forming devices to form a longitudinally corrugated web

专利摘要:
TRAINING DEVICE AND METHOD FOR FORMING A LONGITUDINALLY CORRUGATED SOUL. The present invention relates to a forming device for gathering the width of a displacement core. The forming device includes opposing arrangements of grooving bars which can be interposed to define therebetween a longitudinal grooving labyrinth effective to reduce the width of a web traveling therethrough for a preselected draw ratio. The grooving bars are curved starting at an inlet end of the forming device such that they converge in a lateral direction as they proceed in the machine direction. In this way, the individual web elements traveling between the respective arrangements in the machine direction follow the contour lines along the curved bars or between the adjacent bars of the curved bars so that no element crosses any grooving bar in the transverse direction to the machine as the soul travels and is grooved. A corrugated die to introduce an almost liquid form to the grooved intermediate web is also described, as is a corrugation line incorporating these operations and methods for this (...).
公开号:BR112015009902B1
申请号:R112015009902-5
申请日:2013-10-30
公开日:2021-04-20
发明作者:Herbert Kohler
申请人:Hbk Family, Llc；
IPC主号:

专利说明:

CROSS REFERENCE TO RELATED ORDERS
[001]This application claims the benefit of US Provisional Patent Application No. 61/721,079 filed November 1, 2012, which is incorporated herein by reference. FUNDAMENTALS OF THE INVENTION
[002] Corrugated webs have increased strength and dimensional stability compared to non-corrugated (ie, flat) webs of the same material. For example, corrugated board is widely used in storage and shipping boxes and other packaging materials for strength. A typical corrugated cardboard structure known as a "double wall" includes a corrugated cardboard web placed between opposing uncorrugated cardboard webs called 'liners'. Opposite coatings are adhered to opposing surfaces of the corrugated web to produce a composite corrugated structure, typically by bonding each coating to the crests of adjacent grooves of the corrugated web. This structure is initially fabricated from flat composite boards, which can then be cut, folded, glued, or otherwise formed into a desired configuration to produce a box or other type of package.
[003] Corrugated webs, such as cardboard, are formed in a corrugating machine from flat webs. A conventional corrugating machine feeds the flat web through a nip between a pair of corrugation rolls rotating on axes that are perpendicular to the sheet travel direction when viewed from above. Each of the corrugation rolls has a plurality of longitudinally extending ribs defining alternating peaks and troughs distributed around the circumference and extending the length of the roll. The rollers are arranged so that their respective ribs interlock the nip, with the ribs of one roller being received within the valleys of the adjacent roller. The interlocking ribs define a maze of corrugation through which the web moves as it traverses the nip. As the web is pulled through the corrugation labyrinth, it is forced to conform to its configuration, thereby introducing grooves or corrugations into the web that approximate the dimensions of the path through the corrugation labyrinth. Consequently, it is clear that in a conventional corrugating machine, grooves are introduced into the weft along a direction that is transverse to the weft travel path; that is, the grooves extend in a transverse direction (cross-machine) to the weft travel direction (machine direction). More simply, the grooves conventionally extend across the width of the weft between its side edges. An example of this conventional methodology is shown in the US Patent. No. 8,057,621 (see Figures 7 and 7a thereof), which is incorporated herein by reference.
[004] Corrugating a web in this way can damage cardboard or other web material because it introduces a substantial amount of oscillatory tension and friction forces to the web while traversing the corrugation nip. Briefly, as the web is pulled between the corrugation rolls and forced to negotiate the corrugation labyrinth, the web tension, as well as compressive stresses normal to the input web plane, oscillates in magnitude and direction as grooves successive ones are formed due to the reciprocating motion of the corrugation grooves with respect to the weft, and due to the variations in winding and tension in the weft through the labyrinth as it is being corrugated. The oscillatory nature of the tension in the weft through a maze of corrugation between corrugation rolls is well documented; see, for example, Clyde H. Sprague, Development of a Cold Corrugating Process Final Report, The Institute of Paper Chemistry, Appleton, Wisconsin, Section 2, p. 45, 1985. The resulting substantial cyclic peaks in weft tension typically produce some structural damage to the weft as it is corrugated.
[005] In addition to undesirable tension effects, corrugating the weft in the cross-machine direction introduces grooves that extend transversely to the fibers of the cardboard, which typically run the length of the weft in the machine direction. Thus, grooves formed in a cross-machine direction need to be reoriented and introduce crimps into the paper fibers, which can also lead to reduced strength.
[006] One way to address the problems mentioned above would be to corrugate the weft in the machine direction so that the grooves extend along the weft travel path direction; that is, in the longitudinal direction of the weft itself. This is commonly called 'longitudinal corrugation' or 'linear corrugation'. One problem with longitudinal curl is that as longitudinally extending grooves are formed, they necessarily consume weft width (i.e., weft extension in the lateral, cross-machine direction) in order to convert the weft initially flat on one having peaks and valleys. In other words, to produce longitudinally extending grooves, the web needs to be collected in the cross-machine direction such that its total width after the grooves are formed is less than the width of the web before the formation of the grooves. The ratio of the flat web's original pre-corrugated width to its post-corrugated width is called the 'take-up ratio'. Draw ratios are well known for standard groove sizes in conventional transverse corrugation methods. For example, a transversely corrugated A-grooved web exhibits a typical draw ratio of 1.56 because the amplitude and pitch of A-grooves are such that feeding them into the web reduces the length of the web (ie, its linear dimension in a direction transverse to the grooves) by 64%; that is, making the ratio of the starting length to the final length equal to 1.56. In other words, in conventional corrugation, when you want to end up with 100 yards of transversely corrugated web, you have to feed 156 yards of flat web into the corrugating machine to account for the length of web consumed by introducing slots A.
[007] A similar draw ratio will be present in linear corrugation, except that now the ratio will be applied to the width of the weft in the cross-machine direction rather than its length. This introduces a special problem because typical linear corrugation devices such as linear corrugation rollers cannot simultaneously collect the web width and introduce corrugations without damaging and tearing the web. For example, linear corrugation rollers have circumferentially extending ribs and longitudinally distributed troughs along the length of the rollers, the circumferential ribs of one roller being received within the circumferential troughs of the opposite roller, and vice versa. Unless the web width is condensed sufficiently to justify the stretch ratio of the finished product before entering the nip between these rolls, it will be substantially larger than the product destined to enter the nip and would have to be instantly and simultaneously collected and corrugated to produce the desired product. This cannot be achieved without damaging and tearing the weave. To solve this problem, the shifting web should be collected from its initial width to its approximate final width, based on the anticipated draw ratio, before being fed into the linear corrugation rolls or other corrugating device.
[008] For this reason, until now performing linear corrugation is impractical for commercial applications that require conventional slot sizes (eg A to E slots) for useful weft widths (eg 127 cm (50 inches) final width )). US Patent. No. 7,691,045 (herein incorporated by reference) describes a machine for picking up a weft moving laterally in the cross-machine direction before feeding that weft into a set of rollers to introduce a three-dimensional pattern into the weft. This machine uses a series of opposing rollers arranged along the machine direction to introduce longitudinal folds into the weft starting at the center of the weft. Each successive set of rollers then introduces two additional folds on either side of the previously made fold(s) until the entire weft is made up of a series of longitudinal folds or grooves so that the entire width of the weft is collected in one desired degree. Such a machine can be effective in picking up the width of a paper or other web prior to downstream operations (such as corrugation or other three-dimensional formation) to relatively narrow widths that are not particularly useful on a commercial scale. Unfortunately, however, for commercial widths of, for example, 127 cm (50 inches) or more, the number of successive sets of opposing rollers that would be required to successively form the longitudinal grooves is such that the machine would be impractically long, producing a very large footprint. Consequently, such a machine is not capable of being retrofitted to existing corrugation lines where space is tight, and for new installations, a lot of space would be required to be practical.
[009] Patent Application Publication No. 2010/0331160 (herein incorporated by reference), which is commonly assigned with the present application, describes another machine for picking up the width of a shifting web. This machine uses opposing sets of linear grooving bars that generally extend in the machine direction, where the spacing between adjacent bars generally decreases along the machine direction. Opposite sets of bars are interwoven so that the shifting web gradually adjusts to an intermediate grooved longitudinally groove geometry as it passes between the opposing sets of bars by virtue of decreasing lateral spacing between the bars. This machine has the advantage that it is capable of picking up the width of a moving weft within a relatively short distance of weft travel, and is therefore of a practical size and footprint to be retrofitted in existing installations. However, as the cardboard web traverses the labyrinth between the opposing sets of slotting bars and is collected laterally inward, the individual paper elements in the web are dragged laterally across the bars, thus introducing lateral tension variations. position- and time-dependent and oscillations throughout the weave, which are undesirable and can contribute to weft damage.
[010] It would be desirable to collect the width of a web in material displacement in the cross machine direction according to a desirable predetermined stretch ratio for downstream processing, while minimizing or eliminating the introduction of frictional forces or lateral tension in the web as a result of the collection operation. The collected web could then be introduced into downstream processing operations, such as longitudinal corrugation operations or other operations to introduce three-dimensional structure to the web, downstream operations(s) that will benefit from the lateral stretch ratio introduced in the previous collection operation . SUMMARY OF THE INVENTION
[011]A forming device that is described has an input end and an output end separated along a machine direction. The forming device includes a plurality of groove forming bars which extend adjacent the inlet towards the outlet end. At least a subset of the plurality of grooving bars is curved such that they converge in a cross-machine direction as they advance to the exit end.
[012]A corrugation matrix that is also described has an input end and an output end separated along a machine direction. The corrugation die has a smooth, continuous first forming surface having a first tortuous contour seen in cross section adjacent to the inlet end. The first forming surface gradually evolves in the machine direction to a second tortuous contour seen in lateral cross section adjacent to the exit end. The first winding contour has a greater amplitude and lower frequency than said second winding contour.
[013] A corrugation line which is also described includes the above-mentioned forming device located upstream along the machine direction of the above-mentioned corrugation die. The forming device is configured to deliver from its exit end a web formed of media material that has been grooved to an intermediate longitudinally grooved geometry. The corrugation die is configured to take the formed web and convert it from the intermediate longitudinally grooved geometry to an almost smooth shape having a higher frequency and lower amplitude grooved geometry that approximates a desired final corrugated geometry.
[014]A method of forming a longitudinally corrugated web is also described. The method includes the following steps: uniformly introducing into a web of media material a full-width array of intermediate geometry longitudinal grooves as the web travels along a web travel path in a machine direction, reducing thus the weft width to substantially a final width corresponding to a draw ratio for preselected longitudinal corrugations or other three-dimensional structure to be formed in the weft with the final width mentioned above, where substantially no part of the weft crosses a shape element - tion of grooves in a cross-machine direction while introducing the grooves of intermediate geometry.
[015] A further method of forming a longitudinally corrugated web that is also described includes the following steps: feeding a web of media material having an initial width in a machine direction through a maze of longitudinal grooves defined between opposing sets of at least partially intertwined grooving bars, wherein the plurality of grooving bars in each set are curved such that the bars in said respective pluralities converge in a cross-machine direction as they advance to the exit end ; and reducing the web width to a substantially final width by forming intermediate geometry longitudinal grooves in the web as it passes through the maze, where the individual web elements passing through the maze follow curved contour lines along the maze. respective individual bars of the plurality of groove forming bars from a point where the respective first element contacts the respective bar all the way until the web exits the maze.
[016] A further forming device that is described has an inlet end and an outlet end separated along a machine direction, and a plurality of groove forming bars extending adjacent the inlet end towards the output end. At least one subset of the plurality of grooving bars has a variable tangent configuration such that the imaginary tangents for each of the subsets of bars, at locations spaced along a length thereof, become successively closer. to parallel with the machine direction. In this way, the sub-assembly of grooving bars converges in a cross-machine direction as they advance to the exit end. BRIEF DESCRIPTION OF THE DRAWINGS
[017] Figure 1 is a schematic illustration of a longitudinal corrugation line incorporating a matrix forming device and longitudinal corrugation matrix, as described here.
[018] Figure 2 is a perspective view of a forming device for use in a longitudinal corrugation line, where the respective first (top) and second (bottom) groove forming bar arrangements are separated from each other.
[019] Figure 2a is a close-up view showing details of groove forming bars at the output end of the forming device of Figure 2.
[020] Figure 3 is a perspective view of the forming device of Figure 2, where the first and second arrangement of grooving bars have been partially engaged to interlock with opposing grooving bars at an intermediate location between the input end and output end of the forming device, with the degree of interlacing increasing in the machine direction towards the output end.
[021] Figure 3a is a close-up view showing details of the interlocking groove forming bars at the output end of the forming device of Figure 3.
[022] Figures 4a and 4b are views of the respective first and second sets of groove forming bars attached to the respective first and second frames, each seen along a line that is perpendicular to the respective frame and facing the set of associated bars.
[023] Figure 4c is a schematic view of an arrangement of grooving bars as described herein, for example, of one of the arrangements illustrated in Figures 4a and 4b, illustrating the constant lateral spacing between the grooving bars laterally adjacent in each arrangement.
[024] Figure 5 is a schematic plan view of both the first and the second set of grooving bars, as described herein, at least partially intertwined with each other. The figure also schematically illustrates the collection of the weft width using the forming device described to accommodate the draw ratios associated with “A” and “C” grooves for longitudinal corrugation.
[025] Figure 6 is a side cross section of a grooving bar used in a grooving device as described herein, taken along line 6-6 in Figure 2.
[026] Figure 7 is a side view of a forming device as described herein, shown during an operating state, for example, with slot forming bar arrangements engaged as in Figure 3.
[027] Figure 7a is a perspective view of the forming device of Figure 7 shown during the same state of operation.
[028] Figure 8 illustrates an alternative embodiment of a forming device as described herein, where the forming device defines an intermediate longitudinal corrugation labyrinth that follows a curved path in order to effect the adjustment of the weft course therein, while introducing intermediate corrugations to gather weft width prior to downstream operations.
[029] Figure 9a is a perspective sectional view of a corrugation die, as described herein, for converting a formed web exiting the described forming device into an almost smooth shape compared to a desired final corrugated geometry.
[030] Figure 9b is a perspective view of the corrugation die of Figure 9a where the respective die halves 310 and 320 have been engaged.
[031] Figure 9c is an end view of the corrugation matrix, as shown in Figure 9c, showing the tapered configuration of the ribs that define the initial winding geometry of the web path through the corrugation matrix.
[032] Figure 10 is a perspective view, in section, of a portion of a web in displacement as it is formed in an almost smooth shape in the corrugation matrix described herein, from the intermediate corrugated web produced in the device. formation.
[033] Figure 11 is a perspective view showing longitudinal corrugation rollers engaged to define a corrugation nip therebetween to impart longitudinal corrugations to a web passing between them. DESCRIPTION OF THE INVENTION
[034] Figure 1 schematically illustrates a longitudinal corrugation line 1000. In the illustrated embodiment, the corrugation line 1000 includes, in the machine direction along the travel path of a web 10 of corrugation medium, a corrugation apparatus preconditioning 100, a forming device 200, a corrugation die 300, and a final corrugation apparatus 400. In Figure 1, a single web 10 of corrugation medium is traveling along the web travel path through the corrugation line 1000 in machine direction. The weft is denoted by reference numerals 10, 10a, 10b, 10c and 10d in Figure 1, corresponding to different stages in line 1000 where the weft has been conditioned, treated or manipulated in different operations as described in more detail below.
[035] Briefly, in Figure 1, the web 10 is initially fed from a source of corrugating medium (e.g., from rollers, as is conventional in the art, not shown) into the preconditioning apparatus 100. In the apparatus of preconditioning 100, the moisture and/or temperature of the weft 10 can be adjusted to be within an optimal range, if desired. Then, the conditioned weft 10a is fed into a forming device 200. In the forming device 200, the total width of the moving weft is reduced by picking up the weft laterally (in the cross-machine direction) by introducing slit grooves. extending longitudinally to produce a formed web 10b of intermediate geometry. The longitudinally extending grooves in the formed web 10b are of greater amplitude and lesser frequency than those in the final corrugated web 10d to be made downstream. By introducing the intermediate geometry grooves, the forming device 200 reduces the width of the formed weft 10b (in the cross-machine direction) compared to the original weft 10 (or conditioned weft 10a) by the draw ratio (or approximately that). ratio) corresponding to the final longitudinal grooves to be introduced downstream. Importantly, the overall width of the formed web 10b emerging from the forming device 200 will approach or be substantially the same as the width of a final corrugated web 10d.
[036]Each of the above mentioned operations will now be described. Preconditioning Device
[037]Starting first with the preconditioning apparatus 100, preconditioning is optional and may not be necessary or desirable in each longitudinal corrugation line 1000. Consequently, the preconditioning apparatus may be omitted. When included, the preconditioning apparatus 100 can be used to introduce or adjust a moisture content in the web 10 prior to its entry into the forming device 200. Any device conventional or suitable for supplying or adjusting the moisture in the web can be used or as the preconditioning apparatus 100, such as spray nozzles, moisture application rollers, etc. These will not be described further here, but exemplified moisture conditioning devices suitable in the preconditioning apparatus are known, for example, from US Patent No. 8,057,621 incorporated above.
[038] The preconditioning apparatus 100 may also include one or more devices to adjust the temperature of the displacement web 10 in an optimal range for downstream processing. For example, heated rollers and hot plates are conventional in the art and can be used. In some embodiments, both humidity and temperature can be adjusted at the same time or successively via preconditioning apparatus 100, so as to precondition the web for downstream operations. For example, it is generally desirable for the shifting web to have between 6 and 9 percent by weight moisture to protect the paper fibers. Heating the web to a high temperature (especially in cold climates) but not high enough to burn or otherwise damage the paper can also help to relax the paper fibers making them less susceptible to damage or breakage from the effects of bending and tension introduced in downstream corrugation operations. Both moisture and temperature preconditioning operations are described in the 621 patent mentioned above and elsewhere in the literature, and they will not be described further here. Training Device
[039] Once the weft 10 has been treated to produce the preconditioned weft 10a, that weft (or in the absence of the preconditioning apparatus 100, the unconditioned weft 10) is introduced along the weft displacement path in the forming device 200. An exemplified embodiment of forming device 200 is illustrated in Figure 2. In that embodiment the forming device has a first set or upper set of groove forming bars 210 and a second set or lower set of forming bars of grooves 220. The sets of groove forming bars 210 and 220 are disposed opposite or facing each other on either side of the travel path of the web through the forming device 200. In Figure 2, each of the opposing sets of grooving bars 210 and 220 is provided as a substantially flat arrangement of respective first and second grooving bars 212 or 222 supported. in a respective first (or higher) or second (or lower) frame 215 or 225. Frames 215 and 225 are secured to front and rear support posts 230 and 235 to fix the positions and relative orientations of frames 215 and 225 ( and, correspondingly, the first and second sets/arrays of grooving bars 210 and 220) with each other. In the illustrated embodiment, the lower frame 225 is secured to the support posts 230, 235 in a fixed position so that it is substantially parallel to the path of movement of the web through the forming device 200 and so that its height or position is fixed. The upper frame is attached at its output end 202 to the front support posts 230 via position adjustment actuators 240 capable of adjusting the position or spacing of the upper frame 215 relative to the lower frame 225 at the output end 202 of the device formation 200. Actuators 240 may be, for example, hydraulic or pneumatic pistons, stepper motors, servos, solenoids, or any other suitable or conventional device capable of adjusting the position of upper frame 215 relative to lower frame 225 at the end of exit 202.
[040] In a preferred embodiment, the top frame 215 is similarly secured to the rear support posts 235 via adjustment actuators 240 as described above, so that the position or spacing of the top frame 215 is similarly adjustable with respect to the lower frame 225 at the input end 201. Indeed, in preferred embodiments, both the input end and the output end of the first frame/upper frame 215, and then of the first set/upper set of grooving bars 210, are independently adjustable towards and away from (eg height adjustable relative to) the second frame/bottom frame 225 and then second set/bottom set of grooving bars 220. In one alternative embodiment, both the first and second frames 215 and 225 may be independently position adjustable using actuators similar to those described above, or adjustable relative to the opposite frame, in one or both of the inlet end and the outlet end 201 and 202 of the forming device.
[041] Figures 4a and 4b illustrate the respective upper and lower frames 215 and 225 and the associated arrangements of slotting bars 210 and 220 along a line normal to the respective frame and viewed from a position between the respective arrays 210 and 220. As best seen in these figures, each flat array (set) of grooving bars 210 and 220 is arranged such that the associated bars 212 and 222 all extend generally along the machine direction from from the inlet end 201 towards the outlet end 202 of the forming device 220. The individual bars of the slit forming bars 212 and 222 in each array are curved along at least rear portions or segments thereof such that they converge laterally (in the cross-machine direction) as the bars 212 and 222 proceed in the machine direction from the input end 201 towards the output end 202. As here u used, the term 'converge' means to approach or become closer, without the need for the converging elements to actually meet. As will become evident below, it is in fact preferred that the converging groove forming bars, as described herein, do not actually meet, but instead tend towards and ultimately reach parallel paths. In one embodiment, the bars 212 and 222 no longer bend at a location approaching the output end 202 of the forming device such that all the bars 212 and 222 in that device are substantially parallel along the machine direction. from that location onwards to the output end 202. Alternatively, the curved bars may technically be curved all the way to the output end 202, although tangents to all bars 212 and 222 are preferably substantially parallel to each other along the machine direction at that end 202. More generally, the converging groove forming bars 212 and 222 are characterized by a variable tangent configuration, where the imaginary lines tangent to each of the bars at locations spaced along the length of the bar become successively closer to parallel with the machine direction along which a weft will travel between the end of and input and output end 202. A continuously curved grooving bar 212, 222, or a continuously curved rear region (adjacent to input end 201) thereof, as described in detail herein is preferred for the variable tangent configuration. . But other forms of variable tangent may be possible. The above features are all described more fully below.
[042] Returning to the preferred embodiment illustrated in Figures 4a and 4b, the individual bars 212 and 222 in their respective arrangements are curved so that they converge towards an imaginary line 209 or 229 in the plane of the associated arrangement that runs along the path of displacement from the weft to the machine direction in the forming device. More preferably, such imaginary line 209 or 229 represents a centerline of the respective arrangement, as illustrated in the figures, so that at least some parts of the individual groove forming bars 212, 222 on either side of the centerline in the respective arrangement 215, 225 are curved such that they approach the centerline as they extend in the machine direction. In an exemplified embodiment, one or more of the forming bars 212, 222 may exhibit parabolic curvature, or all of the curved bars 212,222 may exhibit parabolic curvature, between the input end and the output end 201 and 202.
[043] In the illustrated embodiment, the upper array 210 has an odd number of grooving bars 212 (15 are shown) and the lower array 220 has an even number of grooving bars 222 (16 are shown). This arrangement allows the respective arrangements to be interwoven together to define an intermediate longitudinal slot maze 250 (seen in Figure 7) for a web 10 of material traveling through the forming device 200 (described below), while allowing both arrays are centered along a common centerline (viewed from above), for example, along a centerline of the weft displacement path, while interlaced. However, it is clear that both the upper and lower arrangements 210 and 220 may comprise odd or even numbers of grooving bars (for example, both arrangements may include the same number of grooving bars), with the caveat that they could not then be aligned along a common centerline (viewed from above) while intertwined.
[044] Returning to the figures, when an arrangement of grooving bars has an odd number of such bars, for example, bars 212 in the upper arrangement 210 illustrated in Figure 4a, the more central grooving bar 212a is preferably linear and collinearly aligned with centerline 209 of array 210. This centerline preferably coincides with a centerline of lower frame 225 and then of forming device 200. More broadly, in a forming bar arrangement as here described, it is preferred that the only time one of the forming bars is linear and does not curve along at least one segment thereof from the inlet end 201 towards the outlet end 202 either when that forming bar is aligned and collinear with the imaginary line to which the other forming bars in the same array will converge as they extend towards the output end 202. All other forming bars in the same bar njo will be curved at least in parts or rear segments thereof, so as to converge laterally on this imaginary line, and in this case also on the linear formation bar collinear with said imaginary line.
[045] This can be seen in the top array 210 illustrated in Figure 4a, where the most central forming bar 212a is linear, and furthermore is collinear with the imaginary centerline 209 of array 210. A first pair of bars of forming 212b is disposed on either side and laterally spaced from the most central bar 212a, each extending from the inlet end 201 towards the outlet end 202 of the forming device 200, and each being curved so that they converge at the center line 209 (and at the most central forming bar 212a), as it proceeds towards the exit end 202. A second pair of forming bars 212c is disposed on either side and spaced laterally from the first pair of forming bars 212b , again each extending from the inlet end 201 towards the outlet end 202 of the forming device, and each being curved so that it converges on the centerline 209 (and on the most central forming bar 212a) as it proceeds towards the outlet end 202. A third pair of forming bars 212d is disposed on either side and laterally spaced from the second pair of forming bars 212c, again each extending from the inlet end 201 towards the outlet end 202 of the forming device, and again each being curved such that it converges on the centerline 209 (and the more central forming bar 212a) as it proceeds towards the end of output 202. Additional pairs of 212D-h forming bars spaced at successively greater intervals from the centerline may be provided in array 210.
[046] Turning now to the lower arrangement of grooving bars 220 illustrated in Figure 4b, there is no more central grooving bar 222. This is because there is an even number of grooving bars 222. The pair of most central grooving bars 222a are each spaced on either side of centerline 229, with successively farther lateral pairs of grooving bars 222b-h being equally spaced on either side of centerline 229. Thus, as for the upper arrangement 210, here the second pair of forming bars 222b is disposed on either side and laterally spaced from the first pair of forming bars 222a, each extending from the inlet end 201 towards the end. outlets 202 of the forming device, and each being curved so that it converges on the centerline 229 of the lower arrangement 220 as it proceeds toward the outlet end 202. The third to the eighth illustrated successive pair of slotting bars 222c-h are equally successively spaced laterally from the most central pair, and are equally curved so that each converges at the centerline 229 of the lower array 220 towards the outlet end 202 of the forming device 200.
[047] Still referring to Figures 4a and 4b, for each of the arrays 210 and 220, the degree of curvature of the associated groove forming bars 212 and 222 is the greatest at the inlet end 201 of the forming device 200, where a web of middle material first would enter this device 200. The degree of curvature of the grooving bars gradually decreases as the bars proceed towards the exit end 202, from which a web is formed 10b (see Figure 7a) would emerge during a longitudinal corrugation process. The result is that the individual groove forming bars 212 and 222 rapidly converge towards the imaginary centerline (or other longitudinal line) in the respective arrangement 210 or 220 adjacent to the inlet end 201 of the forming device. However, as the degrees of curvature of the bars decrease in the machine direction, also the rate of convergence of the grooving bars gradually decreases, preferably until all bars 212 or 222 in the respective arrangement 210 or 220 become generally linear and parallel to each other in the machine direction at the output end 202 of the forming device 200. That is, the bars 212 and 222 may no longer be curved at a location approaching the output end 202, from which they are all generally linear and parallel, as described above. Alternatively, the bars 212 and 222 may continue to be curved upwards towards the output end 202 of the forming device 200, where the degree of curvature will preferably be substantially reduced at the output end 202 compared to the input end 201, so that at the output end 202 they are all approximately linear and parallel. In either case, the tangents of all the grooving bars 212 and 222 at the output end 202 are all substantially parallel along the machine direction.
[048] As schematically illustrated in Figure 4c, for a given arrangement 210 or 220, it is preferred that the groove forming bars 212 or 222 in that arrangement are substantially equidistant at any given location along the machine direction in the forming device 200 For example, Figure 4c schematically illustrates three longitudinal locations along the machine direction, A, B and C, such that the lateral distances between adjacent bars of the grooving bars are all equal at the respective locations. That is, the lateral distances a1, a2 and a3 between adjacent grooving bars at machine direction location A are all the same, and equally for machine direction locations B (distances b1, b2 and b3) and C (distances c1, c2 and c3). In preferred embodiments, the foregoing holds true for both the first and second (upper and lower) arrangements of groove forming bars 210 and 220 in forming device 200.
[049] It should again be noted with respect to Figure 4c (and also Figures 4a and 4b) that while the grooving bars in a given arrangement are preferably all equidistant to any given location along the machine direction , the lateral distance between adjacent bars decreases as the bars proceed in the machine direction towards the output end 202 of the forming device, at least along segments or rear portions of the bars. That is, with respect to Figure 4c, a1>b1>c1, at least in segments or converging rear portions of the grooving bars 212, 222, consistent with the fact that the bars converge laterally as they advance in the direction of machine to the output end 202. In preferred embodiments, this convergence is the result of the lateral bending of at least one subassembly (e.g., all but the most central) of the groove forming bars 212, 222 in each array 210 or 220 as discussed above. More broadly, however, the noted subset of groove forming bars 212, 222 is understood to have a variable tangent configuration such that the imaginary tangents to each of these groove forming bars are directed at locations spaced along the length of each of these bars, they successively become closer to parallel with the machine direction as that bar proceeds towards the output end 202 of the forming device. This is illustrated schematically in Figure 4c, where, for a given grooving bar 212, 222, a tangent line Ta drawn in machine direction "A" remote from the output end is not parallel with the machine direction; that is, with the centerline in that figure. Whereas a tangent line Tb drawn at location "B" closest to the output end is closest to parallel with the machine direction, and a tangent line Tc drawn at location C essentially at the output end is parallel or approximately parallel to the direction of machine. In the preferred embodiments described herein and illustrated in the figures, each of the grooving bars 212, 222 having the aforementioned variable tangent configuration is continuously and smoothly curved in its variable tangent region, which may be a rear part of the bar or may be the total length of the bar. Alternatively and less preferably, the variable tangent region can be formed as a series of linear or stepped bar-forming segments that together integrate or approach a curve (not shown) starting adjacent to the input end and extending toward the end. output 202.
[050] Returning to Figure 2 and now referring to Figure 3, the respective first and second opposite arrangements 210 and 220 of the grooving bars are configured so that when approaching each other they intertwine to define a intermediate longitudinal grooving labyrinth 250 between them. In Figure 3, the position of the upper frame 215 has been adjusted towards the lower frame 225 at the output end 202 to interlace the front portions of opposite slit forming bars 212 and 222 at the output end 202 and at the output region of the device. of forming 200. In the same figure, the upper frame 215 has also been adjusted towards the lower frame 225 at the input end 201, although to a lesser degree than at the output end 202, so as to adjust the location of the choke point 290 (Figure 7) in which the opposing grooving bars 212 and 222 soon begin to intertwine, as described more fully below. In a preferred embodiment, the curvatures of the respective groove forming bars 212 and 222 in the opposing arrangements 210 and 220 are such that the interlocking groove forming bars 212, 222 are equidistant or substantially equidistant from each other at any given longitudinal location to the along the machine direction in the forming device 200, and such that the curves all converge similarly laterally towards a common imaginary line (preferably a centerline) parallel to the machine direction in the forming device.
[051] Figure 5 is a schematic plan view illustrating the upper and lower interlocking sets 210 and 220 of groove forming bars 212 and 222, where the upper bars 212 are represented by solid contour lines and the lower bars 222 are represented by dashed contour lines. It is appreciated that the representative contour lines of alternating upper and lower grooving bars 212 and 222 are similar to the contour lines illustrated in Figure 4c for only one arrangement of these bars. In fact, the braided arrangement in Figure 5 exhibits similar characteristics. That is, the degrees of curvature (and therefore the rate of convergence) of curved interlocking groove forming bars 212, 222 in Figure 5 decrease as the bars proceed in the machine direction towards the output end 202 , at least on the backs of the bars. The lateral spacing between the adjacent bars of the braided bars 212, 222 is also preferably constant (i.e., all braided bars are preferably substantially equidistant) at any given longitudinal location along the machine direction, with said spacing gradually becoming smaller as it proceeds in that direction. Preferably, the grooving bars 212, 222 in the interlocking arrangement in Figure 5 (and also seen in perspective view in Figure 3) are also generally linear and parallel to each other in the machine direction in an output region of the device. formation; that is, adjacent to the right side of each of Figures 3 and 5.
[052]Returning to Figure 6, an exemplified groove forming bar 212/222 is shown in side section. In the illustrated embodiment, the forming bar 212/222 includes a base portion 260 and a weft engaging portion 262. In interlocking portions of opposing sets of groove forming bars 210 and 220 in operation, the respective engaging portions 262 of one set of bars are received in lateral spaces defined between adjacent engaging portions 262 of groove forming bars in the opposite set. This can be seen more clearly in Figure 3a. Grooving bars 212/222 can be attached directly to the associated frame 215, 225. Alternatively, and particularly when a high degree of interlocking or (i.e. the degree to which the engaging portions 262 of the first set of bars 210 penetrate beyond an imaginary plane tangent to the outermost surfaces of the engagement portions 262 of the second set 210, and vice versa) it may be desired, the groove forming bars 212, 222 may be formed or attached to spacers 270 to increase the distance between the weft-engaging portion and associated frame 215, 225. Grooving bars 212, 222 may be attached to spacers 270 in any conventional or appropriate manner, for example via welding, brazing, adhesives or mechanical fasteners using appropriate gaskets to ensure a fluid tight seal. Alternatively, the grooving bars 212, 222 can be formed integrally with the associated spacers 270, effectively resulting in a relatively tall grooving bar 212, 222.
[053] In operation, the web engaging portion 262 of the grooving bar 212, 222 engages a shifting web 10 in the forming device to thereby form intermediate longitudinal grooves to produce the formed web 10b (see Figure 7a) . Accordingly, the engagement portion 262 preferably has a generally rounded (e.g. cylindrical) surface for contacting the web 10. The surface engagement portion 262 may include an anti-friction surface feature to thereby reduce frictional forces on the web 10 as it passes between the first and second interlocking sets of slotting bars 210 and 220 to introduce the intermediate slotted geometry (i.e., as the web 10b is formed) into the forming device 200. As an example, the grooving bars 212, 222 or portions thereof may be zero contact bars operable to support the web 10 of media material at a variable height above it in an air or other fluid damper that is emitted through fluid ports 205 provided in coupling parts 262. Preferably, ports 205 are distributed along coupling parts 262 of forming bars 212, 222 substantially along its entire lengths, or at least along its portions which will engage a shifting weft 10 during use.
[054] When the grooving bars 212, 222 are operated as zero contact bars, preferably the engaging portion 262 of each zero contact bar has a fluid passage 204 in fluid communication with the fluid ports 205 to conduct the desired fluid (such as air) to these ports 205. The fluid exits these ports 205 to thereby provide a fluid damper between the surface engaging portion 262 and the web 10 in order to support the moving web 10 above the engagement portion 262 and thus reduce or minimize friction as the web passes over the bars 212, 222. Preferably, the fluid damper allows frictionless support of the web as it travels through the labyrinth of intermediate slots 250 between opposing forming bars 212, 222.
[055] Returning to Figure 6, the fluid passage 204 is preferably in fluid communication with a spacer passage 203 within the spacer 270 to which it is attached, for example, via a passage 202 in the base 260 of the bar. formation 212, 222. In this embodiment, groove forming bars 212, 222 can be extruded or gun drilled to provide fluid passage 204 and passage 202. When formed together with spacer 270, the entire assembly can be prepared. as a single extrusion, so that the spacer passage 203, the passage 202 and the fluid passage 204 cooperate to form a delivery manifold for the associated forming bar 212, 222 to deliver fluid through the orifices 205.
[056] As seen in Figures 2 and 6, at least one supply manifold 280 for the damping fluid may be provided on the surface of the top frame 215 opposite the surface where the groove forming bars 212 are mounted. Feed distributor(s) 280 may be in the form of a U-shaped channel having closed ends, with the open face of the channel facing towards and being sealed to the surface of frame 215, so as to define a feed passage 282 for the fluid as seen in Figure 6. The feed passage 282 communicates with the aforementioned spacer passage 203 (or directly with the passage 202 when no spacer 270 is used) to each grooving bar 212 via an opening of feed 283 perforated or otherwise formed in frame 215. As is clear, frame 215 may have a plurality of feed openings 283 in communication with feed passages 282 of each feed distributor 280, corresponding to and laterally aligned with the number and the locations of the slotting bars 212 on the opposite surface of the frame 215. The dispenser 280 can be secured to the surface of the frame 215 by a conventional device. l or suitable, for example, by welding or brazing, to provide a continuous airtight seal, or using other mechanical fasteners with a suitable gasket to also ensure an airtight seal. Fluid may be supplied to manifold 280 through a conventional fitting 285 (see Figure 2). As also seen in Figure 2, a plurality of feed distributors 280 can be distributed along the machine direction. Such a plurality of distributors 280 may be connected to a common fluid source to deliver the same fluid (including flow rate and pressure) at all three locations, or may be connected to different fluid sources, or each may be regulated. independently, to deliver different fluids or different flow rates and pressures at different locations in the machine direction as described in more detail below.
[057] Although the above description of the feed distributor(s) 280 has been provided and illustrated in relation to the first frame 215 to which the first set of groove forming bars 210 is mounted, the identical arrangement can be incorporated for the second frame 225 so as to provide a damping fluid for the grooving bars 222 in the second set of said bars 220.
[058] In one embodiment, all grooving bars 212, 222 in both the top and bottom arrangements 210 and 220 can be supplied from a common fluid source and regulated from a single metering or throttling valve located upstream of both respective feed distributors 280 (e.g., a distributor 280 for each set of forming bars 210 and 220). In this embodiment, a single feed distributor 280 may be used for each of the upper and lower arrangements 210 and 220 (i.e., affixed to each of the respective upper and lower frames 215 and 225). Alternatively, respective plurality of dispensers 280 may be positioned and used in conjunction with each set 210 and 220 of the grooving bars, all connected in parallel to a commonly regulated fluid source. In both of these embodiments, the pressures and flow rates of support fluid delivered to all bars 212, 222 would commonly be controlled, resulting in substantially uniform pressures and fluid flow rates through orifices 205 in all bars forming slots 212, 222.
[059] Alternatively, the respective distributor(s) 280 associated with each set of 210 or 220 grooving bars 212 or 222 could be equipped with its own dedicated device for regulating the pressure and flow rate of the fluid. Suitable regulating devices include, for example, metering or throttling valves, pressure regulators, mass flow controllers or some combination of these. For example, a pressure regulator or mass flow controller may be mounted in-line with the fitting(s) 285 of the respective distributor(s) 280 associated with only one set of groove forming bars 212 or 222, between the fitting. (es) and the fluid source. This embodiment would provide common control and substantially uniform pressures and flow rates for the web support fluid through all of the groove forming bars 212 in the first set 210 thereof affixed to the first frame 215, and separately for all forming bars of grooves 222 in the second set 220 thereof affixed to the second frame 225. In other words, the flow rates and fluid pressures would be substantially uniform in each arrangement of groove forming bars 210 and 220, but the flow rates and the pressures in the first arrangement 210 could be regulated independently of the flow rates and pressures in the second arrangement 220 and vice versa. This may be desirable, for example, for heavy and dense webs moving in the horizontal machine direction, where additional pressure from the bottom can be useful to support the moving web centrally and against gravity within the maze. of longitudinal grooving 250. Alternatively, when the forming device 200 has a grooving labyrinth 250 that follows a curved path (described below), additional pressure may be desired from the side of the weft 10 out of the direction that the weft is to rotate. as it follows the plot's path of travel through curved maze 250.
[060] In another alternative embodiment, successive feed distributors 280 distributed along the machine direction of the forming device 200 can be independently connected in fluid communication with respective isolated longitudinal zones or segments of the grooving bars 212 or 222 attached to the associated frame 215 or 225. For example, one or a plurality of slotting bars 212, 222 may be provided in segments or having segmented distributors (e.g. segmented fluid passages 204 and co-operating spacer passages 203) , where each segment of the bar 212, 222 or its distributor is correlated with a longitudinal zone of the forming device 200 which extends only for part of the total longitudinal extent of that bar (including all its segments) along the machine direction. In this embodiment, different pressures and flow rates of web support fluid, or even different fluids, can be distributed to the grooving bars 212, 222 to be emitted via the fluid ports 205 at different longitudinal zones in the grooving device. formation 200. This may be desirable in order to successively increase the amount of force normal to the flat web extension imparted to it by support fluid emitted along the lengths of the groove forming bars 212, 222. For example, the pressure ( normal to the flat length of the weft) required to induce the curvature of that weft around a radius of curvature following one of the bars 212, 222 can be represented by the following relationship:

[061] As is clear, the radius of curvature of the web at fixed locations gradually decreases as longitudinal grooves are formed as the web moves in the machine direction through the maze 250 between increasingly intertwined forming bars 212, 222. From the previous relationship and assuming a uniform weave, as the radius of curvature decreases, the amount of pressure needed to sustain that curvature will increase proportionately. Then, by increasing the pressure of fluid emitted from fluid ports 205 in successive longitudinal zones in the machine direction, one can conserve fluid and pumping energy in upstream longitudinal locations where a relatively high degree of pressure it is not required to support the web in spaced relationship with the adjacent grooving bars 212, 222. The degree of fluid pressure and its flow rate can thus be increased in successive longitudinal zones where the pressure increases may be required to support the web in spaced relationship with the bars 212, 222 in greater degrees of grooving; that is, smaller radii of curvature in the forming/formed grooves. In this embodiment, respective feed distributors 280 connected in fluid communication with opposite slitting bars 212 and 222 in the same longitudinal zone can be supplied in parallel from the same fluid source and commonly regulated. This will ensure common fluid pressures and flow rates from both the first and second sets 210 and 220 of grooving bars in the same longitudinal zone.
[062] In yet another alternative, each individual grooving bar 212, 222 or groups thereof can be provided with independent fluid flow control, for example, using pressure regulators or mass flow controllers provided in-line with the distributor (e.g., channel passage 203) for each of the grooving bars 212, 222, but downstream of the feed distributor 280 (not shown). In this embodiment, the pressures and flow rates of the web supporting fluid can be individually controlled for each grooving bar 212, 222. This could be desirable, for example, if a web tension peak were detected downstream of the forming device 200 in only a discrete lateral position (across the machine) in the weft. In this case, the pressure/fluid flow rate of only the forming bars 212, 222 in the transverse position to the associated machine can be increased based on a return control system to provide additional damping and thus reduce friction therein. localization.
[063] In each of the foregoing embodiments, a pressurized fluid, such as air or steam, is delivered to feed distributors 280 through ports 285 using appropriate hoses, pipes, or tubes, which are conventional. Pressurized fluid travels through feed passage 282, through respective feed openings 283 and to dispensers associated with each of the grooving bars 212, 222, ultimately being emitted through associated fluid ports 205. The fluid thus provides a fluid (e.g., air) damper above each grooving bar 212, 222 on which the shifting web 10 can be supported or can float as it traverses the intermediate grooving longitudinal labyrinth 250 in the forming device 200. The damping provides air lubrication, which can reduce or eliminate frictional contact sliding between the weft 10 and the forming bars.
[064] In addition to minimizing the friction encountered by the web 10 as it traverses the maze 250, operating the forming bars 212, 222 in the zero contact mode described here can provide an elegant feedback control mechanism for the average stress of the Weft via an active or passive pressure transducer (not shown) that can be used to sense the pressure in the air damper under the web 10. The air damper pressure and the weft tension are related according to the relation P = T/R. Thus, monitoring the air damper pressure, P, provides a real-time measure of the tension in the weave. Additionally, in the mode of zero air damper contact between each of the forming bars 212, 222 and the shifting weft 10 provides an instantaneous dampening mechanism for small oscillations of tension in the weft, because the weft is free to dance above the formation bars in the air damper in response to small voltage variations and transients. The result is that the frame is less affected by such transient voltage variations. Finally, it is important to mention that “zero contact” does not imply here that there can never be any contact (ie literally “zero” contact) between groove forming bars 212, 222 in frame 10. Even operated in zero contact mode as described here, some contact may occur due to transient or momentary fluctuations in the mean frame voltage, or localized frame voltage, of sufficient magnitude.
[065] In addition to or alternatively operating in the zero contact mode as discussed above, the web engaging portions 262 of the forming bars 212, 222 may include other features designed to minimize or eliminate friction. In one example, the surfaces of the engagement portions 262 can be polished or electropolished so as to reduce frictional forces on the web as it passes through the grooving labyrinth 250. In another example, these surfaces can be coated with a release or anti-friction coating such as PTFE (Teflon®) or similar low-friction material in order to reduce the coefficient of friction on the surfaces and thus reduce the frictional forces between them and shifting web 10. In other For example, such surfaces can be treated to create a hard surface coating, such as by black oxide conversion coating, anodizing, flame spraying, deposition coatings, ceramic coating, chrome plating, or other similar surface treatments, in order to reduce the friction coefficient.
[066] In operation, as best seen in Figures 7 and 7a, the forming device 200 receives a substantially flat web 10 (for example, the preconditioned web 10a) at its rear or inlet end 201. At the entrance to the forming device 200, the weft 10 is of maximum width because it is still flat, and none of its width has yet been collected by longitudinal grooving. In use, the degree of interweaving of the opposing grooving bars 212 and 222 is adjusted at the leading or exit end 202 to secure the
lateral stretch ratio of the formed web 10b at the exit of the forming device. For example, the following are typical or traditional stretch ratios for a number of conventional slot sizes:
[067] Thus, if it is desired to ultimately produce a longitudinally corrugated web having, for example, conventional A-size grooves, the starting width of the initially flat web 10 should be 1.56 times the desired final width of the longitudinally corrugated weft to be made at the 1000 corrugation line. Consequently, if a longitudinally corrugated weft with size A grooves of 127 cm (50 inches) wide is desired, then the width of the initially flat weft should be 198 cm ( 78 inches) (1.56 x 50 inches). Similar calculations can be performed for other standard slot sizes based on desired finished weft widths. In each case, the forming device 200 can be used to reduce the width of the flat web 10 from its initial width (eg 198 cm (78 inches) for a longitudinally corrugated web with size A grooves) to the width narrower end of the desired weft (eg, 127 cm (50 inches) for the A-sized slotted weft).
[068] The web 10/10a is fed into the forming device 200 from the rear/input end 201 in the machine direction so that the web passes between the opposing sets 210 and 220 of the groove forming bars 212 and 222. The position of the first frame 215 is adjusted relative to the second frame 225 at the leading/outgoing end 202 so that the degree of interweaving of the opposing bars 212 and 222 produces a serpentine (i.e., transverse direction) path to the machine, best seen in Figure 3a) sufficient to consume the desired proportion of the weft width so that the formed weft 10b exiting the forming device has a width which is or approaches the desired finished weft 10d. In other words, the degree of interweaving of the forming bars 212 and 222 at the exit end 202 determines the degree to which the width of the initial weft 10 is collected to produce a formed weft 10b exiting device 200, as seen in Figure 7a. The greater the degree of weave at the output end 202, the more the web material will be consumed in the cross-machine direction as the web negotiates the weave forming bars 212 and 222 as it travels in the machine direction.
[069] It is also preferred that the position of the first frame 215 is adjusted at its rear or input end 201 relative to the second frame 225. Specifically, once the degree of interlacing at the output end 202 has been fixed, the position of the first frame 215 is set at input end 201 (relative to second frame 225) to select the location of a choke point 290 along the machine direction where opposite bars 212 and 222 just begin to intertwine. In operation, the choke point 290 is where the weft entering 10/10a first contacts or meets the opposite first and second grooving bar 212 and 222 uniformly across its entire width, as seen in Figure 7, as well as Figure 5. In Figure 7, the weft 10 is shown gaining height as the longitudinal grooves are formed in the maze 250. The height of the weft begins to increase in front of the choke point 290 in the illustrated embodiment, because as the web is positively grooved at that point, a portion of the web upstream of the choke point 290 can be induced to assume or begin to conform to a grooved configuration, too.
[070]The location of the throttle point 290 is selected based on the width of the entering weft 10/10a, so that at or adjacent to the throttle point 290, the side edges of the entering weft meet and are positioned adjacent (or contact or are supported by) the forming bars 212 and 222, whose lateral spacing at the exit end 202 (based on its curvature from the forward throttling point) defines or approximates the desired width of the formed web 10b at the exit of the forming device 200. In this way, the side edges of the weft entering 10/10a will follow the curvature of the respectively adjacent forming bars 212 and 222 in the machine direction as they converge laterally approaching the output end 202 of the forming device , and will be spaced apart by the desired width of the formed web 10b at the output of that device 200.
[071] This will be better understood with respect to Figure 5, which illustrates a schematic top view of the interlocking arrangement of opposing forming bars 212 and 222, where the bars are represented by contour lines. As seen in the figure, initial wefts 10/10a are schematically shown entering the interlocking arrangement from inlet end 201 so as to be longitudinally grooved to an intermediate geometry to produce a formed weft 10b having a desired final width. The start weft marked "A" indicates a weft designed to produce a weft longitudinally with size A grooves in the final width illustrated, and the start weft marked "C" indicates a weft designed to produce a weft longitudinally with size C grooves in the final width. (Note that Figure 5 and the stretch ratios therein are not to scale; the figure is for illustrative purposes only). From the table above, a typical draw ratio for A slots is 1.56, and for C slots it is 1.48. Although not to scale, the figure shows that to achieve a formed web 10b of the same final width, an initially wider web will be required if A slots are introduced downstream than C slots, because A slots demand a higher draw ratio.
[072] As discussed above, the final interweaving of the opposing groove forming bars 212 and 222 at the output end 202 will define the draw ratio in the forming device 200. Separately, the choke point 290 is selected based on the initial width of the entering frame 290, as discussed above. In Figure 5 the initial weft width "A" 10/10a corresponds to the spacing between the two outermost forming bars 212, 222 all the way to the rear/inlet end 201 of forming device 200. Thus, the choke point 290 can be positioned at or adjacent to the inlet end 201, because as the side edges of weft "A" proceed in the machine direction, they will follow the contour lines along the curvature of the adjacent forming bars 212 and 222 and therefore will converge to the desired final width of the formed web 10b at the output end 202. However, as the initial “C” 10/10a web is narrower, the choke point 290 is adjusted downstream in the machine direction. , so that the side edges of the weft "C" first meet one of the forming bars 212, 222 which at the exit end 202 will define or approach the final desired width of the formed weft 10b. In the situations illustrated in Figure 5, the opposing sets of forming bars 210 and 220 would be adjusted so that the choke point 290 for the respective weft "A" or "C" is coincident with or adjacent to where the outer edges of the respective web also meet the laterally outermost grooving bars 212, 222. This would be desirable, for example, when the distance between the outermost forming bars 212, 222 at the output end 202 corresponds to the desired width of the formed web. 10b. Thus, as will now be clear, the distance between the outermost forming bars 212, 222 at the output end 202 can be selected to match the desired standard width for longitudinally corrugated webs regardless of the corrugation pitch. When configured in this way, the choke point 290 for a given initial weft width would routinely be adjusted to coincide with or be adjacent to the location where the outer edges of the weft would meet the laterally outermost groove forming bars 212, 222.
[073] Note that for a given combination of frame and stretch ratio, some routine iteration may be desirable to optimize the location of the choke point 290 since the stretch ratio was fixed at the output end 202, to achieve varying degrees by which different wefts can be induced to begin a grooved configuration upstream of the choke point. In such cases, the location of the choke point should be selected to ensure that little or no cross machine transaction of the weft occurs over or in relation to the groove forming bars 212, 222, at least at locations in contact with the weft bars. groove formation. In most cases, the curvature of bars 212, 222 should prevent this even in cases where the web is induced to begin to assume a grooved configuration upstream of the choke point. But some iteration might be desirable in such cases.
[074] It is clear that, in operation, as a web traverses the grooving labyrinth 250 in the machine direction, its width is collected in the cross-machine direction by gradually forming a full-width arrangement of the longitudinal grooves of intermediate geometry. As the web progresses through the maze 250, the arrangement of intermediate geometry slots is gradually and evenly introduced (i.e., substantially at the same time across the entire width of the web) into the web as the degree of interweaving of the bars Opposite grooving 212,222 increases from choke point 290 forward, and as these bars converge in the cross-machine direction based on their curvature. Based on the curvature of the grooving bars 212 and 222, substantially no part of the weft should traverse any of these bars in a cross-machine direction so as to converge in that direction to gather (i.e. reduce) the width of the weft. Preferably, the individual weft elements follow the converging curved contour lines of the forming bars 212 and 222, or the curved contour lines between the adjacent bars of these forming bars, so that they experience translation only in the machine direction. with respect to forming bars 212 and 222 and no translation in the cross-machine direction with respect to these bars or any other grooving element. As a result, zero or substantially no tension or lateral friction forces, or tension fluctuations or lateral friction are introduced into the web as it traverses the slotted maze 250 because the web is not stretched or pulled laterally as it passes through that maze. 250. In other words, in the forming device 200, no part of the web 10 must negotiate a corrugated path delimited by the forming bars 212 and 222 in a lateral direction as it traverses one or more groove forming bars or other elements of formation of grooves in this direction. When operated in a zero-contact mode, as described above, tension fluctuations in the machine direction can also be reduced or even eliminated, because if the web does not contact the forming bars 212 and 222, there will be no friction between them. Thus, substantially each moving web element moves in three dimensions (e.g., laterally, vertically, and forward) simultaneously, while keeping the tension across the machine and in the machine direction substantially constant because the forming device 200 it does not introduce lateral or longitudinal tension fluctuations in the moving weft even though it introduces longitudinal grooves in it to collect the weft width. Upon exiting the forming device 200, the width of the formed web 10b is adjusted to fit or approximate the final width of a longitudinally corrugated web or other three-dimensional web to be made in a downstream operation, based on the lateral stretch ratio required to accommodate the final three-dimensional configuration.
[075] Figure 8 illustrates an alternative embodiment of a forming device 200, wherein the forming device not only collects the width of the weft 10, but also drives that weft through a curved weft path to adjust the weft course formed 10b exiting the forming device 200 relative to the entering weft 10/10a. In this embodiment, the grooving bars 212 of the first assembly 210 have rounded portions that curve about an imaginary axis parallel to the cross-machine direction such that the rounded portions together define a substantially partially cylindrical arc having a first radius of curvature R1 between said axis and bars 212. It is noted that the curvature mentioned above having the radius R1 with respect to the observed imaginary axis is independent of and in addition to the convergent curvature of the individual forming bars 212 in the first set 210 discussed above. . That is, in this embodiment, the forming bars 212 will curve around the partially cylindrical arc noted above and gradually converge as described above to provide simultaneous course correction and weft width pickup for the moving weft. Likewise, the grooving bars 222 of the second set 220 have co-operating rounded portions that curve about another imaginary axis parallel to the cross-machine direction such that the rounded portions of the grooving bars 222 similarly define a substantially partially cylindrical bow having a second radius of curvature R2. And likewise, this curvature based on radius R2 is independent of and in addition to the converging curvature of the individual forming bars 222 in the second set 220 as discussed above.
[076] The arc lengths for each of the first and second sets 210 and 220 of the forming bars 212 and 222 are selected so that the desired stroke adjustment of the weft travel path can be achieved while traversing the maze of longitudinal grooving 250. For example, for a 90° stroke correction, the arc lengths of the forming bar sets 210 and 220 are such that the grooved labyrinth 250 defined between them follows a stroke extending π/2 radians in the desired radius of curvature. Such an embodiment may be desirable, for example, when space saving is desired by feeding the initial 10/10b weft from above the forming device 200 instead along a linear weft path. As is clear, other geometries and curvatures (e.g., torsion) of the forming bar arrangements 210 and 220 are possible and can be selected based on the geometry of a particular installation and the desired resulting web displacement path. Corrugation Matrix
[077] Upon exiting the forming device 200, the formed web 10b can be fed into a corrugation die 300 as illustrated in Figure 9a. Corrugation die 300 includes first and second mold halves 310 and 320 and has an inlet end 301 and an outlet end 302 as shown. The first half of die 310 has a forming surface 315 for converting the formed web 10b emerging from the forming device into an almost smooth shaped web 10c having a grooved configuration that approximates the desired final undulations of a finished web 10d . At or near the inlet end 301 of corrugation die 300, first forming surface 315 has a series of large-amplitude longitudinal ribs 316 defining a lateral cross-section with a substantially tortuous wave configuration whose frequency and amplitude substantially match or approach the intermediate grooves imparted to the formed web 10b in the forming device 200. As the forming surface 315 proceeds in the machine direction, the sinuous contour of the large-amplitude ribs 316 gradually evolves into a final sinuous contour (in cross section lateral) at the output end 302, defined by small-amplitude longitudinal ribs 318 and the valleys alternately intermediate between them. It is clear that the forming surface 315 is a smooth, continuous surface, which smoothly and gradually transitions from the large-span tortuous contour at the input end 301 to the small-span (almost smooth) tortuous contour at the output end 302. As seen in Figure 9a, the small-span ribs 318 gradually and smoothly emerge without sharp transitions from the large-span ribs 316 and are formed in the machine direction until they finally completely replace the original surface contour at the end. the inlet 301 formed by the large-amplitude ribs 316. The ribs 318 are sized so that the frequency and amplitude of the sinuous contour of the forming surface 315 at the outlet end 302 represents an almost smooth shape that approximates the desired final corrugations for the finished plot 10d. The second half of die 320 also has a forming surface configured as described above, which opposes and is the substantial complement to forming surface 315 on the first half of die 310.
[078] Referring now to Figures 9b and 9c, the forming surface 315 of at least one of the matrix halves (for example, the first half of the matrix 310 in Figure 9b) has a tapered portion 312 at the inlet end 301, which tapers gradually towards the forming surface of the opposite die half (half 320 in Figure 9b) along the machine direction until the opposing forming surfaces are uniformly separated along the machine direction. As can be seen in the figure, the tapered portion is composed of the large-amplitude ribs 316 discussed above, which taper towards the opposite die half (preferably with a constant slope), when viewed from the side until they reach and are intertwined. with the opposite large-amplitude ribs 316 on the opposite forming surface. Thereby, the tapered portion 312 cooperates with the forming surface of the opposing die half to form a mouth 330 at the inlet end of the corrugation die 300 into which the formed web 10b can be fed. Mouth 330 prevents a sharp transition to weft 10b when entering the corrugation space between opposing die halves 310 and 320, and instead provides a gradual transition. In an alternative embodiment, the respective opposing die halves forming surfaces may each have oppositely tapered portions to form the mouth 330, rather than just one of the die halves having a tapered portion 312.
[079] In operation, die halves 310 and 320 are engaged as shown in Figure 9b, and the formed web 10b enters the corrugation space between the opposing forming surfaces via the mouth 330. As the web passes through the corrugation matrix 300, the formed web 10b of the forming device 200 is converted to an almost smooth shaped web 10c which approximates the final corrugated web 10d as the large span ribs 316 gradually give way to small span ribs 318 In particular, as the weft progresses, its shape gradually evolves from an initial sinuous contour defined by relatively large-frequency, relatively large-amplitude intermediate geometry grooves (corresponding to the contour of the large-amplitude ribs of ribs 316), in a final sinuous contour at the output end 302 having a relatively higher frequency and a lower amplitude corresponding to the small amplitude ribs 318. The final tortuous shape of the web 10c at the exit of the corrugation die 300 forms an almost smooth shape for the web that approximates the desired final corrugated geometry. Preferably, the weft contour smoothly and gradually transitions from the initial large-span sinuous contour to the small-span sinuous contour (almost smooth shape) as it passes between the first and second complementary opposing formation surfaces, following the transition gradual and smooth from the interlocked large span ribs 316 to the interlocked small span ribs 318. This weft progression can be seen in Figure 10, which illustrates a portion of the weft as it traverses the corrugation space between the surfaces of formation 315, and is smoothly transferred from the grooved configuration at 10b to the nearly smooth shape at 10c. Importantly, the width of the nearly smooth shaped web 10c is approximately the same as the formed web 10b as it enters the corrugation die 300; that is, wi wo in Figure 10. As a result, the lateral tension forces and deformations that could be imparted to the weft 10 in the corrugation matrix 300 (as a result of forming the tortuous pattern almost smoothly) are substantially reduced or eliminated. As the initial and final widths of the weft through the corrugation die 300 are substantially the same, no part of the weft need move laterally (in the cross-machine direction) in order to form the lowest amplitude and highest frequency grooves (at 10c ) from the highest amplitude and lowest frequency slots (in 10b). Instead, the individual weft elements only need to translate vertically as the weft moves in the machine direction, not laterally. As a result, as there is substantially no lateral movement of individual web elements, the corrugation matrix does not substantially introduce any lateral tension or friction forces or fluctuations to the web. This reduces the chances of damaging the plot.
[080]In Figure 9a, the matrix halves 310 and 320 are shown separated to allow the visualization of the contour of the internal forming surfaces of the matrix. But in use, the die halves 310 and 320 are brought into engagement with each other as seen in Figures 9b and 9c and discussed above, where the second die half 320 has an inner forming surface which is the complement of the forming surface. of the matrix half 310, also mentioned above. Preferably, when so engaged, there is a constant or substantially constant spacing between the opposing die halves 310 and 320, and their respective complementary forming surfaces, so that the shifting web 10 is not compressed to any significant degree as the through the corrugation matrix 300. In particular, the spacing between the opposite and complementary forming surfaces downstream of the tapered portion(s) 330 thereof is preferably constant and uniform, and preferably is at least 150% the thickness of the web that will travel between them, more preferably at least 175% of that thickness, and more preferably at least 200% or 250% of that thickness; in any case, the spacing is preferably not more than 400% of that thickness. Thus, the degree of drag on the moving web can be greatly reduced compared to if the spacing between the opposing forming surfaces was selected to only correspond to the approximate thickness of the web.
[081] Furthermore, to operate the corrugation line 1000 continuously, it will be necessary to periodically splice the web 10 in order to sustain a constant feed of material from the middle of a continuous and uninterrupted web 10. The maintenance of the above mentioned spacing between the halves of opposing dies will allow periodic splices in the weft 10 to pass through the forming matrix 300 without incident, and to be formed in the weft nearly smooth 10c with the rest of the continuous weft. In practice, the respective matrix halves 310 and 320 can be mounted to frames (not shown), which support them and maintain a relative distance between them when engaged to provide the modest degree of spacing between the opposing forming surfaces, as discussed above. .
[082] To further reduce drag and the introduction of longitudinal stress fluctuations, the corrugation matrix halves 310 and 320 can be provided with an arrangement of fluid ports 305 along their respective forming surfaces, through which a pressurized fluid similarly to that described above can be delivered to provide a fluid damper to support the web on either side. Also similarly to the above, feed distributors 380 may be distributed in each of the first and second mold halves 310 and 320, connected to a fluid source and provided in fluid communication with the fluid ports in the die half. associated 310 or 320, or with the respective seats of these doors in the respective longitudinal zones along the machine direction. Dispensers 380 may be arranged, configured, and operated analogously to that described above to selectively provide fluid flow rates and pressures uniformly to the fluid ports in each of the first and second half matrix 310 and 320 , or for different longitudinal zones uniformly in the same longitudinal zone(s) in both die halves 310 and 320. In this way, the fluid damper can minimize or prevent friction losses between the moving web and the surfaces of forming the matrix halves 310 and 320, reducing or even inhibiting the contact between them as the web moves.
[083] It is considered that corrugation dies having forming surfaces of different contours can be selected and used based on a) the particular sinuous pattern of the formed web 10b to be inserted therein, and b) the final groove size desired for the finished plot. Thus, different corrugation dies 300 can be provided corresponding to different combinations of draw ratio (corresponding to the desired final slot size) and final weft width, and can be interchanged at the corrugation line 1000 when different wefts are made. It is noted, for example, that various corrugation dies 300 can be made based on standard weft sizes and slot pitches to be installed interchangeably downstream of a forming device 200 and upstream of a final corrugating apparatus 400.
[084]Finally, it is noted that the corrugation matrix 300 described here is preferred in selected embodiments, but is considered optional in the corrugation line 1000. That is, while the corrugation matrix 300 may be desired to gradually convert the formed web with intermediate grooves 10b in the nearly smooth shaped web 10c approaching a final corrugated web 10d, in embodiments, it may be possible or desirable to simply feed the formed web 10b directly into a final corrugating apparatus, eg longitudinal corrugating rollers , to check final longitudinal corrugations or other three-dimensional structure. Ultimate Corrugation Apparatus
[085] Upon exiting the corrugation die 300 (if present) or the forming device 200, the nearly smooth formed web 10b or 10c can be delivered to a final corrugating apparatus 400 to produce the final corrugated web 10d having the desired longitudinal corrugations in the desired final weft width. In one embodiment, the final corrugation apparatus includes a pair of longitudinal corrugation rollers 410 and 420 as seen in Figure 11. In this embodiment, the corrugation rollers 410 and 420 are each seated on respective axes of rotation 411 and 421 which are parallel to each other and perpendicular to the machine direction, when viewed from above, such that the web travel path passes between opposing rollers 410 and 420. Rollers 410 and 420 have respective and complementary sets of longitudinally ribs distributed and extending circumferentially, so that at a narrowing 450 between rollers 410 and 420, the ribs of one roller extend and are received within valleys defined between the opposite ribs of the opposite roller, and vice versa. The opposing ribs are selected so as to define therebetween a substantially sinuous nip 450 having a contour in the lateral direction corresponding in frequency and amplitude to the desired grooves for the longitudinally corrugated web 4d.
[086] In operation, the formed web 10b or the nearly smooth shaped web 10c is fed along the machine direction to and through the nip 450 between the corrugation rollers 410 and 420. The web 10b/10c passes through the nip 450 and is compressed between opposing rollers 410 and 420 to form and relax the web into the sinuous longitudinally corrugated shape so that the final corrugated web 10d retains that shape regardless of the application of any external corrugating force or when that force is removed . If the web entering the corrugation nip 450 is the web formed 10b directly from the forming device 200 or the nearly smooth shaped web 10c from a corrugation die 300 die, its width remains substantially the same before, while and after traversing the corrugation nip 450. As a result, again there is preferably no or substantially no lateral (cross-machine direction) force on the web as it is corrugated on the corrugation nip 450.
[087]The finished 10d corrugated web can then be fed into additional units or operations for further downstream processing. For example, the corrugated web 10d can be delivered to a conventional single facer as is known in the art in order to apply a coating to produce a conventional single sided web. This single sided web can then be fed into a double support to apply a second coat to the remaining exposed groove crests of the web to produce the conventional double wall corrugated sheet, which can then be cut and molded in a conventional manner to make packing material such as boxes. Conclusion
[088]Conventionally, the friction experienced by a paper web proceeding through a longitudinal corrugating machine (as described in US Patent Application Publication No. 2010/0331160) was great enough to damage the paper web. This was because the amount of friction experienced by the moving web, as it was retracted inward (ie, its width reduced to accommodate longitudinal corrugations), increased exponentially with the number of groove-forming bars against which the paper web was required to travel in the non-cross-machine direction. Thus existing longitudinal forming devices would apply an ever-increasing amount of friction and transient and oscillating lateral tension forces to the paper web which can ultimately deform and/or destroy the final product.
[089] On the other hand, the curved (e.g., parabolic) geometry of the groove forming bars 212 and 222 of the forming device 200 described here results in a gradual forming process that uniformly and continuously forms the initial web into a shape. intermediate winding having a reduced width corresponding to the desired draw ratio, but without introducing transient or fluctuating lateral tension forces. As the individual weft elements follow a continuous curved path along the curved contour lines defined by the curved grooving bars (see Figure 5), there is substantially no lateral movement in the weft with respect to the grooving bars 212, 222. In other words, the curved forming bars 212, 222 are designed such that each part of the web (eg, paper web) substantially follows the same forming bar, or a continuously curved contour line between the adjacent forming bars 212, 222, along the machine direction from the input end 201 to the output end 202 of the forming device 200. As a result, the shifting web preferably experiences little, if any, movement in the transverse direction, transverse to the machine in relation to the forming bars 212, 222. This means that few, if any, frictional forces or tension or fluctuations are associated. The threads are applied to the moving web in the forming device 200 along the non-cross-machine direction.
[090] While particular embodiments of the invention have been described in detail, it should be understood that the invention is not correspondingly limited in scope, but includes all changes and modifications encompassed within the spirit and terms of the appended claims.

权利要求:
Claims (25)
[0001]
1. Forming device (200) having an inlet end (201) and an outlet end (202) spaced apart along a machine direction, the forming device (200) comprising a plurality of groove forming bars ( 212, 222, said plurality of grooving bars (212, 222) comprising first and second sets of grooving bars (210, 220) opposing each other and defining therebetween a longitudinal grooved labyrinth (250 ), each said set of groove forming bars (210, 220) extending from said adjacent inlet end (201) towards said outlet end (202), CHARACTERIZED by the fact that at least a subset of the The plurality of groove-forming bars (212, 222) is curved such that imaginary tangents to each of said subset of bars (212, 222), at locations spaced along their length, successively approach a parallel with the address machine operation such that said sub-assembly of bars (212, 222) converge in a cross-machine direction as they proceed towards said output end (202).
[0002]
2. Forming device according to claim 1, CHARACTERIZED by the fact that each of said sub-assembly of grooving bars (212, 222) is curved in at least a rear portion thereof starting adjacent to said end of inlet (201), and has a degree of curvature that decreases along the length of said back towards said outlet end (202).
[0003]
3. Forming device according to claim 1, CHARACTERIZED by the fact that tangents of all said groove forming bars (212, 222) at a location adjacent to said output end (202) are all parallel along of said machine direction.
[0004]
4. Forming device according to claim 1, CHARACTERIZED by the fact that each of said subset of groove forming bars (212, 222) is curved so that they all converge towards a common imaginary line that runs parallel to said machine direction.
[0005]
5. Forming device according to claim 4, CHARACTERIZED by the fact that said imaginary line is a center line of said forming device (200) which extends along said machine direction.
[0006]
6. Forming device according to claim 1, CHARACTERIZED in that a spacing between said first and second sets of groove forming bars (210, 220) is adjustable adjacent said outlet end (202) to at least partially interweave the opposing sets of slotting bars (210, 220) adjacent the exit end (202).
[0007]
7. Forming device according to claim 6, CHARACTERIZED by the fact that said spacing is also adjustable adjacent said inlet end (201) to thereby adjust a location in the machine direction of a choke point (290) where the first and second opposing sets of grooving bars (210, 220) begin to intertwine.
[0008]
8. Forming device according to claim 1, CHARACTERIZED by the fact that said first set (210) is a first flat arrangement of groove forming bars (212), said second set (220) is a second arrangement plane of grooving bars (222), wherein all curved grooving bars (212) in said first flat arrangement converge with respect to an imaginary first centerline (209) in said first flat arrangement, and wherein all curved slotting bars (222) in said second flat arrangement converge with respect to an imaginary second centerline (229) in said second flat arrangement.
[0009]
9. Forming device according to claim 8, CHARACTERIZED by the fact that at a given location along said machine direction, all groove forming bars (212) in said first flat arrangement are equidistant from each other and all groove forming bars (222) in said second flat arrangement are equidistant from each other.
[0010]
10. Forming device according to claim 9, CHARACTERIZED by the fact that said first and second flat arrangements are arranged so that all groove forming bars (212, 222) of both arrangements together are equidistant between itself in the cross-machine direction at any given location in the machine direction.
[0011]
11. Forming device according to claim 8, CHARACTERIZED by the fact that it comprises a linear groove forming bar (212a) in at least one of the first and second plane arrangements, aligned and collinear with the respective first or second imaginary centerline (209, 229) of the same.
[0012]
12. Forming device according to claim 1, CHARACTERIZED by the fact that said first set (210) is a first flat arrangement of groove forming bars (212) and said second set (220) is a second flat arrangement of the grooving bars (222), wherein each curved grooving bar (212, 222) in a respective arrangement among said arrangements has a degree of lateral curvature which decreases in the machine direction so that rates of lateral convergence of the same also decrease.
[0013]
13. Forming device according to claim 12, CHARACTERIZED by the fact that at any given location along said machine direction, all groove forming bars (212, 222) in each of said respective arrangements are equidistant from each other.
[0014]
14. Forming device according to claim 12, CHARACTERIZED by the fact that said first and second arrangements of grooving bars are intertwined starting at a choke point (290) spaced from said inlet end ( 201) along the machine direction, with a degree of interweaving of said arrays gradually increasing from the choke point (290) towards said output end (202).
[0015]
15. Formation device, according to claim 8, CHARACTERIZED by the fact that each of said first and second arrangements is flat.
[0016]
16. Forming device according to claim 12, CHARACTERIZED by the fact that each of said first and second arrangements is curved to define respective partially cylindrical arcs having respective radii of curvature in relation to first and second imaginary axes transverse to the machine , so that at least parts of the grooving bars (212, 222) in each of the respective arrangements are rounded with respect to the respective imaginary axis transverse to the machine in addition to being laterally curved so as to converge laterally along the direction of machine.
[0017]
17. Forming device according to claim 1, CHARACTERIZED in that one of said groove forming bars (212, 222) has a plurality of fluid ports (205) configured thereon to emit a fluid to deliver a fluid damper between said bars and a web (10) traveling through said forming device in operation.
[0018]
18. Forming device (200) having an inlet end (201) and an outlet end (202) separated along a machine direction, the forming device (200) CHARACTERIZED in that it comprises a plurality of bars of grooving bars (212, 222), said plurality of grooving bars (212, 222) comprising first and second sets of grooving bars (210, 220) opposite each other and defining therebetween a slotted labyrinth. longitudinally (250), each said set of groove forming bars (210, 220) extending from said adjacent inlet end (201) toward said outlet end (202), at least one subset of the plurality of groove forming bars (212, 222) having a variable tangent configuration such that imaginary tangents to each of said subset of bars (212, 222), at locations spaced along a length thereof, become succesfull. substantially closer to a parallel with the machine direction so that said subset of bars (212, 222) converge in a cross-machine direction as a result of said variable tangent configuration as they proceed towards said end. exit (202).
[0019]
19. Forming device according to claim 18, CHARACTERIZED by the fact that tangents of all said groove forming bars (212, 222) at a location adjacent to said outlet end (202) are all parallel along of said machine direction.
[0020]
20. Forming device according to claim 18, CHARACTERIZED by the fact that each of said subset of groove forming bars (212, 222) converges towards a common imaginary line running parallel to said machine direction .
[0021]
21. Forming device according to claim 18, CHARACTERIZED by the fact that a spacing between said first and second sets of groove forming bars (210, 220) is adjustable adjacent said outlet end (202) to at least partially interweave the opposing sets of slotting bars (210, 220) adjacent the exit end (202).
[0022]
22. Forming device according to claim 21, CHARACTERIZED by the fact that said spacing is also adjustable adjacent said inlet end (201) to thereby adjust a location in the machine direction of a choke point (290) where the first and second opposing sets of grooving bars (210, 220) begin to intertwine.
[0023]
23. Forming device according to claim 18, CHARACTERIZED by the fact that said first set (210) is a first flat arrangement of groove forming bars (212), said second set (220) is a second flat arrangement of grooving bars (222), wherein all grooving bars (212) of variable tangent in said first flat arrangement converge with respect to an imaginary first centerline (209) in said first flat arrangement, and wherein all slotting bars (222) of varying tangent in said second flat arrangement converge with respect to an imaginary second centerline (229) in said second flat arrangement.
[0024]
24. Forming device according to claim 23, CHARACTERIZED by the fact that said first and second flat arrangements are arranged so that all groove forming bars (212, 222) from both arrangements together are equidistant each other in the cross-machine direction at any given location in the machine direction.
[0025]
25. Forming device according to claim 23, CHARACTERIZED by the fact that said first and second arrangements of grooving bars are intertwined starting at a choke point (290) spaced from said inlet end (201) along the machine direction, with a degree of interweaving of said arrays gradually increasing from said choke point (290) towards said output end (202).

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引用文献:

---

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

---

---

USRE20970E|1939-01-03|Apparatus for imparting stretchability to webs |

---

US1848583A|1932-03-08|swift |

---

US654884A|1899-07-20|1900-07-31|Jeffrey T Ferres|Apparatus for making corrugated paper.|

---

US739276A|1902-05-12|1903-09-22|Walter L Allen|Machine for corrugating paper.|

---

FR335445A|1903-09-22|1904-01-25|Walter Long Allen|Paper corrugating machine|

---

DE159213C|1903-09-22|1905-03-21|Walter Long Allen|MACHINE FOR CORRUGATING VAN PAPER, CARDBOARD O DGL IN THE LENGTH DIRECTION|

---

US1199508A|1914-12-24|1916-09-26|George W Swift Jr|Corrugated paper-board and process of making the same.|

---

US1627966A|1920-04-17|1927-05-10|Arkell Safety Bag Co|Apparatus for operating on paper and other fabrics|

---

US1468766A|1921-09-09|1923-09-25|Herbert E Van Dorn|Drawbar carrier|

---

GB199538A|1922-04-13|1923-06-28|Frederick Rippon Reynolds|Improvements in and relating to machines for the production of pleated or creased paper, fabrics and the like|

---

US1834648A|1930-03-03|1931-12-01|Johns Manville|Corrugating machine|

---

DE595275C|1932-11-29|1934-04-07|Jacob Moll|Device for the production of corrugated sheets from paper, cardboard, etc.|

---

US1981338A|1934-01-10|1934-11-20|George W Swift Jr Inc|Machine for making corrugated paper board|

---

US2257429A|1937-08-04|1941-09-30|Ruegenberg Gottfried|Process for producing all-around extensible paper|

---

US2163063A|1937-08-11|1939-06-20|Hippolyte W Romanoff|Machine for making corrugated articles|

---

US2236932A|1938-01-27|1941-04-01|Arentsen Gerrit Jan|Apparatus for continuously manufacturing corrugated construction boards|

---

US2398844A|1944-03-04|1946-04-23|Combined Locks Paper Co|Paper coating|

---

US2494431A|1945-06-28|1950-01-10|Karl J Eckstein|Continuous corrugating mechanism|

---

US2622558A|1948-01-19|1952-12-23|Inland Wallpaper Company|Machine for coating web material|

---

US2793676A|1952-04-14|1957-05-28|Theodor Bell & Cie Ag|Apparatus for corrugating paper or cardboard|

---

US3002876A|1955-10-22|1961-10-03|Rosati Gildo|Apparatus for corrugating paper in a direction parallel to the length of the sheet|

---

US3024496A|1957-04-05|1962-03-13|S Lavorazione Materie Plastisc|Method and apparatus for manufacturing corrugated thermoplastic sheets|

---

US3046935A|1957-05-24|1962-07-31|S & S Corrugated Paper Mach|Gluing control means|

---

NL275557A|1957-12-23|

---

US2960145A|1958-07-14|1960-11-15|Ruegenberg Gottfried|Method of and apparatus for manufacturing longitudinally folded or longitudinally arched, particularly longitudinally corrugated webs of paper, carton, cardboard, plastics or the like|

---

US3077222A|1959-09-23|1963-02-12|Diamond Alkali Co|Apparatus for producing corrugated board|

---

NL280801A|1961-07-17|

---

US3300359A|1962-02-06|1967-01-24|Willem A Nikkel|Method and apparatus for making corrugated board|

---

US3178494A|1962-11-15|1965-04-13|Lucien E Tisdale|Method and apparatus for forming longitudinal corrugations in sheet material|

---

US3306805A|1963-05-20|1967-02-28|Novelart Mfg Company|Apparatus for making printed corrugated paper board|

---

JPS4023188Y1|1964-01-17|1965-08-07|

---

US3303814A|1964-07-28|1967-02-14|Koppers Co Inc|Apparatus for applying adhesive to a moving web|

---

US3479240A|1964-08-03|1969-11-18|Harris Intertype Corp|Prefeeder mechanism for single facer machines|

---

US3383234A|1964-08-31|1968-05-14|Samuel M Langston Co|Applicator roll with metering means|

---

US3425888A|1964-09-04|1969-02-04|Keith Q Kellicutt|Method and apparatus for producing faced corrugated materials|

---

JPS424916Y1|1964-11-25|1967-03-14|

---

GB1181161A|1967-05-22|1970-02-11|Morane Plastic Company Ltd|Laminating Machine|

---

US3676247A|1969-02-03|1972-07-11|Australian Paper Manufacturers|Corrugating paperboard|

---

JPS4821676B1|1969-03-12|1973-06-30|

---

US3692615A|1970-03-12|1972-09-19|Koichiro Ohmori|Apparatus for forming longitudinal corrugations in sheet material|

---

US3676263A|1970-03-26|1972-07-11|Ridge Ply Inc|Machine for making stress laminated panel|

---

US3738905A|1970-04-29|1973-06-12|Kimberly Clark Co|Paper toweling material and method of combining into multi ply products|

---

JPS4821676Y1|1970-05-20|1973-06-23|

---

US3648913A|1970-09-10|1972-03-14|Harris Intertype Corp|Noiseless paperboard guide|

---

US3700518A|1971-03-17|1972-10-24|Honshu Paper Co Ltd|Method for manufacturing a composite corrugated paper board|

---

US3773587A|1971-07-01|1973-11-20|Domtar Ltd|Manufacture of corrugated board|

---

US3892613A|1971-07-22|1975-07-01|Int Paper Co|Method of making corrugated paperboard|

---

JPS5221433B2|1971-08-17|1977-06-10|

---

US3788515A|1972-03-20|1974-01-29|Koppers Co Inc|Method and apparatus for guiding and tensioning a web|

---

GB1481050A|1973-10-30|1977-07-27|Mitsubishi Petrochemical Co|Corrugated cardboard sheet and method for producing the same|

---

US3966518A|1973-12-26|1976-06-29|Molins Machine Company, Inc.|Paperboard corrugator|

---

US3981758A|1974-11-04|1976-09-21|Koppers Company, Inc.|Process control system for corrugators|

---

US3993425A|1975-03-20|1976-11-23|The Real-Reel Corporation|Apparatus for forming diagonally corrugated paperboard|

---

ES448652A1|1975-06-10|1977-12-01|Cellcor Corp Of Canada Ltd|Process and apparatus for producing modified starch products|

---

GB1544634A|1975-07-04|1979-04-25|Simon Container Mach Ltd|Corrugating machinery|

---

US4177102A|1976-04-19|1979-12-04|Rengo Co., Ltd.|Single facer for manufacturing single-faced corrugated board|

---

JPS5717606Y2|1976-05-08|1982-04-13|

---

JPS52148396A|1976-06-04|1977-12-09|Kobayashi Seisakusho|Apparatus for forming corrugation of corrugated cardboard in direction of flow of sheet|

---

JPS5620982B2|1976-06-18|1981-05-16|

---

CA1072873A|1976-06-28|1980-03-04|Weyerhaeuser Company|Corrugating process|

---

JPS5310833U|1976-07-13|1978-01-30|

---

US4126508A|1976-09-13|1978-11-21|Boise Cascade Corporation|Apparatus for forming multi-flute-layer corrugated board|

---

US4104107A|1977-03-18|1978-08-01|Koppers Company, Inc.|Apparatus for urging web guides toward the corrugating roll of a single facer|

---

US4134781A|1977-05-03|1979-01-16|Key Chemicals, Inc.|Method for controlling warp in the manufacture of corrugated paperboard|

---

US4170347A|1977-06-22|1979-10-09|E. I. Du Pont De Nemours And Company|Web pleater|

---

US4179253A|1978-04-10|1979-12-18|Domtar Inc.|Linear corrugating roll deflection control|

---

DE2851007C3|1978-11-24|1982-02-04|BHS-Bayerische Berg-, Hütten- und Salzwerke AG, 8000 München|Device for the production of corrugated cardboard with a cover on at least one side|

---

GB2039559A|1979-01-18|1980-08-13|Munters Corp|Apparatus for producing a corrugated sheet|

---

US4351264A|1979-03-20|1982-09-28|S&S Corrugated Paper Machinery Co., Inc.|Adhesive metering device|

---

US4316755A|1979-03-20|1982-02-23|S&S Corrugated Paper Machinery Co., Inc.|Adhesive metering device for corrugating processes|

---

US4338154A|1979-09-14|1982-07-06|S. A. Martin|Machine for producing single-face corrugated board|

---

US4267008A|1979-09-24|1981-05-12|Eastern Container Corporation|Corrugating machine|

---

FR2479032B1|1980-03-31|1982-02-19|Martin Sa|

---

JPS5922983Y2|1980-04-30|1984-07-09|

---

US4282998A|1980-05-09|1981-08-11|W. R. Grace & Co.|Maintenance of constant web clearance at contactless turning guide|

---

US4316428A|1980-12-01|1982-02-23|S&S Corrugated Paper Machinery Co., Inc.|Fluid metering device|

---

US4344379A|1981-02-02|1982-08-17|Molins Machine Company, Inc.|Bonding machine and gravure applicator roll|

---

JPH028579B2|1981-06-08|1990-02-26|Kyokuto Int|

---

DE3142832C2|1981-10-29|1987-12-03|Boise Cascade Corp., Boise, Id., Us|

---

DE3215472C2|1982-04-24|1984-02-23|M.A.N.- Roland Druckmaschinen AG, 6050 Offenbach|Reversing bar surrounded by air|

---

US5203935A|1983-03-31|1993-04-20|Payne Packaging Limited|Method of producing packaging material having a tear tape|

---

US4569864A|1983-06-30|1986-02-11|Acumeter Laboratories, Inc.|Roll coating applicator and adhesive coatings and the like and process of coating|

---

FR2555101B1|1983-11-17|1987-10-23|Martin Sa|METHOD AND DEVICE FOR MANUFACTURING A CORRUGATED CARDBOARD STRIP|

---

JPH0519457B2|1984-02-20|1993-03-16|Mori Shigyo Kk|

---

FI853041A0|1985-08-07|1985-08-07|Valmet Oy|ANORDING FROM THE MATERIAL.|

---

ZA866491B|1985-09-04|1987-05-27|Amcor Ltd|Corrugated board|

---

US4806183A|1986-08-11|1989-02-21|Consolidated Papers, Inc.|Method of and apparatus for controlling application of glue to defined areas|

---

US4764236A|1987-06-22|1988-08-16|Westvaco Corporation|Corrugating machine glue applicator|

---

SU1468766A1|1987-10-09|1989-03-30|Всесоюзный Научно-Исследовательский И Экспериментально-Конструкторский Институт Тары И Упаковки|Method of longitudinal corrugation paper web|

---

CA1312540C|1987-12-18|1993-01-12|Peter Gordon Bennett|Forming corrugated board structures|

---

JPH01228572A|1988-03-09|1989-09-12|Yokoyama Seisakusho:Kk|Device for absorbing change of web length in movement of packing roll of coating machine|

---

US4871593A|1988-03-17|1989-10-03|Acumeter Laboratories, Inc.|Method of streakless application of thin controlled fluid coatings and slot nozzle - roller coater applicator apparatus therefor|

---

US4841317A|1988-05-02|1989-06-20|Honeywell Inc.|Web handling device|

---

US4879949A|1988-05-18|1989-11-14|Ildvaco Engineering A/S|Reverse angle doctor blade assembly|

---

US4863087A|1988-08-05|1989-09-05|The Kohler Coating Machinery Corporation|Guide apparatus for elongated flexible web|

---

SE463078B|1988-09-27|1990-10-08|Btg Kaelle Inventing Ab|APPLICATION DEVICE MAKES ONE OR TWO-SIDE COATING OF A CURRENT COAT|

---

US4991787A|1989-03-15|1991-02-12|Minnesota Mining And Manufacturing Company|Pivoting guide for web conveying apparatus|

---

US5037665A|1990-03-29|1991-08-06|Enamel Products & Plating Company|Method of creating a registered pattern on a metal coil and associated apparatus|

---

FI88421C|1990-04-19|1993-05-10|Valmet Paper Machinery Inc|Coating device for coating roll in an adhesive press, paper or cardboard|

---

WO1991017943A1|1990-05-11|1991-11-28|Liedtke Rudolph J|Air bearing for web material|

---

US5185052A|1990-06-06|1993-02-09|The Procter & Gamble Company|High speed pleating apparatus|

---

DE4018426C2|1990-06-08|1992-07-30|Bhs-Bayerische Berg-, Huetten- Und Salzwerke Ag, 8000 Muenchen, De|

---

US5016801A|1990-08-28|1991-05-21|Industrial Label Corporation|Multiple-ply web registration apparatus|

---

US5244518A|1990-11-02|1993-09-14|Stickle Steam Specialties Co. Inc.|Corrugated board manufacturing apparatus and process including precise web moisture and temperature control|

---

US5226577A|1990-12-20|1993-07-13|The Kohler Coating Machinery Corporation|Web guide for elongated flexible web|

---

US5103732A|1991-02-14|1992-04-14|Ward Holding Company, Inc.|Doctor blade head assembly and printing apparatus therewith|

---

SU1805605A1|1991-02-25|1996-07-20|Киевский механический завод им.О.К.Антонова|Method of forming sheet parts made of composite materials with sinusoidal corrugations|

---

IT1252896B|1991-11-08|1995-07-05|Perini Fabio Spa|IMPROVED EQUIPMENT FOR GLUING THE FINAL EDGE OF ROLLS OF TAPE MATERIAL|

---

US5275657A|1991-11-25|1994-01-04|E. I. Du Pont De Nemours And Company|Apparatus for applying adhesive to a honeycomb half-cell structure|

---

CA2067256A1|1992-04-27|1993-10-28|Chiu Hui Wu|Lined and coated corrugated paperboard package systems for modified atmosphere packaging of fresh fruits and vegetables|

---

JP2566502B2|1992-06-24|1996-12-25|西川ローズ株式会社|Bellows sheet continuous manufacturing equipment|

---

US5362346A|1993-04-22|1994-11-08|Mead|Method of making reinforced corrugated board|

---

US5508083A|1993-05-19|1996-04-16|Chapman, Jr.; Francis L.|Machine direction fluted combined corrugated containerboard|

---

SE501564C2|1993-06-18|1995-03-13|Btg Kaelle Inventing Ab|Coating device for one or two-sided coating of a running track|

---

DE4420242A1|1994-06-10|1995-01-05|Voith Gmbh J M|Equipment for the alternative treatment of a running web|

---

DE69600897T2|1995-03-29|1999-05-12|Mitsubishi Heavy Ind Ltd|Method and device for checking the application of glue to corrugated paper|

---

US5947885A|1994-11-01|1999-09-07|Paterson; James G. T.|Method and apparatus for folding sheet materials with tessellated patterns|

---

US5894681A|1995-05-01|1999-04-20|Inland Container Corporation|Automated fabrication of corrugated paper products|

---

US5792487A|1996-04-10|1998-08-11|Witt Plastics Of Florida Inc.|Corrugated plastic wall panels|

---

JPH1034776A|1996-07-19|1998-02-10|Rengo Co Ltd|Pasting apparatus for single facer|

---

US5916414A|1996-08-22|1999-06-29|Mitsubishi Heavy Industries, Ltd.|Glue applicator for corrugated board|

---

CA2214486C|1996-09-04|2006-06-06|Consolidated Papers, Inc.|Method and apparatus for minimizing web-fluting in heat-set, web-offset printing presses|

---

BR9808680A|1997-04-17|2000-08-29|Gruppo X Di X Gruppo S R L|Process for obtaining dimensionally and structurally stable objects, in particular disposable containers, obtained from flexible film, and object obtained by said process|

---

RU2118217C1|1997-07-14|1998-08-27|Казанский государственный технический университет им.А.Н.Туполева|Apparatus for corrugating sheet material|

---

JPH11123780A|1997-10-22|1999-05-11|Mitsubishi Heavy Ind Ltd|Single facer|

---

DE19751697A1|1997-11-21|1999-05-27|Voith Sulzer Papiertech Patent|Device for the indirect application of a liquid or pasty medium to a material web, in particular made of paper or cardboard|

---

JP3664865B2|1998-02-06|2005-06-29|三菱重工業株式会社|Corrugating machine|

---

US6068701A|1998-02-23|2000-05-30|Kohler Coating Machinery Corporation|Method and apparatus for producing corrugated cardboard|

---

US6143113A|1998-03-02|2000-11-07|Le Groupe Recherche I.D. Inc.|Repulpable corrugated boxboard|

---

AU2989899A|1998-03-18|1999-10-11|United Container Machinery, Inc.|Lengthwise web corrugator|

---

IT1305959B1|1998-05-11|2001-05-21|Agnati Spa|GROUP FOR THE COUPLING OF PAPER SHEETS INTO THE MACHINES FOR THE MANUFACTURE OF CARDBOARD ONDUALTO.|

---

DE19841171A1|1998-09-09|2000-05-25|Koenig & Bauer Ag|Turning bar arrangement|

---

CN1123522C|1998-12-23|2003-10-08|巴赫芬和迈耶机械制造股份公司|Device for guiding or treating a continuous line of material in contactless manner, especially a line of paper or cardboard or metal or plastic film|

---

JP2000202930A|1999-01-19|2000-07-25|Oji Paper Co Ltd|Single facer and corrugated fiberboard manufactured by using the single facer|

---

US6470294B1|1999-04-13|2002-10-22|Qualitek-Vib, Inc.|System and method for the on-line measurement of glue application rate on a corrugator|

---

JP2000351500A|1999-06-08|2000-12-19|Fuji Photo Film Co Ltd|Contactless conveying device for web|

---

JP2001047533A|1999-08-12|2001-02-20|Isowa Corp|Corrugation roll and corrugated cardboard manufacturing apparatus|

---

JP4422826B2|1999-08-24|2010-02-24|田中精機株式会社|Tension device|

---

EP1086805B1|1999-09-22|2004-11-10|BHS CORRUGATED MASCHINEN- UND ANLAGENBAU GmbH|Machine for producing corrugated board and method of calibrating the glue applicator gap in such a machine|

---

US6575399B1|2000-01-19|2003-06-10|Energy Savings Products And Sales Corp.|Web control matrix|

---

US6364247B1|2000-01-31|2002-04-02|David T. Polkinghorne|Pneumatic flotation device for continuous web processing and method of making the pneumatic flotation device|

---

KR100378163B1|2000-02-24|2003-03-29|삼성전자주식회사|Sheet coating apparatus|

---

JP3492304B2|2000-09-22|2004-02-03|三菱重工業株式会社|Double facer for corrugated sheet manufacturing system|

---

DE10052372A1|2000-10-20|2002-05-02|Bhs Corr Masch & Anlagenbau|Method for regulating the height of a nip of a gluing device for a corrugated cardboard web and device for carrying out the method|

---

US6505792B1|2000-11-28|2003-01-14|Megtec Systems, Inc.|Non-contact floating device for turning a floating web|

---

JP2002308489A|2001-04-16|2002-10-23|Fuji Photo Film Co Ltd|Manufacturing method for magnetic tape|

---

US6612462B2|2001-05-31|2003-09-02|Kimberly-Clark Worldwide, Inc.|Stack of fan folded material and combinations thereof|

---

DE10129018B4|2001-06-08|2005-05-25|Weile, Frank, Dr.|Method, apparatus and mold element for forming a longitudinally corrugated web|

---

US6595465B2|2001-09-10|2003-07-22|Energy Saving Products And Sales Corp.|Turn bar assembly for redirecting a continuous paper web|

---

US6708919B2|2002-03-19|2004-03-23|Kimberly-Clark Worldwide, Inc.|Turning bar assembly for use with a moving web|

---

US6602546B1|2002-06-21|2003-08-05|Coater Services, Inc.|Method for producing corrugated cardboard|

---

US7115089B2|2003-02-24|2006-10-03|Rutgers, The State University Of New Jersey|Technology for continuous folding of sheet materials|

---

US7758487B2|2003-02-24|2010-07-20|Rutgers, The State University Of New Jersey|Technology for continuous folding of sheet materials into a honeycomb-like configuration|

---

DE10324729A1|2003-05-31|2004-12-16|Bhs Corrugated Maschinen- Und Anlagenbau Gmbh|Method and gluing unit for continuous gluing of webs|

---

JP2005193504A|2004-01-07|2005-07-21|Rengo Co Ltd|Corrugated cardboard sheet manufacturing apparatus|

---

US7267153B2|2004-03-02|2007-09-11|Herbert B Kohler|Corrugator glue machine having web tension nulling mechanism|

---

US20050194088A1|2004-03-02|2005-09-08|Kohler Herbert B.|Method and apparatus for making corrugated cardboard|

---

JP3913746B2|2004-05-24|2007-05-09|株式会社バンダイ|Shape change device|

---

US8057621B2|2005-04-12|2011-11-15|Kohler Herbert B|Apparatus and method for producing a corrugated product under ambient temperature conditions|

---

US9005096B2|2005-05-23|2015-04-14|Daniel H. Kling|Folding method and apparatus|

---

US7595086B2|2005-10-27|2009-09-29|Kohler Herbert B|Method for producing corrugated cardboard|

---

US7740786B2|2005-12-15|2010-06-22|Kimberly-Clark Worldwide, Inc.|Process for making necked nonwoven webs having improved cross-directional uniformity|

---

CA2691708A1|2007-06-20|2008-12-24|Herbert B. Kohler|Method for producing corrugated cardboard|

---

JP5215690B2|2008-03-06|2013-06-19|三菱重工業株式会社|Thermal barrier coating structure, gas turbine high temperature parts, gas turbine|

---

JP5459684B2|2008-03-21|2014-04-02|エイチビーケーファミリー，エルエルシー|Equipment for producing cardboard|

---

NZ599420A|2008-05-27|2013-10-25|Corcel Ip Ltd|Single Face Corrugated Board Methods of Making Same and Products Made Therefrom|

---

CN100584596C|2008-11-05|2010-01-27|李新桥|Crawler type corrugated paper production equipment|

---

EP2391505B1|2009-01-22|2021-03-10|Intpro, Llc|Method for moisture and temperature control in corrugating operation|

---

WO2013063551A2|2011-10-28|2013-05-02|Rutgers, The State University Of New Jersey|Method and apparatus for microfolding sheet materials|

---

CN202412810U|2011-12-31|2012-09-05|广东万联包装机械有限公司|Corrugated machine|

---

WO2014070943A1|2012-11-01|2014-05-08|Hbk Family, Llc|Method and apparatus for fluting a web in the machine direction|IN2015DN00608A|2012-07-24|2015-06-26|Procter & Gamble|

---

WO2014070943A1|2012-11-01|2014-05-08|Hbk Family, Llc|Method and apparatus for fluting a web in the machine direction|

---

MY178267A|2013-03-15|2020-10-07|Scorrboard Llc|Establishing a registered score, slit or slot in corrugated board, and articles produced therefrom|

---

KR102296772B1|2013-12-23|2021-09-03|필립모리스 프로덕츠 에스.에이.|Method and apparatus for treating continuous sheet material|

---

US9783330B2|2014-03-06|2017-10-10|The Procter & Gamble Company|Method and apparatus for shaping webs in a vertical form, fill, and sealing system|

---

US9643812B2|2014-03-06|2017-05-09|The Procter & Gamble Company|Method for pleating or shaping a web|

---

DE102014206083A1|2014-03-31|2015-10-01|Foldcore Gmbh|Method for forming a flat sheet material and device|

---

US10328654B2|2016-04-20|2019-06-25|Scorrboard, Llc|System and method for producing a multi-layered board having a medium with improved structure|

---

US11027515B2|2016-04-20|2021-06-08|Scorrboard Llc|System and method for producing multi-layered board having at least three mediums with at least two mediums being different|

---

US10800133B2|2016-04-20|2020-10-13|Scorrboard, Llc|System and method for producing a facing for a board product with strategically placed scores|

---

US11027513B2|2016-04-20|2021-06-08|Scorrboard Llc|System and method for producing an articulating board product having a facing with score lines in register to fluting|

---

CN108260852B|2016-12-30|2020-12-11|中烟机械技术中心有限责任公司|Pre-folding device for crepe paper|

---

CN109512024B|2017-09-18|2021-07-20|中烟机械技术中心有限责任公司|Method for manufacturing paper filter stick|

---

CN108705813A|2018-05-03|2018-10-26|芜湖凯德机械制造有限公司|A kind of corrugated paper compression molding device|

---

CN108705814A|2018-05-03|2018-10-26|芜湖凯德机械制造有限公司|A kind of automatic press-forming machine of corrugated paper|

---

WO2021026146A1|2019-08-05|2021-02-11|Intpro, Llc|Paper-specific moisture control in a traveling paper web|

法律状态:
2018-11-21| B06F| Objections, documents and/or translations needed after an examination request according [chapter 6.6 patent gazette]|

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2020-01-28| B06U| Preliminary requirement: requests with searches performed by other patent offices: procedure suspended [chapter 6.21 patent gazette]|

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2020-10-06| B06A| Notification to applicant to reply to the report for non-patentability or inadequacy of the application [chapter 6.1 patent gazette]|

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2021-02-23| B09A| Decision: intention to grant [chapter 9.1 patent gazette]|

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2021-04-20| B16A| Patent or certificate of addition of invention granted|Free format text: PRAZO DE VALIDADE: 20 (VINTE) ANOS CONTADOS A PARTIR DE 30/10/2013, OBSERVADAS AS CONDICOES LEGAIS. |

优先权:

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申请号 | 申请日 | 专利标题

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US201261721079P| true| 2012-11-01|2012-11-01|

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US61/721.079|2012-11-01|

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PCT/US2013/067598|WO2014070943A1|2012-11-01|2013-10-30|Method and apparatus for fluting a web in the machine direction|

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