Floor assembly for transportable refrigerated container

Abstract

A floor assembly includes a plurality of transverse stringers spaced from one another in the longitudinal direction of the floor assembly. The assembly also includes a plurality of transverse bottom flanges, each transverse bottom flange being coupled to a lower portion of a respective transverse stringer and to a neighboring transverse bottom flange along respective transversely extending side edges thereof. A top flange comprising a supporting sheet is coupled to an upper portion of each transverse stringer. A plurality of longitudinal panels are supported by the supporting sheet and coupled to one another along respective longitudinally extending edges thereof to form a floor surface, each longitudinal panel in the plurality of longitudinal panels having at least one longitudinally extending rib depending substantially perpendicularly from a bottom surface thereof. The at least one rib is coupled to a top surface of the supporting sheet.

Claims

1. A floor assembly for a transportable refrigerated container, the floor assembly being defined along a transverse direction and a longitudinal direction perpendicular to the transverse direction and comprising: a plurality of transverse stringers made of a thermally insulative material that extend in the transverse direction of the floor assembly and are spaced from one another in the longitudinal direction of the floor assembly; a plurality of transverse bottom flanges that extend in the transverse direction, each transverse bottom flange in the plurality of transverse bottom flanges being adhered to a lower portion of a respective transverse stringer in the plurality of transverse stringers and being welded to a neighboring transverse bottom flange along respective side edges thereof, wherein the side edges extend in the transverse direction; a top flange comprising a supporting sheet made of aluminum, the top flange being adhered to an upper portion of each transverse stringer in the plurality of transverse stringers; and a plurality of longitudinal panels made of aluminum that extend in the longitudinal direction and are supported by the supporting sheet and welded to one another along respective longitudinally extending edges thereof to form a floor surface, each longitudinal panel in the plurality of longitudinal panels having a plurality of ribs that extend in the longitudinal direction and depend substantially perpendicularly from a bottom surface thereof, wherein a lower end of each rib in the plurality of ribs is welded to a top surface of the supporting sheet; wherein the plurality of transverse stringers, adhered between the plurality of transverse bottom flanges and the top flange, act as structural members and together with the plurality of transverse bottom flanges and the top flange support a given load, and wherein no additional transverse beams are provided beneath the plurality of transverse bottom flanges.

2. The floor assembly of claim 1, further comprising a plurality of bottom caps, each bottom cap in the plurality of bottom caps being formed where at least one side edge of each transverse bottom flange abuts a neighboring side edge of a neighboring transverse bottom flange, wherein each bottom cap comprises a lower channel for seating the lower portion of a respective transverse stringer therein.

3. The floor assembly of claim 2, wherein each bottom cap and each respective lower channel are formed by a pair of neighboring transverse bottom flanges.

4. The floor assembly of claim 3, wherein a side edge of a first transverse bottom flange in the pair of neighboring transverse bottom flanges is welded to a neighboring side edge of a second transverse bottom flange in the pair of neighboring transverse bottom flanges to form each respective bottom cap, and wherein each transverse bottom flange, including half of a first bottom cap adjacent a first side edge, a transverse extrusion extending in the transverse direction and projecting upwardly from an upper surface of the transverse bottom flange, and half of a second bottom cap adjacent a second side edge, comprises a single extrusion.

5. The floor assembly of claim 1, wherein the top flange comprises a plurality of top caps, each top cap in the plurality of top caps comprising an upper channel for locating the upper portion of a respective transverse stringer therein.

6. The floor assembly of claim 5, wherein each top cap is formed integrally with the supporting sheet.

7. The floor assembly of claim 1, wherein opposite ends of each transverse bottom flange extend in the transverse direction beyond opposite ends of each respective transverse stringer, and further comprising: first and second side rails that extend in the longitudinal direction and are coupled to the respective opposite ends of and extend perpendicularly with respect to each transverse bottom flange; and first and second lips that extend in the longitudinal direction on the first and second side rails, respectively, and that extend under the respective opposite ends of each transverse bottom flange.

8. The floor assembly of claim 7, wherein the first and second lips are welded to a lower surface of the respective opposite ends of each transverse bottom flange.

9. A floor assembly for a transportable refrigerated container, the floor assembly being defined along a transverse direction and a longitudinal direction perpendicular to the transverse direction and comprising: a plurality of transverse stringers that extend in the transverse direction of the floor assembly and are spaced from one another in the longitudinal direction of the floor assembly; a plurality of transverse bottom flanges that extend in the transverse direction, each transverse bottom flange in the plurality of transverse bottom flanges being coupled to a lower portion of a respective transverse stringer in the plurality of transverse stringers and being coupled to a neighboring transverse bottom flange along respective side edges thereof, wherein the side edges extend in the transverse direction, wherein opposite ends of each transverse bottom flange extend in the transverse direction beyond opposite ends of each respective transverse stringer; and wherein at least one side edge of each transverse bottom flange is welded to a respective neighboring side edge of a respective neighboring transverse bottom flange beneath a respective transverse stringer in the plurality of transverse stringers; a top flange comprising a supporting sheet made of aluminum, the top flange being coupled to an upper portion of each transverse stringer in the plurality of transverse stringers; and a plurality of longitudinal panels made of aluminum that extend in the longitudinal direction and are supported by the supporting sheet and coupled to one another along respective longitudinally extending edges thereof to form a floor surface, each longitudinal panel in the plurality of longitudinal panels having at least one rib that extends in the longitudinal direction and depends substantially perpendicularly from a bottom surface thereof, each at least one rib being welded to a top surface of the supporting sheet; opposite side rails that extend in the longitudinal direction and are coupled to the respective opposite ends of and extend perpendicularly with respect to each transverse bottom flange to respective upper edges located above the supporting sheet that are configured to be connected to respective opposite side wall panels of the container; a transverse extrusion extending in the transverse direction and projecting upwardly from an upper surface of each transverse bottom flange, each transverse extrusion having opposite ends that are welded to a respective one of the opposite side rails; and a plurality of bottom caps, each bottom cap in the plurality of bottom caps being formed where the at least one side edge of each transverse bottom flange is welded to the respective neighboring side edge of the respective neighboring transverse bottom flange, wherein each bottom cap comprises a lower channel for seating the lower portion of a respective transverse stringer therein; wherein each transverse bottom flange, including half of a first bottom cap adjacent a first side edge, a respective transverse extrusion, and half of a second bottom cap adjacent a second side edge, comprises a single extrusion.

10. The floor assembly of claim 9, wherein the plurality of longitudinal panels are friction stir welded to one another along the longitudinally extending edges thereof to form the floor surface.

11. The floor assembly of claim 10, further comprising a plurality of ribs that extend in the longitudinal direction and depend substantially perpendicularly from the bottom surface of each longitudinal panel, wherein a lower end of each rib in the plurality of ribs on each longitudinal panel comprises a projection that is parallel to the top surface of the supporting sheet and is welded thereto.

12. The floor assembly of claim 9, further comprising a longitudinal lip extending in the longitudinal direction on each of the opposite side rails, wherein each longitudinal lip extends under each transverse bottom flange and is welded to a lower surface of each transverse bottom flange at one of the respective opposite ends of each transverse bottom flange.

13. The floor assembly of claim 9, wherein the top flange comprises a plurality of top caps, each top cap in the plurality of top caps comprising an upper channel for locating the upper portion of a respective transverse stringer therein.

14. The floor assembly of claim 13, wherein each top cap is formed integrally with the supporting sheet.

15. The floor assembly of claim 9, further comprising a pair of beams extending in the longitudinal direction that are directly coupled to bottom surfaces of one or more of the plurality of transverse bottom flanges, wherein the pair of beams is configured to couple the floor assembly to a vehicle such that the floor assembly is supported on the vehicle solely by the pair of beams.

16. The floor assembly of claim 9, wherein each lower channel comprises upwardly projecting surfaces that oppositely slope up on an outside of the lower channel toward a top of the lower channel and then step down into the lower channel on an inside of the lower channel.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 illustrates a perspective end view of a floor assembly according to the present disclosure.

(2) FIG. 2 illustrates a perspective underside view of the floor assembly of FIG. 1.

(3) FIG. 3 illustrates a close up view of one side of the floor assembly.

(4) FIG. 4 illustrates a more zoomed out view of the side of FIG. 3.

(5) FIG. 5 illustrates a detailed view of a cross section of the floor assembly along the line 5-5 in FIG. 4.

(6) FIG. 6 illustrates a detailed view of the cross section shown in FIG. 5.

(7) FIG. 7 illustrates a cross sectional view along the ling 7-7 in FIG. 4.

(8) FIG. 8 illustrates a detailed view of the area circled in FIG. 4.

(9) FIG. 9 shows a transverse bottom flange piece separated from the floor assembly.

(10) FIG. 10 shows a longitudinal panel piece separated from the floor assembly.

(11) FIG. 11 shows a portion of the top flange separated from the floor assembly.

DETAILED DESCRIPTION

(12) The present disclosure relates to a refrigerated container that has minimized weight, a lower center of gravity, and increased thermally efficiency in comparison to prior art containers. The present design eliminates the need for steel or aluminum cross members that are usually mounted underneath current refrigerated floors to provide load support. In the present disclosure, the addition of unique top and bottom flanges 19, 14 to a thermal spacer material (transverse stringer 12) transforms the thermal spacer material into a structural member that replaces the steel I-beam cross members used in current systems for load support.

(13) Further, the unique design of the herein-described transverse bottom flanges 14 allows connection thereof to an outer longitudinal side rail 22 (intended for connection to a wall panel of the container) by welding. This welded connection, and the fact that the present floor assembly 10 is held together by welding wherever possible, means that the present design also has improved thermal characteristics, as it eliminates thermal shorts from mechanical fasteners that are currently used in prior art systems. These and other advantages will be described with respect to the embodiment discussed below.

(14) A shown in FIG. 1, the present disclosure is of a floor assembly 10 for a transportable refrigerated container. The container in which the floor assembly 10 is included can be, for example, an intermodal container, a truck body, a trailer, a railroad car box, or any other type of cargo container. The floor assembly 10 is defined along a transverse direction x and a longitudinal direction y perpendicular to the transverse direction x. The floor assembly 10 comprises a plurality of transverse stringers 12 (extending in transverse direction x) spaced from one another in the longitudinal direction y of the floor assembly 10. (See also FIG. 2.) Each transverse stringer 12 has approximately the same length and extends from a location proximate a first side 13 to a location proximate a second side 15 of the floor assembly 10. However, the transverse stringers 12 do not extend all the way to the end of each side 13, 15 of the floor assembly 10, for reasons that will be described further herein below. The sides 13, 15 of the floor assembly 10 are where laterally-spaced, upwardly-extending side walls of the container would be placed. Each transverse stringer 12 is spaced an approximately equal distance from its neighboring transverse stringer 12, such that uniform loads placed on top of the transverse stringers 12 are distributed generally equally across each of the transverse stringers 12.

(15) As will also be described further herein below, the transverse stringers 12 act as a thermal spacer material, and prevent heat transfer from materials below the transverse stringers 12 to materials resting on top of the transverse stringers 12, which latter materials are in contact with refrigerated air that keeps the container's cargo cool. In one example, the transverse stringers 12 are made of wood, such as for example pressure treated oak hardwood. In another example, the transverse stringers 12 are thermoplastic beam extrusions. Any material that can be cut or formed into a beam and that does not conduct heat (or does not conduct heat well) can be used to make the transverse stringers 12. Generally, in order to keep manufacturing of the transverse stringers and the parts with which they connect relatively simple, each transverse stringer 12 has the same size and shape. For example, referring to FIG. 5, each transverse stringer 12 can have a rectangular cross-sectional shape with a height of the transverse stringer 12 being approximately three times its width.

(16) Referring now to FIGS. 2 and 5, a plurality of transverse bottom flanges 14 are also provided in the floor assembly 10. Each transverse bottom flange 14 in the plurality of transverse bottom flanges is coupled to a lower portion 11 of a respective transverse stringer 12 in the plurality of transverse stringers. Each transverse bottom flange 14 is also coupled to a neighboring transverse bottom flange 14 along respective transversely extending side edges thereof. See transverse lines in FIGS. 2 and 41a, 41b in FIG. 9. For example, referring to FIG. 5, the leftmost transverse bottom flange 14a (only a portion of which is shown) is connected along its right transversely extending side edge to a left transversely extending side edge of middle transverse bottom flange 14b at point A. Similarly, the right transversely extending side edge of middle transverse bottom flange 14b is connected to the left transversely extending side edge of rightmost transverse bottom flange 14c at point B. In one example, each flange side edge is welded to its neighboring flange side edge, such as shown at locations A and B. As shown herein, each flange side edge abuts the neighboring flange side edge to which it is welded beneath a respective transverse stringer 12 in the plurality of transverse stringers. This provides a supported location for the weld (see points A, B) to be made, as the transverse stringers 12 are also adhered to the transverse bottom flanges 14 at this location, as will be described further herein below. A transverse bottom flange piece 14 and its transversely extending side edges 41a, 41b are shown separately in FIG. 9.

(17) FIGS. 1-4 show I-beams 24 that are used to support the floor assembly 10 where it is connected to a truck or other vehicle. The I-beams 24 extend in the longitudinal direction y and are coupled to a bottom surface of each of the transverse bottom flanges 14, such as by welding. The I-beams 24 thus extend across a plurality of the transverse bottom flanges 14.

(18) Referring to FIGS. 5-8, a top flange 19 is coupled to an upper portion 21 of each transverse stringer 12 in the plurality of transverse stringers. The top flange 19 comprises a supporting sheet 16. The supporting sheet 16 can be one single sheet of material (see FIG. 11), or if necessary can be several large sheets of material. In one example, the supporting sheet 16 is a single piece of aluminum sheet (plate), which is lightweight yet provides the necessary strength to support other components of the floor assembly 10. Such components include a plurality of longitudinal panels 18 (shown separated by dashed lines in FIG. 1) that are supported by the supporting sheet 16 and coupled to one another along respective longitudinally extending edges thereof to form a floor surface 17. In one example, the plurality of longitudinal panels 18 are friction stir welded to one another along the edges thereof to form the floor surface 17. Each longitudinal panel 18 in the plurality of longitudinal panels has at least one longitudinally extending rib 20 (and here, a plurality of longitudinally extending ribs 20) depending substantially perpendicularly from a bottom surface 36 thereof. (See also FIG. 10.) The ribs 20 are coupled to a top surface of the supporting sheet 16.

(19) FIG. 7 shows a cross sectional view through the lines 7-7 of FIG. 4. Shown herein are a side view of a transverse stringer 12, a transverse bottom flange 14, and two neighboring longitudinal panels 18a and 18b. Individual longitudinal panels 18a, 18b can be joined to one another at the location C where indicated. As mentioned herein above, the joints at location C can be welds, which extend the entire longitudinal length of the floor assembly 10. The welds are preferably friction stir welds, but could also be MIG welds. Additionally, the plurality of longitudinally extending ribs 20 that depend substantially perpendicularly from the bottom surface 36 of the longitudinal panels 18 are shown. As shown in both FIGS. 7 and 8, a lower end of each rib 20 in the plurality of longitudinally extending ribs comprises a projection 38 that is parallel to the top surface of the supporting sheet 16 and is welded thereto. For example, each of these ribs 20 ends in a T-shaped projection 38, which is welded to the top surface of the supporting sheet 16. These welds are shown at locations D and could be MIG welds or spot friction stir welds.

(20) As can be seen best in FIGS. 1, 3-4, and 8, laterally opposite ends of each transverse bottom flange 14 extend in the transverse direction x beyond opposite ends of each respective transverse stringer 12 and beyond the sides of the outermost longitudinal panels 18. This creates a ledge 26 at either side 13, 15 of the floor assembly 10. In one example, the floor assembly 10 further comprises first and second longitudinal side rails 22 coupled to the opposite ends of each transverse bottom flange 14. For example, a longitudinal lip 23 may be provided on each of the longitudinal side rails 22 that extends under the ends of the transverse bottom flanges 14. The lip 23 may be welded, such as by MIG welding, to a lower surface of the transverse bottom flanges 14 along the entire bottom width of the transverse bottom flanges 14 as shown at spots E in FIGS. 6 and 8. As shown in FIGS. 5, 6, and 8, a transverse extrusion 40 may be provided that projects upwardly from an upper surface of each transverse bottom flange 14. In the example shown, the transverse extrusion 40 is a T-shaped extrusion, where the bottom of the T is integral with the remainder of the transverse bottom flange 14. The transverse extrusion 40 has opposite ends on either side 13, 15 of the floor assembly 10 that are welded to a respective one of the opposite longitudinal side rails 22. For example, MIG welds can also be made along the top of T-shaped transverse extrusions 40 such as shown at spots F. The transverse extrusions 40 ensure proper positioning of the longitudinal side rail 22 with respect to the transverse bottom flanges 14, as well as provide extra areas for reinforcing welds.

(21) The longitudinal side rails 22 extend perpendicularly with respect to each transverse bottom flange 14 and perpendicularly to the ledge 26. The ledges 26 are therefore bounded on either lateral side by the opposite ends of the transverse stringers 12 and the opposite longitudinal side rails 22. Each ledge 26 has an open channel 27 above it, defined between the ends of the transverse stringers 12 and the inner surface of the longitudinal side rail 22, into which a side wall of the container can be inserted. The side wall would rest on the ledge 26 and would be coupled to the longitudinal side rail 22 in any manner known to those having ordinary skill in the art.

(22) FIGS. 3, 4, and 8 also show a floor-to-wall connecting panel 28 located at the side of the assembly 10 and connected to one of the longitudinal panels 18. The floor-to-wall connecting panel 28 is shaped differently from the longitudinal panels 18 because it is where the side wall of the refrigerated container would be coupled to the floor assembly 10, as shown at channel 27 in FIG. 8. As mentioned above, a lower portion of the wall panel would fit into the channel 27 formed above the ledge 26 and rest thereupon, and the side wall panel, longitudinal side rail 22, and floor-to-wall connecting panel 28 could be welded together. For example, the floor-to-wall connecting panel 28 could be welded to the side wall panel along an upper edge of an upwardly protruding arm 29 thereof. The side wall panel could also be welded to the longitudinal side rail 22 along its upper edge 31. The longitudinal side rail 22 therefore provides an airtight connection between the floor assembly 10 and a wall assembly (not shown) of the refrigerated container. Although only one longitudinal side rail 22 at side 13 is shown and described herein, it should be understood that a minor image longitudinal side rail is provided at the opposite side 15 of the floor assembly 10.

(23) Turning now to FIG. 5, which shows a cross sectional view along the lines 5-5 of FIG. 4, and to FIG. 6, a more detailed discussion of the cross section of the floor assembly 10 will be described. The transverse stringers 12 are shown in cross section here. The transverse stringers 12 are provided with top caps 30 and bottom caps 32, which caps 30, 32 extend the length of the transverse stringers 12. Thus, the floor assembly 10 includes a plurality of bottom caps 32, each bottom 32 cap in the plurality of bottom caps being formed where each flange side edge abuts its neighboring flange side edge (see points A and B). As shown, the bottom caps 32 provided on each transverse stringer 12 cover only one half of the width of the transverse stringer 12 to which they are adhered. Still referring to FIG. 5, one transverse bottom flange 14 begins at point A and ends at point B, and therefore comprises two separate halves of two separate bottom caps 32. This entire transverse bottom flange 14 from point A to point B comprises one extrusion, thereby providing easy manufacturing of the plurality of transverse bottom flanges 14. The transverse bottom flanges 14 are welded together along neighboring edges at the noted points A and B, for example by friction stir welding or MIG welding. Each bottom cap 32 comprises a lower channel 33 (see FIG. 8) for seating the lower portion 11 of a respective transverse stringer 12 therein. As shown in FIGS. 5 and 6, each bottom cap 32 and respective lower channel 33 are formed partly by a first transverse bottom flange (e.g. 14b) and partly by a neighboring second transverse bottom flange (e.g. 14c). The transverse bottom flanges 14 include oppositely upwardly projecting surfaces that slope up toward the top of the channel 33 and then step down to the channel half formed by that transverse bottom flange 14. The upwardly sloping portions of the bottom cap 32 provide strength to the channel 33, as it holds the transverse stringer 12. The steps, which are oriented perpendicular to the majority of the transverse bottom flange 14, provide a tight fit against the rectangular shape of the transverse stringer 12.

(24) The top flange 19 comprises the plurality of top caps 30. Each top cap 30 in the plurality of top caps comprises an upper channel 35 for locating the upper portion 21 of a respective transverse stringer 12 therein. In the example shown, each top cap 30 is formed integrally with the supporting sheet 16, such as by extruding the aluminum of the sheet. In other examples, the top caps 30 are welded or otherwise adhered to the supporting sheet 16. The top caps 30 are mirror images of the bottom caps 32, except each top cap 30 is preferably a single piece integral with or connected to the supporting sheet 16, rather than two combined halves. Thus, each top cap 30 includes two oppositely downwardly sloping portions and two reverse steps that lead to the upwardly-recessed channel 35, which is sized to fit the transverse stringer 12 therein. See also FIG. 11.

(25) The top and bottom caps 30, 32 are provided as guides for the transverse stringers 12 such that they remain in place between the supporting sheet 16 and the plurality of transverse bottom flanges 14 by being located in the channels 33, 35. The caps 30, 32 may be adhered to the transverse stringers 12 at adhesive joints 34. Each cap 30, 32 and channel 33, 35 is located one above the other so that the transverse stringers 12 can be held upright perpendicular to the supporting sheet 16 and the transverse bottom flanges 14. Thus, the transverse stringers 12 thermally isolate the supporting sheet 16 and the longitudinal panels 18 thereupon from the transverse bottom flanges 14. Refrigerated air can be provided between the ribs 20 of the longitudinal panels 18, thereby cooling the longitudinal panels 18 and the cargo in the container, with such refrigerated air being thermally isolated from the outside temperatures of the transverse bottom flanges 14.

(26) If the longitudinal panels 18 that form the upper floor surface 17 are friction stir welded to one another as shown at dashed lines in FIG. 1 (see also location C in FIG. 7), as opposed to snapping them together and MIG welding them as in the prior art, this will provide increased floor strength at a lighter weight, improved thermal efficiencies, and an increased weight capacity. Further, friction stir welding the aluminum longitudinal panels 18 is not prone to defects associated with MIG welding, which defects contribute to water vapor intrusion into the insulation within the floor assembly 10. Additionally, by welding the flooring across the top flange's supporting sheet 16 as shown at spots D in FIGS. 7 and 8, the longitudinal panels 18 making up the floor are supported better and will not deform as easily as when only fastened on each edge as the current state of the art provides. Further, thermal shorts are eliminated as a result of removing fasteners from the floor and instead using friction stir or MIG welds.

(27) The supporting sheet 16 and attachment guides provided by top caps 30 and bottom caps 32 eliminate the deformation and eventual failure or tipping of the transverse stringers 12, which is also a problem associated with prior art structures. The transverse bottom flanges 14 with bottom caps 32 also provide the ability to weld the assembly to the longitudinal side rail 22, such as at locations E and F, which completely seals the floor assembly 10. Welding eliminates the problem of galvanic corrosion between dissimilar metals and provides an airtight, thermally efficient coupling, in contrast to bolted or riveted connections between the floor supporting members and the outside rail as shown in the prior art. Further, by eliminating the use of steel cross members underneath the floor assembly 10 for mounting purposes by instead requiring that the thermally isolating transverse stringers 12 provide structural support, this present design has a lower center of gravity, reducing the likelihood of tipping.

(28) In the above description, certain terms have been used for brevity, clarity, and understanding. No unnecessary limitations are to be inferred therefrom beyond the requirement of the prior art because such terms are used for descriptive purposes and are intended to be broadly construed. The different assemblies described herein may be used alone or in combination with other assemblies. It is to be expected that various equivalents, alternatives and modifications are possible within the scope of the appended claims.