BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a perspective view of a system for the continuous manufacture of open core elements utilizing one embodiment of the method of the present invention.
FIG. 2 is a top plan view of the system shown in FIG. 1.
FIG. 3 is a perspective view of an upstream portion of the FIG. 1 system showing one embodiment of an apparatus for forming the composite web.
FIG. 4 is a perspective view of an intermediate downstream portion of the system showing the incremental formation of core elements.
FIG. 5 is a perspective view of the downstream portion of the system shown in FIG. 1.
FIG. 6 is a perspective view of an apparatus for forming an all-fluted composite web.
FIG. 7 is a side elevation detail of an alternate flute forming apparatus of a presently preferred construction.
FIG. 8 is a perspective view of an alternate system for the manufacture of open core elements.
FIG. 9 is a perspective detail of a portion of the system shown in FIG. 8.
FIG. 10 is a further perspective detail of the system shown in FIG. 8.
FIG. 11 is a side elevation detail of a preferred embodiment of an upender used in the method of the present invention.
FIGS. 12-14 are cross sectional details of the progressive formation of an open core element from its component webs.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
Referring initially to FIGS. 1 and 3, a core element lay up system 10 utilizes core element components made from a composite web 11 which is converted to form strip like elements (28) which are, in turn, joined to form a core element 13. In the embodiment of the invention shown, a double width composite web 11 is formed by joining a smooth web 14 and a fluted web 15 utilizing any of a number of prior art techniques. For example, the webs 14 and 15 could be formed and glued together in a single facer 16 in a manner well known in the corrugating industry. A smooth web from a supply roll 17 is fluted under heat and pressure in the single facer 16, glue is applied to the flute tips on one side of the fluted web 15, and the fluted web is then joined to the smooth web 14 from the supply roll 18.
The composite web 11 is formed (or reoriented after forming) with the fluted web component 15 facing upwardly. As the composite web 11 exits the single facer 16, it is slit longitudinally on its centerline by a slitting blade 20 to form two web halves 21 and 22. A suitable glue or adhesive is applied to the flute tips of the lower web half 21 by a glue roll 23. The other web half 21 is directed onto an angled turning bar 24 around which it is wrapped and displaced laterally to bring it into contact with the glued web half 21 where the smooth web face of the web half 22 is laid onto the glued flute tips of the other web half 21 to form an open face double wall web 25. The double wall web 25 is directed over a heating plate 26 or other heating device to cure the adhesive and permanently join the two web halves 21 and 22. As will be described in greater detail below with respect to the presently preferred embodiment, the flutes of the two component webs forming the open face double wall web 25 are brought together and joined so that the flutes of the two component webs are in flute tip-to-flue tip alignment.
The open face double wall web 25 is then slit longitudinally with a multi-blade slitter 27 to form a plurality of equal width open face double wall strips 28. The open face double wall web 25 has an upper exposed fluted face and, therefore, the strips 28 also have laterally extending flutes. The strips then pass beneath a second glue roll 30 which applies a suitable adhesive to the exposed flute tips. When the plurality of strips 28 reaches a selected length in the machine direction, a cut-off knife 31 downstream of the glue roll cuts the strips 28 to a common length. The strips are preferably cut at the bottom of the next flute which will provide a core element just slightly larger than the desired length. The plurality of glued and cut strips 32 is accelerated on a transport conveyor 33 to form a gap between the strips and the next-following uncut strips.
The plurality of glued and cut strips 32 is then cross-transferred out of the machine direction path of the next following plurality of strips and onto a lateral feed conveyor 34 to a strip upender 35. As is best seen in FIG. 4, an upender roll 36 has a series of circumferentially spaced vacuum headers 37 that serially capture each glued and cut strip to reorient the strip from a horizontal to a vertical position such that succeeding strips are deposited on common lateral strip edges and in face to face relation with each strip that precedes it. In this orientation, the glued flutes of each strip face the smooth web face of the preceding strip and, when deposited on the element forming conveyor 38, are brought into adhesive contact. As can be seen in FIG. 4, the flutes on the strips extend vertically and together comprise a core element 13. To facilitate removal of each strip 28 from the vacuum header 37 on the upender roll 36, each vacuum header includes a series of laterally spaced vacuum ports between which the tines of a discharge fork 40 extend. The fork is operable to engage the unglued smooth face of each strip and push it into contact with the preceding strip on the element forming conveyor as the vacuum is released. The discharge fork is then returned to its discharge position for the next following strip.
In this embodiment, as the core element 13 is being formed, a set of conveyor belts 41, positioned over the top of the core element, applies a normal force to assist in compacting the core element and press the glued flute tips of each strip to the smooth face of the preceding strip by running slightly faster than the advancing core block which is held back by downstream holding rolls.
When a core element 13 comprising a desired number of strips has been formed, the core element 13 is accelerated into a trim and cut station where it can be cut into any number of smaller core elements. In the example shown in FIG. 5, the large formed core element 13 is trimmed longitudinally (in the longitudinal direction of the strips 28) with a trim blade 42 to a selected edge dimension. The trimmed element 13 is then moved to a cutting position where a series of cutting blades 43, including an edge trim blade, cuts the long core element into final element sizes. For example, if the final core elements are to be used in the manufacture of hollow-core doors, the strips 28 could be cut to lengths of 240″, upended and stacked to a core width of 30″ and finally trimmed and cut to provide three door pieces each 80″×30″.
The height or thickness of the core element 13 depends on the width to which the strips 28 are slit. The length of the core element 13 can be varied as desired. Thus, the system has the capability of continuously and rapidly forming core elements of widely varying dimensions.
Composite fluted webs, useful in forming core elements, can be made in a number of different ways, can utilize different kinds of web materials, and the fluted web can be formed in various ways. As indicated above, it is preferable to utilize a flute size for the fluted web that is larger than flutes commonly made on a typical single facer. A larger flute size will provide adequate strength for the core element, but utilize significantly less paper or other web material in the formation of the fluted web.
Referring to FIG. 6, an alternate apparatus utilizing an alternate flute forming method is shown. In the embodiment shown, a composite web is made by simultaneously fluting two incoming webs which may be made of the same or different materials. If, for example, two paper webs are utilized, an upper web 44 has a layer of glue, such as a starch adhesive, applied to its lower face upstream of a fluting nip 45. A lower web 46 is also fed with the glued upper web 44 into the nip 45 formed at the upper and lower tail sprockets 47 and 48 carrying a pair of intermeshing fluting conveyors 50 and 51. Each of the fluting conveyors 50 or 51 includes a continuous series of fluting bars 52 made, for example, from aluminum extrusions and extending the full width of the incoming webs 44 and 46 (e.g. 96″ or about 2440 mm). The fluting bars may be carried on a series of laterally spaced ¾″ pitch roller chains with the fluting bars 52 attached thereto with conventional K−1 attachments. The roller chains may, for example, be laterally spaced 16″ or about 406 mm apart. Each fluting bar has an exposed flute forming tip 53 that is shaped to form a flute one ½″ (about 13 mm) deep and with a pitch of ¾″ (about 19 mm) corresponding to the pitch of the carrying roller chains.
As the webs 44 and 46 come into the fluting nip 45, they are simultaneously fluted, one flute at a time, and joined by the adhesive previously applied to the contacting face of one of the webs. The joined webs are held together in a straight fluting run 54 of the fluting conveyors 50 and 51 to which heat is applied by upper and lower heating elements 50 and 51 to bond and cure the adhesive. Each of the fluting conveyors 50 and 51 may include flute pre-heaters 57 to help maintain the temperature of the fluting bars 52. A composite fluted web 58 exits the fluting conveyors 50 and 51 at their head ends where, preferably, the conveyor flights are separated gradually on a much larger radius arc than that of the tail sprockets 47 and 48. The resulting composite fluted web 58 is substantially cured and rigid enough for further processing with or without the addition of a smooth facing web.
A composite fluted web 58 of the foregoing type could, for example, be glued to a smooth web and the web processed to form core elements in the manner previously described. However, the composite fluted web 58 also has utility for other applications, such as a substitute for the ubiquitous styrofoam peanuts used as packaging filler and cushioning material.
An alternate and presently preferred apparatus for forming a fluted web is shown schematically in FIG. 7. In this embodiment, a lower fluting conveyor 75 is similar to the fluting conveyor 51 of the FIG. 6 embodiment. The flute bars 76 are heated and, in addition, are provided with a vacuum system enabling the formed flutes to be drawn into the valleys between the flute bars. In lieu of an upper fluting conveyor, a spoked fluting roll 77 is used. The fluting roll is provided with a plurality of circumferentially spaced spokes 78 which press the incoming web one flute at a time into the fluting conveyor 75 where the applied vacuum holds the web in position. If two webs of paper or other materials are joined as described with respect to the FIG. 6 embodiment, the vacuum and heat applied to the web downstream of the fluting roll 77 will cure the composite web resulting in a composite fluted web cured and rigid enough for further processing. the exposed flutes of the upper web may have an adhesive applied by a downstream glue roll 80 for the addition of a smooth facing web.
Although a single wall composite web, having one fluted web and one smooth web, can be utilized in the overall process of the present invention, it is preferable to use an open face double wall web such as web 25 used in the process described with respect to FIGS. 1-5. In that process, a full width single face web is slit on its center line and one of the slit halves is turned and moved laterally on a turning bar to be joined with the other web half. However, an open face double wall web may also be formed by joining two full width single face webs each formed on a separate single facer, as will be described in the following preferred embodiment. Regardless of how an open face double wall web is formed, it is important in order to maximize the strength of the core elements to be formed to align the flutes in the joined single face webs so that they are in alignment flute tip-to-flute tip in the double wall web. On the other hand, if a more springy cushioning effect is desired in a core element, the flutes in the two component single face webs may be aligned one half pitch from flute-to-flute alignment or such that the flutes of one composite single face web align with the valleys of the other composite single face web.
Another embodiment of a system for carrying out the process for the continuous manufacture of open core elements is shown in FIGS. 8-11. The incoming web 60 from the upstream single facer or single facers 59 and 61 may be open face single wall or open face double wall, the later being either full width or half width. Preferably, however, for the reasons stated above, the incoming web 60 is an open face double wall web. A pair of single facers 59 and 61 (or fluted web forming apparatus of FIG. 6 or 7) provide an upper fluted single face web 81 (see the FIG. 12 detail) with its smooth web on the bottom and is joined to a lower fluted single face web 82 (FIG. 12 detail) to the exposed flute tips of which an adhesive has been applied with a glue roll 83. The resulting composite open face double wall web 60 (see the FIG. 13 detail) is heated and cured and brought into the lay-up portion of the system for further processing.
The web 60 is slit in a multi-blade slitting knife 62 into open face double wall strips 63 with the flutes oriented upwardly. As with the previously described process and methods, the width of the strips 63 determines the height or thickness of the finished open core elements. The strips 63 move from the slitting knife under a glue roll 64 where glue is applied to the exposed flute tips. However, in this embodiment one strip is left unglued. The unglued strip 65 may be provided in a number of ways, such as using a laterally movable scraper blade operatively engaging the glue roll to prevent glue from being applied to the unglued strip 65. Successive unglued strips 65 are placed among the strips exiting the glue roll to space between them a selected number of glued strips 63 desired in the finally formed core element. Thus, the unglued strips 65 may not always be in the same lateral position on the strips exiting the glue roll 64 because the desired core element may utilize more or less than the total number strips 63 slit from the incoming web 60.
Each group of strips 63 exiting the glue roll is accelerated on a speed-up conveyor 66 to separate the strips from the next incoming group of strips. The strip group 68 is then cross-transferred onto a lateral feed conveyor 67 where each of the strips now extends laterally across the feed conveyor 67. At the downstream end of the lateral feed conveyor 67, a strip upender 35 identical to the one described with respect to the preceding embodiment, operates to sequentially reorient each strip 63 from a horizontal to a vertical position. Each reoriented strip is positioned with its glued flute tips extending vertically and facing in the downstream direction and is brought into contact with the smooth web on the back of the preceding strip 63.
Referring to FIGS. 8-11, each unglued strip 65 forms the lead strip of a hollow core element 70 (see the FIG. 14 detail) of a desired size. The unglued lead strip 65, after it is upended, is brought into contact with a toothed gate 71 operating between the strip upender 35 and the upstream end of an element forming conveyor 72. When a hollow core element 70 is formed, the toothed gate 71 is retracted and the element 72 moves into contact with a downstream compactor plate 73 on the element forming conveyor 72. As the elements 72 move downstream, an upstream compactor plate 74 moves into contact with the smooth web face of the upstream most stream 63 in the formed element 70. Because the downstream compactor plate 73 engages an unglued strip 65 and the upstream compactor plate 74 engages the smooth web face of the last strip which carries no glue, the problem of a strip adhering to the toothed gate 71 or one of the compactor plates 73 or 74 is minimized.
Instead of utilizing an unglued strip 65, it is also possible to insert an unglued sheet of paper 84 which adheres to the glued flute tips of the facing strip and becomes part of the core element 70. Alternately, the face of the downstream compactor plate 73, in the previously described embodiment, may be coated with a non-stick material.
In an alternate method for compacting the formed core elements 70, the element forming conveyor 72 may be angled downwardly to utilize the force of gravity to help press the strips 63 together. In addition, a weighted plate may be inserted against the smooth web face of the rearmost strip of the core element 70.
Patent Application
20080000580
