초록 ▼

A closed system and method of cooling and remote dispensing beverages (alcoholic or non-alcoholic) to a remote dispensing tower. The closed system employs a closed and sealed loop of continuously circulating coolant. The continuously circulating coolant is daisy chained through a bank of heat exchan

A closed system and method of cooling and remote dispensing beverages (alcoholic or non-alcoholic) to a remote dispensing tower. The closed system employs a closed and sealed loop of continuously circulating coolant. The continuously circulating coolant is daisy chained through a bank of heat exchangers in the closed and sealed loop. Each heat exchanger flash chills a corresponding one beverage to be dispended at the remote dispensing tower via a primary trunk line. The primary trunk line communicates the flash chilled beverage in heat exchange relationship with a supply line of said coolant.

대표청구항 ▼

What is claimed is: 1. A closed cooling and remote dispensing system for dispensing a plurality of beverages, each beverage may be alcoholic or non-alcoholic and is stored in a corresponding container remote from a dispensing tower, comprising: a main chiller for chilling a coolant for circulation

What is claimed is: 1. A closed cooling and remote dispensing system for dispensing a plurality of beverages, each beverage may be alcoholic or non-alcoholic and is stored in a corresponding container remote from a dispensing tower, comprising: a main chiller for chilling a coolant for circulation in a closed and sealed loop to and from said tower; a primary trunk coupled in said closed and sealed loop, said primary trunk bundling supply and return lines of said coolant and product lines for delivering the plurality of beverages in heat exchange relationship with said coolant to said tower; and, a heat exchanger coupled in said closed and sealed loop and in fluid communication to receive a corresponding one beverage for flash chilling a temperature of the corresponding one beverage to a temperature of the coolant in said closed loop before the corresponding one beverage enters a corresponding one product line of said primary trunk, said heat exchanger is a first heat exchanger of a plurality of heat exchangers, wherein each heat exchanger of said plurality of heat exchangers receives a corresponding different one beverage for independently flash chilling a temperature of the corresponding different one beverage to the temperature of the coolant in said close loop before the corresponding one different beverage enters a corresponding different one product line of said primary trunk. 2. The system according to claim 1, wherein: the temperature of said coolant is a temperature of the return line of said coolant; and, said coolant is a food grade coolant and continuously circulates in said closed and sealed loop. 3. The system according to claim 1, wherein: the temperature of said coolant is a temperature of the supply line of said coolant; and, said coolant is a food grade coolant and continuously circulates in said closed and sealed loop. 4. The system according to claim 1, wherein: said first heat exchanger comprises a coolant-in port adapted to receive the coolant from the closed and sealed loop and a coolant-out port daisy chained to the coolant-in port of an adjacent heat exchanger of said plurality heat exchangers; and, remaining heat exchangers of said plurality of heat exchangers are daisy chained to it's corresponding adjacent heat exchanger; and, a last heat exchanger outputs from its coolant-out port said coolant to said closed and seated loop. 5. The system according to claim 1, wherein: each of said plurality of heat exchangers is adapted to be installed in a cooler and has a beverage throughput of approximately 16 gallons/hr. for a delta temperature of 18�� F. for input and output beverage temperatures; and, wherein said main chiller has a pump rate of 1.5 gallons/min. 6. The system according to claim 1, wherein: said heat exchanger comprises a plurality of plated dividers spreading said coolant and said corresponding one beverage into thin sheets of liquid; and, said plurality of plated dividers are plated using Nickel, a Nickel Alloy or other plating materials suitable for food grade products approved by the National Sanitation Foundation (NSF). 7. The system according to claim 1, wherein said each heat exchanger is a non-submersible heat exchanger which is foam insulated and adapted to be vertically mounted on a wall in a cooler. 8. The system according to claim 1, wherein: said corresponding one beverage is carbonated; flash chill comprises chilling said corresponding one beverage at a rate of at least 16 gallons/per hr.; said coolant on said supply line is in the range of 27�� F. to 29�� F.; said corresponding one beverage is delivered at 32�� or less; and, a distance between said tower and said container is within the range of 1 to 500 ft. 9. A method of cooling and remote dispensing a plurality of beverages, each beverage may be alcoholic or non-alcoholic and is stored in a corresponding container remote from a dispensing tower, comprising the steps of: chilling a coolant for circulation in a closed and sealed loop; circulating said coolant in a closed and sealed loop; heat exchanging, in said closed and sealed loop, a bundle of supply and return lines of said circulating coolant and product lines of the plurality of beverages to the tower; flash chilling a temperature of a corresponding one beverage to a temperature of the circulating coolant flowing in said closed and sealed loop; independently flashing chilling, a corresponding different one beverage for flash chilling a temperature of the corresponding different one beverage to the temperature of the circulating coolant daisy chained in said closed loop before the corresponding one different beverage enters a corresponding different one product line of said primary trunk; and, repeating the step of independently flash chilling for at least some of the plurality of beverages. 10. The method according to claim 9, wherein: said flash chilling step takes place before the corresponding one beverage enters a corresponding one product line; the temperature of said coolant is a temperature of the return line of said coolant; and, said circulating step comprises the step of: continuously circulating said coolant in said closed and sealed loop. 11. The method according to claim 9, wherein: said flash chilling step takes place before the corresponding one beverage enters a corresponding one product line; the temperature of said coolant is a temperature of the supply line of said coolant; and, said circulating step comprises the step of: continuously circulating said coolant in said closed and sealed loop. 12. The method according to claim 9, wherein the step of flash chilling comprises the steps of: flash chilling said corresponding one beverage at a rate of approximately 16 gallons/hr. for a delta temperature of 18�� F. 13. The method according to claim 9, wherein said flash chilling comprises: spreading said coolant and said corresponding one beverage into thin sheets of liquid; and, throughputting the spreaded beverage at a rate of at least 16 gallons/hr.