GB2534909A - A cool pack arrangement - Google Patents

Abstract

The invention provides a cool pack arrangement comprising a base cool pack 30 having a plurality of edges 36; and a plurality of side wall cool packs 32 to 35 each arranged to be located on or against a respective edge of the base cool pack 30, wherein the base cool pack 30 has a fill point 37 protruding from one edge and at least one blanking protrusions 38 protruding from at least one other edge in a position along that edge corresponding to the position at which the fill point protrudes from its edge, wherein each side wall cool pack 32 to 35 has a recess 46 in a first edge which, when the side wall cool pack 32 to 35 is located on or against the base cool pack 30 accommodates either the fill point 37 of the base cool pack or a blanking protrusion 38, depending upon which edge of the base cool pack the side wall cool pack 32 to 35 is located on or against. The invention permits two types of cool pack to be assembled into a complete cube (or similar) cool pack layer, which cool packs are located closely together in a manner that the layer of cool packs can act as an efficient barrier to thermal convection currents. The invention may have particular application to passive insulated shipping containers.

Description

A Cool Pack Arrangement The present invention relates to cool packs and particularly, but not exclusively, to a cool pack arrangement for use in a thermally insulated container. The invention has particular application for use in insulated containers, known as passive insulated shippers, which are used to transport products at stabilised temperatures.

It is important that some products, for example certain type of pharmaceuticals or biotech products, are maintained within a specified temperature range, typically 2° to 8°C, to prevent the product from being damaged, or its shelf-life being reduced relative to the shelf-life stated on the product. The product may be a very high value medicine or the like, which will be worthless if its temperature is not correctly controlled. This may be problematic during shipment and use of an insulated shipper will often be necessary to make shipment practicable.

Passive insulated shippers comprise an insulated container comprising an insulated outer casing which is lined with, or houses, a number of cool blocks, cool trays, gel packs, cool bricks or similar, which for the purposes of the present specification are collectively referred to as cool packs. These may be cooled until a phase change occurs in the refrigerant in the cool packs from a liquid to a solid, so that the subsequent phase change back from a solid to a liquid acts to maintain the contents of the container at a constant temperature. Examples of materials which change state from a solid to a liquid to produce a cooling effect, are paraffin wax and water-based solutions.

Although reference above and below is made only to cool packs and the requirement to maintain a product at or below a certain temperature, those packs may also be used to maintain a product above a certain temperature, for example to stop a product freezing if it is being shipped in a cold climate. Thus, although for the purposes of this specification they will be referred to only as cool packs and only the case of keeping the product cool will be discussed, it will be appreciated that the invention is equally applicable to applications where it is desired to maintain the product above a desired temperature and the description and claims are to be interpreted so as not to preclude such an application.

Passive insulated shippers may comprise a container having three layers, an outer insulating layer, typically formed from expanded foam, an inner layer of cool packs and an intervening layer between the outer and inner layers made up of a number of vacuum insulation panels to provide enhanced insulation. The container may further comprise an outer casing to provide protection for the outer insulating layer during transportation and/or an inner lining.

A passive shipper of the type described above therefore has a large number of components which have to be initially assembled. Then, each time the container is used, at least the cool packs will normally have be removed, cooled, and then correctly reassembled in the container, possibly by staff not familiar with that particular container type.

The present inventors have identified that in certain applications, for example in a thermally insulated shipper of the type previously described, it can be advantageous for a cool pack arrangement to form a substantially continuous layer in a container, for example by forming five sides of a cube or similar shape, or six sides where one cool pack also forms a lid. They have further identified that with such an arrangement, if the cool packs are held closely together, so that their edges abut, the cool packs themselves may not only provide a thermal mass, but that they may also improve the thermal efficiency of the container, by forming a physical barrier to convection currents that may otherwise occur within the container. However, it is also desirable that there be a minimum number of cool pack types in an insulated shipper, for the cool packs have to be removed to be cooled prior to a product being shipped in an insulated shipper and therefore the cool packs have to subsequently be quickly and correctly assembled each time the shipper is used and this may present a considerable burden if a single consignment of a product requires a large number of shippers to be charged and dispatched at the same time.

To simplify assembly of the cool packs, each shipper would ideally have six identical square cool packs arranged to form a cube, for in this manner any cool pack could be selected for any of the six sides and each could be correctly positioned in any of eight orientations. However, cool packs, particularly cool blocks, normally have a fill point by which the cool pack is filled with a refrigerant. Due to the construction techniques of cool packs and particularly of cool blocks, the fill point is normally formed on one edge of the cool block. This prevent adjacent edges of cool packs being closely abutted and thus would make it difficult to restrict convection currents between adjacent cool packs, particularly if the edges of the cool packs should be specifically profiled to reduce thermal convection between adjacent edges.

According to the present invention there is provided a cool pack arrangement comprising: a base cool pack having a plurality of edges; and a plurality of side wall cool packs each arranged to be located on or against a respective edge of the base cool pack, wherein the base cool pack has a fill point protruding from one edge and at least one blanking protrusion protruding from at least one other edge in a position along that edge corresponding to the position at which the fill point protrudes from its edge, wherein each side wall cool pack has a recess in a first edge which, when the side wall cool pack is located on or against the base cool pack, accommodates either the fill point of the base cool pack or a blanking protrusion, depending upon which edge of the base cool pack the side wall cool pack is located on or against.

In the cool pack arrangement of the present invention the fill point protruding from one edge of the base cool pack is accommodated in a recess in a first edge of a side wall cool pack. To avoid the requirement to provide a specific additional type of cool pack for this, the present invention provides for multiple side wall cool packs (normally four) to each have a recess, permitting the side wall cool packs to be identical. The base cool pack having at least one blanking protrusion protruding from at least one other edge, then acts to reduce convection losses that may occur through an otherwise unobstructed recess in the or each of the other side wall cool packs which is not positioned on the edge of the base cool pack with the fill point. Thus, the invention permits a plurality of substantially identical side wall cool packs to be employed whilst not significantly increasing convection currents.

Preferably, each side wall cool pack has a further recess on a second edge opposite the first edge so that each side wall cool pack can be located on or against an edge of the base cool pack in a first orientation or in a second orientation inverted relative to the first, so that one of the fill point or blanking protrusions extending from the base cool pack edge may be accommodated in either one of the two recesses on the side wall cool pack, depending on the orientation of that cool pack. The provision of recesses on opposite ends of the side wall cool pack means that if the side wall cool pack is rectangular it may be correctly positioned in any one of four orientations.

Preferably, the cool pack arrangement further comprises a top cool pack identical to the base cool pack wherein, when the cool packs are assembled, the recesses in the opposite edges of each side wall cool pack accommodate both a fill point or blanking protrusion of the base cool pack and a fill point or blanking protrusion of the top cool pack. If, the base cool pack is square and the arrangement comprises four side wall cool packs one on each edge of the base cool pack, which side wall cool packs together with the base cool pack form five sides of the cube, the four side wall cool packs may be identical. Thus a six sided cool pack layer could be formed from only two cool pack types, namely a base/top cool pack type and a side wall cool pack type.

Each edge of the base cool pack may be in the form of a step, wherein each side wall cool pack is arranged to sit on a tread portion of the step with an inner face of the side wall cool pack resting against a riser portion of the step, from which riser portions the fill point or blanking protrusion protrudes. The step may act to restrict convection currents by not only providing a stepped path, where any convection has to pass through a right angled bend, but by also ensuring any gap between the edge of the base cool pack and the edge of the side wall cool pack is a minimised, even if the two cool packs should not be properly aligned. This is because where the side wall cool pack has a corner edge with two surfaces at right angles, which respectively abut the tread portion and the riser portion of the step, then any misalignment of that side wall cool pack relative to the base cool pack may result in either the tread portion or the riser portion of the cool pack still remaining in contact with a respective face of the side wall cool pack and thus restricts convection and thus convection between the two cool packs.

Preferably, the fill point and blank protrusions are each located midway along the respective edge of the base cool pack, with each recess of the side wall cool packs located midway along the respective edge of the side wall cool packs. In this manner, the side wall cool packs may be inverted.

Advantageously, each side wall cool pack has an extended recess on one edge and a fill point which protrudes into said extended recess, the dimensions of the extended recess and location of the fill point being arranged such that the fill point is offset in the recess from the position in which the fill point or blanking protrusion of the base cool pack is accommodated. In this manner, the fill point of each side wall cool pack is accommodated within the overall outer profile of the side wall cool pack and thus does not interfere with the positioning of the side wall cool pack relative to the base cool pack.

In one advantageous embodiment, the cool pack arrangement comprises a square base cool pack and substantially identical top cool pack and four side wall cool packs each with a recess on a top edge and a bottom edge to accommodate a fill point or blanking protrusion of the base cool pack and top cool pack, each side wall cool pack having side edges chamfered at approximately 45° so that adjacent side edges may abut at the corners.

The invention will now be described by way of example only, with reference to the accompanying drawings, of which: Figure 1 is a perspective exploded view of a thermally insulated shipping container with a cool pack arrangement in accordance with the present invention; Figure 2 is a cutaway side elevation of the assembled container of Figure 1; Figure 3 is a top view of the container of Figures 1 and 2 with the lid removed; Figure 4 is an exploded view of the components of the outer casing of the container of Figure 1; Figure 5 is a cutaway side elevation of the components of Figure 4 assembled; Figure 6 is a plan view of the components of the lid portion of the casing of Figures 4 and 5 with a top cover portion removed; Figure 7 is a perspective view of the cool pack arrangement of the container of Figure 1; Figure 8 is a perspective exploded view of the cool packs of Figure 7; Figure 9 is a perspective view of a top or bottom cool pack of Figure 8; Figure 10 is a plan view, together with respective side elevations, of the cool pack of Figure 9; Figure 11 is a perspective view of a side wall cool pack of Figure 7; Figure 12 is plan view, together with respective side elevations, of the side wall cool pack of Figure 11; Figure 13 is a perspective view of an alternative set of cool packs for the container of Figure 1; Figure 14 is an exploded perspective view of the cool packs of Figure 13; Figure 15 is a perspective view of a side wall cool pack of Figure 13; Figure 16 is plan view, together with respective side elevations, of the side wall cool pack of Figure 15; Figure 17 is an expanded perspective view of a top insulation panel, side wall insulation panel assembly and bottom insulation panel for the container of Figure 1; Figure 18 shows the side wall insulation panel assembly of Figure 17 prior to insertion into the container of Figure 1; Figure 19 is a perspective view of the side wall insulation panel assembly of Figure 18 laid out as a linear array; Figure 20 is a plan view of the insulation panel assembly of Figure 19; Figure 21 is a side elevation of the insulation panel assembly of Figure 20; Figure 22 illustrates the components of the side wall insulation panel assembly of Figures 17 to 21, prior to assembly; and Figures 23 to 25 are top views showing two side wall insulation panels of the side wall insulation panel assembly, of Figures 17 to 21, at various stages as the side wall insulation panels are folded together.

Referring to Figure 1, a thermally insulated shipping container 1 comprises a number of components which, as most clearly seen from the partially cutaway side elevation of Figure 2 and the plan view of Figure 3 (with the lid 13 removed) comprises three layers, indicated generally as a thermally insulating outer casing 2, a cool pack layer 3 comprising a cool pack arrangement in accordance with the present invention and a vacuum insulation panel layer 4 located between the two.

The components 5 to 12 of the thermally insulating outer casing 2 are disclosed and described in greater detail in and with reference to Figures 4 to 6 and the cool packs 29 to 35 forming the cool pack layer 3 are disclosed and described in greater detail in and with reference to Figures 7 to 16. The vacuum insulation panels forming the vacuum insulation panel layer 4, are located as shown in Figures 1 to 3 and comprise six panels 4a to 4f, providing additional insulation between the respective cool packs 4a to 4f and the insulation outer casing 3.

The four insulation panels 4b to 4e are side wall insulation panels and, although not shown in Figures 1 to 3, are assembled into insulation panel assembly as shown in and described with reference to Figures 17 to 25.

Referring now to Figure 4, the thermally insulating outer casing 2, shown in exploded view, comprises eight components each formed from expanded polypropylene (EPP) foam. The eight components comprise a base 5, a first pair of identical opposed walls 6 and 7, a second pair of identical opposed walls 8 and 9, a lid, indicated generally as 13 having an inner portion 10, a locking portion 11 and an outer portion 12.

Each of the second pairs of walls 8 and 9 have a plurality of sockets 14 moulded into both side edges of their outer faces. These engage with plugs 15 which protrude from extension portions 16 on the inward facing side edges of each of the first pairs of walls 6 and 7, only one set of which can be seen in Figure 4.

To assemble the outer casing 2, the second pair of walls 8 and 9 are positioned between respective pairs of extension portions 16 on each of the walls 6 and 7 and moved outwards until the plugs 15 on the walls 6 and 7 engage in the sockets 14 on the walls 8 and 9. Base 5 is then inserted and pushed down between the assembled walls 6 to 9 to the position shown in Figure 5, where it is retained in place by lips 17 and 18. The base locks the bottoms of the walls 6 to 9 in place by preventing walls 8 and 9 moving inwardly. The lid 13, when assembled sits between the walls 6 to 9, being retained in place by a step 20 running along the top edges of the walls 6 to 9. This similarly locks the tops of the walls 6 to 9 in place.

The lid 13, shown in Figure 4, has a locking portion 11 sandwiched between the inner portion 10 of the lid 13 and the outer portion 12 of the lid 13 which inner and outer portions 10 and 12 are fixed together to form the lid 13. The locking portion 11 is rotatably retained in place by a downwardly protruding pin 21, seen in Figure 5, engaging in the aperture 22 in the inner portion of the lid 10 and with the upper protruding portion 23 of the locking portion 11 of the lid engaging in the aperture 24 in the outer portion of the lid 12.

The locking portion 11 has four protrusions 25, which when the locking portion 11 of the lid is rotated to a "locked" position extend beyond the four edges of the lid, engaging with respective slots 26 in the top of the walls 6 to 9, to lock the lid in place, as shown in Figures 5 and 6.

As can be seen most clearly from Figure 5, both the inner portion 10 of the lid 13 and the base 5 have recesses 27 and 28. The vacuum insulation panels 4a and 4f, forming the top and bottom of the vacuum insulation panel layer 4 of Figures 1 to 3, are accommodated in these recesses 27, 28, as shown in Figures 1 and 2. The remaining vacuum insulation panels 4b to 4e, of the outer vacuum, insulation panels 4 are then arranged as an assembly against the inner faces of the four walls 6 to 9 of the outer casing 2.

The thermally insulating outer casing 2, being formed from individually moulded walls 6 to 9 defines an inner space between the walls 6 to 9, which space has parallel vertical sides, which would not normally be possible if the four walls 6 to 9 and base 5 had been moulded as a single piece (for it would normally necessary to have tapered inner walls to permit the casing to be released from a mould tool). The advantage of having parallel inner walls is that they can correctly accommodate both standard rectangular or square vacuum insulation panels 4b to 4e of the vacuum insulation panel assembly discussed below with reference to Figures 7 to 16, keeping both the vacuum panels and cool packs tightly confined in order to minimise convection between adjacent panels or cool packs and to retain a correctly packed product in place.

If desired a stretch film wrap may be provided around three of the assembled walls and 6 to 9 of the outer casing 2, prior to the fourth wall being locked in place and tensioning the film wrap. This may not only assist in keeping the walls of the outer container locked together, especially in the event of the container being dropped or otherwise suffering a major impact, but the wrap may also be pre-printed and thus provides an easy way of customising graphics on the container 1 for a particular customer, or enables the customer to easily apply their own graphics.

Once the outer casing 2 has been assembled, as shown in Figure 5, and the vacuum insulation panels 4b to 4e inserted, the cool packs (once cooled) of Figures 7 to 16 may be inserted therein to form the cool pack layer 3.

The cool pack layer is shown in Figure 7 as it would be arranged in the container 1 of Figure 1. As shown in Figure 8, the cool pack layer 3 comprises only two components types, comprising identical top and bottom cool packs 29 and 30, shown in greater detail in Figures 9 and 10, and four identical side wall cool packs 32 to 35, shown in greater detail in Figures 11 and 12. Each of the cool packs may be formed by standard moulding technique and filled with a water-based material or other phase change material such as paraffin wax, which can subsequently be cooled.

The top and bottom cool packs 29 and 30 will now be described in more detail with reference to Figures 9 and 10. In the following discussion the illustrated cool pack is taken to be the bottom cool pack 30, but the same features are found on the identical top cool pack 29 of Figure 8.

The bottom cool pack 30 of Figure 9 is provided with a step 36 around all four edges, with a fill point cap 37 on one of the edges. Because the cool pack 30 is relatively thin in the region below the step 36, the fill point cap 37 extends above the level of the tread portion of the step 36 and partly protrudes out of the riser portion of the step above the tread portion. In corresponding positions on each of the other three sides of the cool pack 30 there are provided blanking protrusions 38 to 40, the purpose of which is described below.

Referring now to Figures 11 and 12, there is illustrated one side wall cool pack 35, identical to each of the other side wall cool packs 32 to 34. This has flat top and bottom edges 41, 42 perpendicular to the front and rear faces of the cool pack 35 and side edges 43, 44 chamfered at 45° to abut adjacent chamfered side edges 44, 43 of adjacent cool packs, when assembled as shown in Figure 7 inside the container 1 of Figure 1.

Referring again to Figures 11 and 12, each side wall cool pack 32 to 35 has vertical notches 45 formed along the top and bottom edges of its inner face and a small recess 46 in the top or bottom edge 42 and a larger recess 47 formed in the opposite edge 41, in which the fill point cap 48 is accommodated, off-set to one side of the layer recess 47. The notches 45 assist when lifting the side wall cool packs 32 to 34 out of the container.

The fill point cap 48 being off-set leaves the recess 47 clear in a midpoint, opposite to the smaller recess 46 in the opposite edge. The side wall cool packs 32 to 35 are readily distinguishable from the top and bottom cool packs 29 and 30 by their chamfered side edges 43, 44 and absence of a step 36. Therefore, when inserting a cool pack layer 3 within the assembled outer casing 2 it is to identify the top and bottom cool packs 29, 30 from the side wall cool packs 32 to 35 and first place one into the base of the outer casing 2 of the container 1 of Figure 1.

Each side wall cool pack 32 to 35, in use, may be located in any of the four side wall positions of Figure 7 and may be mounted with either of its flat edges downwards, as each side wall cool pack 32 to 35, either way up, will accommodate the fill point cap 37 of the bottom cool pack 30. This will either be accommodated in a smaller recess 46 or a larger recess 47 of the respective side wall cool pack 32 to 35.

The riser portion of the step 36 on the bottom cool pack 30, abutting the horizontal flat bottom edge of the side wall cool packs 32 to 35, resists convection of air by providing a double step for any convection currents to negotiate. This double step feature is also present along the top edges of the side wall cool packs 32 to 35, where they engage the step 36 of the top cool pack 29 of Figure 5.

When the cool packs 29 to 34 are assembled, as shown in Figure 7, the protrusions 38 to 40 on the top and bottom cool packs 29 and 30 fit and fill the notches 46 or 47 of the side wall cool packs 32 to 35, (necessary to accommodate fill point cap 37) and restrict the convection through these notches to further prevent convection.

The step 36 on the bottom cool pack 30, being square, as opposed to chamfered, additionally assists in assembly of the side wall cool packs 32 to 35, for the step 36 acts to stop the first side wall cool pack inserted falling inwards before adjacent side wall cool pack 32 to 35 are inserted.

Referring now to Figures 13 to 16, there is shown a slightly modified set of cool packs 49, 50 for use, as the wall portion of the cool pack layer 3 of the container 1 of Figure 1. The top and bottom cool packs 29 and 30 are identical to those disclosed in Figures 7 to 9, but in this embodiment instead of there being four side wall cool packs there are instead only the two identical "double" side wall cool packs 49 and 50. Each of the two side wall cool packs 49 and 50 effectively comprises two side wall cool packs as previously described with reference to Figures 7 to 8 and 11 to 12, but which are joined by a living hinge 31. These can be formed by blow moulding in a conventional manner but with the sides of the moulds being brought together to form a living hinge 31, or the living hinge 31 can be formed by a separate subsequent step in the manufacturing process.

Referring now to Figure 17, this illustrates the components of the vacuum insulation panel layer 4.

The vacuum insulation panel layer 4 comprises a top vacuum insulation panel 4a, a bottom vacuum insulation panel 4f and a vacuum insulation panel assembly 54.

As will be described below with reference to Figures 23 to 25, with this assembly 54, the side wall vacuum insulation panels 4b to 4e may be tightly bound together when in use, as illustrated in Figure 17 and 18, without the need to tape them together. This also provides a vacuum insulation panel assembly 54 that is capable of being easily and quickly inserted into the thermally insulating outer layer 2, once this has been assembled.

The components of the vacuum insulation panel assembly 54 are shown in Figure 22, prior to assembly. These comprise the four side wall insulation panels 4b to 4e and a thin PVC sheet 58. The PVC sheet 58 is shown laid flat with the four side wall vacuum insulation panels 4b to 4e laid thereon with their outer faces uppermost. The PVC sheet is formed with four creases 59 to 62 extending parallel to the top and bottom edges of the sheet 58 and four creases 63 to 66 extending perpendicular to the top and bottom edges of the sheet 58. Each crease is formed so that it acts to fold the sheet to either side of the crease, out of the page as shown in Figure 23.

The sheet 58 has four cut out sections (although they could be formed other than by being cut) 67 to 70, formed between the parallel creases 61 and 62 and four corresponding cut out sections 71 to 74 formed between parallel creases 59 and 60. In addition, cuts 75 to 77 extend between respective pairs of cut out sections 68, 72; 69, 73; and 70, 74 to form four flaps 78 to 81 defined by the respective cuts 75 to 77 or edge of the sheet 58 and respective perpendicular creases 63 to 66. The width of each flap 78 to 81 is the same as the depth of the side wall vacuum insulation panels 4b to 4e, with the perpendicular creases 63 to 66 urging the flaps 78 to 81 vertically, out of the page as shown in Figure 22, so that they lie adjacent to a side edge of a respective vacuum insulation panel 4b to 4e.

The two parallel creases 59 and 60 are also separated by a distance equal to the width of the vacuum insulation panels 4b to 4e, with the two creases together urging the top edge portion of sheet 58 to fold through 180° and wrap over the top edge of the vacuum insulation panels, sandwiching the vacuum insulation panels therebetween. Creases 61, 62 likewise cause the bottom edge of the sheet 58 to wrap over the bottom edges of the vacuum insulation panels 4b to 4e. Thus, the top and bottom edges of the sheet 58, as shown in Figures 17 to 20, thus now respectively form a top strip 82 and a bottom strip 83, which strips 82, 83 both extend across the outer faces of vacuum insulation panels 4b to 4e. The vacuum insulation panels can optionally then be adhered in place.

Referring now to Figure 23, this shows an edge view of a section of the vacuum insulation panel assembly 54, showing the sheet 58 and two of the vacuum insulation panels 4b and 4c. From Figure 23 it can be seen that in addition to forming top and bottom strips 82 and 83 (only 82 of which is shown) on the outward facing surfaces of vacuum insulation panels 4b to 4e, the sheet 58 also provides covering sections 84 for the inner faces of the vacuum insulation panels 4b to 4e. Respective flaps 78 to 81 form extension portions to the covering sections 84, which wrap around one edge only of the respective vacuum insulation panels 4b to 4e.

As shown in Figures 24 and 25, as adjacent vacuum insulation panels 4b, 4c are folded together, the flap 81 is sandwiched between a side edge of vacuum insulation panel 4b and the side edge of a front face of adjacent vacuum insulation panel 4c, with the top and bottom strips 82 and 83 urging the side edge of vacuum insulation panel 4c against the edge of an inner face of adjacent vacuum insulation panel 4b and maintaining them there, avoiding the need for the vacuum insulation panels 4b, 4c to be subsequently taped together. Once the vacuum insulation panel assembly 54 has been folded together, as shown in Figure 17, the PVC sheet 58 then forms a lining for the inner surfaces of the side wall vacuum insulation panels 4b to 4e. These surfaces are maintained substantially flat by one side edge of the covering section 84 and extension portion, or flaps 78 to 81 forming a right angle and with the opposite edge of each covering section 84 overlapping with and being sandwiched against the respective flap 78 to 81, as shown in Figure 23.

Thus each covering section 84 effectively not only covers the inner face of each side wall vacuum insulation panel 4b to 4e, but also extends over the top and bottom edges to form top and bottom strips 82 and 83. Thus the sheet 58 covers all exposed surfaces of the vacuum insulation panels 4b to 4e when they are assembled in the thermal insulating outer casing 2 of container 1 and protects the vacuum insulation panels 4b to 4e when the cool packs are inserted in the container 1.

One embodiment of the present invention has been described byway of example only with reference to the accompanying drawings and it will be apparent that many modifications may be made which fall within the scope of the invention as defined by the appended claims.

Claims (16)

1. Claims 1. A cool pack arrangement comprising: a base cool pack having a plurality of edges; and a plurality of side wall cool packs each arranged to be located on or against a respective edge of the base cool pack, wherein the base cool pack has a fill point protruding from one edge and at least one blanking protrusions protruding from at least one other edge in a position along that edge corresponding to the position at which the fill point protrudes from its edge, wherein each side wall cool pack has a recess in a first edge which, when the side wall cool pack is located on or against the base cool pack accommodates either the fill point of the base cool pack or a blanking protrusion, depending upon which edge of the base cool pack the side wall cool pack is located on or against.
2. 2. A cool pack arrangement according to Claim 1, comprising a plurality of substantially identical side wall cool packs, one for each edge of the base cool pack.
3. 3. A cool pack arrangement as claimed in Claim 1 or 2, wherein each side wall cool pack has a further recess on a second edge opposite the first edge so that each side wall cool pack can be located on or against an edge of the base cool pack in a first position or in a second position inverted relative to the first, so that one of the fill point or blanking protrusions extending from the base cool pack edge may be accommodated in either one of the two recesses on the side wall cool pack, depending on the orientation of that cool pack.
4. 4. A cool pack arrangement as claimed in Claim 3, further comprising a top cool pack identical to the base cool pack wherein, when the cool packs are assembled, the recesses in the opposite edges of each side wall cool pack accommodate both a fill point or blanking protrusion of the base cool pack and a fill point or blanking protrusion of the top cool pack.
5. 5. A cool pack arrangement according to any preceding claim, wherein the base cool pack is square and the arrangement comprises four wall cool packs one for each edge, which together with the base cool pack form five sides of a cube.
6. 6. A cool pack arrangement as claimed in any preceding claim, wherein each edge of the base cool pack is in the form of a step, wherein each side wall cool pack is arranged to sit on a tread portion of the step with an inner face of each side wall cool pack resting against a riser portion of the step from which riser portion the fill point and blanking protrusions protrude.
7. 7. A cool pack arrangement as claimed in any preceding claim, wherein the fill point and blanking protrusions are each located midway along a respective edge of the base cool pack and where the or each recess on the side wall cool packs are located midway along the edge of the side wall cool packs.
8. 8. A cool pack arrangement as claimed in any preceding claim, wherein each side wall cool pack has an extended recess on one edge and a fill point which protrudes into said extended recess, the dimensions of the extended recess and location of the fill point being arranged such that the fill point is offset in the recess from the position in which the fill point or blanking protrusion of the base cool pack are accommodated.
9. 9. A cool pack arrangement as claimed in any preceding claim, comprising a square base cool pack and substantially identical top cool pack and four side wall cool packs each with a recess on a top edge and a bottom edge to accommodate a fill point or blanking protrusion of the base cool pack and top cool pack, each side wall cool pack having side edges chamfered at approximately 45° so that adjacent side edges may abut at the corners of the cool pack cube formed by the assembled cool packs.
10. 10. A cool pack arrangement as claimed in any preceding claim, wherein in use the blanking protrusions reduce convection currents that would otherwise occur through the recesses in the side walls not occupied by a fill point.
11. 11. A cool pack arrangement as claimed in any preceding claim, wherein at least two side wall cool packs are joined by a living hinge so that the two side wall cool packs can be both laid flat and also folded through 90° so that they may form two adjacent walls of a cube.
12. 12. A cool pack arrangement as claimed in any preceding claim, wherein each cool pack is blow moulded.
13. 13. A cool pack arrangement as claimed in any preceding claim, wherein each cool pack is formed from a high density polyethylene.
14. 14. A thermally insulated container comprising a cool pack arrangement as claimed in any preceding claim, the container comprising four outer walls and a base formed of expanded foam into which the cool packs are arranged to be inserted.
15. 15. A container as claimed in Claim 14, further comprising a layer of insulation panels wherein the cool packs are arranged to be received inside of the insulation panel layer of the container to provide a container with an insulation layer, an intermediate insulation panel layer and an inner cool pack layer.
16. 16. A cool pack arrangement substantially as hereinbefore described with reference to, and/or as illustrated in, one or more of the accompanying figures.