lower valves 230lv and 270lv to close, as block 4040 indicates. The weight of the top-head assembly 300 causes it to descend back to its initial position. Any gas remaining in the cylinders below their respective pistons vents to atmosphere as the top-head assembly 300 descends.
In various embodiments, a case sealer of the present disclosure comprises a base assembly; a top-head assembly supported by the base assembly; a top-head-assembly actuator supported by the base assembly and operably connected to the top-head assembly to move the top-head assembly relative to the base assembly; and a controller operably connected to the top-head assembly actuator and configured to: responsive to a first sensor detecting a case to-be-sealed, control the top-head-assembly actuator to begin raising the top-head assembly; afterwards, control the top-head-assembly actuator to slow the ascent of the top-head assembly; and responsive to the first sensor no longer detecting the case, control the top-head-assembly actuator to enable the top-head assembly to stop ascending.
In certain such embodiments, the case sealer further comprises a second sensor, and the controller is further configured to control the top-head-assembly actuator to slow the ascent of the top-head assembly responsive to the second sensor no longer detecting the case.
In certain such embodiments, the controller is further configured to control the top-head-assembly actuator to begin raising the top-head assembly responsive to the first and second sensors both detecting the case.
In certain such embodiments, the top-head-assembly actuator comprises a double-acting pneumatic cylinder comprising a cylinder, a piston slidably disposed within an interior of the cylinder, and a piston rod having one end attached to the piston and another end external to the cylinder and operably connected to the top-head assembly.
In certain such embodiments, the case sealer further comprises a top-head-actuating assembly including the pneumatic cylinder, a first valve fluidly connectable to a pressurized gas source and the interior of the cylinder of the pneumatic cylinder on a first side of the piston, and a second valve fluidly connectable to the pressurized gas source and the interior of the cylinder of the pneumatic cylinder on an opposing second side of the piston.
In certain such embodiments, the controller is operably connected to the second valve and configured to, responsive to the first sensor detecting the case, control the second valve to pressurize the interior of the cylinder on the second side of the piston to a first pressure to begin raising the top-head assembly.
In certain such embodiments, the controller is operably connected to the first valve and further configured to control the first valve to pressurize the interior of the cylinder on the first side of the piston to a second pressure lower than the first pressure to slow the ascent of the top-head assembly.
In certain such embodiments, the controller is further configured to, responsive to the first sensor no longer detecting the case, control the first and second valves to enable the top-head assembly to stop ascending and begin lowering under its own weight.
In certain such embodiments, the controller is further configured to, responsive to the first sensor no longer detecting the case, control the first and second valves to stop directing gas into the interior of the cylinder to enable the top-head assembly to stop ascending and begin lowering under its own weight.
In certain such embodiments, the case sealer further comprises a third sensor communicatively connected to the controller, the controller further configured to, responsive to the third sensor detecting the case, control the second valve to pressurize the interior of the cylinder on the second side of the piston to a third pressure lower than the first pressure to partially counter-balance the top-head assembly.
In certain such embodiments, the case sealer further comprises a fourth sensor communicatively connected to the controller, the controller further configured to, responsive to the fourth sensor no longer detecting the case, control the second valve to enable the top-head assembly to lower under its own weight.
In certain such embodiments, the controller is further configured to, responsive to the fourth sensor no longer detecting the case, control the second valve to stop directing gas into the interior of the cylinder to enable the top-head assembly to lower under its own weight.
In certain such embodiments, the case sealer further comprises a third sensor communicatively connected to the controller, the controller further configured to, responsive to the third sensor detecting the case, control the top-head-assembly actuator to lower the top-head assembly onto the case.
In certain such embodiments, the controller is further configured to, responsive to the first sensor no longer detecting the case, control the top-head-assembly actuator to stop the top-head assembly from ascending.
In certain such embodiments, the controller is configured to control the top-head-assembly actuator to slow the ascent of the top-head assembly while the first sensor still detects the case.
In certain such embodiments, the case sealer further comprises a tape cartridge comprising a roller arm comprising a roller, a cutter arm comprising a cutting device, a roller arm actuator operably coupled to the roller arm to move the roller arm between a roller arm retracted position and a roller arm extended position, and a cutter arm actuator operably coupled to the cutter arm to move the cutter arm between a cutter arm retracted position and a cutter arm extended position.
In certain such embodiments, the case sealer further comprises a a retraction sensor, and the controller is operably connected to the roller and cutter arm actuators and further configured to, responsive to receiving a first signal from the retraction sensor, control the roller and cutter arm actuators to respectively move the roller and cutter arms from their extended positions to their retracted positions.
In certain such embodiments, the controller is further configured to, responsive to receiving a second signal from the retraction sensor after the first signal, control the roller and cutter arm actuators to respectively move the roller and cutter arms from their retracted positions to their extended positions.
In certain such embodiments, the case is not in contact with the tape cartridge when the controller receives the first signal.
In certain such embodiments, the case contacts the tape cartridge when the controller receives the second signal.
In various embodiments, a method of operating a case sealer of the present disclosure comprises: responsive to a first sensor detecting a case to-be-sealed, begin raising a top-head assembly relative to a base assembly; afterwards, slowing the ascent of the top-head assembly; and responsive to the first sensor no longer detecting the case, enabling the top-head assembly to stop ascending.
In certain such embodiments, the method further comprises slowing the ascent of the top-head assembly while the first sensor still detects the case.
In certain such embodiments, the method further comprises slowing the ascent of the top-head assembly responsive to a second sensor no longer detecting the case.
In certain such embodiments, the method further comprises begin raising the top-head assembly relative to the base assembly responsive to the first and second sensors both detecting the case.
In certain such embodiments, the method further comprises, responsive to the first sensor detecting the case, controlling a second valve to pressurize an interior of a cylinder on a second side of a piston slidably disposed in the cylinder to a first pressure to begin raising the top-head assembly.
In certain such embodiments, the method further comprises controlling a first valve to pressurize the interior of the cylinder on a first side of the piston to a second pressure lower than the first pressure to slow the ascent of the top-head assembly.
In certain such embodiments, the method further comprises, responsive to the first sensor no longer detecting the case, controlling the first and second valves to enable the top-head assembly to stop ascending and begin lowering under its own weight.
In certain such embodiments, the method further comprises, responsive to the first sensor no longer detecting the case, controlling the first and second valves to stop directing gas into the interior of the cylinder to enable the top-head assembly to stop ascending and begin lowering under its own weight.
In certain such embodiments, the method further comprises, responsive to a third sensor detecting the case, controlling the second valve to pressurize the interior of the cylinder on the second side of the piston to a third pressure lower than the first pressure to partially counter-balance the top-head assembly.
In certain such embodiments, the method further comprises, responsive to a fourth sensor no longer detecting the case, enabling the top-head assembly to lower under its own weight.
In certain such embodiments, the method further comprises, responsive to the fourth sensor no longer detecting the case, controlling the second valve to stop directing gas into the interior of the cylinder to enable the top-head assembly to lower under its own weight.
In certain such embodiments, the method further comprises, responsive to a third sensor detecting the case, lowering the top-head assembly onto the case.
In certain such embodiments, the method further comprises, responsive to the first sensor no longer detecting the case, stopping the top-head-assembly actuator from ascending.
In various embodiments, a case sealer of the present disclosure comprises a tape cartridge configured to apply tape from a tape supply to a case and comprising a cutter arm and a cutter arm actuator operably coupled to the cutter arm to move the cutter arm between a retracted position and an extended position; a case sensor; and a controller communicatively coupled to the case sensor and operably coupled to the cutter arm actuator to, responsive to receipt of a signal from the case sensor, control the cutter arm actuator to move the cutter arm from the retracted position to the extended position to cut the tape from the tape supply.
In certain such embodiments, the signal indicates that the case sensor no longer detects the presence of the case.
In certain such embodiments, the signal is a second signal, and the controller is operably coupled to the cutter arm actuator to, responsive to receipt of a first signal from the case sensor, control the cutter arm actuator to move the cutter arm from the extended position to the retracted position.
In certain such embodiments, the first signal indicates that the case sensor detects the presence of the case.
In certain such embodiments, the second signal indicates that the case sensor no longer detects the presence of the case.
In certain such embodiments, the cutter arm actuator comprises a double-acting pneumatic cylinder.
In certain such embodiments, the cutter arm actuator comprises a pneumatic cylinder, and the controller is configured to control the cutter arm actuator to move the cutter arm from the retracted position to the extended position by controlling a flow of pressurized gas into the pneumatic cylinder.
In certain such embodiments, the tape cartridge further comprises a front roller arm, a front roller attached to the front roller arm, and a roller arm actuator operably coupled to the front roller arm to move the front roller arm between a retracted position and an extended position, and the controller is operably coupled to the roller arm actuator to, responsive to receipt of the signal from the case sensor, control the roller arm actuator to move the front roller arm from the retracted position to the extended position.
In certain such embodiments, the signal is a second signal, and the controller is operably coupled to the roller arm actuator to control the roller arm actuator to, responsive to receipt of a first signal from the case sensor, move the roller arm from the extended position to the retracted position.
In certain such embodiments, the first signal indicates that the case sensor detects the presence of the case.
In certain such embodiments, the second signal indicates that the case sensor no longer detects the presence of the case.
In certain such embodiments, the roller arm actuator comprises a double-acting pneumatic cylinder, and the controller is operably coupled to the cutter arm actuator to, responsive to receipt of a first signal from the case sensor, control the cutter arm actuator to move the cutter arm from the extended position to the retracted position.
In certain such embodiments, the front roller is below the cutter arm when the front roller arm and the cutter arm are in their respective retracted positions.
In various embodiments, a method of operating a case sealer of the present disclosure comprises controlling a drive assembly to move a case relative to a tape cartridge such that the case contacts the tape cartridge and the tape cartridge applies tape from a tape supply to the case; and after the tape cartridge begins applying the tape to the case, responsive to receipt of a signal from a case sensor, controlling a cutter arm actuator to move a cutter arm of the tape cartridge from a retracted position to an extended position to cut the tape from the tape supply.
In certain such embodiments, the signal is a second signal, and the method further comprises controlling the cutter arm actuator to move the cutter arm from the extended position to the retracted position responsive to receipt of a first signal from the case sensor.
In certain such embodiments, the first signal indicates that the case sensor detects the presence of the case.
In certain such embodiments, the second signal indicates that the case sensor no longer detects the presence of the case.
In certain such embodiments, controlling the cutter arm actuator to move the cutter arm of the tape cartridge from the retracted position to the extended position comprises controlling a flow of pressurized gas into the cutter arm actuator.
In certain such embodiments, the method further comprises controlling a roller arm actuator to move front and rear roller arms of the tape cartridge from respective retracted positions to respective extended positions responsive to receipt of the signal from the case sensor.
In certain such embodiments, the signal is a second signal, and the method further comprises controlling the roller arm actuator to, responsive to receipt of a first signal from the case sensor, move the front and rear roller arms from the respective extended positions to the respective retracted positions and controlling the cutter arm actuator to move the cutter arm from the extended position to the retracted position, wherein respective front and rear rollers of the front and rear roller arms are positioned when in their respective retracted positions to apply the tape onto a top surface of the case, wherein the front and rear rollers are below the cutter arm when the front and rear roller arms and the cutter arm are in their respective retracted positions.
In various embodiments, a tape cartridge of the present disclosure comprises one or more mounting plates; a front roller arm comprising a front roller and mounted to the one or more mounting plates; a roller arm actuator operably coupled to the front roller arm to move the front roller arm relative to the one or more mounting plates between a front roller arm retracted position and a front roller arm extended position; a cutter arm comprising a cutting device and mounted to the one or more mounting plates; and a cutter arm actuator operably coupled to the cutter arm to move the cutter arm relative to the one or more mounting plates between a cutter arm retracted position and a cutter arm extended position. The roller arm actuator and the cutter arm actuator are configured to: responsive to the case reaching a first position relative to the tape cartridge, respectively move the front roller arm and the cutter arm from their extended positions to their retracted positions; and responsive to the case reaching a second position relative to the tape cartridge, respectively move the front roller arm and the cutter arm from their retracted positions to their extended positions.
In certain such embodiments, the case is not in contact with the tape cartridge when in the first position.
In certain such embodiments, the case is in contact with the tape cartridge when in the second position.
In certain such embodiments, the roller arm actuator and the cutter arm actuator each comprise a double-acting pneumatic cylinder.
In certain such embodiments, the tape cartridge further comprises a rear roller arm comprising a rear roller and mounted to the one or more mounting plates, and the front roller arm and the rear roller arm are connected such that movement of the front roller arm from the front roller arm extended position to the front roller arm retracted position causes the rear roller to move relative to the one or more mounting plates from a rear roller arm extended position to a rear roller arm retracted position.
In certain such embodiments, the front and rear rollers are below the cutter arm when the front roller arm, the rear roller arm, and the cutter arm are in their respective retracted positions.
In certain such embodiments, the case is not in contact with the tape cartridge when in the first position, wherein the case is in contact with the tape cartridge when in the second position.
This continuation patent application claims priority to and the benefit of U.S. patent application Ser. No. 17/575,384, filed on Jan. 13, 2022, which continuation patent application claims priority to and the benefit of U.S. patent application Ser. No. 16/353,687, filed on Mar. 14, 2019, now U.S. Pat. No. 11,242,169, issued on Feb. 8, 2022, which claims priority to and the benefit of U.S. Provisional Patent Application No. 62/719,226, which was filed on Aug. 17, 2018, and U.S. Provisional Patent Application No. 62/644,850, which was filed on Mar. 19, 2018. The entire contents of these patent applications are incorporated herein by reference.
Number | Name | Date | Kind |
---|---|---|---|
1352899 | Johnson | Sep 1920 | A |
1779985 | Schroeder | Oct 1930 | A |
2691260 | Schlemmer | Oct 1954 | A |
2804738 | Shenigo | Sep 1957 | A |
3267640 | Romney et al. | Aug 1966 | A |
3374604 | Roesner et al. | Mar 1968 | A |
3716962 | Topler et al. | Feb 1973 | A |
3769777 | Freakes et al. | Nov 1973 | A |
3775937 | Devan et al. | Dec 1973 | A |
3800679 | Bartelheimer | Apr 1974 | A |
3892618 | Griebat | Jul 1975 | A |
3915786 | Collett et al. | Oct 1975 | A |
3954550 | Patterson | May 1976 | A |
3959950 | Fukuda | Jun 1976 | A |
3973375 | Loveland | Aug 1976 | A |
4010597 | Nelson | Mar 1977 | A |
4061526 | Warshaw et al. | Dec 1977 | A |
4063403 | Bergstein et al. | Dec 1977 | A |
4079577 | Ulrich et al. | Mar 1978 | A |
4213285 | Mancini | Jul 1980 | A |
4233798 | Helding | Nov 1980 | A |
4293086 | Fincher et al. | Oct 1981 | A |
4295771 | Mehesan | Oct 1981 | A |
4317319 | Price | Mar 1982 | A |
4422282 | Marchetti | Dec 1983 | A |
4478023 | Becker | Oct 1984 | A |
4517784 | Beckett | May 1985 | A |
4524560 | Goodman | Jun 1985 | A |
4538398 | Marchetti | Sep 1985 | A |
4543767 | Wiseman | Oct 1985 | A |
4545175 | Beckett | Oct 1985 | A |
4554042 | Marchetti | Nov 1985 | A |
4562686 | Focke | Jan 1986 | A |
4565050 | Norris | Jan 1986 | A |
4585504 | Marchetti | Apr 1986 | A |
4642966 | Marchetti | Feb 1987 | A |
4722165 | Marchetti | Feb 1988 | A |
4778554 | Doman | Oct 1988 | A |
4781786 | Lerner et al. | Nov 1988 | A |
4875895 | Donnay et al. | Oct 1989 | A |
4955177 | Lerner et al. | Sep 1990 | A |
4972654 | Marchetti | Nov 1990 | A |
4984409 | Focke | Jan 1991 | A |
5022214 | Kim | Jun 1991 | A |
5063726 | Boisseau | Nov 1991 | A |
5066346 | Long et al. | Nov 1991 | A |
5102382 | Center et al. | Apr 1992 | A |
5173140 | Vasilakes | Dec 1992 | A |
5255490 | Chiu | Oct 1993 | A |
5323586 | Lissoni et al. | Jun 1994 | A |
5338384 | Reichert | Aug 1994 | A |
5341626 | Beckmann | Aug 1994 | A |
5454776 | Ulrich et al. | Oct 1995 | A |
5655356 | Ginestra et al. | Aug 1997 | A |
5685814 | Le | Nov 1997 | A |
5759338 | Marchetti | Jun 1998 | A |
6067773 | Le | May 2000 | A |
6070396 | Rinaldi et al. | Jun 2000 | A |
6308495 | Sambuca | Oct 2001 | B1 |
6318048 | Sambuca | Nov 2001 | B1 |
6318049 | Raudat et al. | Nov 2001 | B1 |
6319183 | Ballos | Nov 2001 | B1 |
6669616 | Bierenacki et al. | Dec 2003 | B1 |
6725629 | Pearce et al. | Apr 2004 | B2 |
6910314 | Le | Jun 2005 | B2 |
7140165 | Ventura et al. | Nov 2006 | B2 |
7269933 | Le | Sep 2007 | B2 |
7278248 | Vinh | Oct 2007 | B2 |
7331916 | Fox | Feb 2008 | B2 |
7383864 | Hogerton et al. | Jun 2008 | B2 |
7819357 | Fox et al. | Oct 2010 | B2 |
7886503 | Chase et al. | Feb 2011 | B2 |
7937905 | Fox et al. | May 2011 | B2 |
8079395 | Fox et al. | Dec 2011 | B2 |
8109062 | Chase et al. | Feb 2012 | B2 |
9630796 | Menta et al. | Apr 2017 | B2 |
20020170271 | Pearce et al. | Nov 2002 | A1 |
20030101688 | Albarran | Jun 2003 | A1 |
20040068956 | Hartness et al. | Apr 2004 | A1 |
20040093829 | Marchetti | May 2004 | A1 |
20040123559 | Le | Jul 2004 | A1 |
20040226268 | Vinh | Nov 2004 | A1 |
20050235603 | Le | Oct 2005 | A1 |
20090064636 | Chu | Mar 2009 | A1 |
20090217535 | Fox et al. | Sep 2009 | A1 |
20090218047 | Fox et al. | Sep 2009 | A1 |
20090218048 | Fox et al. | Sep 2009 | A1 |
20110041464 | Park et al. | Feb 2011 | A1 |
20120102893 | Sambuca | May 2012 | A1 |
20120227905 | Menta et al. | Sep 2012 | A1 |
20120232699 | Menta et al. | Sep 2012 | A1 |
20150210418 | Cheich et al. | Jul 2015 | A1 |
20170247129 | Menta et al. | Aug 2017 | A1 |
20180273335 | Fox et al. | Sep 2018 | A1 |
Number | Date | Country |
---|---|---|
201424150 | Mar 2010 | CN |
201424151 | Mar 2010 | CN |
101804924 | Aug 2010 | CN |
3053864 | Aug 2016 | EP |
2007261774 | Oct 2007 | JP |
Entry |
---|
“Case Sealer Uniform Legend”, Little David, Case Sealing for the Real World (2 pages), 2004. |
“Communication pursuant to Article 94(3) EPC”, corresponding European Patent Application No. 19 714 049.4 (6 pages), Sep. 23, 2021. |
“Extended European Search Report”, from corresponding European Patent Application No. 22184335.2, Nov. 28, 2022. |
“International Search Report and Written Opinion”, PCT/US2012/028226, Jun. 11, 2012. |
“LDXRTB 2.0 Series Random Top and Bottom Drive Fully Automatic Case Sealer Operator's Manual”, Loveshaw, an ITW Company, Little David Case Sealer (100 pages), Feb. 18, 2013. |
“Little David Owners Manual LD16R”, The Loveshaw Corporation (59 pages) available before Mar. 19, 2018. |
“International Search Report and Written Opinion”, PCT/US2019/022495, Sep. 12, 2019. |
Number | Date | Country | |
---|---|---|---|
20230303284 A1 | Sep 2023 | US |
Number | Date | Country | |
---|---|---|---|
62719226 | Aug 2018 | US | |
62644850 | Mar 2018 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 17575384 | Jan 2022 | US |
Child | 18327263 | US | |
Parent | 16353687 | Mar 2019 | US |
Child | 17575384 | US |