The present invention relates to an apparatus and method for cooling a dispensed beverage, and more particularly, cooling of the beverage by direct contact of a refrigerant with a liquid reservoir that holds the beverage prior to being dispensed.
Some beverages, such as beer, are preferably served in a chilled state. For beer on tap dispensed from a dispense tower, it is desirable to cool the beer near the dispense point so that the customer receives the beer at a desired chilled temperature. If the beer is chilled at a location far from the dispense point, the beer will warm due to contact of the beer with the transport line.
There are a number of prior art systems that disclose various ways to chill a dispensed beverage. A few examples of these systems include the inventions disclosed in U.S. Pat. No. 5,079,927; US Patent Publication Nos. US2003/0161925, US2003/0211219, and US2003/0161933.
One common method to chill beer is by the use of a glycol cooling system. In this type of system, a cooled glycol circulation loop is placed in heat transfer relationship with a transport line carrying the beer or a reservoir of the beer. Heat is transferred from the warmer beer to the cooler glycol loop. The warmed glycol is then cooled by circulating the glycol through a heat exchanger which is part of a separate refrigerant loop. The refrigerant loop typically uses a standard refrigerant such as Freon that is continuously recycled in the refrigerant loop. Heat is transferred within the heat exchanger from the warmed glycol to the cooler refrigerant.
For these glycol cooling systems, the cooling of the beer is therefore achieved by indirect cooling. That is, the glycol is the medium which interacts with the warmer beverage to cool the beverage, while the glycol is cooled by a refrigerant. While glycol systems have proven to be adequate for their intended purpose, the requirement to use the glycol circulation loop in conjunction with a refrigerant loop adds to the inefficiency, complexity and cost of a system for cooling a beverage.
Therefore, there is a need for a system and apparatus wherein a dispensed beverage can be effectively and selectively cooled, yet cooling is preferably achieved through a simplified direct cooling system that may be mounted near the point where the beverage is dispensed.
In accordance with the present invention, an apparatus and method are provided for cooling a dispensed beverage. The need for a simple yet effective cooling system is satisfied with the present invention wherein direct cooling of a beverage is achieved by circulation of a refrigerant in contact with a reservoir that holds the beverage just prior to being dispensed. A dispense font or tower surrounds the reservoir that contains the beverage. The open space within the font acts as the evaporator of a closed refrigeration loop so that direct cooling is achieved without having to use a separate heat transfer loop such as a glycol loop.
In the preferred embodiment, the invention includes a beverage supply group or assembly and a refrigerant group or subsystem. Beginning with the beverage supply assembly, a dispense font is mounted to a bar surface in the traditional manner so that the font is displayed for viewing by a consumer. The dispense font is a sealed chamber that communicates with refrigerant flow lines from the refrigerant group. A liquid reservoir is disposed within the chamber and holds a quantity of the beverage. A supply line passes through the chamber and interconnects the liquid reservoir to a source of the beer such as a keg. A dispense line also passes through the chamber and interconnects the liquid reservoir to a spigot. A tap valve at the spigot controls flow of beverage through the spigot.
The refrigerant group components include a compressor for taking an expanded, evaporated refrigerant, and compressing the same for delivery to a condenser. The condenser acts as a heat exchanger to remove heat from the compressed gas thereby condensing the refrigerant into liquid form. The refrigerant is then circulated into the open space or chamber of the dispense font, and as the refrigerant reaches the expanded internal volume, the refrigerant evaporates thus cooling the beverage contained within the liquid reservoir. The evaporated refrigerant is then drawn back into the compressor for recycling within the refrigeration loop.
The components of the refrigerant group are mounted preferably directly under the bar surface thereby minimizing the length of refrigerant lines which must be used to deliver the refrigerant to the chamber of the dispense font. The refrigerant group can be made of such a compact size that it does not require storage at a separate location. The larger glycol cooling systems are not usually stored at the bar because of space constraints at the bar. The short distances that the refrigerant travels within the refrigeration loop of the present invention minimizes loss of cooling and thus enhances refrigeration capability.
Because of the highly efficient nature of direct cooling achieved by contact of the refrigerant with the liquid reservoir, it may be necessary to periodically heat the beverage to keep it from freezing. Accordingly, a heating jacket can be placed within the dispense font and adjacent the reservoir to selectively heat the reservoir. The heating jacket contains one or more heating elements that are placed in close proximity to the liquid reservoir. The heating elements are selectively energized to provide heat when necessary to prevent the beverage from freezing. Temperature control of the beverage can be achieved by use of a temperature sensor placed within or on the liquid reservoir. The temperature sensor electrically connects to a temperature controller which takes temperature data from the sensor, and periodically activates the heating elements to prevent freezing of the beverage. This temperature data can also be used to control the refrigerant loop by periodically activating the compressor and condenser to provide a flow of refrigerant through the open space of the font.
In accordance with another aspect of the present invention, the direct cooling achieved by the refrigerant which evaporates within the dispense font also cools the outer surface of the dispense font to a degree that frost or ice will develop on the outer surface of the dispense font. The iced surface of the dispense font adds commercial value to the dispense font because it conveys the impression that the beverage to be dispensed has been cooled to a very cold temperature, which is desirable for many customers.
In accordance with yet another aspect of the invention, it may be desirable to allow at least some portion of the beverage to freeze in the liquid reservoir so that when the beverage is dispensed, some amount of the beverage is served frozen.
Other features and advantages of the present invention will become apparent from the drawings, taken in conjunction with the detailed description.
The apparatus of the present invention is illustrated in
The font body 18 may be made of a desired metal, such as stainless steel. The interior of the font body 18 defines the chamber having an interior open space 30 which acts as the evaporator. Mounted within the open space is a liquid reservoir 52. A supply or inflow line 44 passes through the front body 18 of the dispense font, and connects with the liquid reservoir 52. The opposite end of supply line 44 connects to a beverage source 70, such as a beer keg that is typically pressurized. An outlet or dispense line 50 exits the upper portion of the liquid reservoir, and passes through the body 18 of the dispense font. The locations where the supply line 44 and dispense line 50 pass through the font body are sealed with respect to the font body. The beverage to be dispensed is held within the liquid reservoir, and when the tap handle 46 is operated, the beverage flows through spigot 48.
The refrigeration subsystem of the present invention may be mounted under the bar surface, and directly adjacent the dispense font 12. As shown, the refrigeration subsystem includes a compressor 20 and a condenser 22. The refrigeration subsystem is a closed loop system which circulates a refrigerant. Beginning with the compressor, the refrigerant is compressed into a high pressure gas. The high pressure refrigerant gas flows through line 24 into the condenser 22. The condenser acts as a heat exchanger to remove heat from the high pressure gas thereby changing the gasified refrigerant to a liquid phase. The liquid refrigerant then flows through line 26 into the interior open space 30 of the font. The open space 30 within the font acts as the evaporator of the refrigeration subsystem. As the refrigerant passes into the larger volume of the open space in the dispense font, the liquid refrigerant evaporates thereby removing heat from the open space, the liquid reservoir 52, and the beverage within the reservoir. The refrigerant flows back to the compressor 20 through line 32. Depending upon the amount of cooling necessary, the compressor will continuously or periodically operate to draw in evaporated refrigerant through line 32. The cycle is then repeated by compressing the refrigerant, and passing the refrigerant to the condenser. An orifice 28 defines the interface between line 26 and the interior open space 30. Similarly, orifice 34 defines the interface between the interior open space 30 and the return line 32. Suitable refrigerants for use in the refrigeration subsystem include R134A and R404A. Other refrigerants may also be used depending upon the specific subsystem design and use.
Because of the cooling efficiency of the refrigeration subsystem, it may be necessary to actually add heat to the interior space 30 in order that the beverage does not freeze in lines 44 and 50, as well as in the reservoir 52. Accordingly, a heating jacket 36 may be disposed within the open space 30, and positioned around the liquid reservoir 52. The heating jacket 36 acts as a means to uniformly transfer heat to the liquid reservoir. It is preferable to space the heating elements along the jacket to best distribute the heat to the reservoir. At various locations on the interior surface of the heating jacket 36, as shown in
Conveniently, the components of the refrigeration subsystem may be mounted directly under the bar surface within a housing 62 which is secured to the lower surface of the bar 14. Thus, no separate storage facility is required for the refrigeration subsystem, and line losses are substantially eliminated by the short distances required for delivering the refrigerant to the open space within the dispense font.
In another aspect of the present invention, the circulation of the refrigerant within the open space of the dispense font many sufficiently cool the dispense font body 18 so that frost and/or ice will form on the outer surface of the dispense font. The formation of frost and ice crystals on the dispense font adds commercial value to the dispense font, particularly for those patrons who enjoy a cooled beverage.
In another aspect of the invention, it may be desirable to provide some portion of the beverage in frozen form. The temperature controller allows precise control so that some of the beverage within the liquid reservoir may freeze.
There are numerous advantages of the present invention in cooling a dispensed beverage. The refrigeration subsystem can be placed very near the reservoir that holds the beverage just prior to being dispensed. Direct cooling is achieved by circulating the refrigerant within the open space of the dispense font. This direct cooling thereby eliminates the need for a separate glycol loop, or other type of secondary cooling loop. The relatively small amount of air space surrounding the liquid reservoir that must be cooled allows the use of very small refrigeration components. These small refrigeration components may be incorporated within a housing that is easily secured under the surface to which the dispense font is mounted. Excess cooling produced by the refrigeration subsystem can be counteracted by a heat source that is also directly incorporated within the dispense font assembly. Use of a temperature controller allows precise control of both the refrigeration subsystem and the heat source.
The apparatus and method of the present invention have been set forth above with respect to a preferred embodiment; however, other changes and modifications to the present invention are contemplated in accordance with the scope of the claims appended hereto.
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