In the field of shipping containers, there is a need to ship non-hazardous fluid cargo not in expensive purpose built stainless steel tank containers but within standard rectangular shipping containers, the fluid being contained within a flexible membrane in the form of a flexible bag or bladder of polythene or other suitable plastics material. Such bags typically contain 24,000 litres (24 tonnes if water) of fluid but have themselves very little structural capability and thus rely on the strength of the sides and ends of the container to stop the bags bulging out and bursting.
This problem is increased when the shipping container is being transported by road, rail or sea when surging or sloshing of the fluid cargo can result in excessive loads being applied to the side walls and end walls of the container resulting in massive and sudden pressure, particularly on the long sidewalls of the container, resulting in permanent damage to the sidewalls necessitating expensive repair and possible rupture of the bags with consequent damage by the fluid to other containers and adjacent equipment This is particularly significant when the container is being carried on board a ship where the ships pumps are designed only for pumping sea water. Should the fluid cargo be one that sets, such as latex, blocking valuable bilge pumps and pumping systems is not only highly dangerous but is also expensive to remedy.
These problems have led the regulating authorities to suggest that the cargo size should be limited to say 16,000 litres with consequent increases in transportation costs and carbon emissions.
It is an object of the present invention to provide a system for transporting fluid cargo within a shipping container which mitigates the above problems.
Thus according to the present invention there is provided a system for transporting fluid cargo within a walled shipping container, the system comprising an open topped box having side walls and end walls and a flexible membrane which either independently or in combination with the box contains the fluid cargo, the box supporting the portion of the cargo within the box and being designed to flex and absorb at least part of the horizontal forces generated within the cargo during its transportation thus preventing overloading of the walls of the surrounding container.
The box may have a floor pan which seals the box against leakage of the cargo and the cargo may be contained by the flexible membrane and the box together with the membrane being sealingly attached to the box and retaining against leakage but not necessarily structurally part of the cargo above an upper rim of the box.
The membrane may comprise a bladder which completely encloses the cargo and is disposed partially within the box to contain the cargo independently of the box.
A top rail extends around an upper rim of the open topped box, the top rail and box walls together supporting the portion of the cargo within the box during transportation.
The end and/or side walls of the box may be of a double skinned construction with gussets between the skins, these double skinned walls supporting the portion of the cargo within the box during transportation. Cargo cooling or heating pipes may extend between the skins of the double skinned walls.
The box has a floor pan which may seal the box against leakage.
The end wall of the box adjacent a rear door of the container may include an aperture to receive a cargo loading/unloading valve connected with the interior of the flexible membrane.
The box and/or the shipping container may be provided with levers, cams or other devices to position the box in a desired position on the floor of the container.
The flexibility of the box under its proportioned load is designed to be not more than the elastic limit of the surrounding walls of the container.
A protective sheet may be provided which extends over the membrane to protect the membrane and to confine any leakage of the cargo through the membrane to within the box.
Straps may be provided over the top of the membrane and any protective sheet fitted to control movement of the fluid cargo within the membrane during transportation.
The straps may be attached to the sides and/or ends of the box. Alternatively one end of the straps may be attached to the box and the other end may be attached to the container.
The end wall of the box adjacent the rear door of the container may include a door to allow insertion and removal of a bladder type membrane or access to the interior of a membrane sealed to the box or to any valve fitted when the system is in use.
The sides and ends of the box are preferably outwardly sloping so that boxes can be stored in a nested configuration when not in use.
The box may have nesting stops which prevent the box jamming when nested and which ensure spacing between the floor pans of adjacent nested boxes to accommodate between the adjacent floor pans any membrane or protective sheet which is used.
The protective sheet may be fastened inside and below the top rail so that when empty the sheet falls inside the box clear of a second nested box to allow nesting of the boxes without the need to detach the sheet.
The box may have bolts or other fasteners which engage the shipping container to prevent relative movement between the box and container during transportation.
The box may have rounded corners where the side and end walls join to more readily conform to the shape of the bladder type membrane.
A second box may be mounted in an inverted configuration on the top rail of the upper rim of the other box to totally enclose the membrane within the boxes.
In such an arrangement the floor pan of the upper box forms a roof for the double box arrangement, the roof including a ventilator.
The underside of the roof may carry downwardly projecting beams which press into the membrane to reduce surging of the fluid cargo within the membrane during transportation.
The inside of the box may be coated with a spongy layer to protect the membrane from damage by contact with the box during transportation.
The floor pan of the box may have a convex domed shape which curves upwardly when the membrane is empty and which deflect to a more flat configuration as the membrane is filled.
The invention also provides a method of transporting a fluid cargo to a desired location within a shipping container comprising the steps of providing an open topped box having side walls and end walls, providing a membrane which either independently or in combination with the box can contain the fluid cargo, placing the membrane and box within the shipping container, loading the cargo within the membrane with the lower portion of the cargo supported by the box to prevent at least part of the horizontal forces generated within the cargo during transportation from overloading the walls of the surrounding shipping container, transporting the shipping container and loaded membrane to the desired location, and unloading the cargo from within the membrane.
Several embodiments of the present invention will row be described, by way of example only, with reference to the accompanying drawings in which:
Referring to the drawings,
In use, the side walls 11 and floor 16 of a container which has been used for general cargo can become jagged and splintered and corroded to such a degree that the flexi-tank 13 can become scuffed, worn or even punctured by debris such as nails, screws, steel banding and general dirt can also remain on the floors of the container adding to the dangers of puncture. Typically in an attempt to prevent such puncture and wear, the interior surfaces of the container walls and floor are lined with corrugated cardboard and the like to cushion and protect the bladder. This is a costly and skilled exercise to install. Also, in the event of leakage of the cargo, there is no means provided to absorb the leak or prevent the cargo from leaking out through gaps in the floor and doors 12 and into the bilges of ships, or elsewhere.
Further, to prevent the cargo bearing on the end doors 12, there are fitted a number of horizontal beams 17 slotted into known shoring slots 18 formed in the corner posts 19 of the container located some inches away from the interior surface of the doors 12 when closed. So as the flexi-tank 13 and its cargo 14 surges towards the doors 12 during transport the beams 17 support the flexi-tank. Furthermore, should the doors be opened for inspection of the contents of the container or for discharge of the cargo, the flexi-tank is prevented from falling out of the container onto personnel or the ground. The fitting of such restraining beams 17 is now mandatory.
Inside the container is shown a first embodiment of the present invention in which an open topped box 20 has a rear wall 21, front wall 22 and side walls 23. There are several ways in which to form the walls 21, 22 and 23. In this example there is a top rail 24 running around the upper rim of the largely rectangular plan shape of the box. This top rail 24 may be a separate component welded to the upper rim or may be formed integrally with the walls by bending a continuation of the wall material over to form the rail.
The box 20 has a floor pan 25 preferably shaped for drainage of liquid and other bulk cargo when discharging thus avoiding puddles and pockets of cargo remaining in the box. Ideally the pan 25 is a simple flat sheet of steel or stainless steel, painted against corrosion. In use filled with cargo (to be described later) the pan 25 is intended to be supported by the structural container floor 16 beneath it. The pan can be of as little thickness as 1 to 2 mm although thicker is acceptable and provides more damage resistance. The pan might be made from metal such as steel or aluminum or indeed a plastic, and if leak containment were not required, then the pan might be of a mesh construction bridging from one side of the box to the other or indeed absent entirely with the flexi-tank 13 resting directly on the container floor 16.
In this example the end wall 21 incorporates a door 26 attached via hinges 27 to the pan 25 of the box 20. The door 26 can be hinged open to provide access to the interior of the box 20 for cleaning or taking in or out an empty folded flexi-tank 13. On the top of the door 26 is a lock 28 locking the door shut to the top rail 24 of end wall 21.
At the top of each corner of the end wall 21 of the box 20 there is provided locking devices, such as shoot bolts 29, which when withdrawn lie within the profile of the end wall 21 yet when operated project out and are inserted into the shoring slots 18 of the posts 19 embodied in common shipping containers. Once they have penetrated the slots, the box 20 is restrained from sliding longitudinally fore and aft of the container 10.
To provide access to the valve 15 of the flexi-tank, an aperture 31 is formed in the end wall 21 or optional door 26 through which the valve 15 of the flexi-tank may project or be accessed. Further details of the aperture are seen in
In
A much taller wall 23 could be made to support even the whole height of the flexi-tank to the top and thus protect the container sidewall completely. However this would add substantial tare weight and cost to the box 20, and make the box 20 bulky so as to occupy a large volume when empty. Various studies have shown that the sidewall 11 of a typical shipping container 10 cannot support the whole pressure exerted upon it, denoted by graph zones E, F and G. However the container wall 11 can support some of the cargo pressure itself.
In
In transport, to control the liquid cargo from excess surging and sloshing straps 33 may be fastened over the flexi-tank 13 (and/or liner 32) and tightened to line 13′ to form a valley 34 in the flexi-tank and thus baffle the movement of the upper part of the fluid cargo 14. The straps 33 might alternatively be attached to the top corners 35 of the container as indicated by lines 33′ and thus support the flexi-tank partly away from the walls 11 and add to the relief of pressure acting on the sidewalls 11.
In
Empty boxes and protective sheets or liners can nest one inside another for shipping back to a home port. To get the boxes to nest one inside another the side 23 and end walls 21, 22 are outwardly sloping. For compact nesting the floor is narrower and shorter than the opening between the top rails 24. The depth of the box 20 below the top rail 24 is designed to ensure that when boxes are nested a gap or cavity 68 is maintained between the pans 25 of the nested boxes to accommodate the liners 32, empty flexi-tank, straps etc. conveniently allowing cargo ready flexi-tanks to be prepared prior to being loaded into shipping containers and filled with cargo.
Furthermore sheet 32 now covers the interior of walls 23 and pan 25 thus keeping the interior of the box 20 free from dirt contamination ready for its next use providing a dual use of sheet 32. However a further use of the sheet 32 is in that it lies in use between the sidewall 11 of the container and the flexi-tank 13 such that dirt and damage on the side wall 11 are prevented from contacting and damaging the flexi-tank when the tank is in use.
In a further utilization of the top sheet 32, non-liquid fluid cargo such as grain might be loaded into the box 20 and sheet 32 provides a housed clean environment for such products keeping them clean and dry, yet providing protection of the container from damage by the movement of the cargo. When it comes to discharge of such cargo, the provision of a door 21 seen in
Once inside the container the box bears on the container front vertical corner posts, and is secured to the container structure to prevent the box from moving towards the doors during transport and handling. A suitable connector is the previously described sliding bolt 29 which is housed on the top end rail 24 which can be slid out to engage with shoring slot 18 formed in the post 19 of most general cargo containers.
Optionally the height of the box 20 is engineered to suit structural requirements, cost, and weight. For the return trip the more boxes that can be shipped the lower the cost up to the point where they cannot be fitted inside a container or that the weight of the boxes equates to the carrying capacity of the container.
In
If a single box 20b will suffice to contain the cargo, it is envisaged that the boxes be fitted with a hard top or roof 43 comprising a rectangular frame 43a with an infill panel 44. A gasket 45 is fitted around the perimeter of the roof 43 to seal the roof 43 to the top 54 of box 20b. A similar gasket 46 can be fitted between the boxes 20a and 20b. To help prevent liquid surging within the box 20b, beams 47 seen in dotted line detail can be fitted within the roof panel 44 to restrict the free movement of liquid or bulk cargo within the box. Such beams can be made strong enough to support the weight of one or more additional boxes placed on top of box 20b, thus enabling a stack of 3 or 4 closed boxes 20b with roofs 43 to be containerized. A ventilator 48 might be provided in the roof 43 to allow gases to escape from the box or to release a negative pressure that might form as a result of the contents cooling and contracting. Similarly the aperture 31 might be fitted with a sight glass to check for leaks, and/or a ventilator.
It is envisaged that the inner surfaces of the pan 25 and walls 21, 22, and 23 and door 26 can be given a thick coating of a spongy rubberized paint of coating sufficient to overcoat any weld spatter or deformation of the steel surface. Such a coating might also have insulation properties so that in extreme weathers, the cargo may be protected from the shock of temperature differences.
The shape of the box although illustrated as rectangular with sharp radiused corners where the front and rear walls meet the side walls could be formed with rounded corners to better match the rounded shape of the flexi-tank and thus support it better.
The end door 26 might be engineered to occupy the whole end wall 22 of the box 1 hinged to the pan 25 and drop down in an outward direction taking with it the end section of the top rail 24 so that personnel or even vehicles could enter the box 20. In another arrangement the whole end door 26 as described might be absent if not needed, the aperture 31 then being formed through the end wall 21.
In
The floor pan 25 supports the whole length of the wall 51 along rail 55. Rail 55 embodies the lip 40 used in lifting and transporting the box 20, as described in
The inner skin 52 of the wall can be made with drain holes, which, in the event of a leak into the box, allow the liquid to drain into the wall cavity 56 and thus improve the capacity of the box 20 to contain leaks.
As can be seen in Figure In
The structure of the box described is of steel but it is envisaged that carbon fibre, stainless steel or other materials might be used. The pan 25 which is supported under load by the floor 16 of the container can be flexible. Furthermore because it is used to support the wall 51 along its base as a tensile structure, it need not be made from steel. For example, it is envisaged that the pan 25 might be made from plastic, glass fibre, aluminum and indeed any other sheet materials able to provide the tensile load requirements and other objectives of this invention. Such flexible materials conform more readily to the shape of any debris it might come to rest upon and thus not become damaged.
As the double skinned box 20 has no overhanging top rail to rest on top of the adjacent box when nested, the outside of the box can be provided with nesting stops 80 which rest on the top of the adjacent box (see
Under the pressures E′, F′ and G′ acting on the wall 51 as described above in relation to
Fair wear and tear damage to the exterior skin 53 of walls double skinned walls of the box might take place over time from handling, but the interior skin 52 is largely protected from such impacts only coming into contact with the flexi-tank. Thus skin 52 maintains a smooth surface desirable to protect the flexi-tank from scuffing damage.
In
However in practice if the gap between the outside of the box and the adjacent side wall was not equal (e.g. zero clearance on the right hand side of the container say 30 mm clearance on the left hand side of the container) then the more flexible box 20 side structure would begin to bear more heavily on the right hand container sidewall and tend to overload it. So in the preferred embodiment, since the geometry of the container and box and the relative location cannot be accurately controlled, the side structure of the box 20 is designed to have a flexibility under its apportioned load of not more than the elastic limit of the container side wall so that as the sidewall deflects outward under its proportioned load, it does so equal or more than the wall 23 or 51 of the box 20.
In
In
The cap is removed for discharging the fluid. If the empty bladder is to be shipped with the box back to base for reuse, then the valve is pushed into the space 68 denoted in
It is envisaged that besides fluid, other bulk cargo such as scrap metal, rubble, soil, nuclear waste and other such materials could be carried in containers using various adaptations of the box thus minimizing damage to the container, making the transport safer, and reducing contamination of the container enabling its use for cleaner cargos on its next trip.
The various box arrangements described above, which are typically for use in 20 ft containers, can also be used in the longer typically 40 ft containers in a tandem configuration.
In another utilization, the tandem boxes 20, 20′ might be fitted with lids as in
Number | Date | Country | Kind |
---|---|---|---|
1306780.6 | Apr 2013 | GB | national |
1308985.9 | May 2013 | GB | national |
1403129.8 | Feb 2014 | GB | national |
Filing Document | Filing Date | Country | Kind |
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PCT/GB2014/000143 | 4/11/2014 | WO | 00 |