EP0538563B1

EP0538563B1 - Combination of a liner with a container

Info

Publication number: EP0538563B1
Application number: EP92113005A
Authority: EP
Inventors: Raymond J. Stopper
Original assignee: INSTA-BULK Inc; Insta Bulk Inc
Current assignee: INSTA-BULK Inc; Insta Bulk Inc
Priority date: 1991-07-30
Filing date: 1992-07-30
Publication date: 1997-04-09
Anticipated expiration: 2012-07-30
Also published as: DE69218874D1; CA2075031A1; EP0538563A2; ATE151375T1; EP0538563A3; CA2075031C

Abstract

This invention relates to systems of handling flowable cargo in lined cargo containers. An inflatable, self-installing liner configured to line the container, when inflated, is installed and inflated within the container. A transparent, rigid bulkhead keeps the filled liner from transferring load directly to access doors to the container. Special inflatable bags are provided between the liner and the container at positions where cargo tends to remain during unloading of the liner. Fluidizing means and agitation means are also provided to enhance the unloading of the cargo. In another embodiment, there is disclosed a novel modular bulkhead configuration that has an interlocking internal construction. This modular bulkhead can be outfitted to include a compartment for housing the liner during shipment, or to receive a cartridge containing a liner. The modular bulkhead can also include a viewport and sample port. <IMAGE>

Description

The present invention relates broadly to systems for loading and unloading cargo containers with fluid-like or fluidizable cargos. The invention more particularly concerns the combination of an inflatable liner for holding a flowable cargo with a box-like cargo container.
Conventional cargo containers are routinely used to transport flowable bulk cargo such as pelletized plastic, grain, pulverized materials and the like. These containers may be transported on truck beds or rail cars or individually shipped in container ships or on barges. They may also be used to store materials at sites to which they are delivered. Typically, these containers conform to standard specifications regulated by the American Standard Association or similar international associations.
Where flowable bulk cargo, including liquid and semi-liquid material, is to be transported in a conventional cargo container, modern practice typically dictates protecting both the cargo and container with a flexible liner. The dimensions of the liner roughly correspond to the internal dimensions of the container. Containment of the cargo inside such a liner provides many advantages including protection of the container from contaminating cargo, protection of the cargo from contamination, exclusion of dust and moisture from the cargo, and similar functions. Many different styles of liners have been designed to accommodate the various functions required.
The installation, loading and unloading of bulk cargo from liners within containers has been a fertile area for invention. Many liners, for example, require the use of a bulkhead positioned between the liner and the unloading portal. This portal, in most cases, embodies the rear doors of the container. In a typical transportation operation, the load within the liner is transferred to the bulkhead which may serve as a load-bearing retaining wall or may transfer the load to another load-bearing retaining wall such as the doors of the container. As noted above, such doors are normally at the rear end of a container, and they will be referred to as the "rear doors" herein.
During a typical unloading process, bulk cargo is removed from a container by first allowing gravity flow, establishing a line of repose of the cargo within the container and then tilting the entire container and achieving further gravity flow of the bulk cargo out of the liner through a portal in the bulkhead positioned near the rear doors of the container. Alternatively, low pressure suction devices may be used to eliminate the requirement for tilting. Unloading with suction, however, requires special equipment. Although it is possible to remove a large percentage of the cargo from a container using the above conventional techniques, typically there is a residual amount of the cargo retained in the corners nearest the unloading portal.
Several bulk cargo handling systems already have been designed which attempt to overcome the above problems. For instance, numerous patents have been issued for bulkheads, liners, and unloading assistance devices. Some patents describe bulk cargo handling systems which include all three such features - i.e., bulkheads, liners, and unloading assistance devices.

Bulkheads

Removable bulkheads used in cargo containers are well known. For the most part, however, such bulkheads are very heavy, wall-like structures requiring substantial support to withstand a load. Certain designs require the bulkhead to serve as the principal load-bearing member replacing, for example, the rear doors of a container.
In other cases, the bulkhead is not required to serve as a structural support member but may serve instead as a baffle inside a flowable bulk cargo container, or merely as a partition to retain refrigerated air. In yet other designs, the bulkhead may be separate and distinct from the container, relying instead on structural members extraneous to the container to provide the necessary support needed in, for instance, a tilting, gravity unloading process.
In yet other designs, the bulkhead may not serve as the load-bearing wall by virtue of its flexible, yieldable nature. Such a bulkhead, when stressed by a load, flexes toward the rear doors of the container thereby transferring the load directly to those rear doors. In designs such as this, safety during transportation and unloading of the cargo is dependent upon the integrity and safe opening of the rear doors.
Bulkheads may be made from a variety of materials including metal, wood, corrugated cardboard, reinforced plastic, and structurally molded plastic. Where a bulkhead material is used which must be reinforced, typically wooden or metallic supporting framework is added.
The bulkheads described above suffer from several limitations. First, although lightweight bulkheads are known, these bulkheads either must rely on substantial supporting framework or must flex to contact a load-bearing, rear door of a container. As noted, when a bulkhead yields and transfers the load within a liner to the rear doors of a container, safety concerns are raised. Heavier bulkheads improve this aspect of flexible bulkheads; however, such heavy-duty bulkheads are unwieldy, require special equipment or extra manpower for installation, and increase the cargo weight considerably.
Second, the bulkheads described above limit viewability of the inside of a container and its liner. The ability to observe interior cargo spaces while a bulkhead is in place is important to many aspects of the handling of bulk cargo. For instance, where liners are installed for receiving bulk cargo, such liners are first expanded or inflated. With most bulkheads, however, it is difficult if not impossible to ascertain whether the liner is fully expanded or properly aligned. It is also difficult to ascertain the level of cargo within such a liner. This is important information to ascertain, not only during loading, but also during actual transport. The possibilities of cargo shifting, contamination, moisture, field inspection, etc., are all reasons for being able to view a cargo within a liner and behind a bulkhead. Unfortunately, known bulkheads and liners are deficient in this regard.

Liners

Flexible liners used in conjunction with bulk cargo containers are also known in the art. In some cases, the liners are used without a separate bulkhead in addition to the rear doors of the container. In other cases, the liners require elaborate, tedious, man-power intensive installations involving hooks and straps to support the liners in an open configuration. In still other designs, internal structural frameworks are required to suspend a liner. In many cases, liners are made of flexible plastic or rubber materials which are translucent.
Typical liners are provided with a variety of sleeves or other inlets or ports for access to the interior of the liners. These sleeves facilitate loading, venting, and unloading. In many cases, the loading and venting sleeves are placed in close proximity to one another yet distant from and above the unloading sleeve.
In some designs, the liner is made contiguous with at least a rear bulkhead, and the bulkhead then serves as a closure for the liner. In other designs, the liner may remain open on one or another of its faces.
All of the liners described above suffer limitations with regard to ease of installation and requirements for manipulation to prepare the liner to receive cargo. Most importantly, liners are needed which may be installed with a minimum of manpower and skill.
DE-A-2027842, which forms the basis for the pre-characterising part of claim 1, discloses a box-like cargo container having an inflatable polyethylene liner for holding a flowable cargo, the container having a bottom wall, a top, two sidewalls, a front end wall, and a removable rear end wall forming an access door. The liner when deflated forms a compact package and when inflated has a floor, a top, front and back end walls and two sidewalls. The liner has, in its back end wall, a first inlet adjacent the top of the liner when inflated for loading cargo into the liner and an outlet adjacent the floor of the liner when inflated for unloading cargo from the liner through open end of the container left by removal of the access door.

Unloading Assistance Devices

Unloading assistance devices are known in the art and include hoppers with fixed, rigid members providing advantageous angles corners for enhancing gravity flow of bulk cargo. In some cases, such hoppers are used with bottom unloading containers such as rail cars. In other instances, the rigid surfaces which form the unloading assistance device may be fixed in place, and in still others, the inclined surface may be pivotally attached to one or another support structure such as a bulkhead or container wall. In yet other designs, the inclined surface which promotes the unloading of corner spaces in the liner may be provided by particular arrangements of the bulkhead member itself. In this type design, the bulkhead may be placed either upright in a vertical position or angled to form an inclined plane to facilitate unloading.
In some designs, a bulkhead is modified to promote the unloading of the flowable cargo. Thus, the typically flat bulkhead may be replaced by a curved bulkhead providing a funnel-like surface to direct the flow of the cargo during unloading. Again, the typically flat bulkhead may be modified with rigid, planar corner members pivotally attached to the bulkhead to truncate the corners of the cargo space and thereby assist unloading of the corners. In the designs with altered corners or curved bulkheads, a substantial portion of the cargo space is sacrificed. Depending upon the design and the mass/packing density of the cargo, this loss of cargo space may represent up to several hundred pounds of material which could otherwise be transported.
Other designs to date have involved modifications of hoppers by addition of inflatable membranes to the wall of the hopper structure. Still other unloading assistance devices have involved forcing gases or liquids in between a container wall and the liner ("second-skin" type liner) to force bulk cargo to pour out of bottom portals. In yet other designs, liners or small container bags have inflatable and semi-pervious corner members which aerate and agitate the pulverant cargo contained in them by release of air into the flowable cargo. In yet other designs, a folded sheet is provided which, when stretched and unfolded, forms a slanted unloading surface.
Unfortunately, each of the systems for assisting the unloading of bulk cargo mentioned above suffers from one or more deficiencies. In some cases, for example, the unloading assistance device is necessarily attached to each the container or to the bulkhead which restrains the liner. In these cases, however, where a liner is to be used independently of either the container or bulkhead, as the case may be, it is not possible to take advantage of the unloading capability of the device. The same limitation applies to bladders attached to the hopper or container in which a liner is to be used to transport bulk flowable cargo. As mentioned previously, fixed corner-truncating devices substantially reduce the available cargo space. Unloading assistance devices are needed which overcome these and other limitations.
The deficiencies pointed out in the bulk cargo transport systems and elements of systems described above continue to limit the safety, efficiency and utility of such systems. Thus, a long-felt and unfulfilled need continues to exist for a bulk cargo unloading system which minimizes or substantially overcomes the variety of deficits in known designs. It is an object of the invention to provide an inflatable liner which can be used in such a system.
According to the invention, there is provided a combination of an inflatable liner for holding a flowable cargo with a box-like cargo container having a bottom wall, a top, two sidewalls, a front end wall, and a rear end wall with an access door, the liner comprising:

(a) an inflatable member foldable when deflated into a compact package and when inflated having a floor, a top, front and back end walls and two sidewalls;
(b) a first inlet proximate the back and top of the liner when inflated for loading cargo into the liner;
(c) an outlet proximate the back and floor of the liner when inflated for unloading cargo from the liner through the access door; characterised by
(d) a second inlet proximate the front of the liner for supplying gas to inflate the liner and a compressible conduit connected with said second inlet and of a length to extend along the outer surface of the liner to the back of the liner to the end of said conduit for connection to a source of inflating medium.

According to another aspect of the invention said compressible conduit extends from said second inlet to the rear of the liner, between the top wall of the liner and the top wall of the container, whereby during inflation of the liner within the container, via said conduit, the conduit becomes increasingly constricted between the liner and the container as the liner is inflated, to prevent subsequent escape of gas from the liner via said conduit with subsequent deflation of the liner.
In a preferred embodiment a cargo container for flowable cargo includes a self-installing, inflatable liner, a transparent bulkhead, and one or more inflatable bags configured and positioned within the container to promote recovery of cargo from the container. The liner, like the bulkhead, is also preferably transparent in that it is either transparent or sufficiently translucent to enable a viewer to view the extent of disposition of cargo within the liner. The liner is also configured such that, upon inflation, it fills substantially an entire container. The liner has at least one port located near the top of the liner at one end of the liner, normally the rear end abutting a door or other access means to the interior of the container. This port may comprise a flexible tube or the like for venting the liner or for filling the liner with a cargo. At least one second port is also located near the bottom of the liner at its rear end to enable cargo to empty from the liner. A third port is located proximate the top of the front end of the liner and includes a compressible tube or other conduit which is designed to extend along and beyond the length of the liner for the purpose of inflating the liner. The compressible nature of the tube enables the tube to serve as a valve in that it is compressed and sealed upon inflation of the liner.
The liner is folded or otherwise arranged within a cargo container which its filling port towards the front end of the container. Then, as air or other suitable gas is passed into the liner through the filling port, the liner inflates, unfolds and ultimately fills the container. A flowable cargo is then passed through the filling port into the liner. As explained above, the liner ultimately seals itself.
To relieve pressure on the doors or other access means to the container, the invention preferably employs a bulkhead between the back end of the liner and the doors. The bulkhead extends across the container and to a height sufficient to relieve loading on the doors, especially the lower portion of the doors.
The inflatable bags of the invention are positioned in one or more of the corners at the rear end of the container between the liner and the container. Each bag includes a port or is otherwise structured to be inflated and deflated. Thus, air or other suitable fluid is injected into each bag when the liner is emptied to dislodge cargo which otherwise tends to be left in the container when the container is emptied. It is of course possible to cause as many cycles of inflation and deflation as necessary to fully unload the liner.
In another embodiment, a modular cargo container liner system includes a lightweight, reusable and/or recyclable bulkhead liner cartridge having a recessed storage area containing a liner in a folded or stored position. A removable or openable flap capable of covering the recessed liner storage area is provided on the bulkhead liner cartridge to protect the liner prior to installation into a container. The bulkhead liner cartridge also preferably contains at least one port or other means of accessing the interior of the liner. This port may comprise a flexible tube or the like for venting the liner or for filing the liner with a cargo. The liner is preferably transparent in that i is either transparent or sufficiently translucent to enable a viewer to view the extent or disposition of cargo within the liner. The liner is also configured such that, upon inflation, it fills substantially an entire cargo container. The liner utilized in the braceless modular system can be of any type, such as the liner preferably outfitted with inflatable angle corner bags, and/or a fluidizing pad as described herein.
The braceless modular container/liner system also includes a lightweight, reusable and/or recyclable bulkhead base cartridge for receiving the liner cartridge. The liner cartridge is preferably telescopingly attached to the bulkhead base unit. The base is constructed using a novel, lightweight, interlocking internal cell matrix that is covered by an outer layer, and may also include an observation port for the cargo area, and a built-in sample storage area. The sample storage area is preferably constructed of sufficient size to accommodate a small, self contained sample of the cargo contents, or is constructed as part of the observation port to allow access to a recloseable sample sleeve attached directly to the liner. The base unit also contains a discharge port.
In another embodiment, the braceless modular cargo liner system is configured as an integrated unit containing both the bulkhead base unit and the liner cartridge unit. In this embodiment, the bulkhead includes a recessed storage area for containing the liner prior to installation in the container. The system is configured with the filling, venting, discharge, sample and/or observation ports.
The braceless liner system is positioned or otherwise arranged within a container with its filling port toward the front end of the container. The protective panel is opened to expose the polyethylene liner which is then extended and secured to the front of the container. The braceless bulkhead is uprighted and positioned at the container's threshold proximate the container doors. The bulkhead extends across the container and preferably to a height sufficient to rest behind the upper horizontal cross brace of the container. The remainder of the bulkhead rests against the left hand door. Positioning guides can by employed to advantage to facilitate placement of the liner system proximate the rear doors. Use of the positioning guides on the right hand side of the container facilitates alignment of the bulkhead during the loading phase to ensure that the right door will have proper clearance for closing, and to prevent the bulkhead from falling over during loading, such as may occur due to the arrival of an unexpected gust of wind. As air or other suitable gas is passed into the liner through the filling port, the liner inflates and ultimately fills the container. A flowable cargo is then passed through the filling port into the liner. The liner is ultimately sealed.
Another embodiment includes a means for fluidizing the bulk cargo contained within the liner to facilitate its removal from the liner during the unloading process. More specifically, the means for fluidizing the bulk cargo is accomplished by inserting or attaching a fluidizing pad or bed within the interior of the liner, preferably along the bottom or lower horizontal panel of the liner. The fluidizing pad preferably contains a plurality of fluidizing jets, or perforations capable of directing sufficient jet flow into the liner to fluidize the contents of the liner. In a preferred embodiment, the fluidizing jets are energized by the introduction of air through the jets. However, other gases, preferably inert, or mixtures thereof, may be employed to advantageously energize the jets, if desired. The fluidizing pad preferably contains at least one inflation tube to introduce the air or gas source to the fluidizing pad. The inflation tube is preferably sufficiently rigid and self-supporting so that it will not collapse if it is located under the weight of a liner filled with the bulk commodity. Fluidizing pads can be installed along the interior vertical sides of the liner, if desired. This means for fluidizing the contents of the liner is particularly advantageous for the unloading of bulk commodity powders, and the like.
In another embodiment, there is means for agitating the liner bag to facilitate the discharge of the bulk cargo contained in the liner. More specifically, a fluidizing pad, such as that mentioned above, is attached beneath the liner bag, such that the fluidizing jets are directed to toward the container. An air source is applied to the agitation pad in an oscillating or pulsating fashion to agitate the liner bag thereby dislodging residual bulk material present in the interior of the liner. This agitation means can be used alone or in combination with the fluidization means.
In another embodiment of the present invention, the liner has opposed side walls, a top and a floor defining an interior space corresponding generally to the side walls, top and floor of the container, the liner being positionable within the container in spaced relation with a first wall in the container. A fluid impervious plenum is provided adjacent the floor of the liner, the plenum corresponding to an area of the floor of the liner and having a plurality of spaced apart perforations for directing a fluid from the plenum into the interior space. A bulkhead is positionable between the access door and a side wall of the liner, the bulkhead having a liner inlet port, a liner outlet port, and a plenum inlet port. The liner has a liner inlet for introducing material into the interior space through the liner inlet port; a liner outlet for removing material from the interior space through the liner outlet port and a plenum inlet for introducing a fluid into the plenum through the plenum inlet port whereby a fluidized bed of flowable material can be created within the liner by supplying air to the plenum inlet to facilitate unloading of the material through the liner outlet. In this embodiment, the plenum is preferably positioned inside the liner floor.
It is anticipated that the plenum could also be positioned beneath the floor of the liner, in which case, perforations would be provided in the floor of the liner in registry with the perforations in the plenum.
In another embodiment, the cargo liner apparatus further includes a liner compartment in the bulkhead, the compartment being operable to contain the liner when the bulkhead is transported.
The cargo liner apparatus liner compartment may comprise an upper portion of the bulkhead that is detachable from and replaceable on the remaining portion of the bulkhead. The detachable liner compartment can be telescopingly carried by the bulkhead.
The cargo liner may comprise a positioning guide for positioning the bulkhead adjacent the access door. The positioning guide preferably comprises: a channel engager for engaging a channel on a side wall of the container; a bulkhead engager for engaging the bulkhead; and a connecting web for connecting the channel engager to the bulkhead engager. The channel engager preferably has a box-like cross-section having one dimension substantially the same as the depth of a stiffening member on a side wall of the container. The bulkhead engager preferably engages the bulkhead along only a portion of a width of the bulkhead. In an alternative preferred embodiment, the bulkhead engager engages the bulkhead by penetrating a face of the bulkhead.
The positioning guide may be magnetic or may comprise an adhesive for adhesive engagement with a side wall of the container.
The liner system bulkhead unloading sleeve may be adapted with an openable and recloseable port to facilitate access to the liner for cutting open the liner membrane prior to the discharge operation, and to serve as a venting means for the unloading sleeve. This port allows for access to the discharge area of the liner bag without necessitating a removal of the unloading sleeve fro the unloading equipment.
Embodiments of the invention are described below with reference to the drawings.

Figure 1 is an exploded, isometric view of the construction of a self-installing liner system,
Figures 2A and B show construction of a corner bag,
Figure 3 is an isometric view of a completed liner system,
Figures 4A-D are isometric views of rigid bulkheads,
Figure 5 is a partially exploded view of a liner apparatus packaging system.
Figures 6A-D are stepwise, isometric views of a phantom container showing the stepwise self-installation of a liner within the container.
Figures 7A-C are stepwise isometric views, partially sectioned, showing an alternative packaging and attachment system used in conjunction with the self-installing liner.
Figure 8 is an isometric view of a self-installing liner with corner bags, transparent bulkhead and structural support members installed within a container.
Figure 9 is a partially sectioned view of a transparent bulkhead installed within a container with structural support members, corner bags and liner.
Figures 10A-D are stepwise views of the unloading of a phantom container-liner system showing the use of corner bag members.
Figure 11 is an exploded, isometric view of a liner system embodiment of the present invention containing a fluidizing pad.
Figure 12 is an isometric view of a liner system embodiment of the present invention containing a fluidizing pad.
Figure 13A is an isometric view of a modular bulk cargo container liner system embodiment of the present invention.
Figure 13B is an isometric view of a liner unloading sleeve embodiment of the present invention.
Figure 13C is an isometric view of a liner unloading sleeve embodiment of the present invention.
Figure 14A depicts a liner cartridge embodiment of the present invention.
Figure 14B depicts a liner cartridge embodiment of the present invention.
Figure 14C depicts a bulk cargo liner system embodiment of the present invention.
Figure 14D depicts a bulk cargo liner system embodiment of the present invention.
Figure 15A illustrates an isometric, cross-sectional view of a bulkhead portion of a bulk cargo liner system of the present invention as taken from lines 1-1 in Figures 14C and 14D.
Figure 15B illustrates a cross-sectional view of a bulkhead edge or perimeter cap.
Figure 15C illustrates a cross-sectional view of a bulkhead edge or perimeter cap.
Figure 16 is an isometric cross-sectional view of a bulkhead portion of a cargo liner system of the present invention.
Figure 17A is a exploded cross-sectional view of an exemplary braceless bulkhead of the present invention.
Figure 17B is an enlarged cross-sectional view of exemplary bulkhead beams in accordance with the present invention.
Figures 18 and 19 depict exemplary braceless bulkhead systems made in accordance with the present invention.
Figure 20 shows an exploded view of a bulkhead view port cabinet.
Figures 21A and 21B show exemplary bulkhead positioning guides.
Figures 22A and 22B show a top cross-sectional view of a braceless bulkhead positioned with positioning guides.
Figure 23 shows an exemplary means for securing the discharge sleeve fitting of the liner to a retainer bulkhead.
Figure 24 shows an exemplary means for securing the discharge sleeve fitting of the liner to a retainer bulkhead.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

As noted above, the present invention relates in one aspect to a rigid bulkhead, at least a portion of which is transparent -- i.e., either clear or sufficiently transparent as to enable viewing through the bulkhead. The rigidity of the bulkhead provides a principal advantage over prior art bulkheads which are flexible or at least yield under load to transfer the load to the doors or other opening means for the container. The materials from which the bulkhead is made are not so heavy as to require machinery or extensive manpower for installation. Thus, installation of a bulkhead of the invention has been demonstrated to be easily carried out by two persons.
The bulkhead may be constructed, in whole or in part, from transparent, rigid material which is: (1) sufficiently transparent to provide at least some view of the cargo space of the container including the lower corners nearest the bulkhead; and (2) rigid enough to help prevent any substantial portion of a load from bearing upon the bulkhead and other support structures from being transferred to the opening means (doors) of the container.
It has been found that loads in cargo container liners may impose pressure on the lower and most central portion of a bulkhead of about 600 pounds per square foot. On the other hand, the loads at the lower corners of a typical cargo contained behind a bulkhead may run about 400 pounds per square foot. At the topmost corners of such a load-bearing bulkhead, about 50 pounds per square foot are typically encountered. The bulkhead of the present invention counteracts such forces sufficiently to prevent transfer of the load to the rear container doors.
A preferred rigid, transparent bulkhead material is an acrylic resin sheet. However, it is anticipated that a variety of other materials are also suitable, including safety-reinforced glass, fiber reinforced plastic, structurally molded plastic, and other products which possess the necessary rigidity and transparency. As will become more apparent when the bulkhead is described in detail below, some portions of the bulkhead will not be required to be either rigid or transparent, so long as enough overall rigidity and transparency is retained by the bulkhead to provide the advantages of the invention. The overall bulkhead unit, however, should demonstrate both of these characteristics.
By making a bulkhead of the invention of a material through which the interior of the container and liner may be seen, the bulkhead overcomes a substantial limitation of opaque bulkheads or bulkheads with only limited capability to provide such a view. In a preferred embodiment, the bulkhead is clear thereby providing maximum visibility of the cargo space. In any case, the view provided by the bulkhead of the invention facilitates observation of the interior cargo space with relative ease compared with prior art devices. Thus, a preferred embodiment facilitates observation of important aspects of the bulk cargo transport system including: (1) installing of the liner; (2) loading of the bulk cargo; (3) viewing of cargo during transport; and (4) unloading of cargo.
This capability represents a substantial improvement over prior art devices and facilitates bulk cargo handling with reduced manpower requirements. For instance, automated machinery may be used in combination with liner systems for both loading and unloading to minimize handling by personnel of bulky or hazardous materials. Where such automated devices are utilized, the ability of a single handler to view the entire operation is enhanced. Cargoes may include any cargo such as pelletized plastic, grain, particulates, or other flowable cargoes.
The bulkhead of the invention is capable of being positioned between a liner and the opening means for a container. The opening means typically comprises a rear door or doors of the container. Alternatively, the opening means may be openings positioned along any wall of a container wherein an opening is found so long as the bulkhead may be adjusted to function as described above in conjunction with such opening.
Of independent significance, the bulkhead of the invention is capable of relieving the load caused by a cargo within a liner from being transferred directly to the opening means. The ability to restrain the load within the liner relies, in one aspect, upon the rigid and substantial construction of the bulkhead. In addition, the restraining ability relies on the special construction of the bulkhead itself, including the portions of the bulkhead which extend forwardly into the container cargo space. The restraining ability of the bulkhead is increased by a minimal use of structural support members.
Another important aspect of the bulkhead of the invention is that there is no requirement for any attachment to a liner used with the bulkhead. This represents a considerable improvement over those prior art bulkheads which are integral with the liner or which function as a closure for the liner. Such prior art devices do not facilitate use of the bulkhead separate from the liner. The present invention on the other hand uses discrete components. This is especially important in those countries where laws require either reusable shipping container liners or fully recyclable shipping container liners. Many commercially available liners are recyclable, but many bulkheads are not. Inasmuch as the bulkhead of the present invention is not attached to the liner, the bulkhead is fully reusable.
An inflatable air bag used in conjunction with a liner within a container is also a feature of the present invention. The air bag may take a number of configurations depending upon the unloading procedures being used. In a preferred embodiment, the air bag will be attached to the liner to facilitate the unloading of the residual cargo that remains following gravity flow unloading. However, in alternative embodiments, the air bag may be attached to other elements of the invention such as the transparent bulkhead or the container itself. In addition, air bags need not be attached to any of the other elements of the invention.
Regardless of whether attached or unattached, the air bag is positioned in close proximity to an outlet in the liner. The outlet in the liner is, in turn, positioned in close proximity to the opening means in the container, usually the rear doors.
A self-installing liner capable of containing bulk cargo and separating the cargo from the interior surfaces of a bulk cargo container is also a feature of the present invention. The term "self-installing" means a liner which requires minimal manpower and manipulation for installation and preparation for receiving bulk cargo. More particularly, the self-installing liner of the present invention requires only attachment of the liner to the forward container wall, thereafter relying on forced air inflation of the liner to fully install the liner within the container. Attachment of the liner to the forward container wall is achieved with minimal manpower as well. In one embodiment, the folded liner is placed in the front of the container in a manner exposing a top and bottom edge of the front panel of the liner. In this embodiment, the bottom edge of the front panel is manually attached near the forwardmost container floor with attachment being achieved by nailing, tacking or by applying adhesive. Next, the top edge of the front panel of the liner is attached to a forwardmost container wall or ceiling in a manner to fully extend the front liner panel. The attachment of the top edge of the liner may be by means of a nailing or hanging board or by means of hanging straps looped over a lash bar in the container. In another embodiment, attachment of the liner to the forward container wall and floor portions is achieved with even less manpower or manipulation. In this embodiment, the bottom edge of the front panel of the liner is previously attached to a packaging member. The packaging member comprises at least two panels the outer surface of which panels are coated with an adhesive which adhesive-coated, outer surface is additionally covered with a removable release paper or sheet. Instead of requiring a manual attachment of the bottom edge of the front panel, installation of this embodiment of the invention merely requires removal of the release paper exposing the adhesive-covered panels. These panels are then placed in the front most corner of the container where floor and front wall members join. If greater than two panels comprise the package member, these panels may be unfolded to additionally adhesively attach to the container wall or floor. The top edge of the forward panel of the liner is next attached as noted above. Upon inflation, as described below, the adhesive covered panels of the package member become even more firmly attached to the container. This attachment is enhanced when bulk cargo is placed in the liner. After the front panel of the self-installing liner is attached, inflation is initiated. This is achieved, in a preferred embodiment, by providing an inflation tube for filling with gas the deflated liner. In certain embodiments, this gas will be compressed ambient air, either filtered or unfiltered. In other embodiments, especially where inert gases are preferred due to an explosive, combustible or otherwise reactive nature of certain cargo or due to the need for maintaining low moisture content of the inflating gas and cargo, gases other than air may be used.
A surprising attribute of the invention lies in the lack of necessity for a means to close the inflation tube to prevent gas from escaping from the liner. The position of the inflation tube is such that upon continuing inflation, the liner presses against the inflation tube, progressively causing enough pressure against the inflation tube to effectively seal the liner from losing internal air. Thus, the self-installing liner may be inflated inside a container and bulkhead as much as two days prior to being loaded. This added flexibility in operation provides a considerable advantage.
An additional surprising aspect of the self-installing liner is its automatic inflation limitation feature when using certain forced-air equipment. As the inflation tube delivers the forced air into the liner, the inflow and outflow of air equilibrates to prevent over inflation of the liner and potential rupturing of the liner material. Thus, there is no requirement when using certain forced air equipment, such as a small centrifugal blower as might be found on home leaf-blowing equipment, to monitor a self-installation for possible over inflation. Hanging strap means are provided at the top edge of the rear panel of the liner for positioning and hanging of the liner once the self-installation is achieved.
The invention also pertains to a self-bracing, modular cargo container liner system. The self-bracing system includes a self-supporting bulkhead to permit maximum load space by resting on the rear door of the container, and may also include an observation port for the cargo area, and a built-in sample storage area. In one preferred embodiment, the bulkhead includes a recessed storage area for containing the liner prior to installation in the container. In another alternative preferred embodiment, the bulkhead comprises a base unit capable of receiving a cartridge unit which contains the liner.
The overall self-inflation features of the liner of the invention represent a substantial improvement over conventional systems for installing liners. The self-installing liner employs a relatively few, simple steps for deployment, compared with conventional liners which use numerous straps, belts, hooks, attached bulkheads, adhesives and the like. Although certain limited use may be made of attachment devices such as these in conjunction with the self-installing liner, such use is kept to a minimum.
The various elements described above individually represent considerable improvements over the existing art. However, they may also be combined in a number of ways to achieve even further improvements. In that regard, it is contemplated that the systems of the invention will be used in connection with a typical walled container having at least side walls, front and rear walls, and a floor. However, the apparatus and methods of the invention may also be applied to cylindrical containers or other irregularly shaped containers. The container should have at least one wall with an opening through the wall to provide access to the interior of the container. This opening in many instances will comprise the rear doors of a container. At the present time, most containers are being configured to provide rear door access to the cargo compartment; and this description, accordingly, has generally assumed that type of access.
Each system of the invention will have a liner bag capable of containing bulk cargo and capable of providing a barrier between the cargo and the interior surfaces of the container. In a preferred embodiment, the liner bag is constructed of lightweight, flexible materials known well in the art. In alternative embodiments, the liner may be constructed of heavier, more durable materials where multiple uses or the characteristics of the cargo so require.
Where the liner bag is to be used with a bulkhead which does not extend the full height of the container, such as where only a lower portion of the container opening is provided with a rigid and transparent bulkhead, the face of the liner bag which will encounter the bulkhead and supporting bracing structures may be reinforced with multiple layers of liner material or with a more substantial plastic material. In a preferred embodiment, even with reinforcement as necessary, the liner bag should be sufficiently transparent to provide a view into the interior of the liner.
Preferably, the liner bag will be constructed of a material through which the cargo may be clearly seen. Moreover, in a preferred form, the liner bag will be constructed to fill, upon complete installation, the space defined by the interior walls of the container.
It will be apparent to those of skill in the art that the bulkheads of the present invention may be used with a wide variety of containers, container liners, and opening mechanisms. Thus, many commercially available containers, fitted in a variety of ways with opening means, may be used in combination with the cargo liner systems of the present invention. Likewise, many commercially available liners may be adapted for use with the bulkhead and other features noted herein.
It is contemplated that the inflatable bags, the fluidizing means, and/or the agitating means of the invention will be placed at positions within a lined container, wherever cargo tends to be left behind when the liner is emptied. Thus, when a container is tilted to drain cargo from a liner through an outlet port or a container door, cargo frequently remains on the floor of the liner and along the outlet end of the container, and especially in the corners of the container. It is, therefore, preferred that the outlet of the liner be positioned in close proximity to the bottom of the container and also in close proximity to the opening means in the container. Inflatable bags placed in the corners at the outlet end of the container may then be most effectively used to promote the unloading of cargo within the liner.
As mentioned above and as is required by any particular bulk cargo handling situation, the inflatable bags may be variously attached to the liner, the bulkhead or the container. Alternatively, the bags may be entirely separate members, unattached to any of the other elements. The air bags need not be uniformly sized, particularly where asymmetry in the position of the opening means in the container and the outlet in the liner require differently sized air bags.
Inflation of the bags may be achieved in a variety of ways. One embodiment involves the use of filler tubes to which may be attached a source of pressurized air or other suitable gas or fluid. It is necessary, of course that the pressure of the gas be sufficient to inflate the bags when covered by cargo material. It is also necessary that the bags, when inflated, have a shape, size and slope sufficient to cause the cargo to flow toward the outlet. Where the cargo is relatively lightweight, centrifugal blowers may provide sufficient pressure. When the container is used in facilities without access to electrically powered compressors, blowers, pumps or the like, compressed gas tanks may be packaged with the other elements of the apparatus.
It will be apparent that the use of the inflatable bags of the invention is not limited to the specific liners and bulkheads of the present invention. Thus, the bags may be used with any bulkhead or container and used effectively with any of a number of liners known in the art. The bags may also be attached to the liners, themselves, or to a baseboard or to elements of the containers. Likewise, the other aspects described herein, such as the fluidizing means, the agitation means, the sample port, and the recloseable access in the discharge port, can be used in a variety of liner systems, including those described herein and those known in the art.
The self-installing liner of the invention may be used in conjunction with virtually any known cargo container, bulkhead, opening means, and the like. However, their use with the rigid and transparent bulkheads and the inflatable bags of the invention provide particular benefits. Thus, in a preferred embodiment, a rigid and transparent bulkhead, fitted into a container with a self-installing liner and inflatable unloading assistance devices, provide especially safe and efficient transport of bulk flowable cargo. Although the elements discussed above may be provided and shipped separately, they may also be packaged as a unit. Additionally, where it is desirable to do so, a facade which covers the apparatus of the invention may be provided for purposes of identitying the source, the nature, the required handling procedure and other pertinent information relating to the apparatus and its use.
Furthermore, the braceless cargo liner system of the present invention can also be employed in conjunction with virtually any known cargo container. The liner bags employed with the braceless system can be of any variety, and can contain the preferred inflatable angle corners, fluidizing means, and/or agitating means described herein.
Methods for transporting fluid or fluidizable bulk cargo are also achieved by the use of one or more of the elements of the invention. These methods generally require selecting an appropriate apparatus as provided by the invention and matching it with a particular bulk cargo, transporting the bulk cargo therein, and then unloading the cargo in a manner to take advantage of the considerable improvements in safety and efficiency provided by the present invention. The specific improvements available when one or another of the elements, alone or in combination with one or more of the other elements of the invention, is also claimed. Thus, where safety and viewability of the cargo space are of importance, one would select a method of transporting the cargo utilizing at least the rigid and transparent bulkhead of the present invention, or the braceless system employing the viewport. Where efficiency and low manpower requirements are important, one would select a method where at least the self-installing liner of the present invention is used. Where efficiency and the need to remove residual cargo left after unloading are important, a method which at least uses the air bags, fluidizing means, and/or agitating means of the present invention is preferred. Where efficiency and low manpower requirements are important, but bracing is undesirable, one would select the braceless system containing one or more of the features described herein.

DESCRIPTION OF DRAWINGS

In general, the figures depict the construction of the various elements of the liner-bulkhead-corner bag system of the invention including alternative packaging systems therefor. The figures also illustrate the self installation of a liner with alternative attachment means therefor. Certain figures are included to show the fully installed liner-bulkhead systems within containers. Finally, figures are included which illustrate the unloading of cargo from a liner within a container. Although not depicted in the figures to follow, it will be understood by those of skill in the art that certain commonly encountered elements may be used in conjunction with the elements of the invention.
Thus, the elements of the invention will typically be used with containers used in transportation and commerce such as those seen carried on truck beds, rail cars and in vessels. In some instances, these means of conveyance will include means for tilting the container for unloading of the contents therein. It will be readily apparent from the disclosure herein that the elements of the invention may be used to advantage in such containers. It will also be readily apparent that certain modifications of the current invention may be necessary to accommodate the variety of container systems available. These modifications are, as will be apparent to one of skill in the art, intended to be included within the scope of the claims of the present invention.
Turning first to the construction of the various elements of the invention, Fig. 1 shows construction of a self-installing liner system which comprises an appropriately sized tubular section 12 with upper panel 16, side panels 14 and 20 and lower panel 18. Panel construction is selected in accordance with the specifications of the container in which the liner is to be used and dimensions of such panels generally conform to the internal dimensions of the container. Materials generally used for construction of tubular sections such as 12 include polyethylene but may also include in special circumstances vinyl film or plastic-coated fabric. Tubular section 12 is further provided at the front open end 21 and again at the rear open end 19 with flared lip members 22 and 24, respectively, along each of the four panels 14, 16, 18, 20 of tubular section 12.
Tubular section 12 is also provide with an aperture 26 to which is attached a tubular conduit 28. Tubular conduit 28 is typically constructed of polyethylene, vinyl film, plastic-coated fabric and extends from the aperture 28 near the front open end 21 along the entire length of tubular section 12 and sufficiently past rear open end 19 of tubular section 12 to allow facile access to end 30 of the tubular conduit 28 for applying a source of inflating gas or liquid.
Preferably, corner bags to facilitate unloading as described herein are placed inside the tubular section. Construction of such corner pieces is described more fully below in conjunction with Fig. 2A and B, but attachment of the corner bags to the inside corners 23 and 25 is accomplished to provide corner bags 34 and 36 with an airtight seal against the walls of the tubular section 12. Corner bags 34 and 36 are further fitted with inflation tubes 38 and 40, respectively, to provide a means of inflating and deflating the respective corner bags.
End panels 32 and 42 are provided for fixed attachment in an airtight manner to the open ends 19 and 21 of tubular section 12. The rear panel 42 is typically provided with a number of apertures and sleeves to facilitate access to the interior of the liner. Selection of the numbers, sizes and placements of the various apertures is dependent upon the type of cargo and container to be transported. However, most uses will require apertured sleeves for loading and venting such as sleeves 46 attached near the upper edge of rear panel 42. These sleeves are typically selected to fit standard sized loading and venting equipment well known to those of skill in the art of container liner construction. Similarly, apertured sleeves for unloading such as sleeves 44 will be attached near the lower edge of rear panel 42. In some cases, more than one sleeve will be provided (as here), while in others only a single unloading sleeve will be provided (as in Fig.3 below). Numbers, sizes and placement of such sleeves are again dependent upon the job to be accomplished. Other apertures and fixtures may be provided in the rear panel 42 such as apertures 41 and 43 for access to inflation tubes 38 and 40, respectively, of corner bags 34 and 36, respectively. Fixtures such as loops, straps, hooks, ropes, nailing boards, adhesive straps, reinforcing strips and the like (not shown in this figure) may be attached to the end panels as needed.
End panels such as 32 and 42 are typically constructed from polyethylene, vinyl film or plastic-coated fabric. In preferred aspects, the rear panel 42, at least, will be constructed of sufficiently transparent materials to allow viewing of the interior of the liner. In a finishing step, end panels 32 and 42 are attached in an airtight manner to tubular section 12 along flared lips 22 and 24, respectively. The self-installing liner of Fig. 1 is depicted in a completed state in Fig. 3.
Figures 2A and B show construction of a corner bag. In Fig. 2A, two workpieces 48 and 50 are shown which are attached as follows to produce the space-filling corner bag depicted in Fig. 2B. Workpiece 48 is an isosceles triangular piece which may be fashioned from polyethylene, vinyl film, plastic-coated fabric or similar materials. Workpiece 48 has equilateral sides 54 and 56 forming an edge at their intersection whose position 61 above the base of the triangular workpiece coincides with a point 59 which transects the base of the workpiece 48 into two equal sections 58 and 60. Workpiece 48 is further provided an aperture 52 in the upper corner near the point at which sides 54 and 56 intersect. Workpiece 50 in Fig. 2A is an isosceles triangular workpiece of similar material to workpiece 48 and has equilateral sides 62 and 64, and a base side 66.
The following pairwise sides are attached one to the other to form airtight seals: section 60 is attached to side 62 to form side 76 of Fig. 2B; side 58 is attached to side 64 to form side 74 of Fig. 2B. The resulting space-filling, tetrahedrally-shaped bag 80 comprises an open face 68 opposite a right triangular corner 72. The open face of the tetrahedral bag may be attached to a third workpiece matching the first two to produce a freestanding closed bag; or the open face may be attached in an airtight manner to a surface of a liner as shown in Fig. 1. In either case, a final installation of an inflation tube 70 attached at aperture 52 completes the construction.
Figure 3 is an isometric view of a completed liner system. Tubular section 12 comprising side panels 14, 16, 18 and 20 is attached to rear panel 42 and front panel 32. Inflation tube 28 is attached to aperture 26 and extends past rear end panel 42 to end 30. Rear end panel 42 is fitted with upper loading and venting sleeves 46, lower unloading sleeve 44, inflation tubes 38 and 40 providing inflatable access to corner bags 34 and 36, respectively. Inflation tubes 38 and 40 are fitted with a standardized valved tube 37 for fitted attachment to standard sized nozzle 35 providing means for delivering the inflating gas or liquid 33 into the corner bag. Rear end panel 42 is further fitted with hanging straps 88 and 90. Front end panel 32 is further fitted with hanging means including nailing board 82 and hanging straps 84 and 86. Lower attachment means 92 are also provided and may consist of a nailing board, an adhesive strip, or a means of attachment as shown in Fig. 7.
The completed liner as shown in Fig. 3 may be deflated and folded to facilitate inflation and unfolding. Furthermore, it is possible with a liner folded in such a manner, to easily package the liner with other elements such as bulkheads, support members, attachment members, and the like.
Figs. 4A-C are isometric views of rigid, transparent bulkheads of the invention. Fig. 4A depicts a bulkhead 94 the length dimension of which corresponds to the dimension required to approximately span the rear opening of a container. Bulkhead 94 is constructed of a rigid and transparent material according to the details provided in the disclosure above. In this case, a 90 degree bend at 98 is induced in the bulkhead material which causes a horizontal return panel 96 to horizontally return in the direction of the interior of the container. Vertical bulkhead panel 95 and horizontal return panel 96 are contiguous and preferably formed of the same initial workpiece. An aperture 100 is provided in bulkhead panel 95 which is closeable by door 102 hinged to horizontal return panel 96 by hinges 104. Other apertures may be provided in vertical bulkhead panel 95, where necessary, such as for inflation tubes providing inflatable access to corner members (not shown).
In Fig. 4B, bulkhead 106 provides similar aperture 100 closeable by door 102 hinged to horizontal panel 108 by hinges 104. However, in this embodiment, bulkhead panels 107 and 108, while adhesively made contiguous one to the other, are not constructed of the same workpiece bent to produce a 90 degree return at point 98.
In Fig. 4C, rigid bulkhead 111 comprises a rigid and transparent vertical panel member 109 and a flexible sheet material 110 adhesively attached thereto to provide the horizontal return panel. Aperture 100 in panel 109 is similarly closeable by door 102. However, in this embodiment, hinged attachment of the door to the bulkhead is achieved through adhesive attachment to flexible sheet material 110 along joint 112. A partial sectional end view of the bulkhead depicted in Fig. 4C is shown in Fig. 4D.
Figure 5 is a partially exploded view of a liner apparatus packaging system. A packaged bulkhead, liner and bracing unit 114 is illustrated which is insertable into a 6-paneled package 116. Bulkhead 118 serves as a base upon which bracing members 126, 128, 130, 136 and 138 immediately rest. On either side of the bulkhead are placed additional bracing members 122 and 134. The overall height of the bulkhead combined with the width of each of members 122 and 134 establish the minimum width of the package member along panels 148 and 150. End cap members 140 and 142, the height of each being equal to the height of the bracing members 122 and 134, establish a minimum depth for the package member 116. Deflated and folded liner 120 is placed in the receptacle formed by the bulkhead and bracing members and is additionally retained by bracing members 124 and 132. The entire unit 114 is then placed inside package member 116, which package member includes side panels 144 and 148, end panels 146 and 150, bottom panel 146 and top panel 152. Package member 116 may be constructed of any suitable material such as scored corrugated paper sheet. Top panel 152 is closeable to seal the contents of the package member.
Figure 6A-D are stepwise, isometric views of a phantom container showing the stepwise self-installation of a liner within the container. Turning to Fig. 6A, a deflated and coiled or folded, self-installing liner 168 is placed inside a container 154 depicted here in phantom with top wall 156, side walls 158 and 162, bottom wall 160, front wall 164 and rear wall 166 (as described herein, preferably comprising right and left hand doors for gaining access to the container). Initial placement of liner 168 is near the front wall 164. Liner 168 is partially unfolded to expose top edge attachment devices, such as, nailing board 170 and hanging straps 174 and 175, as well as bottom edge attachment device 172. The attachment devices are provided on the outer face of the front panel of liner 168 as shown in previous figures.
As shown in Figs. 6A-D, liner 168 is configured, upon inflation, to fill the container 154. Thus, the liner 168 has end walls, side walls, top wall and bottom wall formed in a manner to fit within container 168.
As a second step, shown in Fig. 6B, the bottom edge attachment device is attached to the frontmost corner at the junction of container rear wall 164 and bottom wall 160. Similarly, top edge attachment devices are attached to the frontmost corner at the junction of container rear wall 164 and top wall 156. These attachments result in the front panel of liner 168 being fully extended in close proximity to container front wall 164. Furthermore, as can be seen in the Fig. 6B, attachment results in a further partial unfolding of the liner 168 to expose aperture 182 and inflation tube 180. Inflation tube 180 is then fully extended from the front of the container to a point outside the container past the rear wall thereof to facilitate inflation of the self-installing liner through inflation tube end 184.
In Fig. 6C, it can be seen that bulkhead 190 has been installed using structural support members (bracing) 192. Inflation tube end 184 serves as a means for passing air via inflation tube 180 and into the self-installing liner 168 at aperture 182 (air flow shown here as arrows from end 184 toward aperture 182). Inflation tube end 184 is also shown to extend past the bulkhead 190 and structural support members 192 past rear wall 158 of the container 154. As can be seen in the figure, as air passes into liner 168, further unfolding occurs causing the liner to fill the space delimited by the container walls in a manner progressing from frontmost container space to rearmost container space. Inasmuch as liner 168 does so occupy the space within container 154, inflation tube 180 becomes increasingly constricted between the liner's upper panel and the container's upper wall as shown between point 186 along the container's top wall 156 and point 188 along the liner's upper panel. The constriction so produced is designed to allow complete inflation and self-installation of the liner; however, the constriction also serves to eventually seal off air flow from inside the container back along the inflation tube which would result in deflation.
Turning now to Fig. 6D, it can be seen that the self-installing liner 168 fully occupies the container 154 interior space fully exposing liner top panel 194, side panels 196 and 200, bottom panel 200, front panel 202 and rear panel 204. The fully exposed liner panels conform in general to the interior space and dimensions of container 154. Along rear panel 204, the liner is contained by bulkhead 190 and support bracing 192. Full exposure of rear panel 204 further provides access to the loading sleeve 206, venting sleeve 208, unloading sleeve 210, corner bag inflation tube 212 (attached to corner bag 222), and corner bag inflation tube 218 (attached to corner bag 220). In this particular construction access for inflation tube 212 and for unloading sleeve 210 is provided through bulkhead 190. Unloading sleeve 210, for instance, is directed from inside the container spaces through aperture 214 in bulkhead 190 after opening the hinged door member 216. It is expected that both the bulkhead and the bracing members will be adjusted accordingly to provide access to all such sleeves and tubes as required. At a time just prior to full inflation, the nearly inflated liner may be adjusted to fit the container space by means of hanging straps near the top edge of rear panel 204 (not shown here).
Figure 7A-C are stepwise isometric views, partially sectioned, showing an alternative packaging and attachment system used in conjunction with the self-installing liner. Fig. 7A illustrates a fragment of an alternative packaging and attachment means 224 containing bulkhead 226 and self-installing liner 228. Package 224 may be constructed out of any suitable material such as scored corrugated paper sheet material or the like.
Package 224 is introduced into a container as depicted by the arrow, and placed in the forwardmost corner at the junction of front container wall 230 and bottom container wall 232. As can be seen, the length of package 224 corresponds approximately to the width of the container. Box sealing tape 240 is removed from an outer surface of package 224 thereby allowing panels 234 and 236 to swing freely through an arc of at least 90 degrees and expose the interior of package 224. The bulkhead 226 is removed from the package 224 and placed aside for installation near the rear of the container as described previously. Adhesive-backed release tape (for example, those tapes shown being removed at 242 and 244), which completely covers the surfaces of panels 234, 236 and 238, is removed to expose the adhesive coated surfaces of the panels.
Panel 234 with adhesive outer surface 246 is brought into contact with the inner surface of container front wall 230 and adhesively attached thereto. Similarly, panels 236 and 238 with adhesive outer surfaces 248 and 247, respectively, are brought into contact with the inner surface of container bottom wall 232 and adhesively attached thereto. Front panel 250 of liner 228 is next attached by means of nailing board 252 or hanging straps (such as 254) as previously described. Self-installation of the liner may then proceed as described in Fig. 6.
Figure 8 is an isometric, partially sectioned view of a self-installing liner with corner bags, transparent bulkhead and structural support members installed within a container. In the view provided here more detail is shown concerning the positioning of the self-installing liner and the viewability of the internal portions of the liner and container space through the transparent bulkhead and liner. Container 256 typifies the containers used to ship bulk cargo and includes rear doors of which only the left door 257 is shown in this view for simplicity. Liner 258 is shown fully inflated but not loaded with cargo. Inflation of the liner and the self-installation that results was achieved as described before by attaching a source of forced air to inflation tube end 278 and directing air flow through inflation tube 266 and into the interior portions of the liner via aperture 264. When fully inflated in this manner, the pinching or collapsing of inflation tube 266 serves to seal air inside the inflated container. Liner rear panel 259 can be seen to be contacting the horizontal structural support members such as 272 which are in turn spaced conveniently by interval attachment to vertical structural support member 274. Spacing of the structural support members may be adjusted to accommodate attachments to the rear liner panel 259 such as for loading sleeve 286, venting sleeve 284 or inflation tube 266.
As illustrated, internal portions of both the liner and the container space are visible through both the rear liner panel 259 and the transparent bulkhead 270. The view is possible even through both the bulkhead 270 and the liner at position 268. This degree of viewability which encompasses virtually all of the interior portions of the liner and container is an important aspect of the invention. Access 276 is provided in the bulkhead 270 for unloading sleeve 280. Importantly, it is possible to see the corner bag 288 (shown here in a deflated condition) through the bulkhead 270 and liner rear panel at position 268. This ability becomes crucial when using the corner bag to unload residual cargo on the corners after gravity flow unloading.
Another important aspect of the liner-bulkhead design of the current invention is the manner in which the bulkhead and support members prevent the load exerted by the cargo within the liner from being directly transferred to the rear doors. Spacing 282 between the rear door 259 and any element of the bulkhead, structural support members or liner is provided to help insure no portion of the bulkhead liner system transfers a load directly to the rear doors. As will be shown in Fig. 9 to follow, all load is transferred via the bulkhead and bracing to the container at a position forward of the rear door posts of the container (not shown here).
Figure 9 is a partially sectioned, side and partial top view of a transparent bulkhead installed within a container with structural support members, corner bags and liner visible. As one opens rear doors 302, it is apparent that there is spacing 300 between the rear doors 302 and the structural support members 296 (vertical) and other support members such as 298 (horizontal). Through the bracing as well as through the transparent bulkhead 294 liner 292 is visible. The contents and space within the liner 292 as well as within the container 290 are visible through both liner rear panel and bulkhead. Corner bag 295 is visible as well.
A partial top view of the positioning of the bracing, bulkhead and liner is also provided in Fig. 9. Container 290, typical of commercially used containers, possesses along its interior wall, intervally spaced stiffening members 304, 306 and 308, which serve to stiffen the walls of the container. In many cases, the stiffening member 304 nearest the rear doors may also serve as a door post for attachment of the door hinges. Horizontal structural support members such as 298 are intervally spaced along vertical structural support members such as 296, and are inserted into the channel 310 formed by stiffening members 304 and 306 nearest the rear doors. Bulkhead 294 and liner 292, when cargo is loaded within, transfer the cargo load through horizontal structural support members such as 298 to the container wall via the stiffening member 304.
Figures 10A-D are stepwise schematic views of the unloading of a filled container-liner system showing the use of corner bag members. The container and/or the liner 312, each includes a top wall 316, side walls 314 and 318, bottom wall 320, front wall 322 and rear wall 324 as shown in Fig. 10A. The liner and container are shown previously loaded in the manner and methods described herein with a flowable cargo 326. While the container and liner are maintained in a level position, cargo 326 has been allowed to establish a natural line of repose 328 by flowing out of port 330. The port 330 is offset toward the right side of the rear wall 324 in order to, for instance, allow access to the unloading port by opening only a single one of the container rear doors. Shown in Fig. 10A, as well, are deflated corner bags 332 and 334.
Turning next to Fig. 10B, after the line of repose 328 has been obtained through gravity flow with the container level, the container is typically elevated such that the front wall at position 336 is substantially higher than the rear wall at position 338. This provides for most of the remaining cargo 326 to exit the liner and container through port 330. However, as shown, typically there is a residual amount of cargo, 340 and 342, retained in either lower corner nearest the port 330.
As shown in Fig. 10C, corner bags 348 and 350, partially inflated, have begun to empty residual cargo 344 and 346 through port 330. Fig. 10D shows corner bags 348 and 350 fully inflated and all cargo removed from the container.
Referring now to Figure 11 (in conjunction with the numbering in Figure 1) is an exploded, isometric view of a liner system embodiment of the present invention containing a means for fluidizing the bulk cargo contained within the liner to facilitate its removal from the liner during the unloading process. Referring also to Figure 12 (in conjunction with the numbering in Figure 3), the means for fluidizing the bulk cargo is accomplished by a fluid impervious plenum adjacent the floor of the liner, the plenum corresponding to an area of the floor of the liner and having a plurality of spaced apart perforations for directing a fluid from the plenum into the interior space. The fluid impervious plenum is created by inserting or attaching a fluidizing pad or bed 360 within the interior tubular section 12 of the liner, preferably along the bottom or lower horizontal panel 18 of the liner. The outer edges 364 of the fluidizing pad 360 are welded with heat or other known means, to the interior of the liner in the desired location, such as along the seams where the side panels 14 and 20, and the front panel 32 and the rear panel 42 meet the lower panel 18 such that a plenum or chamber is formed between the fluidizing pad 360 and the liner bottom panel 18. The fluidizing pad 360 preferably contains a plurality of fluidizing jets, or perforations 362 capable of directing sufficient jet flow into the liner to fluidize the contents of the liner. The fluidizing pad 360 can be constructed out of the same material used for the liner, such as a polyethylene material, that has been modified to contain the perforations 362. In a preferred embodiment, the fluidizing jets are energized by the introduction of air through the jets. However, other gases, preferably inert, or mixtures thereof, may be employed to advantageously energize the jets, if desired. The fluidizing pad preferably contains at least one inflation tube, or plenum inlet port 364 to introduce the air or gas source to the fluidizing pad. The inflation tube 364 is preferably sufficiently rigid and self-supporting so that it will not collapse if it is located under the weight of a liner filled with the bulk commodity. Fluidizing pads can be installed along the interior vertical sides of the liner, if desired.
It is anticipated that the plenum could also be positioned beneath the floor of the liner, in which case, the perforations would be provided in the floor of the liner 18 in registry with the perforations in the fluidization pad 360.
In another alternate preferred embodiment, a means for agitating the liner bag to facilitate the discharge of the bulk cargo contained in the liner is created by attaching a fluidizing pad, such as that mentioned above, beneath the liner bag, such that the fluidizing jets are directed to toward the container. An air source is applied to the agitation pad in an oscillating or pulsating fashion to agitate the liner bag thereby dislodging residual bulk material present in the interior of the liner. This agitation means can be used alone or in combination with the fluidization means.
Referring again Figures 10A-D, the unloading of a phantom container-liner system employing corner air bag members would be enhanced with the use of a fluidizing pad. The liner, corner air bags, plenum, liner unloading port and plenum inlet cooperate to create a fluidized bed of material in the interior space when fluid is supplied to the plenum inlet to facilitate unloading of the material through the liner outlet. In this embodiment, the plenum is preferably positioned inside the liner floor.
Referring now to Figures 13A, 14A, 14B, and 14C, there is disclosed an isometric view of a braceless modular bulk cargo container liner system 370. In this preferred embodiment, the modular cargo container liner system 370 includes a lightweight, reusable and/or recyclable bulkhead liner cartridge 380 having a recessed storage area 390 containing a liner 416 in a folded or stored position. A removable or openable flap 418 capable of covering the recessed liner storage area is provided on the bulkhead liner cartridge to protect the liner prior to installation into a container. The bulkhead liner cartridge also preferably contains at least one port or other means of accessing the interior of the liner, such as a venting port 392 or filling port 394. This port may comprise a flexible tube or the like for venting the liner or for filling the liner with a cargo. The liner 416 is preferably transparent in that it is either transparent or sufficiently translucent to enable a viewer to view the extent or disposition of cargo within the liner. The liner is also configured such that, upon inflation, it fills substantially an entire cargo container. The liner utilized in the braceless modular system can be of any type, such as the liner preferably outfitted with inflatable angle corner bags, and/or a fluidizing pad as described herein.
The braceless modular container liner system also includes a lightweight, reusable and/or recyclable bulkhead base cartridge 396 for receiving the liner cartridge 380. In this embodiment, the liner cartridge is preferably telescopingly attached to the bulkhead base unit by tape, adhesive, or other means of attachment 398. The base is constructed using a novel, lightweight, interlocking internal cell matrix (shown later) that is covered by an outer layer, and may also include an observation port or cabinet 400 for the cargo area, and a built-in sample storage area which could also be located in the cabinet. The sample storage area is preferably constructed of sufficient size to accommodate a small, self contained sample of the cargo contents, or is constructed as part of the observation port to allow access to a recloseable sample sleeve attached directly to the liner. The base unit also contains a discharge port 402. Additionally, the base unit is preferably equiped with a panel 412 that covers the base during shipment to the end user. The panel 412 can then be folded down along bottom seam 414 and placed on the container floor during installation. A double sided-adhesive strip 420, with peel off cover can be added to the outside of the panel such that the tape can function to help anchor the panel to the container floor. Additionally, the weight of the bulk commodity placed in the liner will also help anchor the panel to the floor.
Figures 13B and 13C show isometric views of a liner unloading sleeve embodiments, in a gussetted 408 and non-gussetted 404 configuration, such as might be employed in conjunction with the discharge or unloading port 402 of a bulkhead 406. The sleeves 404 and 408 can be advantageously modified by adding a recloseable access port 410, preferably along a seam, so that access to the liner bladder can be facilitated without having to disconnect the exits end of the sleeves 404 or 208 from the unloading equipment (not shown). The means for reclosure can be accomplished using standard reclosure devices, such as a "ZipLok"-style closure.
Referring now to Figure 14D, in another alternative preferred embodiment, the braceless cargo liner system 430 is configured as an integrated unit containing both the bulkhead base unit 432 and the liner cartridge unit 434. In this embodiment, the bulkhead includes a recessed storage area 436 for containing the liner (not shown) prior to installation in the container. The system is configured with the filling, venting, discharge, sample and/or observation ports, such as those described in conjunction with Figures 13A, 14A, 14B, and 14C. Additionally, the system 430 is preferably equiped with a panel 436 that covers the system 430 during shipment to the end user. The panel 436 can then be folded down along bottom seam 414 and placed on the container floor during installation. A double sided-adhesive strip 438, with peel off cover can be added to the outside of the panel such that the tape can function to help anchor the panel to the container floor. Additionally, the weight of the bulk commodity placed in the liner will also help anchor the panel to the floor..
The braceless liner system is positioned or otherwise arranged within a container with its filling port toward the front end of the container. The protective panel(s) is opened to expose the polyethylene liner which is then extended and secured to the front of the container. The braceless bulkhead is uprighted and positioned at the container's threshold proximate the container doors. The bulkhead extends across the container and preferably to a height sufficient to rest behind the upper horizontal cross brace of the container, although shorter hieghts are acheivable. The remainder of the bulkhead rests against the left hand door. Positioning guides, such as those described later, can by employed to advantage to facilitate placement of the liner system proximate the rear doors. Use of the positioning guides on the right hand side of the container facilitates allignment of the bulkhead during the loading phase to ensure that the right door will have proper clearance for closing, and to prevent the bulkhead from falling over during loading, such as may occur due to the arrival of an unexpected gust of wind. As air or other suitable gas is passed into the liner through the filling port, the liner inflates and ultimately fills the container. A flowable cargo is then passed through the filling port into the liner. The liner is ultimately sealed.
Referring now to Figure 15A, there is shown a cross-sectional view of an exemplary bulkhead base 474 having a core cell matrix such as that employed in the base sections of the braceless liner embodiments, i.e., across lines 1-1 of figures 14D. 14C or 13A. In this preferred embodiment, the cell matrix or core 440 is preferrably constructed using a single piece of solid fibre, reinforced corrugated fibreboard, such as that manufactured under the trademark "Gaywood" by Gaylord Packaging, Inc., Bogalusa, Mississippi. The core sheet starting material is preferentially 600 # test double wall Gaywood which is scored (and/or reverse scored) on one or more sides of the core sheet 440, and then folded at the score marks, such as indicated at 440, 442, 446, 448, 450, 452, 454 ,456, 458, and 460. The top distance 466 between the top edge 462 and the score/fold 442 is preferrably about 4 inches, but can be modified according to the bulkhead size requirements. The bottom distance 468 between the bottom edge 464 and score/fold 460 is substantially the same as distance 466. The scored/folded core 440 is fixable attached to an outer panel 470 and an inner panel 472 and capped with perimeter caps (such as described in figures 15B and 15C) around all edges. The resultant bulkhead 474 is a sealed unit containing cavities, apertures or void spaces 476. The width of the bulkhead 474 is preferentially about the same width of the container. The height 480 of the bulkhead 474 can be varied, but is preferrably about 60 inches, which would allow for the creation of about four void spaces. The outer panel 470, is preferably constructed from a 350 # test double wall corrugated paper or fibre, or the like, while the inner panel 472 is preferrably constructed from a 350 # test single wall corrugated paper or fibre, or the like. Referring now to Figure 15C, there is shown a cross section of the perimeter cap 482 which is preferably constructed from an elongated, rectangular piece of Gaywood, double wall fibreboard or the like 484 fixably or adhesively covered on three sides by an overlapping fibre paper or .120 fibre board previsously scored at locations 486, such that overlap flaps 488 can slip over and be attached to the outside of the panels 470 and 474. The bulkhead can then be modified to include the various ports required by the end user. For example, where an inflatable air bag is employed, the air inflation tubes can be routed througth the void spaces of channels 476 created within the bulkhead. Additionally, the uppermost large void space 476, as defined by scores 442, 444, 446 and 448 could be employed as the liner cartridge compartment if desired.
Another preferred embodiment pertains to a bulkhead for a cargo container, the container having opposing side walls, a top, and a floor, and an opening in one wall defining a doorway, the bulkhead comprising: a first panel defining a back wall having a first width; a second panel defining a front wall having a second width, the second panel being spaced apart from and substantially parallel to the first panel, the first and the second widths being substantially the same; a plurality of beams arranged side-by-side between the first and the second panels, each of the beams defining a zone within the bulkhead having a quadrilateral cross-section and having a length corresponding generally to the first and the second widths; the first panel, the second panel, and the plurality of beams being cooperable when the bulkhead is positioned across the doorway to resist forces at the doorway of the cargo container when the cargo container contains a flowable load. The first and second widths of the bulkhead preferentially correspond generally to a width of the doorway of the cargo container. The first and second panels are preferentially constructed from corrugated paper. Some of the beams comprise a single panel of corrugated paper scored with parallel score lines and folded at the score lines. In another embodiment, some of the score lines are on a first side of the single panel and other of the score lines are on a side opposite the first side of the single panel. In yet another embodiment, half the score lines are on the first side of the single panel and half of the score lines are on the side opposite the first side of the single panel to define a beam having a member extending across a diagonal of a rectangular cross section. Some of the beams interlock along a side with adjacent beams to define a laminated beam seam. The laminated beam seam preferentially includes an adhesive and can include a shim to define an additional layer of laminate in the beam seam. The plurality of beams are preferentially parallel to the floor of the cargo container. The bulkhead can also be outfitted to further include a liner compartment in the bulkhead that is operable to contain a liner when the bulkhead is transported.
In another preferred embodiment, the liner compartment comprises an upper portion of the bulkhead that is detachable from and replaceable on the remaining portion of the bulkhead. The liner compartment can be telescopingly carried by the bulkhead.
A bulkhead for a cargo container, the container having opposing side walls, a top, and a floor, and an opening in one wall defining a doorway, the bulkhead comprising: a first panel defining a back wall having a first width; a second panel defining a front wall having a second width, the second panel being spaced apart from and substantially parallel to the first panel, the first and the second widths being substantially the same; a plurality of laminated beams having a length corresponding generally to the first and the second widths, the beams comprising at least four layers of corrugated paper and an adhesive, the plurality of beams arranged in substantially parallel relationship to each other and positioned between the first and the second panels; an adhesive for connecting the first and the second panels to the laminated beams; the first panel, the second panel, and the plurality of beams being cooperable to define a bulkhead for resisting the forces of a flowable load in the cargo container when the bulkhead is positioned in the doorway.
In a preferred embodiment, the laminated beams are comprised of a plurality of side-by-side beams that are interlocked along an edge.Some of the beams comprise a single panel of corrugated paper scored with parallel score lines and folded at the score lines. Alternatively, some of the score lines may be on a first side of the single panel and other of the score lines are on a side opposite the first side of the single panel. in another preferred embodiment, the score lines are on the first side of the single panel and half of the score lines are on the side opposite the first side of the single panel to define a beam having a substantially rectangular cross section and a member extending across a diagonal of the rectangular cross section. The bulkhead of this embodiment can preferably include a liner compartment in the bulkhead, the compartment being operable to contain a liner when the bulkhead is transported. In another embodiment, the liner compartment comprises an upper portion of the bulkhead that is detachable from and replaceable on the remaining portion of the bulkhead. The liner compartment can be telescopingly carried by said bulkhead.
Another preferred embodiment pertains to a bulkhead for a cargo container, the container having opposing side walls, a top, and a floor, and an opening in one wall defining a doorway, the bulkhead comprising: a first panel defining a back bulkhead wall having a first width; a second panel defining a front bulkhead wall having a second width, the second panel being spaced apart from and substantially parallel to the first panel, the first and the second widths being substantially the same; a plurality of beams placed side-by-side between the first and the second panels, each of the beams having a substantially rectangular cross-section and having a length corresponding generally to the first and the second widths; a liner for the cargo container, the liner having opposing side walls, a top, and a floor corresponding to the opposing side walls, top, and floor of the container, the liner being attached to the bulkhead. The bulkhead can be adapted to include a cabinet accessible from at least one of the first and the second panels. The cabinet can comprises a flange, an open ended member corresponding generally in height to the spacing between the first and the second panels and attached to the flange, and a collar for attachment to the open ended member at a location spaced apart from the flange, the flange resting on one panel, the collar resting on the other panel, and the open ended member positioned therebetween. The bulkhead can also be modified to include a port in the cabinet for placing the cabinet in fluid communication with an interior of at least one of the beams.
Preferrably, the first and second widths of teh bulkhead correspond generally to a width of the doorway of the cargo container. The first and second panels opf the bulkhead preferably comprise corrugated paper. Some of the beams comprise a single panel of corrugated paper scored with parallel score lines and folded at the score lines. Some of the score lines can be are on a first side of the single panel and other of the score lines are on a side opposite the first side of the single panel. Also, in another embodiment, half the score lines are on the first side of the the single panel and half of the score lines are on the side opposite the first side of the single panel to define a beam having a member extending across a diagonal of the rectangular cross section. The bulkhead of this embodiment may have some of the beams interlocking along a side with adjacent beams to define a laminated beam seam. The laminated beam seam may comprise an adhesive or a shim to define an additional layer of laminate in said beam seam. The plurality of beams are parallel to the floor of the cargo container. The bulkhead can further include a liner compartment in the bulkhead, the compartment being operable to contain the liner when the bulkhead is transported. The liner compartment can comprise an upper portion of the bulkhead that is detachable from and replaceable on the remaining portion of the bulkhead. The liner compartment can be telescopingly carried by the bulkhead.
Referring now to Figure 16, there is shown a preferred braceless cargo liner embodiment 500 of the instant invention. In this embodiment the bulkhead comprises a first panel 502 defining back bulk headwall having has a first width, a second panel 506 having a second width, the second panel being spaced apart from and substantially parallel to the first panel, the first and the second widths being substantially the same. This bulkhead also comprises a plurality of beams 508 having a substantially rectangular cross-section and having a length corresponding generally to the first and the second widths. In this embodiment there is shown a recessed aperture 510 in the backside of the bulkhead capable of containing a liner 512 for the cargo container. The liner 512 can be stored in the aperture 510, or can be first placed into a liner cartridge 514 that is inserted into the aperture 510. Either the aperture 510 or the liner cartridge 514 can also contain other fixtures and accessories 516 necessary for installing the liner in the cargo container, such as nailing boards, hanging straps and the like. Also in a preferred embodiment, the liner cartridge 514 is fixably mounted within the aperture 510 by using hand puppets 518 that puncture through the lower wall of the liner cartridge 514 and into the lower portion of the aperture 510 as shown at positions 520. Alternatively, adhesives can be applied to attach the cartridge 514 within the aperture 510. Also shown in Figure 16 is the outer cover panel 522 which serves to cover the entire back surface of the bulkhead 500 during shipment. The cover panel is preferentially attached to the lower most beam 508 and is scored and folded at line number 524 to allow it to swing down and make contact with the bottom floor of the container. Double-sided adhesive tape 526 can be applied to the backside of the outer cover panel 522 to promote friction between the cover panel 522 and the container floor 528. In an alternative preferred embodiment, the liner cartridge comprises the top section 530 of the bulkhead 506 and is removable and attachable to the bulkhead.
Referring now to Figure 17A, there is shown an exploded cross-sectional view of the plurality of beams 540 contained within the outer wall 542 and the inner wall 544 of the braceless bulkhead 546. Also shown is outer cover panel 548. As constructed, the beams 540 contain internal void space 571 which can be utilized to route necessary air tubing and the like for operation of the bulkhead liner.
Figure 17B shows an enlarged view of two bulkhead beam cross-sections 540 in interlocking relationship with one another. Referring to the left most beam of Figure 17B, the beam is created by taking a core material such as gaywood fiberboard 550 and scored (and/or reverse scored) one one or more sides of the gaywood fiberboard 550, such as shown at score/folds 552, 554, 556, 558, 560 and 562. The thus scored and folded beam can be interlocked with an adjacent beam as illustrated in Figure 17B. The beams can also be attached to one another by using adhesives and can be reinforced by affixing one or more shims 564 within the interlocking zone 556. In a preferred embodiment the outer cover panel 548 comprises a 275 # test single wall with a B flute fiberboard. The inner bulkhead wall 544 is preferably constructed of a 275 # test single wall B flute fiberboard. The bulkhead beams 540 are preferably constructed from a 525 # double wall gaywood type material with an AC flute. Also the bulkhead outer wall 542 is preferably constructed from a 275 # single wall fiberboard. As shown in Figure 17A, a liner cartridge or liner recess area 570 is provided to house a liner bag. As in evident from Figure 17A, the liner cartridge or liner recess area 570 can be interlocked with a bulkhead beam and secured thereto.
Referring now to Figure 18, there is shown a schematic depiction of a one piece braceless bulkhead design installed in a container. The bulkhead 580 has been equiped with a filling port 582 and a venting port 584. Also shown in Figure 18 is a discharge port 586 which can contain within its inner boundaries an aperture 588 for receiving the air inflation tube 590 utilized for filling the left hand corner air bag 592. A similar access port 594 can be installed in the right lower corner of the bulkhead for accessing the inflation tube 596 of the right hand corner air bag 598. The bulkhead cover drop panel 600 is shown in its installed position along the floor of the container. An adhesive layer 602 can be utilized to secure the bulkhead to the floor to prevent the bulkhead from sliding out when loaded. Also shown in Figure 18 is a sample view port or sample storage area 604 for providing access to the sample tube 606 tht may be attached directly to the liner bag 608. Alternatively, samples can be stored in small containers that fit within the view port access area 604. Additionally, view port access 604 can be equipped with an aperture for receiving the corner air bag inflation tubes, if so desired.
Referring now to Figure 19, there is disclosed a braceless liner embodiment similar to the one piece design described in conjunction with Figure 18 except having a two piece design. The lower base bulkhead unit 610 is adapted to receive a liner cartridge 612.
Referring now to Figure 20, there is shown a bulkhead view port cabinet 620 for installation into a bulkhead (not shown) such as the braceless bulkheads depicted in Figures 18 and 19. The cabinet 620 comprises a flange 622, an member 624 corresponding generally in heigth to the front and back panels of the braceless bulkhead (not shown). The openended member 624 is attached to the flange 622 and is placed in a cutout within the bulkhead. A collar mechanism 626 is utilized in conjunction with the lip 628 of openended member 624 to create a interference fit thereby securing the cabinet to the bulkhead. Other means for securing the cabinet to the bulkhead will be apparent to those of skill in the art. It is anticipated that adhesives and mechanical couplings can be employed to advantage. The openended member 624 can be adapted to contain at least one aperture 630 to allow fluid connection with the internal void spaces of the bulkhead beams (not shown). The view port/cabinet member 620 allows access to, for example, a reclosable sample tube 632 that is connected to the liner bag 634.
Referring now to Figure 21A, there is shown a schematic view of a bulkhead positioning guide 640 which can be employed in conjunction with the braceless bulkhead depicted in for example, in Figures 18 and 19. The positioning guide 640 contains a channel engaging member 642 for engaging a channel on a side wall of the container. The positioning guide also contains a bulkhead engager 644 for engaging the bulkhead and a connecting web 646 for connecting the channel engager 642 to the bulkhead engager 644. The channel engager 642 preferably has a box-like cross-section having one dimension substantially the same as the depth of a stiffening member on a side wall of the container. In a preferred embodiment, the bulkhead engager engages the bulkhead only along a portion of the width of the bulkhead. In a preferred embodiment of this invention the bulkhead positioning guide 640 is formed out of ten or twelve gauge galvonized steel and has a length 648 of 30 inches, a depth 650 of 1.75 inches, a width 652 of 1.75 inches and a width 654 of 1.5 inches. The bulkhead 660 rests against the surfaces of the connecting web 646 and bulkhead engager 644.
Referring now to Figure 21B, there is also shown a alternative preferred bulkhead positioning guide 670 having a channel engager 672 for engaging a channel on a side wall of the container (not shown); a bulkhead engager 674 for engaging the bulkhead; and a connecting web 676 for connecting the channel engager 672 to the bulkhead engager 676. In this embodiment the bulkhead engager 672 contains a pointed member 678 capable of penetrating a face of the bulkhead. In a preferred embodiment the point 678 has a depth 680 of 1 inch; the bulkhead engager 674 has a depth 682 of 1.5 inches and a width 684 of 3 inches. The channel engager preferably has a depth 682 of 1.75 inches; a height 684 of 1.75 inches and a length 686 of 1.5 inches. The positioning guide 670 is preferably constructed from 1/8 inch flat stock.
Referring again to both Figures 21A and 21B, in a preferred embodiment of the present invention, the positioning guide is magnetic to enhance engagement with the channel of the container wall. In an alternative preferred embodiment, the positioning guide includes an adhesive on the surface contacting the channel of the container wall.
Referring to Figure 22A, there is depicted a cross-sectional top view of a braceless bulkhead 690 employing a positioning guide 640 such as that described in Figure 21A. The channel engager fits within the container channel 692 which typically can be found in most containers adjacent the container stiffening member 694 which is built into the container outer wall 696. In this configuration, the bulkhead 690 is positioned approximate the container rear door 698 by being placed against the bulkhead engager. The bulkhead engager can be modified to contain cleats 700 for enhancing frictional contact between the bulkhead face and the bulkhead engager.
Similar to Figure 22A, there is depicted a braceless bulkhead 690 being positioned adjacent the cargo container rear door by a positioning guide 702 such as that depicted in Figure 21B.
Referring now to Figure 23, there is disclosed a means for securing the outlet or discharge fitting of the liner bag to the retainer 800. The retainer 800 is adapted to receive a fitting 802 having a circular flange portion 804. The retainer 800 is adapted to contain an aperture capable of receiving the flange 804. The fitting 802 and the retainer 800 are drilled with two holes 806 where the holes in the retainer and the fitting are in substantial alignment with each other. A knotted rope is then fitted to the fitting 802 and the plastic liner bag 808 is then adhesively attached to the back side of the fitting 802. Upon isntallation of the liner into the cargo container, the knotted rope can then be passed through the holes 806 in the retainer, and tied off thereby securing the liner bag to the retainer 800. As also illustrated in Figure 23, the retainer 800 can be attached to the floor of the container by employing a series of self-tapping set screws.
In similar fashion, referring now to Figure 24, the liner bag 820 is adhesively attached to the backside of a fitting 802 containing a circular flange 804. The retainer 800 is adapted to receive the flange 804 of the fitting 802 by interference fit or other mechanical means of attachment thereby securing the fitting to the retainer.
The present invention has been described in terms of particular embodiments found or proposed to comprise preferred modes for the practice of the invention.

Claims

The combination of an inflatable liner (168) with a a box-like cargo container (154) having a bottom wall (160), a top (156), two sidewalls, (158, 162), a front end wall (164), and a rear end wall (166) with an access door, said liner comprising:
(a) an inflatable member foldable when deflated into a compact package and when inflated having a floor (18), a top (16), front (42) and back (32) end walls and two sidewalls (14, 20);

(b) a first inlet (46) proximate the back (42) and top (16) of the liner when inflated for loading cargo into the liner;

(c) an outlet (44) proximate the back (42) and floor (18) of the liner when inflated for unloading cargo from the liner through the access door; characterised by

(d) a second inlet (26) proximate the front (32) of the liner for supplying gas to inflate the liner and a compressible conduit (28) connected with said second inlet and of a length to extend along the outer surface of the liner to the back of the liner to end (30) of conduit (28) for connection to a source of inflating medium.
The combination according to claim 1 characterised in that said compressible conduit (28) extends from said second inlet (26) to the rear of the liner, between the top wall of the liner and the top wall of the container, whereby during inflation of the liner within the container, via said conduit (28), the conduit (28) becomes increasingly constricted between the liner and the container as the liner is inflated, to prevent subsequent escape of gas from the liner via said conduit with subsequent deflation of the liner.
The combination of claim 2, further including a bulkhead (190) supported by the container between the liner and said rear end wall (166) of the container and extending upward from and along the floor of the container.
The combination of claim 3 including inflation bags (36) separately inflatable from the liner and positioned at corners formed between the floor of the container and said bulkhead, said bags being so configured that, upon inflation, the bags displace cargo within the liner from such corners.
The combination of claim 2, further including inflation bags (36) inflatable separately from the liner and positioned within the corner between the liner and the container.
The combination of any of claims 2 to 5 wherein the second inlet (26) is located in the liner top wall.
The combination of claim 3 or claim 4 wherein said liner is transparent.
The combination of claim 7 wherein said bulkhead (190) is transparent so as to allow viewing of the cargo during loading, unloading and transport.
The combination of claim 7 wherein the bulkhead has an observation port (400).
The combination of claim 7, 8 or 9 wherein said
bulkhead comprises a first panel (502) defining a back bulkhead wall having a first width;

a second panel (506) defining a front bulkhead wall having a second width, said second panel (506) being spaced apart from and substantially parallel to said first panel (502), said first and said second widths being substantially the same;

a plurality of beams (508) placed side-by-side between said first and said second panels, each of said beams having a length corresponding generally to said first and said second widths, said liner (512) being attached to the bulkhead.
The combination, according to claim 1, including a fluid impervious plenum (360) adjacent the floor of the liner, said plenum corresponding to an area of the floor of the liner and having a plurality of spaced apart perforations (362) for directing a fluid from said plenum into the interior of the liner and
a plenum inlet (364) for introducing a fluid into the plenum.
The combination according to claim 3 including a liner compartment (436) to receive said liner in a folded condition.
The combination according to claim 12 wherein said liner compartment (436) comprises an upper portion of said bulkhead (190) which is detachable from and replaceable on the remaining portion of said bulkhead.