阅读说明：本技术 饮料冷却器 (Beverage cooler ) 是由 E·贾法 E·D·斯托内斯库 T·H·赫利尔 J·S·奥利弗 于 2019-07-09 设计创作，主要内容包括：本发明提供了用于储存和冷却瓶装饮料的饮料冷却器。饮料冷却器可包括由制冷系统冷却的冷却室,以及该冷却室中用于接收待冷却瓶装饮料的开口。开口可具有门和/或密封件以使该冷却室与环境之间的热交换最小化,其中瓶子可设置在或不设置在开口中。开口中的每个开口可具有视觉指示器,诸如多个LED,其被配置成指示设置在该开口中的瓶子的温度。(The present invention provides a beverage cooler for storing and cooling bottled beverages. The beverage chiller may include a cooling chamber cooled by a refrigeration system and an opening in the cooling chamber for receiving a bottled beverage to be chilled. The opening may have doors and/or seals to minimize heat exchange between the cooling chamber and the environment, wherein bottles may or may not be disposed in the opening. Each of the openings may have a visual indicator, such as a plurality of LEDs, configured to indicate a temperature of a bottle disposed in the opening.)

1. A beverage cooler, the beverage cooler comprising:

a first compartment accessible to a user through a cooler door;

a second chamber disposed below and separated from the first chamber;

a beverage container tray disposed between and separating the first chamber and the second chamber, wherein the beverage container tray comprises a plurality of beverage container openings, each configured to receive a beverage container;

a seal disposed within each beverage container opening, wherein the seal is configured to fill a space between the beverage container opening and a beverage container disposed in the respective beverage container opening; and

a visual indicator corresponding to a beverage container opening, wherein the visual indicator is configured to display information about a temperature of a beverage container disposed in the respective beverage container opening.

2. The beverage cooler according to claim 1, further comprising a refrigeration system disposed in the second chamber.

3. The beverage cooler according to claim 2, wherein the refrigeration system comprises an evaporator coil and a fan disposed in the second chamber.

4. The beverage cooler of claim 1, wherein a beverage container door is disposed at each beverage container opening, wherein the beverage container doors are configured to open when a beverage container is inserted into the beverage container openings.

5. The beverage cooler of claim 1, wherein the visual indicator comprises a plurality of LED lights disposed along a perimeter of the beverage container opening.

6. The beverage cooler of claim 1, further comprising a beverage container shelf disposed in the second chamber, wherein the beverage container shelf is configured to support one or more beverage containers disposed in the beverage container opening.

7. The beverage cooler according to claim 6 wherein the shelf is positioned such that at least a portion of beverage containers supported by the beverage container shelf are disposed within the first chamber.

8. The beverage cooler of claim 6, wherein the position of the beverage container shelf is adjustable.

9. The beverage cooler of claim 1 wherein at least a portion of the cooler door is transparent such that a user can see the first chamber.

10. A beverage cooler, the beverage cooler comprising:

a cooling chamber having an opening;

a beverage container tray disposed across the opening of the cooling chamber, wherein the beverage container tray comprises a plurality of beverage container openings, each beverage container opening configured to receive a beverage container;

a door disposed at each beverage container opening and configured to open when a beverage container is inserted into the respective beverage container opening;

a seal disposed within each beverage container opening, wherein the seal is configured to fill a space between the beverage container opening and a beverage container disposed in the respective beverage container opening; and

a visual indicator corresponding to a beverage container opening, wherein the visual indicator is configured to display information about a temperature of a beverage container disposed in the respective beverage container opening.

11. The beverage chiller according to claim 10, further comprising a refrigeration system.

12. The beverage cooler according to claim 11, wherein the refrigeration system comprises an evaporator coil and a fan disposed within the cooling chamber.

13. The beverage cooler of claim 10, wherein the visual indicator comprises a plurality of LED lights disposed along a perimeter of the beverage container opening.

14. The beverage chiller according to claim 10, wherein a user can access a beverage container disposed in one of the beverage container openings to receive a chilled beverage container.

15. The beverage cooler of claim 10, wherein the door is biased to close when a beverage container is not in the respective beverage container opening.

16. The stubby cooler of claim 10, wherein the door comprises two adjacent door panels, wherein a sealed seam is formed between the two door panels when the door panels are in the closed position.

17. A beverage cooler, the beverage cooler comprising:

a cooling chamber having an opening;

a cooler door disposed across the opening of the cooling chamber, wherein the cooler door is openable by a user to access the cooling chamber;

a plurality of beverage container receivers disposed within the cooling chamber, wherein each beverage container receiver is configured to receive a beverage container; and

a visual indicator corresponding to each beverage container receiver, wherein the visual indicator is configured to display information about a temperature of a beverage container disposed in the respective beverage container opening.

18. The beverage cooler according to claim 17 wherein the visual indicator is a plurality of LED lights that change color as a function of the temperature of the beverage container.

19. The beverage cooler according to claim 17, wherein the visual indicator is disposed outside of the cooling chamber.

20. The beverage cooler according to claim 17, wherein the visual indicator is disposed within the cooling chamber.

21. The beverage cooler according to claim 20 wherein at least a portion of the cooler door is transparent so that the user can see the cooling chamber.

Technical Field

The embodiments relate generally to beverage coolers. In particular, embodiments relate to a rapid beverage cooler.

Background

Some beverages are preferably served at low temperatures, so the consumer can utilize a beverage cooler to cool and/or maintain the beverage at a low temperature until ready to drink. Athletes may use chilled beverages in sports related applications to help regulate body temperature and water levels. Beverage coolers come in many forms and utilize a variety of mechanisms to reduce the temperature of the beverage to be consumed. For example, some beverage coolers use ice as a means of cooling the beverage. Some ice-based beverage coolers may require that the ice be placed in direct contact with the beverage to be cooled. Other ice-based beverage coolers may require that ice be placed around a container (e.g., a bottle or a can) that stores the beverage. Other beverage coolers may use powered cooling systems, such as refrigeration systems or thermoelectric cooling, to cool the beverage.

Disclosure of Invention

Some embodiments of the present invention provide a beverage cooler for cooling bottled beverages. They can rapidly cool bottled beverages using a refrigeration system and can include means for indicating to a user when the bottles are cooled to a desired temperature.

For example, embodiments include a beverage chiller for chilling a bottled beverage, where the beverage chiller includes a first chamber accessible to a user via a chiller door, a second chamber below the first chamber, and a beverage container tray located between and separating the first chamber from the second chamber. The beverage container tray may include a beverage container opening configured to receive a bottle to be cooled. A seal may be located within each beverage container opening to fill the space between the beverage container opening and a bottle placed in the beverage container opening. Each beverage container opening may include a visual indicator, wherein the visual indicator is configured to display information about the temperature of a bottle placed in the beverage container opening.

Embodiments also include a beverage chiller for chilling a bottled beverage, where the beverage chiller includes a cooling chamber having an opening, and a beverage container tray placed across and sealing the opening of the cooling chamber. The beverage container tray may include a beverage container opening configured to receive a bottle to be cooled. A door may be located within each beverage container opening, wherein the door is configured to open when a bottle is inserted into the beverage container opening. A seal may be located within each beverage container opening to fill the space between the beverage container opening and a bottle placed in the beverage container opening. Each beverage container opening may include a visual indicator, wherein the visual indicator is configured to display information about the temperature of a bottle placed in the beverage container opening.

Embodiments also include a beverage chiller for chilling a bottled beverage, where the beverage chiller includes a cooling chamber having an opening, and a chiller door positioned across and sealing the opening of the cooling chamber. The user may access the cooling chamber by opening the cooler door. The cooler may include a beverage container receiver configured to receive a bottle to be cooled. Each beverage container receiver may include a visual indicator, wherein the visual indicator is configured to display information about the temperature of a bottle placed in the beverage container opening.

Drawings

The accompanying drawings, which are incorporated herein and form a part of the specification, illustrate embodiments of the present invention and, together with the description, further serve to explain the principles of the invention and to enable a person skilled in the pertinent art to make and use the invention.

Fig. 1 is a perspective view of a stubby cooler according to some embodiments.

Fig. 2 is a perspective view of the stubby cooler of fig. 1 in an open position according to some embodiments.

Fig. 3 is a partial cross-sectional view of a stubby cooler according to some embodiments.

Fig. 4 is a partial cross-sectional view of a stubby cooler according to some embodiments.

Fig. 5 is a partial perspective view of a stubby cooler according to some embodiments.

Fig. 6 is a partial perspective view of a stubby cooler according to some embodiments.

Fig. 7A is a partial perspective view of a stubby cooler according to some embodiments.

Fig. 7B is a partial perspective view of a beverage cooler and beverage container according to some embodiments.

Detailed Description

The present invention will now be described in detail with reference to embodiments thereof as illustrated in the accompanying drawings. References to "one embodiment," "an example embodiment," etc., indicate that the embodiment described may include a particular feature, structure, or characteristic, but every embodiment may not necessarily include the particular feature, structure, or characteristic. Moreover, such phrases are not necessarily referring to the same embodiment. Further, when a particular feature, structure, or characteristic is described in connection with an embodiment, it is submitted that it is within the purview of one skilled in the art to effect such feature, structure, or characteristic in connection with other ones of the embodiments whether or not explicitly described.

Some conventional stubby coolers utilize ice as the primary mechanism for cooling the beverage to be consumed. These beverage coolers may comprise, for example, an insulated enclosure filled with ice into which liquid may be poured or into which the packaged beverage may be placed. However, the ice for these beverage coolers can be difficult to obtain and replenish, particularly if the beverage cooler and ice maker are not in the same location. Furthermore, the use of ice as the primary cooling method may limit user control over the temperature of the beverage and the rate of cooling of the beverage.

Some beverage coolers that use ice to cool beverages require the ice to be placed in direct contact with the liquid. While this may cool the beverage, the strength of the beverage will change as the ice melts, thereby diluting the beverage. Such dilution may be less than ideal in beverages having a particular ingredient ratio, such as sports beverages. Some stubby coolers may require ice to be placed around a container, such as a bottle, if the beverage to be cooled is stored in the container. While this method may not dilute the beverage, the ice may melt upon contact with the relatively warm surface of the container, causing the surface of the container to wet. This may require the consumer to dry the bottle before drinking the beverage, which may create a poor experience for the consumer.

Some beverage coolers do not use ice as the primary cooling mechanism, but rather use an electrically powered cooling system, such as a refrigeration system or a thermoelectric cooling system. However, some existing powered beverage coolers may not cool beverages quickly or efficiently enough for use in applications requiring continuous large amounts of cooled beverages, such as in sporting events. For example, some existing beverage coolers may not have the capability to: after the beverage is removed from the beverage cooler, the beverage is cooled at the same rate that the beverage is heated by ambient conditions. Similarly, some existing beverage coolers may not have the ability to cool an amount of beverage that matches or exceeds the beverage consumption rate requirement. This is especially true in sports-related applications, where athletes can drink large quantities of beverages in a short period of time.

In some powered beverage coolers, once the beverage container is cooled, condensation may form on the outer surface of the beverage container, which may require the consumer to dry the bottle before consuming the beverage. As with ice-based coolers, this can lead to a poor experience for the consumer.

Some powered or unpowered beverage coolers may not display the temperature of the beverage being cooled, which may result in the beverage being removed for consumption above a desired temperature. Similarly, the beverage may remain in the cooler longer than desired after reaching the desired temperature, wasting energy or resources and occupying cooler space otherwise available for another beverage.

As described herein, some embodiments may provide an efficient system for rapidly cooling a beverage in a bottle without the use of ice. Some of these stubby coolers may include a cooling chamber into which one or more bottles may be inserted for cooling. The stubby cooler may include a refrigeration system having an evaporator and a fan in a cooling chamber, wherein the evaporator removes heat from the cooling chamber and the fan circulates chilled air around the bottles and through the evaporator in the cooling chamber. The bottles to be cooled may be inserted into the cooling chamber through an opening in the cooling chamber. Each opening may have a respective door that minimizes air loss when a bottle is not disposed in the opening, and may have a respective seal that minimizes air loss when a bottle is disposed in the opening. Each seal may wipe condensation off the outer surface of the bottle as it is removed from the opening so that a user may receive a relatively dry cooling bottle from the stubby cooler. One or more openings, and in some embodiments, each opening, may have a corresponding display, such as, for example, a series of lights that use color or light intensity to indicate the temperature of the bottle disposed in the opening or to indicate whether the bottle has cooled to a desired temperature. Some embodiments may allow a user to select a desired beverage temperature and/or cooling rate of the beverage using an automated control system.

Embodiments will now be described in more detail with reference to the accompanying drawings. Referring to fig. 1-3, the beverage cooler 10 may include a cooler housing 100, a beverage container tray 200, and a cooling system 300.

The cooler housing 100 may be configured to receive and store a plurality of beverage containers 400, such as bottles 400, and to reduce and/or maintain the temperature of the beverage containers 400. The beverage container 400 may include bottles, squeeze bottles, cans, and other beverage containers for providing a beverage to a consumer. Throughout the disclosure, the component may be referred to as a bottle, but it should be understood that other beverage containers may be used. In some embodiments, the cooler housing 100 is configured to rapidly reduce the temperature of one or more beverage containers 400 such that a continuously high demand for cooled beverage at a desired temperature may be met. The cooler housing 100 may include an exterior surface 110 defining the shape of the stubby cooler 10 and an interior surface 120 defining an interior space 122. In some embodiments, the cooler housing 100 has a rectangular cuboid shape. In some embodiments, the cooler housing 100 may comprise other shapes, including, for example, cubic, tubular, cylindrical, spherical, or frustoconical, and may be symmetric or asymmetric about any axis.

In some embodiments, the cooler housing 100 may be made of metal, plastic, or composite materials, as well as combinations thereof. In some embodiments, the cooler housing 100 or a portion of the cooler housing 100 may include a thermally insulating material to reduce heat exchange between the interior space 122 and the ambient conditions surrounding the beverage cooler 10. In some embodiments, a layer of air may be sealed between the outer surface 110 and the inner surface 120 to act as a thermal insulator.

The cooler housing 100 may include wheels 160, such as casters, that allow the beverage cooler 10 to roll. In some embodiments, the beverage cooler 10 may include four wheels 160 disposed on the bottom 116 of the cooler housing 100.

The beverage container tray 200 may be disposed within the cooler housing 100. In some embodiments, the beverage container tray 200 may be a substantially flat member and may have a top surface 210 and a bottom surface 220. As shown in fig. 1 and 2, for example, the beverage container tray 200 may be oriented such that it is substantially perpendicular to one or more sides 114 of the cooler housing 100. However, the beverage container tray 200 may be disposed at a non-perpendicular angle relative to the side 114. The beverage container tray 200 may be arranged such that it divides at least a portion of the interior space 122 into two portions, thereby forming a first chamber 170 and a second chamber 180. In some embodiments, the second chamber 180 is disposed below or adjacent to the first chamber 170. In some embodiments, the volumes of the first chamber 170 and the second chamber 180 may be equal. In some embodiments, the first chamber 170 may have a larger volume than the second chamber 180. In some embodiments, the second chamber 180 may have a larger volume than the first chamber 170. The beverage container tray 200 may include an insulating material to reduce heat exchange between the first and second chambers 170, 180.

The beverage container tray 200 may include a plurality of beverage container openings 230 that extend through the beverage container tray 200 from the top surface 210 to the bottom surface 220. Each beverage container opening 230 may be configured to receive one of the beverage containers 400, such as a squeeze bottle 400. In some embodiments, the beverage container opening 230 may have a perimeter 232 that is circular in shape and may have a diameter of at least 2 inches. As shown in fig. 2, the beverage container tray 200 may include twenty-four beverage container openings 230 arranged in a grid pattern defining rows and columns of openings 230. However, the beverage container tray 200 may include any number of beverage container openings 230 arranged in any arrangement.

As shown in fig. 3 and 5, for example, a beverage container shelf 270 may be disposed within the cooler housing 100 and may have a support surface 272 configured to support one or more beverage containers 400. In some embodiments, the beverage container shelf 270 may be disposed below the beverage container tray 200 in the second chamber 180 such that the bottom end 420 of one or more beverage containers 400 disposed in the beverage container opening 230 may be supported by the support surface 272. In some embodiments, the distance between the bottom surface 220 of the beverage container tray 200 and the support surface 272 may be less than the distance between the top end 410 and the bottom end 420 of the beverage container 400, such that the bottom end 420 of the beverage container 400 may be disposed in the second chamber 180 while the top end 410 of the beverage container 400 may be disposed in the first chamber 170. Such an arrangement may facilitate user access to the beverage container 400. In some embodiments, the distance between the bottom surface 220 of the beverage container tray 200 and the support surface 272 may be at least half the distance between the top end 410 and the bottom end 420 of the beverage container 400.

In some embodiments, the position of the beverage container shelf 270 may be adjustable relative to the beverage container tray 200 such that the beverage cooler 10 may cool beverage containers of various heights.

As shown in fig. 1 and 2, the first door 130 may be disposed in the top surface 112 of the cooler housing 100 such that a user may access the interior space 122 of the cooler housing 100 through the first door 130. In some embodiments, at least a portion of the first door 130 can be made of a transparent material (e.g., glass or plastic) such that a user can see the interior space 122 of the cooler housing 100 without opening the first door 130. For example, the first door 130 may comprise a transparent glass or plastic panel. In some embodiments, a user may access the first compartment 170 through the first door 130. With the first door 130 in the open position, a user may insert a beverage container 400 to be cooled into one of the beverage container openings 230 or may remove the cooled beverage container 400 from one of the beverage container openings 230.

The beverage container tray 200 may include a plurality of beverage container doors 240 coupled to the beverage container tray 200 and disposed at each of the beverage container openings 230. As shown in fig. 4, each beverage container door 240 may include two adjacent door panels 242 hingedly connected to the beverage container tray 200 and configured to together completely cover the respective beverage container opening 230. However, in some embodiments, each beverage container door 240 may include a single door panel 242 configured to completely cover the respective beverage container opening 230.

The beverage container doors 240 may be hingedly coupled to the bottom surface 220 and may include one or more biasing mechanisms 246 that bias the doors in a closed position (i.e., covering the respective beverage container openings 230). When in the closed position, the beverage container door 240 may form a seal with the beverage container tray 200, thereby restricting air from passing through the beverage container opening 230 when the beverage container 400 is not disposed in the beverage container opening 230. In embodiments including two adjacent door panels 242, the seam 244 may be formed where the two door panels 242 meet in the closed position. The seam 244 may include a seal that restricts air from passing through the seam 244. In some embodiments, one or more door panels 242 may be substantially flat such that a substantially flat surface is provided when the door panel 242 is in the closed position without beverage containers being disposed in the corresponding beverage container openings 230. In one embodiment, the biasing mechanism 246 comprises a torsion spring. The beverage container door 240 may include an insulating material to reduce heat exchange between the first and second chambers 170, 180 when the beverage container door 240 is in the closed position. The beverage container door 240 may have an open position wherein the beverage container door 240 does not form a seal with the beverage container tray 200 and does not cover the respective beverage container opening 230.

In some embodiments, when a user inserts the beverage container 400 into the beverage container opening 230, the bottom end 420 of the beverage container 400 may press against the respective beverage container door 240, overcoming the biasing force provided by the biasing mechanism 246, thereby moving the beverage container door 240 from the closed position to the open position without direct contact with the user. Then, when the user removes the beverage container 400 from the beverage container opening 230, the biasing force provided by the biasing mechanism 246 causes the beverage container door 240 to automatically move from the open position to the closed position. In some embodiments, the beverage container door 240, including the door panel 242, may be made of plastic, hard rubber, or other suitable rigid or semi-rigid material.

In some embodiments, the beverage container tray 200 may include a plurality of beverage container seals 250 coupled to the beverage container tray 200 and disposed at one or more of the beverage container openings 230. In some embodiments, when the beverage container 400 is disposed in the beverage container opening 230, the seal 250 may be configured to fill a space between the beverage container tray 200 and an outer surface 430 of the beverage container 400, thereby preventing air from passing through the beverage container opening 230 when the beverage container 400 is disposed in the beverage container opening 230. In some embodiments, the seal 250 may be made of silicon, rubber, or another flexible material.

In some cases, condensed water may form on the outer surface 430 of the beverage container 400 as the beverage container 400 is cooled in the beverage cooler 10. The beverage container seal 250 may be configured to remove condensed water from the beverage container 400 when the beverage container 400 is removed from the stubby cooler 10. The beverage container seal 250 may be flush with the outer surface 430 of the beverage container 400, and thus, when the beverage container 400 is removed from the beverage container opening 230, the seal 250 will wipe along the outer surface 430 of the beverage container 400, thereby collecting and removing accumulated condensed water from the outer surface 430.

As shown in fig. 6, the beverage container tray 200 may include one or more visual indicators 260 configured to display information about the beverage containers 400 disposed in the beverage container tray 200. In some embodiments, there may be one visual indicator 260 for each beverage container opening 230, and each visual indicator 260 may be configured to display information related to the temperature of the beverage container 400 disposed in the respective beverage container opening 230. In some embodiments, the visual indicators 260 may be associated with beverage containers 400 in a row or column to display information related to the temperature of the beverage containers disposed in the respective row or column. In some embodiments, the visual indicator 260 can be a plurality of lights (e.g., LEDs) disposed along the perimeter 232 of each respective beverage container opening 230. In some embodiments, the visual indicator 260 may be a single light, a multi-colored light, or an electronic display. In some embodiments, the visual indicator 260 may be disposed within the first chamber 170. In some embodiments, the visual indicator 260 may be disposed outside of the first chamber 170 and may, for example, be coupled to the outer surface 110.

In embodiments where the visual indicator 260 comprises a plurality of lights, the visual indicator 260 may be disposed within the beverage container opening 230. As shown in fig. 7A, for example, if the beverage container 400 is not disposed within the beverage container opening 230, the light may illuminate the beverage container opening 230, the seal 250, and/or the beverage container door 240. As shown in fig. 7B, for example, if the beverage container 400 is disposed within the beverage container opening 230, the light may illuminate the outer surface 430 of the beverage container 400, the beverage container opening 230, and/or the seal 250.

The visual indicator 260 may be electrically coupled to an indicator controller 262 that may control the visual indicator 260 based on the temperature or estimated temperature of the beverage container 400 disposed in the beverage container opening 230. In some embodiments, each beverage container opening 230 may include a temperature sensor 264 that measures the temperature of an outer surface 430 of a beverage container 400 disposed in the beverage container opening 230. Indicator controller 262 may be electrically coupled to a temperature sensor 264 and may receive input from temperature sensor 264. In some embodiments, each beverage container opening 230 may include a beverage container sensor 268 that senses when a beverage container 400 is inserted into the beverage container opening 230. The indicator controller 262 may be electrically coupled to the beverage container sensor 268 and may receive input from the beverage container sensor 268. The indicator controller 262 may estimate the temperature of the beverage container 400 based on the amount of time the beverage container 400 has been disposed in the beverage container opening 230, which may be measured from the time the beverage container sensor 268 first sensed the beverage container 400.

In some embodiments, the visual indicator 260 may be a plurality of multi-colored LEDs configured to display certain colors corresponding to the measured or estimated temperature of the beverage container 400. For example, if the measured or estimated temperature of the beverage container 400 is higher than the desired temperature, a red light may be illuminated by the indicator controller 262, indicating that the particular beverage container is not suitable for drinking. If the measured or estimated temperature of the beverage container 400 is equal to or below the desired temperature, the blue light may be illuminated by the indicator controller 262. Similarly, the visual indicator 260 may be a plurality of single color LEDs configured to turn on or off based on a measured or estimated temperature of the beverage container 400. For example, if the measured or estimated temperature of the beverage container 400 is higher than the desired temperature, no light may be illuminated. If the measured or estimated temperature of the beverage container 400 is equal to or below the desired temperature, a light may be illuminated by the indicator controller 262 to indicate that cooling is complete. In some embodiments, the visual indicator 260 may be a plurality of LEDs configured to vary the light intensity based on a measured or estimated temperature of the beverage container 400. For example, if the measured or estimated temperature of the beverage container 400 is higher than the desired temperature, the light may be dimly illuminated. If the measured or estimated temperature of the beverage container 400 is equal to or below the desired temperature, the light may be brightly illuminated or may be turned on or off to indicate that cooling is complete. In some embodiments, the desired temperature may be user defined.

As shown in fig. 3, the beverage chiller 10 may include a cooling system 300, which may be, for example, a refrigeration system having an evaporator 310, a compressor 320, a condenser 330, and an expansion valve 340, interconnected with a conduit 360 and containing a refrigerant.

The evaporator 310 may be disposed in the second chamber 180 and may include a coil for absorbing heat from air in the second chamber 180. In some embodiments, a circulation fan 312 may be disposed in the second chamber 180 to circulate air within the second chamber 180 such that the air is drawn over the evaporator 310 to be cooled, and then moved to cool the beverage containers 400 disposed in the second chamber 180.

In some embodiments, a circulation isolation wall 314 may be disposed in the second chamber 180. In some embodiments, the second chamber 180 may have a substantially rectangular cuboid shape. The circulation partition wall 314 may extend between two opposing sides 114 of the cooler housing 100 while leaving a circulation space 318 between the circulation partition wall 314 and the inner surface 120 on the two remaining sides 114. In this configuration, the air diverted by the circulation fan 312 may circulate within the second chamber 180. As shown in fig. 3, air may be drawn through the evaporator 310 by a circulation fan 312. The air may then reach the side 114 where it is forced downward through the circulation space 318 and under the circulation isolation wall 314. Then, when the air reaches the opposite side 114, it may be forced upwardly through the opposite circulation space 318, where it travels over the circulation partition wall 314, through the beverage container 400, and back to the fan 312, completing the circulation. This configuration may allow a greater amount of air to contact the evaporator 310, which may help to quickly cool the beverage container 400. In some embodiments, the beverage cooler may cool the beverage container faster than the beverage container 400 is heated by ambient conditions.

In some embodiments, the beverage container door 240 may be oriented parallel to the direction of airflow in the second chamber 180 when in the open position, such that air may more easily flow through the door 240 when open.

In some embodiments, the circulation isolation wall 314 may also be used to support the beverage containers 400 in a manner similar to the beverage container rack 270, wherein the bottom ends 420 of the beverage containers 400 may rest on the top surface 316 of the circulation isolation wall 314. In some embodiments, the circulation partition wall 314 may be made of metal and may be conductively coupled to the evaporator 310. In embodiments where the beverage container 400 rests on the top surface 316 of the circulation isolation wall 314, the beverage container 400 may be cooled by conduction.

In some embodiments, the interior space 122 can include a floor 192 that can be configured to partition the interior space 122, thereby forming a machine chamber 190 adjacent to one or both of the first and second chambers 170, 180. The floor may include an insulating material to reduce heat exchange between the first and/or second chambers 170, 180 and the machine chamber 190.

The compressor 320 may be disposed in the machine room 190 together with the condenser 330, the condenser fan 332, and the expansion valve 340. In some embodiments, the compressor 320 may be electrically driven and may use grid power. In some embodiments, the compressor 320 may be electrically powered and receive power from a battery, which may be stored in the machine room 190. In some embodiments, the compressor 320 may be powered by gasoline or another petroleum-based fuel.

The condenser 330 may be disposed in the machine compartment 190 and may include coils for rejecting heat absorbed by the evaporator 310 to the environment. In some embodiments, the vent 150 may be disposed in the side 114 of the cooler housing 100, whereby heat from the condenser 330 may be transferred from the machine compartment 190 to the ambient environment. In some embodiments, the condenser 330 may be disposed outside of the cooler housing 100 and may be attached to the side 114 of the cooler housing 100, for example. In some embodiments, the condenser fan 332 may be disposed proximal to the condenser 330 and may force air through the condenser 330 such that heat is more quickly dissipated from the condenser 330. In some embodiments, the condenser fan 332 may be disposed in the machine compartment 190. In some embodiments, the condenser fan 332 may be disposed proximate the exhaust 150. In some embodiments, the condenser fan 332 may not be used, and air may naturally pass through the condenser 330 in order to dissipate heat from the condenser 330. An expansion valve 340 may be provided in the machine chamber 190, and may adjust the amount of refrigerant flowing into the evaporator 310 through a pipe 360.

As shown in fig. 1, in some embodiments, the cooling system 300 may further include a cooling controller 350 that may be used to automatically control the cooling system 300. The cooling controller 350 may include a user interface 352 whereby a user may turn the cooling system 300 on or off, set a desired temperature of one or both of the chambers 170, 180, or set a rate at which the beverage container 400 is cooled. The user interface 352 may include means for receiving user input (e.g., electromechanical buttons), means for communicating with a user (e.g., a visual display), and/or a combined means for receiving input and communicating with a user (e.g., a touch screen display). The user interface 352 may include a combination of buttons, visual displays, and/or touch screens. The user interface may be disposed in the side 114 of the cooler housing 100. In some embodiments, the user interface may be remotely connected to the cooling system 300 such that the user interface is not secured to the stubby cooler 10. The user interface 352 may be interconnected to the cooling system 300 by a wired or wireless connection. In some embodiments, a user may control the cooling system 300 using an application on a mobile communication device (e.g., a smartphone).

In some embodiments, the cooling controller 350 may be used to automatically change the rate at which the cooling system 300 cools one or both of the chambers 170, 180 and/or the beverage containers 400. For example, when the cooling system 300 is first activated, the cooling system 300 may operate to rapidly cool one or both of the compartments 170, 180 and/or the beverage container 400 from ambient temperature to a refrigerated temperature in a given amount of time. For example, during this initial phase of cooling, the cooling system 300 may reduce the temperature of the beverage container 400 from about 70 degrees Fahrenheit to 110 degrees Fahrenheit to less than about 30 degrees Fahrenheit to 50 degrees Fahrenheit in less than about 30 to 90 minutes. In some embodiments, the cooling system 300 may reduce the temperature of the beverage container 400 from about 90 degrees fahrenheit to less than about 40 degrees fahrenheit in less than about 60 minutes. The cooling system 300 may generate cooling air at approximately-20 to 20 degrees Fahrenheit within one or both of the cooling chambers 170, 180. In some embodiments, the cooling system 300 may generate about-5 degrees Fahrenheit of cooling air within one or both of the cooling chambers 170, 180. Then, after the initial stage of cooling is complete, the cooling system 300 may automatically reduce the rate at which one or both of the chambers 170, 180 and/or the beverage container 400 are cooled, or may maintain a particular temperature of one or both of the chambers 170, 180 and/or the beverage container 400. The cooling controller 350 may receive input from one or more temperature sensors 264, and may change the cooling rate, the cooling phase, or turn the cooling system 300 on or off based on the input received from the temperature sensors 264. In some embodiments, the cooling system 300 may maintain the temperature of the beverage container 400 at a user-defined temperature. In some embodiments, the cooling system 300 may maintain the temperature of the beverage container 400 at approximately 20 to 40 degrees fahrenheit. In some embodiments, the cooling system 300 may maintain the temperature of the beverage container 400 at about 32 degrees fahrenheit.

In some embodiments, the second door 140 may be disposed on the side 114 of the cooler housing 100 such that a user may access the interior space 122 of the cooler housing 100 through the second door 140. In some embodiments, a user may access only the machine compartment 190 using the second door 140. In some embodiments, a user may access one or more of the first chamber 170, the second chamber 180, or the machine chamber 190 using the second door 140.

It is to be understood that the detailed description section, and not the summary and abstract sections, is intended to be used to interpret the claims. The summary and abstract sections may set forth one or more, but not all exemplary embodiments of the present invention contemplated by the inventors, and are therefore not intended to limit the present invention and the appended claims in any way.

The foregoing description of the specific embodiments will so fully reveal the general nature of the invention that others can, by applying knowledge within the skill of the art, readily modify and/or adapt for various applications such specific embodiments, without undue experimentation, without departing from the general concept of the present invention. Therefore, such adaptations and modifications are intended to be within the meaning and range of equivalents of the disclosed embodiments, based on the teaching and guidance presented herein. It is to be understood that the phraseology or terminology herein is for the purpose of description and not of limitation, such that the terminology or phraseology of the present specification is to be interpreted by the skilled artisan in light of the teachings and guidance.

The breadth and scope of the present invention should not be limited by any of the above-described exemplary embodiments, but should be defined only in accordance with the following claims appended hereto and their equivalents.