U.S. patent application number 13/032237 was filed with the patent office on 2011-06-16 for insulated cooking vessel.
This patent application is currently assigned to MEYER INTELLECTUAL PROPERTIES LTD.. Invention is credited to Stanley Kin Sui Cheng.
Application Number | 20110139795 13/032237 |
Document ID | / |
Family ID | 39284074 |
Filed Date | 2011-06-16 |
United States Patent
Application |
20110139795 |
Kind Code |
A1 |
Cheng; Stanley Kin Sui |
June 16, 2011 |
Insulated Cooking Vessel
Abstract
A dual wall cooking vessel has an inner cooking portion or shell
with a thermally conductive outer cladding that terminates prior to
the interior of the rim of the cooking vessel. The construction
provides uniform temperature during the cooking process, yet
minimizes heat loss after cooking.
Inventors: |
Cheng; Stanley Kin Sui;
(Hillsborough, CA) |
Assignee: |
MEYER INTELLECTUAL PROPERTIES
LTD.
Kowloon
HK
|
Family ID: |
39284074 |
Appl. No.: |
13/032237 |
Filed: |
February 22, 2011 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
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11953153 |
Dec 10, 2007 |
7913372 |
|
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13032237 |
|
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60871357 |
Dec 21, 2006 |
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Current U.S.
Class: |
220/573.1 ;
126/390.1 |
Current CPC
Class: |
A47J 41/0077 20130101;
A47J 27/002 20130101; A47J 36/00 20130101; Y10T 29/49826 20150115;
Y10T 29/49908 20150115; A47J 41/0055 20130101 |
Class at
Publication: |
220/573.1 ;
126/390.1 |
International
Class: |
A47J 27/00 20060101
A47J027/00; A47J 36/00 20060101 A47J036/00 |
Claims
1. A dual wall cooking vessel, the vessel comprising: a) a vertical
portion having, i) an internal bottom cooking surface, and ii) an
exterior bottom surface, b) a seamless substantially upright wall
having, i) an interior wall that surrounds and is connected at the
bottom thereof to the internal bottom cooking surface, wherein the
internal bottom cooking surface and the interior wall provide an
inner vessel capable of containing fluid having a rim, and ii) an
exterior wall that is a substantially downward continuation from
the top of the interior wall wherein the interior and exterior
walls meet at the rim, in which the exterior wall terminates by
connecting to the exterior bottom surface of the vertical portion,
wherein the exterior wall is spaced apart from the interior wall to
form an annular cavity there between, c) wherein the inner vessel
has a laminated construction wherein an inner surface is a first
material and an outer surface is a more thermally conductive
material than the first material, the more thermally conductive
material surrounding at least the interior wall vertical walls and
terminating below the rim so as to face the cavity formed between
the interior wall and the exterior wall.
2. A dual wall cooking vessel according to claim 1 wherein the
first material is stainless steel and the more thermally conductive
material comprises one or more layer of at least one of copper and
aluminum.
3. A dual wall cooking vessel according to claim 1 further
comprising a first metal cap as the exterior bottom surface wherein
the bottom of the exterior wall is bonded to the first metal
cap.
4. A dual wall cooking vessel according to claim 3 further
comprising a second metal cap that is bonded to the first metal cap
wherein the bottom of the outer vessel wall is bonded between the
first and second metal caps such that the second metal cap provides
the exterior bottom surface.
5. A dual wall cooking vessel according to claim 4 wherein at least
one of the first and second metal caps consists essentially of a
metal selected from the group consisting of copper and
aluminum.
6. A dual wall cooking vessel according to claim 4 wherein the
second metal cap is a ferromagnetic material.
7. A dual wall cooking vessel according to claim 1 the more
thermally conductive material surrounds the interior wall and the
internal bottom cooking surface.
8. A dual wall cooking vessel according to claim 1 wherein the
vertical portion has 2 or more layers and the bottom of the
interior wall is bonded between said two of more layers.
9. A dual wall cooking vessel according to claim 2 further wherein
the exterior bottom surface is bonded between the first metal cap
and the portion of at least one of the vertical portion and
seamless upright wall in a portion in the vicinity of connection of
the vertical portion to the seamless upright wall that is external
to the inner vessel.
10. A dual wall cooking vessel, the vessel comprising: a) an inner
vessel having a bottom portion surrounded by vertical walls
terminating at an inner rim to form an inner surface for containing
fluids, b) an outer vessel having a bottom portion surrounded by
vertical walls terminating at an outer rim to form an inner surface
capable of containing fluids and surrounding the inner vessel, c)
wherein the inner vessels is nested within the outer vessel such
that the inner rim and the outer rim are concentrically aligned
with each other, and d) wherein a cavity is formed between the
inner surface of the outer vessel and the outer surface of the
inner vessel by coupling the bottom of the outer vessel wall to the
exterior bottom of the inner vessel, e) wherein the inner and outer
rims are formed of the same continuous sheet of material that forms
the outer vessel and the interior of the inner vessel.
11. A dual wall cooking vessel according to claim 10 further
comprising a first metal cap that is bonded to the exterior bottom
of the inner vessel wherein the bottom of the outer vessel wall is
bonded to the first metal cap.
12. A dual wall cooking vessel according to claim 11 further
comprising a second metal cap that is bonded to the first metal
wherein the bottom of the outer vessel wall is bonded between the
first and second metal caps.
13. A dual wall cooking vessel according to claim 12 wherein at
least one of the first and second metal caps is selected from the
group consisting of copper and aluminum.
14. A dual wall cooking vessel according to claim 11 wherein the
second metal cap is a ferromagnetic material.
15. A dual wall cooking vessel according to claim 10 wherein at
least the interior wall has a clad construction and the outer
vessel is a unitary wall of a single metal layer.
16. A dual wall cooking vessel according to claim 10 wherein the
vertical portion has 2 or more layers and the bottom of the
interior wall is bonded between said two of more layers.
17. A dual wall cooking vessel according to claim 10 wherein at
least one of said two or more layers is a ferromagnetic
material.
18. A dual wall cooking vessel, the vessel comprising: a) a
vertical portion having, i) an internal bottom cooking surface, ii)
an exterior bottom surface, b) a seamless substantially upright
wall having, i) an interior wall that surrounds and is connected at
the bottom thereof to the internal bottom cooking surface, wherein
the internal bottom cooking surface and the interior wall provide
an inner vessel capable of containing fluid having a rim, ii) an
exterior wall that is a substantially downward continuation from
the top of the interior wall wherein the interior and exterior
walls meet at the rim, in which the exterior wall terminates by
connecting to the exterior bottom surface of the vertical portion,
wherein the exterior wall is spaced apart from the interior wall to
form an annular cavity there between, c) wherein the vertical
portion has 2 or more layers and the bottom of the interior wall is
bonded between said two of more layers.
19. A dual wall cooking vessel according to claim 18 further
comprising a metal cap that forms the exterior bottom surface.
20. A dual wall cooking vessel according to claim 19 wherein at
least one of 2 or more layers consists essentially of a metal
selected from the group consisting of copper and aluminum.
21. A dual wall cooking vessel according to claim 19 wherein the
metal cap is a ferromagnetic material.
Description
CROSS REFERENCE TO RELATED APPLICATIONS
[0001] The present application is a Division of and claims the
benefit of priority to the US Non-provisional patent application
having Ser. No. 11/953,153, which was filed on 10 Dec. 2007 under
the title "Insulated Cooking Vessel", which in turn claims the
benefit of priority to the US provisional patent application having
Ser. No. 60/871,357, which was filed on 21 Dec. 2006 under the
title "Insulated Cooking Vessel", both of which are incorporated
herein by reference.
BACKGROUND OF INVENTION
[0002] The present invention relates to an improved article of
cookware, and in particular a cooking vessel having hollow
sidewalls for insulation.
[0003] Prior methods of forming a cooking vessels having hollow
walls for insulation involves a separate forming and bonding of two
cookware vessels.
[0004] Prior forms of hollow wall cooking vessels have inferior
cooking performance to the extent that the most of the heating of
the foodstuffs is that the bottom of the cookware vessel, as the
sidewalls are not intended to conduct heat, but rather provide
insulation.
[0005] It is therefore a first object of the present invention to
provide improved hollow wall cooking vessels wherein the cooking
performance is not compromised by the insulating qualities, and the
insulating qualities are not compromised by the cooking
performance.
[0006] It is a further objective of the present invention to
provide a method for forming such a cookware article.
[0007] It is still yet another object of the present invention to
provide a method of forming a cookware article having attributes of
the other objectives wherein the process of welding is not required
to seal the hollow wall. A still further objective of the present
invention is to provide a method of forming a cookware article
having the attributes of the other objectives wherein there is
provided in the lower portion of the sidewalls between the inner
and outer vessel a sufficient mass of thermally conductive material
to avoid damage or discoloration from the heating element or
flame.
SUMMARY OF INVENTION
[0008] In the present invention, the first object is achieved by
providing a dual wall cooking vessel having a sealed insulating gap
between the interior and exterior wall wherein the interior wall is
a laminated structure with a substantially thermally conductive
laminated layer facing the sealed insulating gap.
[0009] A second aspect of the invention is characterized in that
the hollow wall cooking vessel is formed by first drawing a high
walled vessel from one or more planar sheet of metals, and then
reversed rolling the central portion of the bottom of the high
walled vessel wherein the upper portion of the wall in the initial
vessel becomes the exterior wall of the dual walled vessel and the
lower portion of the high wall becomes the interior wall of the
dual walled vessel.
[0010] The above and other objects, effects, features, and
advantages of the present invention will become more apparent from
the following description of the embodiments thereof taken in
conjunction with the accompanying drawings.
BRIEF DESCRIPTION OF DRAWINGS
[0011] FIG. 1 is a cross-sectional elevation of a first embodiment
of the invention.
[0012] FIG. 2A-G are a sequence of cross-sectional elevations
showing a method of forming one embodiment of the invention.
[0013] FIG. 3A is a perspective view of a cooking vessel according
to another embodiment of the invention inverted to show the
exterior bottom cooking surface. FIG. 3B is an upright
cross-sectional elevation to the vessel shown in FIG. 3A. FIG. 3C.
is an expanded view of the bottom corner of the cooking vessel
shown in FIG. 3B, whereas FIG. 3D is an expanded view of the rim
portion of the cooking vessel shown in FIG. 3B.
[0014] FIG. 4A is a perspective view of a cooking vessel according
to another embodiment of the invention inverted to show the
exterior bottom cooking surface. FIG. 4B is an upright
cross-sectional elevation to the vessel shown in FIG. 4A. FIG. 4C.
is an expanded view of the bottom corner of the cooking vessel
shown in FIG. 4B, whereas FIG. 4D is an expanded view of the rim
portion of the cooking vessel shown in FIG. 4B.
[0015] FIG. 5A-D are a sequence of cross-sectional elevations
showing an alternative method of forming an embodiment of the
invention.
[0016] FIG. 6 is a cross-sectional elevation of another alternative
embodiment of the invention.
DETAILED DESCRIPTION
[0017] Referring to FIGS. 1 through 6, wherein like reference
numerals refer to like components in the various views, there is
illustrated therein a new and improved insulated cooking vessel,
generally denominated 100 herein.
[0018] In accordance with the present invention, FIG. 1 illustrates
a first embodiment wherein a dual wall cooking vessel 100 comprises
an inner shell 110 and outer shell 120. Each of the inner 110 and
outer shell 120 include a substantially horizontal bottom cooking
surface 102 and substantially upright and surrounding vertical
walls formed by the walls of the inner and outer shells 110 and 120
terminating at rim 130. The diameter of the outer shell 120 is
larger than the inner shell 110 such that an insulating gap 150 is
formed there between. As the inner and outer shells are preferably,
but not exclusively, formed from a unitary sheet of metal, they can
be considered to be integrally joined at rim 130. The bottom of the
inner shell 110 and the outer shell 120 are joined to form a
unitary bottom portion of the cooking vessel 105. In a most
preferred embodiment, the inner shell 110 has a laminated
construction wherein the inner cooking surface 111 is a first
material, preferably stainless steel, and the surrounding laminated
structure 108 is a more thermally conductive material, such as
copper or aluminum, or alloys and combinations thereof. As the more
thermally conductive material 108 lines both the bottom and
sidewalls of the cooking vessel 100, the entire inner cooking
surface 111, that is the interior bottom and interior sidewalls,
are uniformly heated, as the heat is efficiently transferred
through the bottom portion and sides via the thermally conductive
material 108. Thus, the foodstuff cooked or heated within the
cookware vessel 100 and will reach a uniform temperature faster
than if the thermally conductive material did not line the inner
shell 110. However the insulating gap 150 minimizes the heat
transfer away from the food after cooking is complete. Further, as
the more thermally conductive material 108 faces this gap, but does
not continue along the exterior sidewall of shell 120, or make any
direct contact therewith, it does not contribute to heat loss after
cooking is complete. Thus, the cooking vessel 100 has the advantage
of heating or cooking foods uniformly, but also maintaining a
uniform temperature within after cooking so that the foods stays
hot during serving from the same cooking vessel 100.
[0019] FIG. 2 illustrates another embodiment of the invention
showing a sequence of process steps that may be used to form an
article of cookware shown in FIG. 1, or in the alternative
embodiments of FIGS. 3-5.
[0020] Generally, the first step in a process of forming the
cooking vessel 100 at least one substantially planar sheet of metal
is deep drawn to form a fluid containing pre-form vessel 50, shown
in FIG. 2A. In this preferred method of creating the more thermally
conductive outer layer 108 a deep drawing process is applied to a
pair of stacked planar metal sheets or discs, with the smaller
diameter sheet sized to form the more thermally conductive lining
108 and the larger diameter sheet intended to form both the inner
shell 110 and walls 220 of the outer 120 shell and their integrally
connected rim 130. The inner and outer discs can be bonded by
rolling, laminating or braising as well as bonded during the deep
drawing process. The initial drawing step results in the high
walled pre-form vessel 50 having diameter D and wall height
H.sub.1, shown in FIG. 2A. The pre-form vessel 50 is shown
inverted, that is with rim pointing downward and bottom 59 pointing
upward.
[0021] Following the creation of pre-form vessel 50, a reverse
drawing process deforms the bottom portion 59 inward, which is
downward in the illustration, such that the bottom 59 and a portion
of the surrounding walls 51 are inverted to form the work piece
50', which has the nascent interior cooking surface 111 and inner
walls 210 of shell 110 as well as the outer wall 220 of outer shell
120. The rim 130 integrally connects to the inner shell 110 to the
outer wall 220 of outer shell 120. This inverted drawing process
provides an open gap 150' between the inner upright walls 210 and
outer wall 220.
[0022] It should be noted that the drawing die used to form the
inner walls 210 has a smaller diameter than the pre-form vessel 50
formed in the first step in the drawing process. Thus, the work
piece 50', shown in FIG. 2B, has an outer diameter D, that is
substantially the same as vessel 100, with an inner diameter d
between the inner wall 210. Further, the wall height of work piece
50' is now reduced to H.sub.2, which is less than about half the
initial wall height of the preform vessel 50 in FIG. 2A. It should
be noted there is now a gap 150' between the inner wall 210 and
outer wall 220, which are substantially parallel to each other.
[0023] In one alternative embodiment it is possible to form a
completed dual wall vessel 100 from the work piece 50', as shown in
FIG. 2G. This can be accomplished by "necking` or drawing inward,
as shown by arrows 20, what is now the circumferential lower
portion 217 of the outer wall 220 to the exterior bottom surface
219, bonding these portions together at seam 218 to seal the cavity
150 associated with gap 150'. This step of bonding may be performed
by braising or welding and the like.
[0024] However, more preferred methods are shown in FIG. 2C-2F in
which a first bottom plate or dish 201, is optionally spot welded
or otherwise attached to the exterior bottom surface 219 of the
work piece 50' forming work-piece 50''. Next, as shown in FIG. 2D,
the lower portions 217 of the outer wall 220 are "necked" or
deformed inward as indicated by reference arrow 20 along the entire
perimeter of the work piece 50'' overlapping the perimeter of the
first bottom plate 201.
[0025] It should be noted that plate or dish 201 preferably has an
outward concavity matching the exterior bottom disk 219, rather
than being a flat plate. In the next step, as shown in FIG. 2E, a
second bottom disk or plate 202, such as another aluminum plate, is
attached in concentric alignment with the first bottom dish 201 at
the bottom of the work piece 50'' to form work piece 50''. A
presently preferred method of initial attachment is spot welding,
followed by impact bonding. It should be appreciated that the
second bottom disk 202 in this more preferred embodiments has a
diameter sufficient to surround the necked in lower portion 217 of
the outer wall 220 for eventual bonding thereto.
[0026] Optionally, as shown in FIG. 2H, the lower portion 217 of
outer wall 220 can necked in and subsequently bonded at seam 518 to
the first bottom dish 201 to seal the cavity 150 to completes
another embodiment of a cooking vessel 100. This step of bonding
may be performed by braising or welding and the like.
[0027] It should also be appreciated that impact bonding is also
the preferred means to join the second disk or dish 202 in the step
shown in FIG. 2E when the first bottom disk 102 is relatively
ductile aluminum disc. Impact bonding locks the lower portion 217
outer wall 220 between first 210 and second 202 bottom discs or
plates, integral bottom portion 105 of the cooking vessel 100, as
shown in FIG. 2F, sealing the cavity 150 between the parallel
sidewalls formed in the step shown in FIG. 2B. It is further
preferable in this step to heat at least the bottom portion of
preform 50''' to a high temperature to assure sufficient plasticity
of the aluminum so that it will flow between the inner shell 110
and the outer shell 120 and partially moving upward in gap 150.
However it should be appreciated that the bottom portions of the
inner 110 and outer 120 shells are optionally joined together by
other means such as brazing or welding to each other or a third
intermediate structure.
[0028] Alternatively, first disc 201 can be a shallow concave dish
with sidewalls that extend the desired height to fill the lower
portion 251 of gap 150. Either method provides a thick interlayer
of a thermally conductive material to fill the bottom portion 251
of the gap 150 between the inner and outer vessel at the margin
between bottom cooking surface and surrounding sidewalls. Fillings
a lower portion of the sidewalls between the inner 110 and outer
shell 120 in the above, or any other manner, provides sufficient
thermal mass to avoid damage or discoloration from the heating
element or flame. It should be appreciated that although impact
bonding provides this significant benefit when the first bottom
disk 201 is aluminum, impact bonding need not be the exclusive
means adjoining a first bottom disk of aluminum, or any other
material, with a second bottom disk of an other material. The
cooking vessel of FIG. 2G is shown schematically in FIG. 6 to
emphasize the preferred structure of the integral bottom 105.
[0029] FIG. 3A illustrates a dual wall cooking vessel having the
more thermally conductive material 108 form the exterior bottom of
the cooking vessel 102, as might be desirable when this more
thermally conductive material is copper. This structure can be
achieved in the previously described alternative methods wherein
the first and second bottom disks are not required to seal the
inner gap 150, as shown by FIG. 2G. Alternatively, copper disks, or
any combination of the copper disk with another material, could
alternatively be brazed together to create a thicker bottom portion
of cooking vessel 100.
[0030] As will be evident from FIG. 3C, showing the junction
between the interior cooking surface 111 and the inner shell 110
wall that extends upward, the exterior cladding 108 of the inner
shell 100 extends across the exterior bottom cooking surface being
either a portion of the sidewall that was drawn inward, as shown in
FIG. 2F, or alternatively attached after a separate drawing
process. FIG. 3D illustrates in more detail the rim portion 130 of
the cooking vessel 100 above gap 150. It can also be seen in this
embodiment that the outer cladding 108 of the inner shell 110 does
not extend upward to reach the interior top of the cavity 150 to
the rim 130, but rather terminates just below the rim 130. This
facilitates the double drawing operation illustrated with respect
to FIG. 2 B. Further, by terminating the outer cladding 108 of the
inner shell 110 just below the rim 130, the rim 130 remains cooler
during cooking. This facilitates handling, but also prevents
further heat, as would occur after cooking through the more
thermally conductive outer cladding 108 if it extended to outer
shell 120. In this embodiment the stainless steel that forms the
inner and outer shells 110 and 120 preferably has a thickness of
about 0.5 mm. The copper that forms the thermally conductive outer
cladding 108 preferably has a thickness of about 1.0 to 1.2 mm.
[0031] FIG. 4 A illustrates another dual wall cooking vessel
wherein the exterior bottom cooking surface 102 is a different
material than the thermally conductive material used to line the
outer portion of the inner shell. Thus, in FIG. 4C, bottom plate
103 is below the outer cladding 108 that surrounds the inner shell
110. For example, it would be desirable in some instances to
provide an exterior bottom cooking surface 103 wherein the unitary
bottom portion 105 containing at least one ferromagnetic material,
such as bottom plate 103 so that cooking vessel 100 can be used on
an induction stove. One means of providing a ferromagnetic material
in the exterior bottom cooking surface is by lamination as shown in
FIG. 2 F. Alternatively, the ferromagnetic material can be attached
to the exterior bottom cooking surface of the vessel shown in FIG.
3A by a subsequent step of either impact bonding, brazing or
embedding a discontinuous layer of ferromagnetic material such as a
mesh or grid.
[0032] FIG. 5A-D illustrates an alternative method of forming the
cookware vessel 100. In FIG. 5A a substantially round or oval blank
of clad metal sheet 510 has an upper layer 505 and a lower layer
508. At least a portion of layer 508 is intended to form the more
thermally conductive layer 108 that clads or is laminated to the
inner shell 110. Layer 505 is preferably stainless steel of about
0.5 to 0.6 mm thick, whereas layer 508 is preferably at least one
of aluminum and copper that is about 0.8 to 2 mm thick. In FIG. 5B
partially clad sheet 510' has a upper sheet 505' and a narrower
lower layer 508'. The lower layer 508' has been narrowed by
machining away material from layer 508 of sheet 510. Alternatively,
the clad sheet combination 510' can be formed by bonding two disks
of different diameters together, such as by explosive or impact
bonding, as well as by repeated rolling operations or brazing.
[0033] Next, as shown in FIG. 5C, sheet 510' has been deformed by
deep drawing to form the inner shell 513, having a bottom 503,
surrounding sidewall 503 terminating at an outward flared rim 530.
An outer vessel or shell 520, having a bottom 523 and surrounding
sidewall 522, is then joined to the inner shell 520, by sealing its
rim 533 to flared rim 530, forming wall cavity 150 in vessel
100.
[0034] It is also preferable that another metal plate or disc 583
is bonded between the inner shell 513 and outer shell 520 by impact
bonding prior to the attachment of rims 530 and 533, forming vessel
100 in FIG. 5D.
[0035] Again it should be emphasized that the cooking vessels 100
illustrated with respect to FIG. 1, 3-5 need not be fabricated
exclusively by the process shown in FIGS. 2 and 5. Further, it
should be appreciate that bottom disks 201 and 202 are optionally
any combination of thermally conductive material such as copper and
aluminum, and may also comprise either a layer or mesh of a
ferromagnetic material for induction cooking.
[0036] While the invention has been described in connection with a
preferred embodiment, it is not intended to limit the scope of the
invention to the particular form set forth, but on the contrary, it
is intended to cover such alternatives, modifications, and
equivalents as may be within the spirit and scope of the invention
as defined by the appended claims.
* * * * *