Thermal receptacle with phase change material

Abstract

A phase change apparatus has a generally tubular housing with an open upper and lower end and a sidewall having inner and outer surfaces with a chamber defined therein. At least one of the surfaces is convoluted, and a phase change material is disposed in the chamber. The upper end of the generally tubular housing engaged the upper end of an insulated cup. At least one passage is defined between the inner and outer surfaces of the generally tubular housing to allow the flow of liquid when the cup is tilted. The phase change material disposed in the chamber absorbs thermal energy from the liquid and then releases the thermal energy back to the liquid to maintain the temperature of the liquid.

Claims

1. A method of lowering a temperature of a liquid in an insulated cup having an open upper end, a closed lower end and a side wall extending therebetween, the method comprising the steps of: providing an insert for the insulated cup, the insert comprising; a tubular housing having an open upper end and an open lower end with a side wall extending therebetween, the sidewall having an inner surface and an outer surface, the sidewall further having a chamber defined therein; a phase change material disposed within the chamber; at least one passage being defined between the inner surface and outer surface of the side wall of the tubular housing, the at least one passage being defined near the upper end of the tubular housing; engaging the upper end of the tubular housing with the upper end of the insulated cup such that the tubular housing extends down into the insulated cup inside the side walls of the insulated cup; and regeneratively absorbing thermal energy from the liquid into the phase change material and then releasing the thermal energy from the phase change material to the liquid to maintain the temperature of the liquid.

2. The method according to claim 1, wherein at least one of the surfaces of the sidewall of the tubular housing is a convoluted surface.

3. The method according to claim 1, wherein the upper end of the tubular housing is formed of a material having less thermal conductivity than a material forming a remainder of the tubular housing.

4. The method according to claim 3, wherein the upper end of the tubular housing is formed of plastic and the remainder is at least partially formed of metal.

5. The method according to claim 1, wherein: the tubular housing has an upper portion defining the upper end of the tubular housing and configured to engage the upper end of the insulated cup; the tubular housing further having a lower portion defining the lower end, sidewall and chamber of the tubular housing; the upper portion and lower portion being formed of different materials.

6. The method according to claim 5, wherein: the upper portion is plastic; the inner and outer surfaces of the lower portion are metal.

7. The method according to claim 5, wherein: the upper portion of the tubular housing has a lip element, the lip element has an upper part defining a drinking lip and a lower part configured to engage the upper end of the insulated cup.

8. The method according to claim 5, wherein: the at least one passage is defined in the upper portion of the tubular housing and no passages are formed in the lower portion.

9. The method according to claim 5, wherein: the lower portion of the tubular housing is non-tapered such that the upper end of the lower portion has a width equal to a width of the lower end.

10. The method according to claim 5, wherein: the lower portion is press-fit into or threaded onto a receiving area of the upper portion.

11. The method according to claim 1, wherein the phase change material comprises stearic acid or palmitic acid.

12. The method according to claim 1, further comprising providing a lid that engages the upper end of the tubular housing.

13. The method according to claim 12, wherein the lid forms part of a drinking lip.

14. A method of lowering a temperature of a liquid comprising the steps of: providing an insulated cup having the open upper end, the closed lower end and the side wall extending therebetween; providing an insert for the insulated cup, the insert comprising; a tubular housing having an open upper end and an open lower end with a side wall extending therebetween, the sidewall having an inner surface and an outer surface, the sidewall further having a chamber defined therein; a phase change material disposed within the chamber; at least one passage being defined between the inner surface and outer surface of the side wall of the tubular housing, the at least one passage being defined near the upper end of the tubular housing; engaging the upper end of the tubular housing with the upper end of the insulated cup such that the tubular housing extends down into the insulated cup inside the side walls of the insulated cup; and regeneratively absorbing thermal energy from the liquid into the phase change material and then releasing the thermal energy from the phase change material to the liquid to maintain the temperature of the liquid.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a cross-sectional view of a first embodiment of a liquid receptacle in accordance with the present invention;

(2) FIG. 2 is a cross-sectional view of a portion of an upper end of the receptacle prior to rolling and crimping;

(3) FIG. 3 is a cross-sectional view of the upper end of FIG. 2 during the crimping process;

(4) FIG. 4 is a cross-sectional view of a portion of a liquid receptacle showing a dimpled inner vessel;

(5) FIG. 5 is a cross-sectional view similar to FIG. 4 showing a waffle-like pattern of indentations;

(6) FIG. 6 is a cross-sectional view of a portion of a liquid receptacle in accordance with the present invention having a folded fin heat sink in the phase change chamber;

(7) FIG. 7 is a cross-sectional view similar to FIG. 6 showing a body of aluminum wool disposed in the phase change chamber;

(8) FIG. 8 is a cross-sectional view similar to FIGS. 6 and 7 showing a metal mesh or a metal or graphite powder disposed in the phase change chamber;

(9) FIG. 9 is a cross-sectional view of a further embodiment of the present invention having at least two chambers;

(10) FIG. 10 is a cross-sectional exploded view of a further embodiment of the present invention having an inner two wall cup and an outer two wall cup interconnected by a lip element;

(11) FIG. 11 is a detailed view of the upper end of the liquid receptacle of FIG. 10 after the inner and outer cups are received by the lip element;

(12) FIG. 12 is a cross-sectional view of a further alternative wherein an inner two wall cup and an outer two wall cup threadingly interconnect;

(13) FIG. 13 is a view of the components of FIG. 12 with the inner cup and outer cup separated;

(14) FIG. 14 is a cross-sectional view of an embodiment of the present invention providing an insert for an insulated cup;

(15) FIG. 15 is a view of the assembly of FIG. 14 tilted for drinking;

(16) FIG. 16 is a cross sectional view of a beverage lid with at least one chamber defined therein;

(17) FIG. 17 is a perspective view of a further embodiment of the present invention, providing an insert for an insulated cup; and

(18) FIG. 18 is cross sectional view of the embodiment of FIG. 17 in a cup.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

(19) The present invention provides a number of improved thermal receptacles or accessories that utilize at least one phase change material for rapidly lowering the temperature of a hot liquid to a suitable drinking range and then to maintain the temperature of that liquid at a suitable range for an extended period. The various features and elements of the embodiments discussed herein may be used in any combination.

(20) FIG. 1 provides a cross-sectional view of a first embodiment of a liquid receptacle 10. The receptacle has an inner vessel 12 with an open upper end 14, a closed lower end 16, and a side wall 18 extending therebetween. In the illustrated embodiment, the side wall 18 tapers outwardly from the lower end to the upper end. The inner vessel 18 has an inner surface 17 and an opposed outer surface 19.

(21) The receptacle 10 further has an insulated outer shell 20 with an open upper end 22 and a closed lower end 24. A side wall 26 may be said to extend between the closed lower end 24 and open upper end 22. Like the side wall 18, the side wall 26 tapers outwardly. The outer shell 20 has an inner surface 28 that is spaced from the outer surface 19 of the inner vessel so as to define a chamber 30 therebetween. In the illustrated embodiment, the chamber 30 extends between the respective side walls and between the respective closed lower ends of the inner vessel 12 and outer shell 20. A phase change material, also indicated at 30, fills the chamber. The open upper ends 14 and 22 of the inner vessel 12 and outer shell 20, respectively, are interconnected by a hermetic double seam created by double rolling the upper ends and compressing or crimping the double rolled ends so as to form a joined upper end 32.

(22) Referring to FIGS. 2 and 3, this double seaming process is illustrated. In FIG. 2, the open upper end 14 of the inner vessel is shown having an outwardly extending flange 34. The flange 34 has a curled portion 35 that extends downwardly and inwardly. The curled portion 35 may be created prior to the double seaming process or as part of the process. The open upper end 22 of the outer shell also has an outwardly extending flange 36. This flange 36 is shorter than and positioned just below the flange 34. The flange 36 is flat and stops short of the curled portion 35. A sealant may be applied as part of the double seaming process. A portion of sealant is shown at 37 on the underside of the flange 36.

(23) A chuck 38 engages the inside of the upper end 14 of the inner vessel and a seam roller 40 moves in and engages the flanges 34 and 36. As the seam roller 40 moves inwardly to the position shown in FIG. 3, the flanges 34 and 36 are double rolled. That is, the flange 34 extends around the outside of the flange 36 as well as back up under it so that there are two “rolls” in the flange 34. The flange 36 is captured between two layers of the flange 34 and a portion of the flange 34 is captured between the flange 36 and the upper end 2 of the outer shell. Following the step shown in FIG. 3, the seam roller 40 may be moved further inwardly so as to compress or crimp the double rolled flanges or a separate crimping step and tool may be used. The finished hermetic double seam is shown at 32 in FIG. 1. As known to those of skill in the art, this illustrative process is similar to the process used to roll and seal the upper ends of metal cans.

(24) Referring again to FIG. 1, some embodiments of the present invention may further include a lip element 42 that interconnects with the double seamed upper end. The lip element is illustrated as having an upper part 44 that defines a drinking lip and a lower part 46 that receives the double seamed upper end. Preferably, the lip element snaps 42 onto the upper end 32 in a semi-permanent fashion. Additional sealing elements or adhesive may be provided, as needed.

(25) As will be clear to those of skill in the art, the insulated outer shell may be formed in a variety of ways. For example, the outer shell may have an inner wall that defines the inner surface and a layer of insulating material that is applied to this inner wall and defines the outer surface of the outer shell. In the illustrated version, the outer shell 20 has a first wall 48 and a second wall 50 that each have closed lower ends and open upper ends. The first and second walls are joined at their open upper ends to form the outer shell. A chamber 52 is defined between the walls. The chamber 52 may be filled with air or other gas, acting as an insulating material. However, preferably, the chamber is filled with an insulating material such as insulating foam, or is evacuated so as to form a vacuum insulated outer shell. Such a vacuum is typically a partial vacuum.

(26) In some versions, the inner and outer walls are both metal. In these versions, the inner vessel is also metal. In versions with an outer shell with two metal walls, the two walls may be joined at their upper ends by welding or the double seaming process may serve to join the upper ends. In further versions, the inner vessel 12 is metal but the walls 48 and 50 of the outer shell 20 are plastic. The plastic walls may be joined at their upper edges by being molded together, glued or melted together, or by other processes. The upper ends of the metal inner vessel and plastic outer shell may be double seamed as illustrated, thereby forming a seal. This process may also interconnect the upper ends of the walls 48 and 50. Additional sealant, adhesive, or melting of the plastic may be used to improve the seal. In an alternative, one of the walls 48 or 50 is plastic while the other is not. In some versions, plastic walls are coated so as to allow them to hold a vacuum and/or resist interaction with the phase change material.

(27) As will be clear to those of skill in the art, the phase change material and insulating material may be provided in a number of ways. In one approach, where the outer shell is vacuum insulated, a port is provided in the outer wall 50. After the walls of the outer shell are interconnected, the cavity 52 is at least partially evacuated and the port is sealed. In a version where an insulating material is provided between the walls 48 and 50, the insulating material may be added prior to inserting the inner wall 48 into the outer wall 50. The same may be done with the phase change material. It may be added to the inside of the insulated outer shell prior to inserting the inner vessel into the outer shell 20. One example of an assembly method for a liquid receptacle in accordance with the present invention is to first form the insulated outer shell having an open upper end with an outwardly extending flange. An inner vessel is also formed with an open upper end with an outwardly extending flange. This inner vessel is formed of metal. A phase change material is added to the inside of the insulated outer shell and then the inner vessel is inserted down into the outer shell causing at least some of the phase change material to be displaced up into the chamber between the side walls. The phase change material and the outer shell and inner vessel are warmed to maintain the phase change material in a liquid state during the process. A chuck is then inserted into the inside of the inner vessel and a seam roller rolls the flange on the inner vessel around the flange of the outer shell to form a double rolled connection. This connection is compressed or crimped, which is defined as compressing the metal flange of the inner vessel sufficiently to produce the desired mechanical interconnection. This manner of connection and sealing is commonly described in the industry which stores food in metal cans as a “hermetic double seam.” Other approaches to interconnecting the inner vessel and outer shell may also be used.

(28) The inner vessel 12 is preferably formed of a material with good heat transfer properties. It is desirable to transfer heat from liquid contained in the inner vessel 12 into the phase change material 30 rapidly so as to rapidly lower the temperature of the liquid to the desired range. One preferred material is aluminum. The aluminum may be coated or anodized on its inner surface to improve its appearance, durability and/or food contact properties. Other materials may be used. For example, other metals, including stainless steel, may be used for the inner vessel. While metals such as stainless steel have a lower thermal conductivity than aluminum, the thermal conductivity is sufficient for some applications. According to a further embodiment, the inner vessel may be at least partially formed of a thermally conductive plastic, such as thermally conductive HDPE. While this plastic also has a thermal conductivity lower than aluminum, and also lower than most metals, the thermal conductivity may be sufficient for some applications.

(29) As known to those of skill in the art, it is desirable to use a material for the inner vessel that quickly conducts thermal energy from the liquid to the phase change material. The present invention further provides approaches for improving the transfer of energy from the liquid to the phase change material, other than the use of more thermally conductive materials. Referring to FIG. 4, a portion of a liquid receptacle in accordance with the present invention is shown. A wall of an inner vessel is shown at 60. Another wall is shown at 62, spaced from the inner wall 60. A chamber 64 is defined between the two walls. This drawing is generic to any of the embodiments of the present invention, as well as to other designs. The wall 62 may be considered to be the inner wall of an insulated outer shell. As shown, the inner wall 60 has a plurality of indentations 66 defined therein. These indentations distort the wall 60 thereby increasing the surface area both on the inner surface and outer surface. The wall 60 may be said to have indentations in the inner surface and corresponding protrusions in the outer surface. In the illustrated embodiment, the wall thickness is substantially uniform. Alternatively, the wall thickness may vary somewhat, due to the process of adding the indentations. The indentations may take any of a variety of forms. The configuration may also be reversed, with the indentations being formed in the outer surface and corresponding protrusions on the inner surface, or protrusions and indentations may be mixed on each surface.

(30) In FIG. 4, the indentations take the form of a plurality of dimples uniformly distributed on the wall 60. Alternatively, the dimples may be distributed differently than shown, may have different shapes than shown, or may be spaced apart differently than shown. In one example, the surface may have more of the appearance of the surface of a golf ball. FIG. 5 illustrates an alternative version wherein the indentations extend from the outer surface to the inner surface in a waffle-like grid with each indentation being generally square. This forms protrusions 68 on the inner surface. Further alternatives are indentations that are in the form of lines or grooves such as forming a grid. As will be clear to those of skill in the art, these various approaches substantially increase the surface area of both the inner and outer surfaces.

(31) One challenge with phase change materials is that as heat is transferred through the inner wall into the phase change material, the phase change material closest to the wall melts or changes phase. Phase change materials often have poor thermal conductivity, and further the thermal conductivity is often lower in a phase change material in a liquid state than it is in that same phase change material in a solid state. Phase change material farther from the wall may not melt and the rate of heat transfer into the chamber containing the phase change material may drop off. Put another way, it is often a challenge to transfer the heat into the phase change material that is farther from the wall.

(32) According to an additional aspect of the present invention, approaches are provided for improving the transfer of heat across the chamber by augmenting thermal conductivity and/or heat flow properties through design and materials to enhance thermal performance. Referring to FIG. 6, an inner wall is shown at 70, an outer wall is shown at 72, and a chamber 74 is defined therebetween. The chamber 74 is filled with a phase change material. Additionally, a metal heat transfer element is disposed in the chamber 74. The metal heat transfer element may take a variety of forms. In FIG. 6, a folded fin heat sink 76 is provided. It is a very thin sheet of highly conductive metal that is folded into a zigzag pattern and is positioned so as to extend between the walls 70 and 72. When used with a thermal receptacle as discussed herein, one approach would be to insert the heat sink 76 between the concentric walls of the inner vessel and outer shell such that the zigzag pattern would be seen in a horizontal cross section. FIG. 6 merely illustrates a pair of parallel walls, whereas in use the walls would likely be curved.

(33) FIG. 7 illustrates an alternative version in which the metal heat transfer element is a body of aluminum wool 78. Aluminum wool consists of a large number of very thin strands of aluminum bunched together similar to steel wool. FIG. 8 illustrates yet another approach in which a metal mesh 80 is provided between the walls. Alternatively, FIG. 8 may be considered to illustrate a plurality of metal or graphite particles dispersed in the phase change material. Each of these approaches may improve the transfer of heat from the phase change material close to the inner wall to the phase change material that is farther from the inner wall.

(34) Referring now to FIG. 9, a further embodiment of the present invention will be discussed. FIG. 9 illustrates a liquid receptacle 82 with a drinking lip 84 at the uppermost end and a base 85 at the lowermost end. The receptacle 82 includes an inner vessel 86 with an open upper end 88 and a closed lower end 90. A side wall 92 extends between the lower end 90 and upper end 88. A first intermediate wall 96 has an upper end 98 and a lower end 100. The first intermediate wall 96 surrounds the inner vessel 86 and is at least partially spaced therefrom so as to define a first chamber 102 therebetween. An insulated outer shell 104 is formed by a second intermediate wall 106 and an outer wall 108. The outer wall 108 is at least partially spaced from the second intermediate wall 106 so as to define an insulation chamber 110 therebetween. The second intermediate wall 106 surrounds the first intermediate wall 96 and is spaced therefrom so as to define a second chamber 112 therebetween.

(35) In the illustrated embodiment, the second intermediate wall is shown as a two layer wall, such as two layers of metal. This represents a version in which an inner assembly is press fit into an outer assembly to form the receptacle 82. Alternatively, the second intermediate wall is a single layer.

(36) In the illustrated embodiment, the inner vessel 86, first intermediate wall 96, second intermediate wall 106, and outer wall 108 all have a similar shape and are nested within each other so as to form a four-wall vessel. In the illustrated embodiment, the chambers between the walls extend between the sides as well as across the bottom of the vessel. The upper ends of the inner vessel and the walls are interconnected at the upper lip 84. In the illustrated embodiment, the first chamber 102 has a first phase change material disposed therein, while the second chamber 112 has a second phase change material disposed therein. The phase change materials may be the same or may be different materials and/or have different phase change temperatures. In one example, the phase change temperature of the second phase change material is slightly higher than the phase change temperature of the first phase change material. The insulation chamber 110 may have a vacuum or an insulating material disposed therein. In the illustrated embodiment, this chamber is shown as empty, which may correspond to a vacuum or to air. In alternative embodiments, the outer shell may be formed in other ways, not having two separate walls. In this case, the inner surface of the insulated outer shell forms the outer wall of the second chamber 112. In further alternatives, the second chamber may not have a second phase change material therein. In yet further versions, additional walls are provided so as to provide additional chambers, such as a five or six wall receptacle with four or five chambers.

(37) In versions having two phase change materials, the first phase change material in the first chamber 102 may very quickly change phases, or melt, as heat is transferred through the wall of the inner vessel 92 into the phase change material. Heat may then be transferred into the second chamber 112 causing the second phase change material to begin to melt. However, by choosing the phase change temperatures of the phase change materials and the construction materials of the various walls of the device, the heat flow can preferentially be directed to flow back towards the liquid rather than outwardly to the insulated outer shell. As compared to a receptacle having a single phase change material in a single chamber, the illustrated version may have a lower quantity of phase change material in the first chamber than the total used in a single phase change material version. As such, the entirety of the phase change material in the first chamber melts more quickly, and then further heat transfer may occur to the second chamber.

(38) In a further version, having multiple chambers, phase change material may be provided in a first chamber and a third chamber with a second chamber being disposed between the first and third chamber. A heat transfer material, such as water, oil or other liquids, may then be provided in the second chamber.

(39) As will be clear to those of skill in the art, a receptacle with four or more walls may be formed in various ways. In one approach, the upper portion of the vessel is molded out of plastic with concentric walls. A bottom cap is then attached, such as by spin welding, to define the bottoms of each wall. The different chambers then may be filled through ports. The embodiment illustrated in FIG. 9 may be referred to as a four-wall receptacle or, where the insulated outer shell is not formed with two walls, it may be referred to as a two chamber receptacle. Other numbers of walls may be formed. In another approach, the receptacle is formed using metal injection molding, allowing the creation of accurate parts.

(40) Referring now to FIGS. 10 and 11, a different approach to forming a two-chamber or four-wall receptacle will be discussed. In this version, an inner two wall cup 120 is received inside of an outer two wall cup 124. Each of these two wall cups may be formed in a variety of ways. In one approach, an inner and outer wall are interconnected in the same way as discussed for FIGS. 1-3, wherein an upper edge of each wall is interconnected by double seaming. The two wall cup may also be formed in any of the ways currently used to form vacuum insulated vessels. The two wall cup may also be formed by molding, including plastic or metal injection molding.

(41) In the illustrated embodiment, the inner two wall cup 120 may be said to have an inner vessel 121 that is surrounded by a first intermediate wall 122. The inner vessel and intermediate wall 122 are interconnected at their upper ends and are spaced apart so as to define a chamber 123 defined therebetween. This is the first chamber, corresponding to the first chamber in FIG. 9. A second intermediate wall 125 and an outer wall 126 form the outer two wall cup 124. The walls are spaced apart so as to define an insulation chamber 127, which is filled with an insulating material or is evacuated. The second intermediate wall 125 is spaced from the first intermediate wall 122 when the inner two wall cup 120 is received in the outer two wall cup 124. This defines the second chamber 128. The inner two wall cup 120 and outer two wall cup 124 may be interconnected by double seaming the upper ends. However, in the illustrated embodiment, a lip element 130 interconnects the two cups. The lip element 130 has an upper part 132 that defines a drinking lip and a lower part 134 that receives the upper ends of the inner two wall cup and the outer two wall cup. The lower part 134 has a pair of concentric grooves 136 and 138 and the inner and outer cups preferably snap into these grooves. Sealing elements or materials may be provided for improving the seal. Alternatively, the inner and outer cups may thread into the lip element 130. FIG. 10 shows the inner and outer cup before being assembled into the lip element 130 and FIG. 11 shows the upper portion after the pieces are assembled.

(42) This approach may allow inner two wall cups filled with different phase change materials to be interconnected with outer two wall cups to form receptacles with different performance characteristics. In one approach, a plurality of inner two wall cups are produced with different phase change materials. Outer two wall cups are also produced with phase change materials in the chamber. The inner two wall cup can be received in the outer two wall cup, with a heat transfer material in the chamber 128 therebetween, to transfer heat from the inner chamber to the outermost chamber. The heat transfer material may be a liquid such as water or oil. The outer two wall cup may have an additional layer of insulation thereon, or may have another chamber and be a three wall cup. In one option, the outer two wall cup has a phase change material in the chamber between its walls, and the phase change materials are chosen such that heat preferentially flows back to the inner vessel.

(43) An approach similar to that shown in FIGS. 10 and 11 may be used to provide more than four walls. For example, a six wall receptacle may be formed by nesting three two wall cups and interconnecting them using a lip element.

(44) Referring now to FIGS. 12 and 13, an alternative approach is illustrated. In this approach, an outer two wall cup 140 has threads 142 defined on the outer surface of its upper end. An inner two wall cup 144 has a receiving portion 146 near its upper edge with threads 148 on the inside of the receiving area. These threads 148 cooperate with the threads 142 so as to interconnect the inner cup 144 with the outer cup 140. The inner cup 144 is also shown as having threads on an outer surface near its upper edge for threadingly connecting a lid or a lip element. A seal may be provided above the threads 148 in the receiving portion 146. This approach could allow different two wall cups to be interconnected to provide different performance characteristics. As one example, the inner two wall cup could have one phase change material therein and the outer two wall cup could have another. A heat transfer liquid could fill the chamber between the two cups.

(45) Referring now to FIGS. 14 and 15, the present invention also provides an apparatus for providing the benefits of phase change material to an insulated cup such as the many currently available insulated mugs. Such an insulated cup is shown at 150 in FIG. 14. The illustrated version is a double wall vacuum insulated cup with a threaded upper end 152. This is merely exemplary of the wide variety of insulated cups available, some of which have upper drinking lips and others have detachable lips or lids. The illustrated cup 50 is of the type that would have a separate lid or lip element that forms the drinking lip. The present invention provides a phase change apparatus 154 designed to interconnect with the insulated cup 150. The phase change apparatus includes a generally tubular housing 156 with an open upper end 158 and an open lower end 160. In the illustrated embodiment, the generally tubular housing 156 is tapered such that the open lower end 160 is substantially smaller than the open upper end 158. A side wall 162 extends between the upper end 158 and lower end 160 and has an inner surface 164 facing inwardly and an opposed outer surface 166 facing outwardly. A chamber 168 is defined between the inner surface 164 and outer surface 166. A phase change material is disposed in this chamber 168 for regeneratively absorbing thermal energy from a liquid in the insulated cup 150 and then releasing the thermal energy back to the liquid to maintain the temperature of the liquid.

(46) As shown in this embodiment, the outer surface 166 of the side wall 162 is spaced inwardly from the inner surface 151 of the insulated cup 150 such that liquid fills the space between the surfaces as well as inside the tubular housing. This provides a large surface area for transferring heat between the liquid and the phase change material. The upper end 158 of the tubular housing is configured to engage the upper end of the insulated cup, as shown. In this embodiment, the upper end 158 includes a receiver 170 that threads onto the threads of the upper end 152 of the cup 150. A sealing element 172 is provided for sealing between the generally tubular housing and the cup 150. A plurality of passages 174 are defined between the inner surface 164 and outer surface 166 of the generally tubular housing near the upper end of the housing. As best shown in FIG. 15, these openings allow liquid disposed between the inner surface 151 of the insulated cup and the outer surface 166 of the tubular housing to flow therethrough and to be consumed. FIG. 15 also illustrates a snap-on lid 176 that may form part of the drinking lip of the cup. The tubular housing is preferably formed of a material with good thermal conductivity. However, the upper end may be made of or covered with a less thermally conductive material, such as plastic.

(47) FIG. 16 illustrates a drinking lid 180 that may form an aspect of the present invention, and may be used with other aspects described herein. The lid has a perimeter 182 with a drinking lip 184 and a lower portion 186. The lower portion 186 may be configured to be received in or on the upper end of a cup or mug. In the illustrated embodiment, the lower portion has an outer surface designed to fit into the upper end of a mug or cup, with a sealing element 188 for providing a good seal. Any configuration may be used, including threaded, snap-on and press-fit. The lid 180 has a central portion 190 that is spaced inwardly from the perimeter 182 so as to define a plurality of drinking passages adjacent the perimeter. The central portion 190 has a bottom wall 194 that faces the inside of the mug or cup. A first intermediate wall 196 is spaced upwardly from the bottom wall so as to define a first chamber 198 therebetween. In this embodiment, the chamber 198 is filled with a first phase change material. In the illustrated embodiment, the central portion 190 further has a second intermediate wall 200 spaced upwardly from the first intermediate wall 196 so as to define a second chamber 202 therebetween. A second phase change material is disposed in the second chamber 202. A top wall 204 is spaced above the second intermediate wall 200 so as to define an insulation chamber 206 therebetween. The insulation chamber may be evacuated or filled with an insulating material. The lid 180 helps to maintain the temperature of a beverage in the cup but may also help to modulate the temperature of liquid that flows through the passages 192. Alternative versions may include only a single chamber for phase change material, with or without insulation.

(48) FIG. 16 also shows an optional sealing cap 207 for the lid 180. In this version, a center post 205 extends up from the top wall 204. The post 205 may be threaded. The cap 207 fits onto this post and extends outwardly to a perimeter edge with a perimeter seal 208. As shown, the perimeter and seal 208 is located outboard of the passages 192. As such, if the cap 207 is tightened against the lid 190, the seal 208 seals the top of the lid. Tightening of the cap may be accomplished in several ways. A thumb screw is illustrated, which may form part of the cap or be separate. The entire cap may rotate to tighten. Other approaches are also possible. The seal 208 may take different forms. For example, a wider seal may be provided and positioned so as to seal the openings 192 themselves, rather than the entire area.

(49) FIG. 17 illustrates a further embodiment of an insert 210 for an insulated cup and FIG. 18 illustrates, in cross-section, the insert 210 received in an insulated cup 212. The insert 210 includes a generally tubular housing 214 with a portion 216 configured to engage the upper end 218 of the cup 212. In the illustrated embodiment, the upper portion 216 is a molded plastic element defining a drinking lip 220. The generally tubular housing further has a lower portion 222 extending downwardly from the upper portion. The lower portion 222 has a sidewall 224 having an inner surface 226 and an outer surface 228 with a chamber 230 defined in the sidewall 224 between the inner and outer surfaces. The chamber is sealed and filled with a phase change material, as discussed for earlier embodiments. The outer surface 228 of the sidewall 224 is convoluted. In the illustrated embodiment, the convoluted outer surface is corrugated and may be said to have a plurality of peaks 232 separated by valleys 234. Other types of convoluted surfaces may also be used. The tubular housing 214 may be said to have a generally vertical axis, in the position shown, and the peaks 232 and valleys 234 are each generally disposed in planes generally perpendicular to the vertical axis, so that the outer surface has the appearance of a plurality of stacked rings. The peaks may also be referred to as crests and the valleys may be referred to as roots, while the distance between the crests may be referred to as the pitch. Preferably, the outer surface is formed of a thin metal and the peaks are sized such that phase change material resides within each of the peaks.

(50) In an alternative, the inner surface is convoluted instead of or in addition to the outer surface. The inner surface may be corrugated or convoluted in another manner. If corrugated, the pitch and valley and peak configuration of the inner surface may be the same as or different from the outer surface.

(51) In the illustrated embodiment, the inner surface 226 of the sidewall 224 is generally smooth and generally tube-shaped with a generally consistent upper and lower width. In other words, it is not tapered, though a taper is an alternative, as is convoluting the inner surface 226. In one alternative, the inner surface is convoluted and the outer surface is smooth.

(52) The sidewall 224 is dimensioned such that after the insert 210 is received in the cup 212, a lower end 236 of the insert is spaced from a bottom 238 of the inside of the cup, allowing liquid to flow between an area inside the sidewall and outside the sidewall. Further, the outer surface 228 of the sidewall 224 is dimensioned such that the outer surface is spaced from an inner sidewall 240 of the cup 212

(53) In an example, the inner and outer surfaces of the sidewall 224 are formed of metal such as aluminum or stainless steel while the upper portion 216 is formed of plastic. The upper portion 216 has a lip element defining the drinking lip 220 and a lower part 250 configured to engage the cup. In the illustrated version, the engagement is by threads. The shape, size and use of threads may be altered to fit a variety of insulated cups, including cups produced for independent use. In such a case, the insert 210 is an accessory.

(54) At least one passage is defined in the upper portion of the generally tubular housing. In the illustrated embodiment, a plurality of passages 254 are provided in the upper portion 216, positioned outboard of the lower portion, so that liquid may flow to the drinking lip 220 when the cup is tilted. In some versions, no passages are provided in the lower portion.

(55) The lower portion 222 may be joined to the upper portion 216 in a variety of ways, such as being press-fit, threaded or bonded. A lid, such as described for prior embodiments may be received on the upper portion.

(56) A variety of phase change materials may be used with the present invention. In some embodiments, a preferred phase change material is palmitic acid. The phase change temperature of the phase change material may be selected to provide a desired drinking temperature. This temperature may be different for different applications, such as providing a higher temperature phase change material for users that like to drink beverages very hot and a lower temperature phase change material for those that prefer beverages at a lower temperature. In embodiments using two phase change materials, the phase change material in the inner chamber may be stearic acid or palmitic acid. Preferably, any phase change materials selected are non-toxic, food-grade materials that are also not corrosive or reactive to the metals or materials being used for containment of such phase change materials. In some versions, the phase change material has a phase change temperature in the range of 61 to 68 degrees Celsius.

(57) As will be clear to those of skill in the art, the herein described embodiments of the present invention may be altered in various ways without departing from the scope or teaching of the present invention. It is the following claims, including all equivalents, which define the scope of the invention.