Abstract:
A shipping pallet is constructed of multiple laminations of corrugated sheet material, with specific construction details providing advantages in strength and trueness of the completed pallet, and further advantages in the reduction of tooling and labor costs. The stringers or runners, deck boards, and top and bottom sheets may be sawn from stacks of plural laminations, thus precluding any requirement for costly dies and intensive labor. Asymmetrical corrugated sheets may be used, with one side having a different weight than the other. By laminating two such sheets together with like weighted sides in contact, the tendency of such sheets to curve or warp due to the difference in side thickness is substantially eliminated. Different orientations of the corrugations or flutes of the sheets during lamination and assembly of the pallet, provide advantages in strength for specific applications. The deck boards and stringers may be notched so as to interlock with one another, thus providing additional strength and durability. The pallet may be constructed of plural laminations of various corrugated sheet materials, such as paperboard or fiberboard, or plastic.

Description:
REFERENCE TO RELATED PATENT APPLICATION 
     This application is a continuation in part of U.S. patent application Ser. No. 08/178,835, filed on Jan. 7, 1994. 
    
    
     FIELD OF THE INVENTION 
     The present invention relates generally to shipping pallets used in the shipping industry, and more specifically to pallet construction using corrugated cardboard, paperboard, plastic and/or other corrugated materials. Specific orientation of the corrugations or flutes of the material, and in laminating the corrugated sheets, provide advantages in the manufacture and use of the pallets. Some of the components are notched for interlocking assembly, which interlocking provides significant strength when used with other features of the present pallet construction. 
     BACKGROUND OF THE INVENTION 
     Traditionally, shipping pallets have been constructed of wood slats and/or runners or stringers of various dimensions. Such wood pallets are relatively costly, even though they are generally cheaply made of relatively poor quality wood. The hasty assembly and poor wood quality result in pallets which may rapidly become damaged to the point of being unusable. Moreover, such pallets are relatively heavy, resulting in additional shipping costs to the shipper, just for the weight and volume of the pallets themselves. 
     As a result, pallets formed of other materials have been developed, and in fact pallets constructed of corrugated cardboard have been known since the early &#39;60&#39;s, if not earlier. However, the various pallets formed of corrugated materials have been deficient in areas of strength, durability, warping, and/or environmental concerns (e.g., difficulty in recycling), compared to the present invention. 
     The need arises for pallets constructed of corrugated sheet material, which provide for specific orientation of the corrugations and laminations to provide additional strength and freedom from warping. Superior strength is achieved by providing multiple laminations of corrugated material, and notching the deck boards and stringers of the pallets for an interlocking fit and for the elimination of voids between components. The materials used are preferably recyclable in order to provide further environmental advantages. 
     DESCRIPTION OF THE PRIOR ART 
     U.S. Pat. No. 2,045,733 issued to Allen L. Spafford on Jun. 30, 1936 discloses an Insulation Structure utilizing multiple sheets of corrugated material. Only FIG. 1 discloses the use of plural corrugated sheets, each of which includes opposite backing layers, and no disclosure is made of securing the layers together except at their peripheries. This construction lacks the structural strength required for use in pallet construction. 
     U.S. Pat. No. 3,006,590 issued to Lowell E. Hoag on Oct. 31, 1961 discloses a Corrugated Pallet generally formed of a single sheet of material, rather than the multiple laminations of the present invention. The resting pads or feet of the pallet are hollow, unless an additional step is taken to fill them with additional material for additional strength. The sheet requires a relatively costly die to make the required cuts, as well as a folding machine, rather than enabling construction by sawing multiple sheets, as can be done with the present construction. No interlocking of separately laminated layups is disclosed. 
     U.S. Pat. No. 3,464,371 issued to Sheldon R. Gifford on Sep. 2, 1969 discloses a Disposable Pallet having folded upper and lower sheets and runners. The runners include filler material for additional strength. However, the folding of the structure requires additional costly equipment, and the interlocking assembly of separate laminated components is not disclosed. 
     U.S. Pat. No. 3,661,099 issued to Clifford D. Shelor on May 9, 1972 discloses a Pallet Deck having an upper and/or lower deck each formed of vertically oriented corrugations with top and bottom corrugated sheet overlays bonded thereto. Wood blocks are used for the pads or spacers between upper and lower sheets, thus resulting in a heavier pallet than otherwise. The wood blocks are nailed to the upper and lower sheets. The localized stress of a nail or screw at the cardboard sheet, would appear to cause premature damage to the structure when the nails are torn out. Moreover, the different materials and hand labor required to nail the blocks in place, would result in a more labor intensive pallet construction than the present pallet construction. None of the major components are interlocked, as in the present invention. 
     U.S. Pat. No. 4,044,981 issued to Robert H. Richter on Aug. 30, 1977 discloses a Paperboard Pallet formed of a plurality of folded corrugated sheets. The folds are upwardly disposed to provide for the securing of an article thereto, resulting in a non-planar upper surface. Due to the relatively thin nature of the overall structure, the laminations are oriented only horizontally, rather than providing other orientations for additional strength. No interlocking of intersecting components is disclosed. 
     U.S. Pat. No. 4,378,743 issued to William M. McFarland on Apr. 5, 1983 discloses a Paperboard Pallet Having Interlocked Runners. The pallet sheet is formed of a single layer of material, folded up at the edges, with cutouts providing for the insertion of support pads or feet therethrough. The pads are secured to overlying runners, with pads and runners being formed of a solid material (wood, rubber, plastic) rather than having internal corrugations. The formation of the runners and pads, as well as the folding of the pallet sheet, result in the need for costly equipment or labor for the construction of the McFarland pallet. The runners are interlocked only with the bottom sheet; no interlocking of intersecting elongate components, as with the deck boards and stringers of the present invention, is disclosed. 
     U.S. Pat. No. 4,424,753 issued to John R. Eatherton on Jan. 10, 1984 discloses a Pallet Of Composite Construction having top and bottom sheets and runners of corrugated paperboard, but also including &#34;stringers&#34; (i.e., deck boards immediately beneath the top sheet) of wood. The different materials result in additional labor and/or equipment costs for production, as well as resulting in a relatively heavy pallet. While the runners (called &#34;stringers&#34; in the present disclosure) underlying the wooden deck boards of the Eatherton patent are notched, the overlying wood members are not, whereas both the underlying and overlying intersecting corrugated laminated members of the present invention are notched for mutual interlocking. 
     U.S. Pat. No. 4,647,063 issued to Robert Piringer et al. on Mar. 3, 1987 discloses a Lightweight Core For Laminate Constructions. Plural corrugated sheets laminated either flat, folded or rolled are disclosed. The corrugated sheet used in the laminations includes a backing on only one side, which is desirable for flexibility, according to the disclosure. The present invention requires greater strength and rigidity, and hence utilizes corrugated material having opposite backing sheets to each side of the corrugated core. 
     U.S. Pat. No. 4,714,026 issued to Akio Yamaguchi et al. on Dec. 22, 1987 discloses a Pallet For Material Handling having upper and/or lower sheets (described as deck boards) formed of corrugated material, with folded rectangular tubular runners or stringers therebeneath. Another embodiment utilizes a plurality of rectangular pads set in specially cut upper and lower sheets. The pads and stringer each include plastic inserts for greater strength. The numerous folds and different materials result in a pallet construction requiring relatively costly equipment and/or labor, unlike the single type of material used in the construction of a pallet of the present invention. No interlocking of any of the structural components is disclosed. 
     U.S. Pat. No. 4,863,024 issued to Clarence R. Booth on Sep. 5, 1989 discloses a Collapsible Pallet And Related Products. Again, special dies and folds must be used for the formation of the pallet, and the pallet also includes a plurality of wood deck boards, resulting in more complex construction than that required for the present invention. While the stringers are notched in the Booth construction, the intersecting wood deck boards are not; the result is more akin to the Eatherton pallet discussed above than to the present invention, where both of the intersecting components are notched. 
     U.S. Pat. No. 4,979,446 issued to Ken N. Winebarger on Dec. 25, 1993 discloses a Corrugated Pallet formed of a plurality of folded and die cut corrugated sheets. The cutouts or punchouts of the folded sheets form slots providing for the interlocking of the components to form runners and stringers to support a single corrugated top sheet. Again, the required dies and folding machinery result in a complex and costly construction, compared to the present invention. At least one of the sets of base members or deck members (analogous respectively to the stringers and deck boards of the present invention) is formed in an &#34;L&#34; or other non-rectangular cross sectional shape, further increasing the complexity of the Winebarger pallet and the interlocking of the structure. 
     U.S. Pat. No. 5,042,397 issued to Leslie C. Fiedler on Aug. 27, 1991 discloses Pallet Construction using corrugated sheets filled with a plastic material for greater strength. The pallet is otherwise conventional, with the multiple filled corrugated laminates having similar properties to wood, both in manufacture and in use. The construction results in additional costs for the resins or plastics used in the manufacture of the pallet. In addition, glass fiber reinforcement is also disclosed for additional strength. No interlocking structural members are disclosed. 
     U.S. Pat. No. 5,057,176 issued to William Bainbridge on Oct. 15, 1991 discloses a Method Of Forming Corrugated Paperboard Automotive Liner. The method bonds additional vapor barrier and sound dampening sheets to the corrugated layup, which has only a single ply between two corrugations. The present pallet provides for additional laminations using only corrugated sheet. 
     U.S. Pat. No. 5,076,176 issued to Hank A. Clasen on Dec. 31, 1991 discloses a Corrugated Cardboard Pallet formed of plural layers of corrugated cardboard. The construction is relatively complex, comprising base slats, spacer blocks, intermediate slats, and top slats, in addition to top and bottom sheets. The present invention provides stringers each formed as a single unit, to take the place of several of the Clasen pallet components and thereby simplify manufacture and provide a stronger pallet with fewer joints. Moreover, while Clasen states that his provided corrugation orientation is optimal, this will only be true for a relatively narrow range of desired pallet applications. (The intermediate slat 24 of FIG. 3 of Clasen is particularly confusing, as it shows the ends of the corrugations or flutes of the laminations in two different planes.) The present invention provides alternative orientations of the corrugated sheets used in the pallet laminations, for greater versatility. Also, it is noted that Clasen specifically provides only a single corrugated sheet for the top and (optional) bottom platform, relying upon the multitude of slats for lateral strength and support of a load. The present invention provides for multiple laminations of top and bottom sheets in one embodiment, for greater strength and protection against penetration. In addition to the above, the specific orientation of the present pallet corrugated sheets relative to top and bottom during the lamination, provides advantages in reducing or eliminating component warping, not foreseen by Clasen. None of the Clasen components are notched for interlocking construction, as in the present invention. 
     U.S. Pat. No. 5,156,094 issued to Bengt Johansson et al. on Oct. 20, 1992 discloses a Load-Carrying Pallet Of Corrugated Cardboard comprising one or more corrugated laminations forming an upper sheet, with plural pads or feet formed of multiple corrugated laminations secured thereto. As no intermediate structure is disclosed, each of the pads must be relatively low and wide, in order to reduce shear stresses. The present pallet is of a more conventional configuration, providing for more standardized utility, by means of its structure. The Johansson et al. pallet is relatively light and requires a wire or plastic matrix reinforcement of the pads, and is unsuitable for larger and/or heavier objects due to the relatively thin upper sheet. Due to the relatively thin structural components, no notching is provided by Johansson et al. for interlocking. 
     U.S. Pat. No. 5,226,544 issued to Frank Gallucci et al. on Jul. 13, 1993 discloses a Reusable Pallet Wrapper. While the device relates to shipping pallets and is reusable, as are the prior art and present pallets at least to some extent, no further relationship is seen to the present invention. 
     British Patent No. 2,173,768 issued to Akio Yamaguchi et al. and published on Oct. 22, 1986 discloses a Pallet For Material Handling. The disclosure is essentially identical to that of U.S. Pat. No. 4,714,026 to the same inventors, discussed above. 
     Finally, Swiss Patent No. 558,741 to Philip J. Vecere and published on Feb. 17, 1975 discloses a Disposable Pallet Made From Cardboard Layers. The pallet has the same configuration as simpler wood pallets, but uses multiple corrugated laminations for the runners. The laminations are parallel to the upper sheet. No notching or interlocking of structural components is disclosed. 
     None of the above noted patents, taken either singly or in combination, are seen to disclose the specific arrangement of concepts disclosed by the present invention. 
     SUMMARY OF THE INVENTION 
     By the present invention, an improved construction of pallets from corrugated sheet material is disclosed. 
     Accordingly, one of the objects of the present invention is to provide an improved pallet of corrugated sheet material which is of sturdy yet relatively simple construction and requires no special dies or folding machinery for its manufacture. 
     Another of the objects of the present invention is to provide an improved pallet which utilizes multiple laminations of corrugated sheets for the various structural components, with the corrugations or flutes of the sheets being oriented either parallel or perpendicular to one another and to those of other components, depending upon the structural requirements of the pallet. 
     Yet another of the objects of the present invention is to provide an improved pallet in which the intersecting stringers and deck boards are notched to interlock with one another, thereby providing additional structural strength. 
     Still another of the objects of the present invention is to provide an improved pallet which utilizes asymmetrical corrugated sheets, with the sheets each having different weights of paper disposed to each side of the central corrugated flutes, and further to provide a lamination of such sheets which substantially reduces or eliminates any warping or curvature of such sheets due to their asymmetrical nature. 
     A further object of the present invention is to provide an improved pallet which provides an essentially standard configuration, thus providing substantial strength and durability in combination with the alternative materials used. 
     An additional object of the present invention is to provide an improved pallet which may be constructed of various corrugated materials, such as corrugated paperboard or cardboard, as well as corrugated plastic sheet material. 
     Another object of the present invention is to provide an improved pallet which in at least one embodiment, provides for pickup by a fork lift or the like from any of the four sides of the Wallet. 
     Yet another object of the present invention is to provide an improved pallet which requires no mechanical fasteners for construction or assembly, but uses glues, adhesives and the like exclusively for construction and assembly. 
     A final object of the present invention is to provide an improved pallet for the purposes described which is inexpensive, dependable and fully effective in accomplishing its intended purpose. 
     With these and other objects in view which will more readily appear as the nature of the invention is better understood, the invention consists in the novel combination and arrangement of parts hereinafter more fully described, illustrated and claimed with reference being made to the attached drawings. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is an exploded perspective view of a pallet of the present invention, showing its general configuration and features, and the notches providing for the interlocking of the deck boards and stringers. 
     FIG. 2 is a perspective view of the assembled pallet of FIG. 1, showing the interlocking deck board and stringer construction. 
     FIG. 3A is a side view in section of two mirrored asymmetrical corrugated sheets each having opposite walls of different weights or thicknesses, showing the warping or curvature inherent in such asymmetrical sheets. 
     FIG. 3B is a side view in section of the corrugated sheets of FIG. 3A adhesively secured together to form a reverse lamination and substantially cancel the curvature or warping of the individual asymmetrical corrugated sheets. 
     FIG. 4A is an end view of a deck board, showing a plurality of reverse laminations in a vertical array and a double ply corrugated top sheet. 
     FIG. 4B is an end view of another embodiment of a deck board, showing a plurality of reverse laminations with the corrugations or flutes in a horizontal array and a triple ply corrugated top sheet. 
     FIG. 5A is an end view of a stringer, comprising a plurality of vertical reverse laminations in the manner of the deck board of FIG. 4A, and a reverse laminated bottom sheet. 
     FIG. 5B is an end view of another embodiment of a stringer, comprising a plurality of reverse laminations with the corrugations or flutes in a horizontal array, as in the deck board of FIG. 4B. 
    
    
     Similar reference characters denote corresponding features consistently throughout the figures of the attached drawings. 
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     Referring now particularly to FIGS. 1 and 2 of the drawings, the present invention will be seen to relate to a pallet construction using laminated plural sheets of corrugated material. Pallet 10 is of a generally conventional configuration, having a top sheet 12, plural deck boards 14, plural stringers 16 disposed at right angles to the deck boards 14, and a bottom sheet 18. The top sheet has opposite first and third edges disposed parallel to the deck boards and opposite second and fourth edges disposed parallel to the stringers. The bottom sheet has opposite first and third edges disposed parallel to the stringers and opposite second and fourth edges disposed parallel to the deck boards. However, each of the above components are formed of varying numbers of laminations of corrugated sheet material, adhesively secured together. In the pallet 10 of FIGS. 1 and 2, it will be seen that the top sheet 12 comprises two corrugated sheets laminated together with their corrugations or flutes at right angles to one another, in order to provide maximum strength. The deck boards 14 will also be seen to include multiple plies or layers of corrugated sheets, and the stringers 16 are also formed of multiple plies. Finally, a bottom sheet 18 of one or more plies may be applied to the bottoms of the stringers 16 if desired. The bottom sheets of FIGS. 1 and 2 comprise three individual sheets disposed across the pads or feet 19 of the stringers 16, with their corrugations running perpendicular to the stringers 16 for maximum strength. Alternatively, the bottom sheet 18 may be formed as a single, unitary sheet with the stringers 16 having an unbroken bottom surface, if desired or required, as shown by the broken lines joining the individual bottom sheets 18 of FIG. 1. 
     The number of sheets used in the formation of the deck boards and stringers may be greater than shown in FIGS. 1 and 2, so as to provide greater strength. The precise number of corrugated sheets, and their orientation, may be adjusted according to the required strength and anticipated loads for a given pallet. FIGS. 4A, 4B, 5A, and 5B show greater numbers of corrugated sheets, which may be more typical for pallets requiring relatively high strength. Also, the relative thicknesses of the corrugated cores of the top and bottom sheets 12 and 18 have been exaggerated in FIGS. 1 and 2, for clarity. Normally, the sheet thickness used for these components will be similar that of the sheets used in the construction of the deck boards 14 and stringers 16. 
     One problem with the assembly of multiple plies of sheet material is that often the sheets each have different properties, and when assembled the different properties result in the warping or curvature of the completed lamination. This problem may occur due to the properties of otherwise flat and uniform sheets of material when they are laminated, but often is due to the sheets themselves being warped or curved prior to laminating into multiple sheets. Nevertheless, it may be desirable to utilize sheets having different properties, e.g., two or more corrugated sheets of different thicknesses, and/or unsymmetrical sheets having different wall thicknesses or weights on each side of the corrugated core, as shown in FIG. 3A. For example, it may be desirable to provide a relatively thick wall sheet along the outer surface to resist puncture to a greater degree, while providing lighter core sheets having greater spacing as a filler; other requirements might result in entirely different assemblies or configurations. The present invention includes means providing for the trueness or flatness of completed laminations using unsymmetrical sheets, as shown in FIGS. 3A and 3B. 
     FIG. 3A discloses a first corrugated sheet 20, comprising a first outer wall sheet 22 having a relatively heavy weight, an opposite second outer wall sheet 24 having a lighter weight than the first sheet 22, with the two wall sheets 22 and 24 separated by a corrugated core 26. The second corrugated sheet 20a is formed similarly, with a heavy first outer wall sheet 22a, a lighter second outer wall sheet 24a, and a corrugated core 26a. Due to the heavier first outer wall sheets 22 and 22a respectively of the two corrugated sheets 20 and 20a, it will be seen that the two corrugated sheets 20 and 20a have become warped. 
     When such warped sheets are laminated together with their curvatures and like sides facing the same direction, the warp or curvature will be &#34;built in&#34; to the resulting laminated plies. The resulting warped laminations are extremely difficult to work with, as it is nearly impossible to construct a pallet or other structure of laminated corrugated sheets, which is straight and true. Attempting to flatten or straighten such laminations after their formation can weaken the structure, thus removing much of the advantage of such multiple plies, and/or it can be difficult to form proper glue or adhesive joints between such warped components (e.g., between a base board having horizontally disposed laminate layers and an overlying top sheet), due to the difficulty in achieving complete contact between the two curved surfaces. 
     The present invention addresses this problem by assembling two such sheets with their like outer walls (e.g., 22 and 22a) facing one another, so the two corrugated sheets 20 and 20a are disposed in a &#34;mirror image&#34; to one another. Adhesive, glue, etc. is applied between the two sheets and pressure is applied (press, stacking, weights, etc.) during the adhesive curing process. The resulting reverse lamination 28, shown in FIG. 3B, causes any warping or curvature of the two individual corrugated sheets to be canceled, and a substantially flat reverse lamination results. The above process may be applied to any number of corrugated sheets to produce multiple laminations for any of the components used in the construction of the present shipping pallets. In addition, it will be seen that individual corrugated sheets 20 and 20a having differing corrugation thicknesses (e.g., a relatively thin sheet 20 and a relatively thick sheet 20a) may be used to form such reverse laminations, if desired, with much the same result. 
     The deck boards 14a and 14b respectively shown in FIGS. 4A and 4B, provide applications of the above reverse lamination technique. In FIG. 4A, a deck board 14a is formed of plural reverse laminations 28a of individual corrugated sheets of differing thicknesses, as shown substantially in FIG. 3B. However, the corrugated sheets and resulting laminations will be seen to be vertically oriented, with the individual corrugations or flutes 30 in a vertical array as in the deck board configuration of pallet 10 of FIGS. 1 and 2. Such an arrangement provides a deck board 14a (or other component using the same arrangement) of substantial strength in the vertical direction, due to the crush resistance of the individual corrugations 30 along their lengths. 
     Alternatively, it may be desirable to provide greater bending resistance by arranging the laminations 28b so that the individual corrugations are disposed horizontally, as shown in the deck board 14b of FIG. 4B. In the deck board 14b, the reversed lamination sheets 28b are still vertically disposed, but the ends of the individual corrugation flutes 30 may be seen in this end view; thus, the corrugations 30 are horizontal and run the length of the deck board 14b. While offering less vertical crush resistance, the vertically disposed walls of the corrugated sheets provide relatively good resistance to bending loads when such is desired. 
     In each of the above deck boards 14a and 14b, a top sheet 12a and 12b is respectively provided. These top sheets will be seen to have differing configurations, in the manner of the various deck boards discussed above. The top sheet 12b of FIG. 14b will be seen to be a single reverse lamination of a single relatively thick and single relatively thin corrugated sheet. However, it may be desirable to provide a top sheet 12b having greater strength, as in the triple ply top sheet 12b of FIG. 4B. Even greater strength may be provided by a four ply top sheet formed of two reverse laminations (not shown), if desired. 
     FIGS. 5A and 5B provide end views respectively of two configurations of stringers 16a and 16b. In FIG. 5A, the stringer 16a is formed of plural reverse laminations 28a with both the vertical reverse laminations 28a and the corrugations or flutes 30 therein arrayed vertically, as in the vertical reverse laminations 28a of the deck board 14a of FIG. 4A and the pallet 10 of FIGS. 1 and 2. Similar advantages are provided by the similar arrangement. FIG. 5B discloses a stringer 16b comprising plural reverse laminations 28b with the laminations 28a oriented vertically, but with the corrugations or flutes 30 being disposed horizontally, as in the stringer 14b of FIG. 4B. The shear strength of such a configuration is essentially equal to that of a vertical reverse lamination having the corrugations 30 in a vertical array; however, the bending strength may be somewhat less. The specific balance of shear and bending strength required may be obtained by providing an appropriate orientation of both the reverse laminations and the flutes or corrugations, the number of laminations used to build up the deck boards and stringers, the weight and thickness of the individual corrugated sheets used, the depth of the deck boards and stringers, and/or the number and spacing of the deck boards and stringers used for a given application. 
     As in the case of the various top sheet configurations of FIGS. 4A and 4B, different configurations of bottom sheets may be applied to the stringers 16a and 16b of FIGS. 5A and 5B. In FIGS. 5A and 5B, a single reverse lamination comprising two corrugated sheets is disclosed, similar to the top sheet 12a of FIG. 4A. While these various configurations are each shown with their corrugations or flutes running parallel to one another, it will be seen that the individual corrugated sheets may be cross laminated if desired, as in the top sheet 12 of FIGS. 1 and 2. However, the corrugations or flutes 30 of the various deck boards 14 and stringers 16 are preferably parallel to one another, for optimum structural strength and resistance to bending and shear loads. The cross laminations of the top sheet 12 (or a bottom sheet) may be desirable to reduce warping to a greater degree; ultimate strength is not so critical with the top and bottom sheets, as they are supported by the deck boards and stringers. 
     Referring back to FIGS. 1 and 2, further strength for the present pallets 10 may be obtained by providing cooperating deck board notches 32 in the lower surfaces 34 of the deck boards 14, along with stringer notches 36 in the upper surfaces 38 of the stringers 16. This notched construction contributes further strength to the present pallet 10, by providing a much more rigid structure due to the physical interlocking of the primary structural components of the deck boards 14 and stringers 16, rather than relying only upon adhesives for securing those components together. Another advantage is that an essentially continuous contact is made between the deck boards 14, stringers 16, and the top sheet 12. Conventionally, deck boards are laid up over the stringers, with the top sheet being in contact only with the deck boards. By providing cooperating notches 32 and 36 of sufficient depth so that the upper surfaces of both the deck boards 14 and the stringers 16 are mutually coplanar, with the rectangular cross section of the deck boards 14 recessed into the rectangular cross section stringers 16 by means of the notches 32 and 36 in both, any gaps or voids between the top sheet 12 and the underlying stringers 16 are eliminated. In addition, the two sides of each of the notches 32 and 36 provide additional gluing area, over and above the adjacent upper and lower surfaces respectively of the stringers and deck boards which would ordinarily be in adhesive contact with one another. The capturing of the deck boards 14 within the stringer notches 36 provides yet another advantage, in that the deck boards 14 are precluded from twisting angularly relative to the stringers 16, by means of the sides of the stringer notches 36 capturing the deck boards 14 therebetween. Finally, the deck boards 14 and stringers 16 may be made deeper vertically, thereby contributing further to the bending and shear strength of the pallet 10. 
     The present interlocking construction of pallet 10 is intended to provide a pallet 10 constructed of multiple plies or sheets of corrugated material, which is capable of handling loads literally hundreds of times its own weight. Accordingly, particularly the main structural components of the present pallet 10 (i.e., deck boards 14 and stringers 16) are preferably constructed of a considerable number of sheets of corrugated material. While this is generally indicated in FIGS. 1 and 2, FIGS. 4A through 5B provide a clearer disclosure of the number of sheets used. In FIGS. 4A and 4B, representing typical deck board construction, each deck board 14a and 14b will be seen to have a total of twelve plies or sheets (i.e., six reverse laminations) disposed vertically; the only difference is the orientation of the corrugations or flutes 30, as discussed above. Typically, ten or more plies or corrugated sheets are used in the construction of each deck board, depending upon the required strength of the completed pallet, the number and spacing of the deck boards, and other factors. Similarly, the stringers 16a and 16b respectively of FIGS. 5A and 5B are formed of a considerable number of vertically oriented reverse laminated sheets, e.g., twenty sheets of ten reverse laminations. Preferably, anywhere from ten to twenty sheets are used in the construction of the stringers for the present pallet, again depending upon the required strength, stringer spacing, and other factors. The present pallet construction results in a pallet 10 having a finished weight of some twelve pounds, depending upon the specific number of plies used for the various components, and yet being able to support a sustained load of some four thousand pounds or more. 
     The above disclosure will be seen to provide shipping pallets 10, or of other configurations, formed of various configurations, arrangements and orientations of corrugated sheet material. The present shipping pallets are particularly adaptable to construction from corrugated fiberboard or paperboard, either of virgin fiber or recycled material. However, other materials may also be used, e.g., virgin or recycled corrugated plastic sheet. The present shipping pallets provide for ready disposal when they have deteriorated so they are no longer usable, as facilities exist virtually throughout the country at present for the recycling of such materials, unlike wood pallets. 
     The specific reverse lamination technique disclosed provides for the substantial elimination of warped sheets of materials and the accompanying problems incurred by such, including poor glue joints resulting from poor contact between adjacent sheets being glued, misalignment of components, etc. The reverse laminations may be assembled in virtually any orientation of corrugation plies, thus enabling the manufacturer to &#34;tune&#34; the strength of the present shipping pallet as required for a specific purpose; such is not possible with wood pallets, other than by adjusting the thickness of the wood. 
     While the construction of the present pallets of multiple laminations of corrugated material provides numerous advantages, as discussed above, the general configuration of such pallets is preferably along the lines of earlier pallets of wood, known in the shipping industry. As such, no special handling or equipment modification is required. Standard fork lifts and other equipment can handle the present pallets with equal or greater facility as with earlier pallets, due to the relatively light weight of the present shipping pallets. The stringers may include lower cutouts or notches 40, as shown in FIGS. 1 and 2, providing for the insertion of the forks of a forklift therein, thus providing for lifting access from any of the four sides of the pallet. The lower deck board(s) 18 may comprise a single, unitary, continuous sheet spanning the entire bottom of the pallet across the stringers, or alternatively may comprise a series of separate boards spanning the stringer pads or feet, as shown in FIGS. 1 and 2. Additional upper notches 36 in the stringers 16 and cooperating lower notches 32 in the deck boards 14 may be provided for the interlocking placement of the deck boards 14 within the stringers 16 to provide a mutually coplanar stringer 14 and deck board 16 upper surface, as well as other advantages discussed above from such notched construction. The resulting strength to weight ratio of a pallet 10 constructed according to the present disclosure is phenomenal. 
     The present shipping pallets thus require little in the way of costly tools and equipment to manufacture, other than means for applying pressure during the adhesive lamination of the individual corrugated sheets and saws or other cutting tools to shape the resulting laminations as required to form the various pallet components. No complex folding machines or other devices for applying mechanical fasteners or other devices are required. The result is an exceptionally cost effective shipping pallet, providing numerous advantages in shipping costs due to its light weight, low cost of manufacture, and ease of recycling. 
     It is to be understood that the present invention is not limited to the sole embodiments described above, but encompasses any and all embodiments within the scope of the following claims.