U.S. patent application number 11/739564 was filed with the patent office on 2007-08-23 for insulated shipping container.
Invention is credited to Rodney Derifield.
Application Number | 20070193298 11/739564 |
Document ID | / |
Family ID | 34079130 |
Filed Date | 2007-08-23 |
United States Patent
Application |
20070193298 |
Kind Code |
A1 |
Derifield; Rodney |
August 23, 2007 |
Insulated Shipping Container
Abstract
Shipping containers, and more particularly insulated shipping
containers, for holding temperature sensitive products and coolant
in a predetermined relationship to maintain a refrigerated or
frozen condition for an extended period of time. Containers of this
type can be molded from rigid polyurethane foam or other materials
for shipping or transporting products such as biological and
similar products which need to be maintained at 2.degree. to
8.degree. Centigrade or frozen. Specific constructions are shown
and described.
Inventors: |
Derifield; Rodney; (Corona
Del Mar, CA) |
Correspondence
Address: |
ORRICK, HERRINGTON & SUTCLIFFE, LLP;IP PROSECUTION DEPARTMENT
4 PARK PLAZA
SUITE 1600
IRVINE
CA
92614-2558
US
|
Family ID: |
34079130 |
Appl. No.: |
11/739564 |
Filed: |
April 24, 2007 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
|
|
11283155 |
Nov 18, 2005 |
7225632 |
|
|
11739564 |
Apr 24, 2007 |
|
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10886310 |
Jul 7, 2004 |
7028504 |
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11283155 |
Nov 18, 2005 |
|
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|
60485484 |
Jul 7, 2003 |
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Current U.S.
Class: |
62/372 ;
62/457.2 |
Current CPC
Class: |
F25D 2303/0844 20130101;
F25D 2303/082 20130101; B65D 81/3827 20130101; F25D 3/08 20130101;
F25D 2331/804 20130101 |
Class at
Publication: |
062/372 ;
062/457.2 |
International
Class: |
F25D 3/08 20060101
F25D003/08 |
Claims
1. A shipping container for holding temperature sensitive products
and a coolant in a predetermined relationship to maintain a
refrigerated or frozen condition for an extended period of time,
comprising a container having a base, four walls and a top, the
base being capable of supporting a temperature sensitive product,
wherein the four walls interlock together, and further interlock
with the base and top, and interior surfaces of the walls include
vertical grooves to provide predesigned air flow therein around the
product via thermal convection to minimize temperature gradient
within the product load.
2. A container as in claim 1 wherein the walls, bottom and top
interlock via a tongue and groove arrangement.
3. A container as in claim 1 including a removable coolant tray
being disposable within the container above the product, and for
receiving thereon coolant packages.
4. A container as in claim 3 wherein the coolant tray includes a
central pre-molded conduction block and is configured for receiving
coolant packages surrounding the conduction block.
5. A container as in claim 1 wherein the walls, bottom and top are
molded from rigid polyurethane foam.
6. A container as in claim 1 further including four internal walls
spaced within the container and surrounding the product for
providing an air space between the container walls and these inner
walls.
7. A shipping container for holding temperature sensitive products
and a coolant in a predetermined relationship to maintain a
refrigerated or frozen condition for an extended period of time,
comprising a container having a base, four walls and a top, the
base being capable of supporting a temperature sensitive product,
and wherein two or more interior surfaces of the walls include one
or more vertical grooves to provide predesigned air flow therein
around the product via thermal convection to minimize temperature
gradient within the product load.
8. A container as in claim 7 wherein the four walls interlock
together, and further interlock with the base and top.
9. A container as in claim 7 wherein the walls, bottom and top
interlock via a tongue and groove arrangement.
10. A container as in claim 7 including a removable coolant tray
being disposable within the container above the product, and for
receiving thereon coolant packages.
11. A container as in claim 7 wherein the coolant tray includes a
central pre-molded conduction block.
12. A container as in claim 7 wherein the walls, bottom and top are
molded from rigid polyurethane foam.
13. A container as in claim 7 further including four internal walls
spaced within the container and surrounding the product and
providing an air space between the container walls and these inner
walls.
14. A shipping container for holding a temperature sensitive
product and a coolant in a predetermined relationship to maintain a
refrigerated or frozen condition for an extended period of time,
comprising a container having a base, four walls and a top, the
base being capable of supporting a temperature sensitive product,
and the four walls interlock together and interlock with the base
and top four internal walls spaced within the container for
surrounding the product and providing an air space between the
container walls and these internal walls, and a pad surrounding the
top of the product to minimize tipping thereof.
15. A container as in claim 14 wherein the walls, bottom and top
interlock via a tongue and groove arrangement.
16. A container as in claim 14 wherein one or more interior
surfaces include vertical grooves to provide a predesigned air flow
therein around the product via thermal convection to minimize
temperature gradient within the product load.
17. A container as in claim 14 including a coolant tray with a
central pre-molded conduction block.
18. A container as in claim 14 wherein the walls, bottom and top
are molded from rigid polyurethane foam.
19. A shipping container for holding temperature sensitive products
and a coolant in a predetermined relationship to maintain a
refrigerated or frozen condition for an extended period of time,
comprising a container having a base, four walls and a top, the
base being capable of supporting a temperature sensitive product,
and wherein one or more interior surfaces include grooves to
provide predesigned air flow therein around the product via thermal
convection to minimize temperature gradient within the product load
two opposing walls have an internal "V," "U" or curved shape to
facilitate thermal convection within the container and around the
product, and two other opposing walls having coolant cavities to
receive coolant packages.
20. A container as in claim 19 wherein the four walls interlock
together, and further interlock with the base and top.
21. A shipping container for holding temperature sensitive products
and a coolant in a predetermined relationship to maintain a
refrigerated or frozen condition for an extended period of time,
comprising a container having a base, four walls and a top, the
base being capable of supporting a temperature sensitive product,
and wherein one or more interior surfaces include grooves to
provide predesigned air flow therein around the product via thermal
convection to minimize temperature gradient within the product
load, two opposing walls having coolant cavities to receive coolant
packages, wherein each of the coolant cavities includes vertical
grooves on one or more opposing interior surfaces of the cavity.
Description
CROSS REFERENCE TO RELATED APPLICATIONS
[0001] The present application is a continuation of co-pending
application U.S. Ser. No. 11/283,155 filed Nov. 18, 2005, which is
a continuation of U.S. patent application Ser. No. 10/886,310 filed
Jul. 7, 2004, which claims priority from U.S. provisional patent
application Ser. No. 60/485,484 filed Jul. 7, 2003, the disclosure
of which is fully incorporated herein by reference.
FIELD OF THE INVENTION
[0002] The present invention relates to shipping containers, and
more particularly to insulated shipping containers for holding
temperature sensitive products and coolant in a predetermined
relationship to maintain a refrigerated or frozen condition for an
extended period of time. For example, containers of this type are
molded from rigid polyurethane foam or other materials for shipping
or transporting products such as biological and similar products
which need to be maintained at 2.degree. to 8.degree. Centigrade or
frozen.
BACKGROUND OF THE INVENTION
[0003] Various type of shipping containers have been developed
including conventional cardboard cartons having an insulating
material therein that may be formed into a desired shape or may
comprise panels or the like. Generally, a coolant such as packaged
ice, gel-packs or loose dry ice is placed around the product in a
cavity to refrigerate the product during shipping.
[0004] With regard to shipping particularly sensitive products,
such as certain medical or pharmaceutical products, rigid
polyurethane containers often are used because of the superior
thermal properties. Conventional insulated shipping containers have
many problems, particularly when shipping temperature sensitive
products for extended periods of time, such as when products are
shipped internationally. These containers, especially modular liner
systems, often include a number of seams in the insulating material
through which air can enter and heat the cavity in the carton. In
addition, the cavity often includes airspaces around the product
and coolant which can facilitate but not control convection,
especially if the insulating material includes leaking seams.
Unfortunately, temperature gradients or zones are created. These
conditions may accelerate the melting of the coolant, consequently
shortening the time that the container can maintain a refrigerated
condition. In addition, the cover may be formed from different
material, such as polyester foam which may have a thermal
resistance substantially lower than the body itself and thus may
compromise the performance of the container.
[0005] Furthermore, the product and coolant typically are placed
together within the cavity in a carton, which may have adverse
effects. When shipping certain products it may be desired to
refrigerate but not freeze the product. Placing a coolant, such as
loose blocks of dry ice, into a cavity against the product may
inadvertently freeze and damage the product. Even if held away from
the product, the coolant may shift in the cavity during shipping,
especially as it melts and shrinks in size, inadvertently
contacting the product. In addition, melted coolant may leak from
its container, possibly creating a mess within the cavity or even
contaminating the product being shipped.
[0006] Some suitable solutions to some of the foregoing problems
have been developed in the past such as shown and described in U.S.
Pat. No. 5,924,302. Still, there are needs for containers
particularly for shipping a large amount of product for long
periods of time.
SUMMARY OF THE INVENTION
[0007] The concepts of the present invention are directed to new
and improved containers for shipping temperature sensitive products
in a refrigerated and/or frozen condition for an extended period of
time.
[0008] In accordance with the present invention, several
embodiments of containers constructed of, for example; rigid
polyurethane foam are described and shown herein and which are
particularly useful for, among other purposes, small and large
shipments, such as via air freight, including via LD3 shipping
containers. Importantly, containers according to the present
invention are basically formed of a bottom, preferably with a tray
for holding product, four sides, and a lid, and preferably with a
coolant tray. Furthermore, the bottom, sides and lid are designed
to interlock (the sides and base preferably are slide locked or are
tongue and grooved, as versus typical 45 degree corners that do not
lock together or "grip" together), so as to reduce thermal
convection. Also, preferably a rigid polyurethane foam is molded to
form a bottom for the container and can have "pallet" grooves as
distinguished from using wood which can invite termite problems,
particularly in an air freight environment. The coolant tray
preferably is a slide-in tray which contains a suitable coolant
such as dry ice or gel packs, and which also is preferably made of
rigid polyurethane foam and to maintain the coolant out of direct
contact with the product. In addition, the interior walls and
bottom of the container can be configured to provide a convection
design to create a controlled air flow within the product
compartment, and this air flow can reduce the temperature gradient
within the product compartment and thus provide better and even
temperature control when shipping biological and other
products.
[0009] Thus, according to the concepts of the present invention,
the containers can have gripping walls, particularly on larger
containers, to reduce thermal convection between the outside
environment and the internal environment. The sliding coolant tray
can take any of many forms and/or shapes and is used to regulate
the temperature between the coolant and the product. The interior
walls of the sides, bottom, and top preferably are designed to
provide convection and thus create a controlled air flow within the
product compartment to control and reduce the temperature gradient
within the product compartment, and thereby provide better control
when shipping biological and other products. For example, the
walls, bottom, and/or top can have shapes, such as grooves and/or
protrusions, molded therein to provide convection and thus coolant
air flow around the product load. Also, the side walls can have a
shape such as a V or U shape or some variant thereof to provide
"convection walls" on two sides, and coolant on the other two
sides. Furthermore, a coolant tray can include a central pillar
molded into the tray to keep the cooling effect of the coolant
controlled in the center of the product load. Thus, containers
according to the present invention provide control of thermal
convection via predesigned air flow by the design of sides, grooves
and the like to minimize the temperature gradient in the product
load and in an attempt to maintain the same temperature at the
corners, middle and at all areas of the product load. The gripping
connection between the sides and base aid in controlling thermal
conduction and convection from the outside to the inside of the
container. The base is designed to maintain the product load off of
the actual bottom of the container and is provided with air
channels to allow internal air to circulate all around the load.
The base for large containers is designed preferably to transport
pallet loads of products such as biological products.
BRIEF DESCRIPTION OF THE DRAWINGS
[0010] FIG. 1 is a view of a large insulated container according to
the present invention;
[0011] FIG. 2 is an exploded view of the container of FIG. 1;
[0012] FIG. 3a is an exploded view of a partially assembled
container of FIG. 1, and FIGS. 3b-3d are detailed views of
components thereof;
[0013] FIG. 4 is a view illustrating the open top of the container
and a coolant tray having a conduction block, and gel packs;
[0014] FIGS. 5a through 5e; further illustrate the assembly of a
container similar to that of FIG. 1 for assembling the container
about a cryogenic vessel;
[0015] FIGS. 6a through 6c illustrate an alternative container
having a pair of V-shaped sides and grooves to facilitate
circulation of cold air all around a product load to be disposed in
the middle of the container, and
[0016] FIG. 7 is a perspective view of another embodiment.
DETAILED DESCRIPTION OF THE INVENTION
[0017] Turning now to the drawings, FIG. 1 illustrates one
embodiment of an insulated container 10 according to the present
invention. It preferably is constructed of water-based rigid
polyurethane foam with sides 12, back of front 13, bottom 14 and
lid or top 15 all with an interlocking design for easy storage and
assembly, and, for reduction of convection.
[0018] Turning to the exploded view of FIG. 2, a temperature range,
for example, of 0.degree. C. to 10.degree. C. can be maintained by
the use of an upper ice tray 16 to hold the necessary coolant 17
for the product load 18 in the container. The tray 16 can
preferably be slid in on top of the product 18. An internal product
tray 20 with built up sides 20a can be provided to insulate the
bottom of the product load 18 from the bottom or base 14 and reduce
the temperature gradient within the container. The bottom 14 of the
container can include forklift grooves molded into the bottom
thereof for eliminating the need for a separate wooden pallet. It
is desirable to eliminate wooden pallets and other wooden
components because of the termite problem involved with air freight
and elsewhere. The container shown in FIG. 1 can be any desired
size and can be sized to fit the standard LD3 shipping container to
optimize the payload.
[0019] Turning now to the particular interlocking structure of the
present container 10, FIGS. 2 and 3a-3d particularly illustrate the
interlocking structure of the sides, back, front, top and bottom.
The sides 12 have tongues 12a on the upper end thereof, vertical
elongated slots 12b at the outer edges of the inside, and a slot
12c at the bottom as best seen in FIGS. 2 and 3a-3b. On the other
hand, the back and front have top and bottom tongues 13a and side
tongues 13b as best seen in FIG. 2. The back and front sections 13
fit with the side sections 12 by the tongues 13b of the back and
front sections sliding into respective elongated grooves 12b in the
sides 12. This allows the back and front 13 to slide into the slots
12b of the sides 12 in a simple manner to provide a very tight and
rigid front, back and side structure, three components of which are
illustrated interlocked in FIG. 3a (the front has not yet been
added). The bottom 14 has elongated slots 14a for receiving the
lower tongues 13a of the front and back sections 13, and further
has elongated tongues 14b for mating with the bottom slots 12c of
the sides 12. The lid or top 15 has elongated slots 15a (see FIG.
3d) for receiving the tongues 12a of the sides 12 and the tongues
13a of the back and front sections 13. This tongue and groove
construction is particularly important in providing "gripping
walls" to reduce the thermal convection between the outside
environment and the internal environment of the container 10. They
provide a positive interlocking of the four sides with the base and
lid in accomplishing this task.
[0020] It is important that the coolant 17 not be in direct contact
with the product load 18. The sliding coolant tray 16 provides this
insulation or buffering function, and grooves 12d in the sides,
grooves 13d in the back and front sections 13, provide a
predesigned downward air flow in the side grooves around the
product load via thermal convection to minimize temperature
gradient within the product load. Similar grooves 16b in the
coolant tray 16 cooperate in this regard. Also, similar grooves can
be provided in the base 14 or product tray 20, if desired.
[0021] Importantly, a pillar 16a in the center of the sliding tray
16 preferably is provided and extends vertically upwardly as best
seen in FIGS. 2 and 4, and is particularly important from a thermal
conduction standpoint to reduce the coolant conduction down into
the center of the product load 18 that would occur if the coolant
17 was disposed in the location of the pillar 16a. It has been
found that without the pillar 16a, the center of the product load
18 becomes too cool, and this pillar 16a of foam reduces the
temperature of the normally very cold center portion of the load to
help maintain an even product temperature. Preferably spacers 16c
are provided within the ice tray 16 to help hold the ice packs 17
in place. Furthermore, these spacers 16c may have holes
therethrough to allow air flow freely within the ice pack 17. This
arrangement and construction increases the thermal efficiency of
the ice pack.
[0022] FIGS. 5a through 5e illustrate the assembly of an
alternative container commencing with a base 42 on to which a
product tank 40 is loaded as shown in FIG. 5a. Four inner walls 46
are inserted into the base 42, and then side female outer walls 48a
are inserted into the base (FIG. 5b), followed by a pair of male
outer walls 48b (FIG. 5c). The outer walls, base and top can be
tongue and groove construction as in the earlier Figures. The space
44 between the inner walls 46 and the outer walls 48 is filled with
the dry ice pellets (not shown). A tongue and groove structure
similar to those discussed above is used. Then, a thick, such as
four inches think, die cut foam pad 50 is inserted into in the
outer walls 48 (FIG. 5d) in the product cavity to reduce the
tendency for tall product to "tip" and fall, followed by the
application of a snugly fit lid 52 (FIG. 5e). The thus constructed
container preferably is inserted into a corrugated box and taped
closed.
[0023] Turning now to FIGS. 6a through 6c, the same illustrate
another container embodiment of rigid polyurethane foam and which
is designed to create an air flow within the product compartment
for reducing the temperature gradient within the product
compartment and thus providing better control when shipping
biological products. This embodiment includes, as seen in FIG. 6,
right and left sides 80 and front and back sides 82, along with a
base or bottom 83. Of particular importance in this container
design are the inside right and left side walls 86 which in this
embodiment are V-shaped, but could be U-shaped, channeled or
another suitable curved configuration. The purpose is to provide an
air space between these inside side walls 86 and a stack of product
(not shown) disposed in the cavity provided between inside walls 86
and upstanding barrier walls 88 which create air currents. The
insides of the front and back walls 82 along with the outer sides
of the barriers 88 form coolant cavities 90 for coolant which is
typically gel ice. The barriers 88 can be spaced as shown or each
can be a solid wall. The base 83 has raised areas 84a forming
grooves 84b between the areas 84a so as to provide some air space
at the base. The combination of the V-shaped inside walls 86,
grooves 84b in the bottom and similar grooves in a lid if desired
(not shown) allow cool air flow by convection within the product
compartment 92. As with the other embodiments, the container shown
in FIG. 6 preferably is formed of rigid polyurethane foam.
[0024] The embodiment of FIG. 6a has a relatively large product
compartment 92, whereas the embodiment of FIG. 6b has a smaller
product compartment 92a, but otherwise the V wall and groove
construction is similar. It has raised areas 84a forming grooves
84b like in FIG. 6a, the embodiment of FIG. 6c is like that of FIG.
6a but further includes a slide-in product tray 96. The FIG. 6
embodiments can use tongue and groove walls, base and top if
desired.
[0025] FIG. 7 illustrates another embodiment particularly for use
with a product container having a cap on top. The overall container
100 is similar to other embodiments and includes a lower pad 102
and lid 106. A foam ice tray 104 is configured to fit on the cap of
a product container to provide a consistent insulation barrier.
Side areas 104a and 104b form trays for the coolant (not shown) on
each side of the upstanding central section 104c. The tray 104 also
includes notches 104d for improved air flow. The central section
104c is a conduction block like 16a of FIG. 4 to control the
temperature in the central area. The walls, base and top also can
be tongue and groove construction.
[0026] Thus has been described in an improved shipping container
for maintaining a refrigerated or frozen condition for an extended
period of time for a product contained therein. The particular
features of importance are the slide-in ice tray 16 (for coolant
17) which can be slid into the container once the product 18 is
disposed therein. Another particularly important feature is the
interlocking walls, lid and base for controlling thermal convection
between the external environment and the internal atmosphere. A
further important feature is the pre-design shapes, cavities and
channels in various places throughout the container to use thermal
convection in moving and dispersing energy more evenly within the
container. The same maximizes the release of energy from the
coolant as well as reduces temperature gradients within the
container's internal atmosphere. Furthermore, the provision of a
pre-molded conduction block for reducing temperature pockets within
the container by protecting specific places within the container
from direct contact with coolants, particularly the center. This
barrier uses the properties of thermal conduction to consume energy
from the coolant source before it reaches the product load. The
pre-molded shape and size of the barrier can be designed to allow
only the desired amount of energy through while remaining stable
and constant throughout the duration of transport.
[0027] Various changes, modifications, variations, as well as other
uses and applications of the subject invention may become apparent
to those skilled in the art after considering this specification
together with the accompanying drawings and claims. All such
changes, modifications, variations, and other uses and applications
which do not depart from the spirit and scope of the invention are
intended to be covered hereby and limited only by the following
claims.
* * * * *