This disclosure generally relates to methods and apparatus for reconfiguring containers from a first configuration such as a storage configuration to a second configuration such as an erected configuration. Such methods and apparatus may be employed as part of a container packaging system.
Containers are used to package many different kinds of items. One form of container used in the packaging industry, generically referred to as a “box”, can be used to hold various items including products and sometimes other boxes containing products. Some in the packaging industry refer to boxes used to package one or more products as “cartons”. In the industry, there are also containers/boxes that are known by some as “cases”. Examples of cases include what are known as a regular slotted case (also referred to as an “RSC”).
In this patent document, including the claims, the words “carton”, “cartons”, “container”, “containers” are used collectively and interchangeably to refer to boxes, cartons, trays, containers and/or cases that can be used to package any type of items including products and other cartons/containers.
Cartons come in many different shapes and sizes and can be made from a wide variety of materials. However, many cartons are foldable and are “formed” when they are erected from a first configuration (eg. a flattened state) commonly referred to as a “carton blank”—to a second configuration (eg. an expanded state). Cartons may be made from an assortment of foldable materials, including but not limited to cardboard, chipboard, paperboard, corrugated fibreboard, other types of corrugated materials, plastic materials, composite materials, and the like and possibly even combinations thereof.
In many known systems, carton blanks may be serially retrieved from a carton magazine, reconfigured from a flattened state into an erected state, and placed in a slot on a carton conveyor. The erected carton may then be moved by the carton conveyor to a loading station where the carton may be filled with one or more items. The loaded carton may thereafter be sealed and/or otherwise closed.
To permit carton blanks to be readily configured for use, such as by reconfiguring them from a storage configuration to an erected configuration, blanks may be held in a storage magazine in a generally completely flattened configuration. An apparatus may be provided to manipulate the blanks such that are folded into a particular erected configuration and sealed to form an erected carton. The sealing process typically involves gluing or taping panels and or flaps/together, and specialized apparatus that handle such flat, unfolded and unsealed carton blanks are known.
Some blanks are provided to users not in a flat, unfolded and unsealed configuration, but rather in what is known as a “knock-down” configuration. Blanks in a knock-down configuration are often referred to as “KD” blanks. KD blanks may take partially folded storage configurations, and they may be partially glued or otherwise sealed along one or more seams (typically along one side seam). As such, KD blanks in a storage configuration typically have generally flattened tubular shapes. Accordingly, the erection of a KD blank may require pulling apart generally opposed panels of the blank (such as wall panels) to reconfigure the blank from a generally flattened tubular configuration to an open tubular configuration. The open tubular configuration, or “erect carton”, may then be suitable for delivery to a carton conveyor for loading/filling and sealing/closing.
After being placed on a carton conveyor, an erect carton may have one end closed by folding and sealing the bottom flaps, so that it can be filled from the opposite end while on the carton conveyor. Any required additional flap folding and sealing, such as for example with glue or tape, can be carried out to close and seal the carton with one or more items contained therein. Alternately, for example the erect carton may be reoriented from a side orientation to an upright orientation with an upward-facing opening and a sealed bottom face. The erect carton may then be moved to a loading station/loading system where it may be top loaded with one or more items. The upward-facing opening may then be closed by folding over and sealing the top flaps.
It is well known that carrying out these types of operations under typical industrial conditions involves machinery which is quite complex. For example, the erection of a KD blank into an erected carton is typically done with an apparatus referred to as a “carton erector” or “carton feeder”. In this patent application, the terms “carton erector” and “carton feeder” are used interchangeably. Carton feeders can be configured to serially retrieve KD blanks from a stack of KD blanks held in a magazine, open them up into erect cartons, and place the erect cartons on a carton conveyor. Carton feeders may use suction cups that employ a suction force to engage and hold the KD blanks. The suction cups are typically mounted on a rotary transfer apparatus and the carton feeder may be configured to move the KD blanks/cartons along a rotational path that is generally arcuate, and which may be cyclical, between the various locations for retrieval, opening and release of an erected carton.
These operations may be executed at high speed and with a high degree of precision in order to provide a reliable and efficient carton feeding process. However, difficulties can arise in designing components that can achieve a clean retrieval, rotation and release by the carton feeder. For example, during retrieval of blanks from a magazine, rotation of the rotary transfer apparatus may result in retrieved KD blanks held by one or more suction cups making contact with one or more of the stack of blanks, the magazine, and the support frame. Undesirable contact may reduce the precision of the retrieval operation, and may lead to issues—especially when the KD blanks/cartons are large and/or are rigid/semi-rigid. For example, the contact may result in the KD blank becoming improperly oriented while being held by the suction cups, with potential problems in the opening of the KD blank and/or its proper placement on a carton conveyor.
Accordingly, an improved system for retrieving a KD blanks, erecting them into cartons and releasing the cartons for further processing is desirable.
In one aspect, the present disclosure relates to an apparatus the comprises a blank holding apparatus operable to releasably hold a plurality of carton blanks in a first configuration; a rotary apparatus operable to rotate an engagement device along a rotational path from a first retrieval location where the engagement device is operable to engage with and retrieve a blank from the plurality of blanks held in said blank holding apparatus, to a second operational location; and a movement apparatus inter-connected to said rotary apparatus, said movement apparatus operable to move the rotary apparatus and the engagement device with said engaged blank away from the blank holding apparatus.
In another aspect, the present disclosure relates to an apparatus that comprises a magazine for containing a plurality of flattened tubular container blanks; a rotary apparatus operable to rotate an engagement device along a cyclical rotational path between an on-loading location where the engagement device engages a blank from the plurality of flattened tubular container blanks, an operation location where the blank is at least partially erected into a container, and an off-loading location where the engagement device releases the container; and a slide apparatus comprising a slide assembly on which the rotary apparatus is mounted, the slide apparatus operable to translate the rotary apparatus from a first translational position where said engagement device can engage a blank, to a second translational position away from the magazine to allow the engagement element to traverse the rotational path without causing the blank to contact the plurality of flattened tubular container blanks, and then after the container is released, to translate the rotary apparatus back to the first translational position.
In another aspect, the present disclosure relates to a method of retrieving a blank from a plurality of blanks that comprises rotating an engagement device of a rotary apparatus along a rotational path to a first retrieval location; retrieving a blank from the plurality of blanks with the engagement device; moving the rotary apparatus including the engagement device with the engaged blank away from the plurality of blanks; and rotating the rotary apparatus including the engagement device with the engaged blank to a second operational location.
In another aspect, the present disclosure relates to a method of erecting a flattened tubular container blank into a container, the method comprises retrieving a blank from a plurality of flattened tubular container blanks, at an on-loading position, by engaging the blank with an engagement device which is connected to a rotary member which is mounted on a slide frame; translating the slide frame to bring the rotary member, the engagement element and the blank a distance away from the plurality of flattened tubular container blanks; rotating the rotary member to bring the blank into an operation location and at least partially erecting the blank into a container; and releasing the container from the engagement element at an off-loading location.
Other aspects and features will become apparent, to those ordinarily skilled in the art, upon review of the following description of the specific illustrative embodiments.
Non-limiting embodiments are described in detail below, with reference to the following drawings.
With reference initially to
Allen Bradley.
Suitable power sources such as electrical power sources may be provided to supply power to components of system 101, including components of carton feeder 100, such as PLC 109 and the various motors, servo drive motors, valves and sensors as described herein.
Carton feeder 100 may be operable to: (i) retrieve flattened tubular carton blanks 200 (hereinafter referred to as KD blanks 200 from a stack 210 of blanks, (ii) erect them into an at least partially erect cartons 220; and (iii) release the cartons 220 for further processing/handling.
With reference to
KD blanks 200 may be made of a variety of materials such as cardboard, chipboard, paperboard, corrugated fibreboard, other types of corrugated materials, plastic materials, composite materials, and the like and possibly even combinations thereof. KD blanks 200 may be of any particular shape and may have any particular dimensions. By way of example only, KD blanks 200 when erected may form generally cuboid shaped cartons and may typically have width dimensions W and height dimensions H. When held in a blank holding apparatus 150 (see
With reference to
Carton feeder 100 may also comprise a translational movement mechanism 240 which may include a sliding apparatus 120. Sliding apparatus may be operable to move the rotary transfer apparatus 110 such as with translational movement, relative to the blank holding apparatus 150. Sliding apparatus 120 may include a slide assembly 121. Components of slide assembly 121 may each be made from one or more suitable materials such as for example steel or stainless steel.
Slide apparatus 120 may also include rail members 124a, 124b mounted to a respective support plate 199a, 199b (
Sliding apparatus 120 may be configured to be able to move sliding assembly 121 with sliding, reciprocating, translational movement relative to sub-frame 160 on rails 124a, 124b. Rotary transfer apparatus 110 may be mounted to and supported on sliding assembly 121 for sliding, reciprocating, translational movement with sliding assembly 121 towards and away from blank holding apparatus 150. Components of sliding apparatus 120 such as sliding assembly 121 may be configured to move with reciprocating translational movement relative to sub-frame 160 such that rotary transfer apparatus 110 may be moved in translational movement between a first position which is proximate to storage apparatus 150 (i.e. at a blank retrieval location 300) and a second position which is at an increased distance from blank holding apparatus 150.
Rotary transfer apparatus 110 may have at least one engagement device such as pairs of engagement elements 116a, 116b (eg. a suction cup) that may be movable along a path, as described further below. In carton feeder 100, rotary transfer apparatus 110 has one pair of spaced engagement elements 116a oriented in one direction a second pair of spaced engagement elements 116b oriented in an opposite direction such that they are oriented at an angle 180 degrees apart.
In overview, rotary transfer apparatus 110 and slide apparatus 120 may provide a mechanism for enabling pairs of engagement elements 116a, 116b of rotary transfer apparatus 110 to: (i) successively and serially engage and retrieve KD blanks 200 from storage apparatus 150, (ii) translate each KD blank 200 in turn away from blank holding apparatus 150; and (iii) rotate each blank along a rotational path.
In various embodiments, translational movement of the rotary transfer apparatus 110 with engagement elements 116a, 116b with the KD blank 200 engaged by the engagement elements 116a, 116b, away from the engagement location proximate storage apparatus 150, may occur at the same time as, during, or prior to commencing, rotation of the KD blank by rotary transfer apparatus 110 on a rotational path away from storage apparatus 150. This translational movement may minimize or eliminate unwanted contact between KD blank 200 and one or more of stack 210, blank holding apparatus 150, and sub-frame 160.
Rotation of rotary transfer apparatus 110 may also be operable to move engagement elements 116a, 116b thereof, and each KD blank 200 secured to the engagement elements, on rotational paths from the engagement location proximate the blank storage apparatus 150, to a carton opening location 310 which is proximate to carton opening apparatus 130. In the carton opening location, KD blank 200 may be at least partially opened into an erected carton 220 with the assistance of carton opening apparatus 130. Further rotation by rotary transfer apparatus 110 of engagement elements 116a, 116b on their rotational paths may bring each KD blank 220 (at least partially erected) into a release location 320 which is proximate to hold-down apparatus 140. At the release location, the KD blank 200 may be reconfigured to its fully erect configuration. This may occur by engagement of the KD blank 200 with a wall of a bucket/slot on carton conveyor 105. Hold-down apparatus 140 may be operable to stabilize carton 220 as it is released and positioned by engagement elements 116a, 116b of rotary transfer apparatus 110 in a bucket/slot of carton conveyor 205. Rotary transfer apparatus 110 and engagement elements 116a, 116b, in combination with hold-down apparatus 140, may co-operate to hold erected carton of KD blank 220 in a bucket/slot on carton conveyor 105.
Once the erected carton 220 has been released from hold down apparatus 140, slide apparatus 120 may move rotary transfer apparatus 110 and its engagement elements 116a, 116b in translational movement back towards blank holding apparatus 150 to permit the rotation of rotary transfer apparatus 110 and engagement elements 116a, 116b. Rotary transfer apparatus 110 may also rotate engagement elements 116a, 116b. The combined result of such movement is that engagement elements are brought again to a position and are operable to retrieve the next KD blank 200 from the blank holding apparatus 150. Then the cycle may start again.
Rotary transfer apparatus 110 may rotate the engagement elements 116a, 116b in such a manner that first pair of engagement elements 116a engaging a KD blank 200 may follow the same rotational path as second pair of engagement elements 116b engaging another KD blank 200, relative to sliding apparatus 120, but with the engagement elements 116a, moving and operating 180 degrees out of phase with engagement elements 116b.
Now specific components and the operation of carton feeder 100 are hereinafter described in more detail. In general, the components of carton feeder 100 may be made of suitable known materials. For example, some components may be made from suitable steels, aluminum and other metals. Again with particular reference to
With particular reference back again to
Magazine 152 may be configured such that KD blanks 200 are oriented in a manner which is favourable for retrieval in series by rotary transfer apparatus 110. For example, each stack 210 may be oriented such that when held in magazine 152 ready to be retrieved by rotary transfer apparatus 110, each KD blank 200 is positioned with an engagement surface that lies substantially parallel to the engagement surface of engagement elements 116a, 116b when the engagement elements are at the pick-up location as defined by the rotational movement of rotary apparatus 110.
Magazine 152 may be supported on sub-frame 160 in a cantilevered manner by transversely spaced, longitudinally oriented support beams 162/163 which may be connected to respective vertically oriented support columns 164/165. Longitudinal beams 162/163 and vertical support columns 164/165 may form components of sub-frame 160. Sub-frame 160 may also include transverse beam 161 which may fixedly inter-connect, stabilize and support longitudinal support beams 162 and 163. Magazine 152 may be positioned and operable to be size adjustable to accommodate KD blanks 200 of varying dimensions.
With particular reference to
Rotary transfer apparatus 110 may include a transversely oriented rotary shaft member 112 that may rotate about transversely oriented axis X1 (
With particular reference to
As shown, rotary shaft member 112 along with gearing mechanism 117 may be rotatably mounted in a cantilevered manner from support bracket 122. In other embodiments, carriage 122b may support an opposite side of rotary transfer apparatus.
Bracket/carriage 122a may also be interconnected and secured to a longitudinally and vertically oriented plate member 128a forming part of slide assembly 121 of slide apparatus 120 (see
With particular reference to
Valves (not shown) may be provided in the supply of pressurized air to the vacuum generators and the valves may be controlled by PLC 109 based on signals provided by an encoder associated with servo drive motor 118 (as described below) associated with rotary transfer apparatus 110. PLC 109 may thus control the turning on and off of suction of engagement members 116a, 116b during movement about the rotational and translational path (i.e. turn the suction on and off depending upon the position of each of pairs of engagement members 116a, 116b).
The first radial arm portions 114a are transversely spaced apart and operable such that first pair of engagement elements 116a, can engage, rotate and release KD blanks 200 they retrieve from blank holding apparatus 150. The second radial arm portions 114b move and operate out of phase by 180 degrees to the first radial arm portions 114b, and second radial arm portions 114b are also operable such that the second pair of engagement elements 116b can separately engage, rotate and release KD blanks 220 they retrieve from the blank holding apparatus 150.
Rotary transfer apparatus 110 may be configured such that first and second pairs of radial arm portions 114a, 114b, and in particular the respective engagement elements 116a, 116b secured thereto, move in a rotational path (and in particular a hypotrochoidal/hypocycloidal cylical path relative to the sliding components of sliding apparatus 120 like the suction cups of the rotary transfer mechanisms in U.S. Pat. Nos. 3,937,458 and 4,537,587).
With particular reference to
Rotary shaft member 112 may, by way of example only, be typically in the range of between 24 and 36 inches in length.
Rotary shaft member 112 may be made of any suitable material (such as steel or stainless steel) which is suitably strong and rigid to support plurality of radial arms 114, platforms 111, support elements 113 and engagement elements 116 (as well as KD blank 200) and be able to withstand the forces imparted thereon during operation. Likewise, radial arms 114 and platforms 111 may be made from suitable materials such as aluminum or be plastic 3D printed.
With particular reference to
With particular reference to
Guide rails 224a may be mounted to sliding plate 128a (
As indicated above, support bracket/carriage 122a may be fixedly secured to slide plate 128a. Rotary transfer apparatus 110 may thus be interconnected to slide plate 128a via bracket 122/carriage, and slide plates 128a, 128b may be configured to translate together along respective rails 124a, 124b. Thus, slide plates 128a, 128b may be configured to have reciprocating translational movement in the longitudinal direction relative to sub-frame 160, and thus provide for the reciprocating translational movement of rotary transfer apparatus 110 in a longitudinal direction relative to blank holding apparatus 150.
Slide plates 128a, 128b may be fixedly spaced relative to each other by interconnecting transverse beams 127a and 127b (
Also as shown in
Servo drive motor 126 may be any type of servo drive motor which is capable of driving the rotational movement of rotary drive shaft 123 about axis X2 in both clockwise and anti-clockwise directions. For example, servo drive motor 126 may be a model VPL-A1153C made by Allen Bradley.
Servo drive motor 126 may include an encoder and may be in communication with PLC 109 such that the rotational movement of rotary drive shaft 123, and the linkage mechanism 125 connected thereto, can be controlled by PLC 109.
Linkage mechanism 125 may be configured to convert the rotation of rotary drive shaft 123 into the translational longitudinal movement of slide assembly 121. For example, linkage member 125 may have a first portion 125a with a distal end 125a′ which is keyed to drive shaft 123, a second portion 125b with a distal end 125b′ which is rotatably fixed to slide assembly 121, and a hinge portion 125c which connects adjacent ends of first and second portions 125a, 125b and defines an angle α between first portion 125a and second portion 125b. In this configuration, distal end 125a′ of linkage member 125 is fixed from longitudinal translational movement due to its connection with drive shaft 123. In contrast, distal end 125b′ of linkage member 125 is translatable due to its connection with slide assembly 121.
Referring to
Rotation of drive shaft 123 in a second clockwise direction (opposite to the first direction), may return first portion 125a of linkage member 125 to its earlier position, which may “pull” slide assembly 121 back to its earlier position as angle α is decreased. As rotary transfer apparatus 110 may be mounted on slide assembly 121 (via bracket 122), the rotation of drive shaft 123 in the second direction may return rotary transfer apparatus 110 to its earlier position proximal to blank holding apparatus 150 (i.e. pick-up/retrieval location 300).
The slide apparatus 120, including slide assembly 121 and linkage mechanism 125, and drive shaft 123 may be configured such that servo drive motor 126 may, by way of example only, drive the rotation of drive shaft 123 through only a portion of a full rotation, such as for example an angle of rotation of 120 degrees. In an example embodiment, this may equate to a longitudinal translation of slide assembly 121 by a distance of between about 5 and 10 inches. In particular, the components may be configured such that servo drive motor 126 may drive the longitudinal translation of slide assembly 121 a distance of about 7 inches. The distance travelled by slide assembly 121 may be adjusted to account for various processes including the size and shape of KD blank 200 and the sizes of the various components of carton feeder 100.
Drive shaft 123 may be in some embodiments be between 24 and 36 in length and between 1¼ and 1½ inches in diameter. Drive shaft 123 and linkage mechanism 125 may be made of one of more materials which are suitably strong and rigid to withstand the torsional force required to translate slide assembly 121 such as steel.
As noted above, drive shaft 123 may be rotatably mounted such that it does not translate with slide assembly 121. Openings 129 in longitudinal plates 128a, 128b allow for the translational motion of slide assembly 121 without interfering with the fixed longitudinal position of drive shaft 123 relative to sub-frame 160.
Slide apparatus 120 may comprise any number of linkage mechanisms 125. Preferably, slide apparatus 120 comprises two linkage mechanisms 125 spaced transversely apart from each other such as having with one proximate each end of drive shaft 123. Each linkage mechanism 125 may take a number of different configurations to transfer the rotational movement of drive shaft 123 into the longitudinal translation of slide assembly 121.
In other embodiments, other drive mechanisms are contemplated for driving the translational movement of slide assembly 121 and/or rotary transfer apparatus.
As best seen in
In carton feeder 100, carton opening apparatus 130 may comprise a pair of transversely spaced blank releasable panel attachment elements 134 (which may be suction cups as described above). Attachment elements 134 may be supported on fixtures 133. Fixtures 133 may be hollow rigid tube members that may be in air flow communication with the outlet of vacuum generators 239. Vacuum generators 239 may themselves be supported on a common transversely oriented support bar 135. Transverse support bar 135 may be supported by a pair of transversely spaced, longitudinal bars 132. Bars 132 may be mounted to a support plate 139. Support plate 139 may be mounted on a rail carriage 241 that may be movable along a rail 136.
Rail 136 may be fixedly interconnected to sub-frame 160. This may accomplished by centrally mounting rail 136 on a support plate 260. Support plate 260 maybe supported proximate one end thereof to a support bracket/post 131 that may be oriented vertically.
Vacuum generators 239 may be mounted on transverse bar 135 by having rods (not shown) engaging with slots 243 such that vacuum generators 239 and their fixtures 133 and attachment elements 134 may be selectively positioned along transverse bar 135. This may provide a mechanism to facilitate the adjustment of the spacing of multiple attachment elements 134 to allow for engagement with various sizes/shapes of KD blanks 200.
Preferably, releasable attachment elements 134 may be vacuum-actuated suction cups coupled to a vacuum generator. Similar to the vacuum generators referenced above, separate vacuum generators 239 may be mounted to transverse bar 135 any fixtures 133 may be mounted to an outlet of the vacuum generators 239. A vacuum generator suitable for this use is produced by PIAB AB sold under model no. PCL.X4BN.S.EE.SV.
Valves may be controlled by PLC 109 based on signals provided by an encoder associated with servo drive motor 118 (as described below) associated with rotational movement of rotary transfer apparatus 110 and signals provided from the encoder associated with servo drive motor 121 that are indicative of the translational movement and position of slide assembly 121 and rotary transfer apparatus 110. PLC 109 may thus control the actuation of suction of attachment elements 134 (i.e. turn the suction on and off depending upon the position of each of the pairs of attachment elements 134 and the position of the rotary transfer apparatus 110 and the engagement elements 113a, 113b.
Continuing with
Support plate 139 may be mounted on a rail carriage 241 that may be movable along a rail 136. Still with reference to
Servo drive motor 138 may be any type of servo drive motor which is capable of driving belt 137. For example, servo drive motor 138 may be a model VPL-A0633F made by Allen Bradley. Servo drive motor 126 may include an encoder and may be in communication with PLC 109 such that longitudinal position of attachment elements 134 relative to sub-frame 160, and relative to engagement elements 116a, 116b can be controlled by PLC 109.
Servo motor 138 may drive the translation of attachment elements 134 a distance of 7 inches. The distance travelled may be adjusted to account for various process including the size and shape of KD blank 200/carton 220
Rail 136 may be made of any material which is strong enough to support the translation of carriage 139 and the components which translate therewith. Rails 136, and any other linear rails used in the system may be for example Bosch Rexroth standard rails with sliding blocks size 15 or 20.
As best seen in
Hold-down apparatus 140 may be mounted to the rear of slide assembly 121 such that it moves in translational longitudinal movement with sliding assembly 121 and rotary transfer apparatus 110.
Hold down apparatus 140 may also include vertical columns 147 which may be fixedly attached to transverse beams 127a of slide frame 121. A plate 148 may be mounted to columns 147 such that plate 148 hangs from slide frame 121 in a substantially horizontal configuration. Rail 141 may be fixedly mounted to plate 148, and belt 146/servo drive motor 144 may also at least in part be supported by plate 148. The servo drive motor 144 and belt 146 may be configured to drive and translate carriage 145 in reciprocating longitudinal movement along rail 141.
Staying with
Columns 147 and plate 148 may, independently, be of any shape, size or materials, provided that they cooperate to provide a platform for carriage 145 to translate along rail 141 as driven by belt 146 and servo motor 144.
Servo drive motor 144 may be any type of servo drive motor which is capable of driving belt 146, carriage 145, and the other components connected thereto. For example, servo drive motor 144 may be a model VPL-A0633F made by Allen Bradley. Servo drive motor 144 may include an encoder and may be in communication with PLC 109 such that longitudinal position of hold down members 142d relative to rail 141, and relative to the slot on conveyor 105 at the release location holding an erected deposited carton, can be controlled by PLC 109.
Servo motor 144 may by way of example only drive the translation of hold down members 142d a distance of in the range of 4 to 12 inches. The distance travelled may be adjusted to account for various factors including the size and shape of KD blank 200/carton 220.
Each component of hold-down apparatus 142 may be of any size, shape and material provided that they cooperate to facilitate the release of carton 220 at release location 320. For example, hold-down member 142d may be ski-, rod-, or bar-shaped, and proximal ends 142d′ of hold-down member 142 may be curved upwards to better facilitate the release of carton 320 from rotary transfer apparatus 110.
In operation, carton feeder 100 including rotary transfer apparatus 110 and each set of its engagement elements 116a, 116b, may pass through the sequence of configurations generally set out in
Referring to
Referring to
In some embodiments, the clockwise rotation of engagement elements 116a may be commenced by rotary transfer apparatus 110 after time slide assembly 121 starts to move the rotary transfer apparatus 110 in translational movement away from blank holding apparatus 150. In some embodiments, the clockwise rotation of engagement elements 116a may be commenced by rotary transfer apparatus 110 at the same time slide assembly 121 starts to move the rotary transfer apparatus 110 in translational movement away from blank holding apparatus 150. In other embodiments, the clockwise rotation of engagement elements 116a may be commenced by rotary transfer apparatus 110 while slide assembly 121 is still moving the rotary transfer apparatus in translational movement away from blank holding apparatus 150.
Referring to
Referring to
Referring next to
Referring next to
Referring to
Referring now to
Although not shown in
It may be appreciated then that between position I and position J of
Also, not shown is the movement of the hold down members 142d which would also move between positions C and E in
It will be appreciated by those skilled in the art that changes could be made to the various aspects of the subject application described above without departing from the inventive concept thereof. It is to be understood, therefore, that this subject application is not limited to the particular aspects disclosed, but it is intended to cover modifications as defined by the appended claims.
When introducing elements of the present disclosure or the embodiments thereof, the articles “a,” “an,” “the,” and “said” are intended to mean that there are one or more of the elements. The terms “comprising,” “including,” and “having” are intended to be inclusive and mean that there may be additional elements other than the listed elements.
This application is a Continuation of U.S. patent application Ser. No. 15/970,477 filed on May 3, 2018 and which claimed the priority benefit of U.S. Provisional Patent Application Ser. No. 62/501,562 filed on May 4, 2017. The contents of the aforementioned applications are incorporated herein in their entirety.
Number | Date | Country | |
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62501562 | May 2017 | US |
Number | Date | Country | |
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Parent | 15970477 | May 2018 | US |
Child | 17084047 | US |