Embodiments of the present invention relate generally to beverage dispensers, including carbonated beverage dispensers and non-carbonated beverage dispensers.
According to some disclosed embodiments, a method of converting a carbonated beverage dispenser to a non-carbonated beverage dispenser includes disconnecting a carbonation tank from fluid communication with the beverage dispenser and installing a pressure tank. The pressure tank may be installed in fluid communication with a carbonation pump and mixing nozzle of the beverage dispenser. The mixing nozzle may dispense the beverage from the beverage dispenser. A pressure switch may also be installed to monitor a pressure in the pressure tank. The pressure switch may actuate the carbonation pump when the pressure in the pressure tank falls below a lower threshold pressure. The pressure switch may also shut off the carbonation pump once the pressure increases above an upper threshold pressure. A pressure regulator may also be installed to regulate the pressure in the beverage supply line. The pressure tank may be a hydro-pneumatic tank.
A beverage dispenser according to some embodiments may include a carbonation pump fluidly coupled to a water source by a beverage supply line. A pressure tank, monitored by a pressure switch, may be fluidly coupled to the beverage supply line. A mixing nozzle may be located at one end the beverage supply line. The pressure switch may monitor a pressure in the pressure tank. The pressure switch may actuate the carbonation pump to increase the pressure in the pressure tank when the pressure falls below a lower threshold pressure and may shut off when the pressure in the tank exceeds an upper pressure threshold.
A beverage dispenser may also comprise a syrup source configured to add syrup to the mixing nozzle. A pre-chilling coil and a post-chilling coil may be in line with the beverage supply line to cool a temperature of the beverage before it is dispensed. The beverage dispenser may include solenoid valves configured to release water from the beverage supply line into the mixing nozzle. A solenoid valve may also release syrup in to the mixing nozzle. The syrup may be pumped from a syrup source using a syrup pump. The syrup may also travel through a syrup chilling coil prior to being released into the mixing nozzle. The syrup chilling coil may lower the temperature of the syrup before it is added to the mixing nozzle so a cooler beverage can be dispensed to the user. According to some embodiments, a second syrup source may be added to the beverage dispenser. The second syrup source may be integrated into the beverage dispenser in much the same way as the first syrup source. Additional syrup sources may also be added.
According to some embodiments, one or more mixing nozzles may be used with the beverage dispenser. Each nozzle may have its own syrup source. Also, a syrup source may serve one or more mixing nozzles.
According to some embodiments, a method of dispensing a non-carbonated beverage from a carbonated beverage dispenser includes actuating a carbonation pump to increase a pressure in the pressure tank. The carbonation pump may be configured to shut off when a pressure in the pressure tank is above an upper threshold pressure. In some embodiments, the pressure tank may discharge the pressure into the beverage supply line in response to a user actuating a dispensing mechanism of the beverage dispenser. Actuating the dispensing mechanism releases the beverage from the beverage dispenser.
A method of dispensing a beverage may also include dispensing a predetermined amount or volume of a beverage from the beverage dispenser. A method may also include adding a syrup to the beverage supply line to in response to the user activating the dispensing mechanism. A syrup may be added with a syrup pump. The syrup may be routed through a syrup-chilling coil to lower the temperature of the syrup.
The disclosure will be readily understood by the following detailed description in conjunction with the accompanying drawings, wherein like reference numerals designate like structural elements, and in which:
Reference will now be made in detail to representative embodiments. Some embodiments will be illustrated in the accompanying drawings. It should be understood that the following description is not intended to limit the embodiments to one preferred embodiment. To the contrary, it is intended to cover alternatives, modifications, and equivalents as can be included within the spirit and scope of the described embodiments as defined by the claims.
The present disclosure is directed to beverage dispensing systems and methods of dispensing beverages. Beverage dispensers are used in wide variety of settings including concessions, convenience stations, and restaurants. Beverage dispensers are economical and visually attractive ways of storing and combining beverage components. A wide variety of beverage products including, but not limited to, carbonated beverages, non-carbonated beverages, juices, flavored waters, and others may be dispensed from beverage dispensers. Carbonated beverages may include soft drinks, such as, for example, Pepsi©. Non-carbonated beverages may include tea, such as iced-tea, for example, Pure Leaf©.
Beverage dispensers may include several components for preparing a beverage. The components may differ depending on the type of beverage, or specific beverage, that will be dispensed. For example, a carbonated beverage dispenser may require a carbonation tank and carbonation pump. Because beverage dispensers require components specific to the beverage product that will be dispensed, operators of beverage dispensers may have relatively limited options for adapting a beverage dispenser originally intended for one type of beverage product for use with another type of beverage.
Beverage components may include water, syrups, and carbon dioxide gas, among other. Beverage dispensers may combine beverage components to make a beverage. Beverage dispensers may also offer levels of customization to a beverage user. For example, more than one syrup may be added to a beverage. For example, a base flavor syrup may be added to water to make a beverage. The base flavor may be, for example, a lemon-lime flavor. A second flavor syrup may be added to the beverage to change the flavor of the dispensed beverage. For example, a user may add a cherry flavor to change, or customize, the beverage dispensed.
A carbonated beverage dispenser may include specific components to combine the beverage components of a carbonated beverage. A carbonated beverage may be made with water infused with carbon dioxide gas and a syrup. The carbonated beverage may be dispensed from a beverage dispenser that includes a carbonation source, a water source and syrup source. The carbonation source may be, for example, a canister of compressed carbon dioxide gas. The water source may be, for example, a water faucet connected to a municipal water supply or the like.
Beverage dispensers require pumps or other mechanisms to drive a beverage or beverage component through the beverage dispenser. In a carbonated beverage dispenser, the carbonation pump drives the beverage through the beverage dispenser. In a carbonated beverage dispenser, a carbonation pump pumps water into a carbonation tank. The carbonation tank is connected to a carbon dioxide supply to supply the carbonation tank with carbon dioxide gas. Once the carbon dioxide gas and water are in the carbonation tank, the carbon dioxide gas diffuses into the water to form carbonated water. The carbonation tank not only carbonates the water, but because the tank is pressurized, the pressure tank also acts to force a beverage out of the beverage dispenser.
The carbonation pump may operate when a user of the beverage dispenser engages a dispensing mechanism. The dispensing mechanism may be located under the mixing nozzle of the beverage dispenser. The dispensing mechanism may be a lever, button, or other user interface device. The activation mechanism opens one or more valves of the beverage dispenser to dispensing a beverage to the user.
As shown in
Carbonation pump 106 also pumps carbon dioxide gas into carbonation tank 110.
In addition to water supplied by beverage supply line 102, a syrup system may also supply a syrup to the beverage. As shown in
A carbonated beverage dispenser according to some embodiments may be converted into a non-carbonated beverage dispenser. According to some methods, a carbonated beverage dispenser may be converted into a non-carbonated beverage dispenser by removing the carbonation tank from the beverage dispenser. The carbonation tank may be physically removed from the beverage dispenser, for example, by disconnecting the carbonation from the beverage supply lines and removing it from the beverage dispenser's housing, or the carbonation tank may be operatively removed from the beverage dispenser. The carbonation tank may be operatively removed the beverage dispenser by means of a shut off valve or flex valve fluidly located between the carbonation tank and the beverage supply line.
A method of converting a carbonated beverage dispenser to a non-carbonated beverage dispenser may include installing a pressure tank in the beverage dispenser. The pressure tank may be fluidly coupled to the beverage supply line between the mixing nozzle of the beverage dispenser and carbonation pump. The pressure tank may be fluidly connected to the beverage supply line with a shut off valve or flex valve. With the shutoff valve or flex valve, an operator may quickly add or remove the pressure tank from the beverage supply line without installing or uninstalling the pressure tank.
In operation, the converted non-carbonated beverage dispenser uses the carbonation pump to increase a pressure of the pressure tank. The pressure tank includes a diaphragm that separates a first and a second chamber of the pressure tank. The first chamber may be fluidly coupled to beverage supply line 102 and the second chamber is closed off and includes a compressible fluid, such as, for example, air. When the carbonation pump is activated and solenoid valve 152 is closed, the carbonation pump pumps water into the first chamber of the pressure tank. As more water enters the first chambers, the diaphragm is displaced into the second chamber of the tank. The diaphragm thus pressurizes the system. Therefore, even when the carbonation pump is off, a beverage may still be dispensed from the beverage dispenser because the pressure tank pushes the water through the beverage dispenser.
As shown in
The dispensing mechanism may be integral to mixing nozzle 154. The dispensing mechanism may be actuated by a mechanical toggle or an electrical signal. For example, an operator may select a beverage size option from a menu of options. In response to a selected size, mixing nozzle 154 may dispense a specific volume of beverage. For example, if an operator selects a button labeled “Large,” 16 fluid ounces of beverage may be dispensed. If an operator selects a button labeled “Small,” 8 fluid ounces of beverage may be dispensed.
A pressure in pressure tank 204 may be monitored by a pressure switch 202. Pressure switch 202 may also be operatively coupled to carbonation pump 106. Pressure switch 202 may be configured to operate carbonation pump 106. According to some embodiments, pressure switch 202 may turn on carbonation pump 106 when a pressure in pressure tank 204 falls below a lower threshold pressure. Pressure switch 202 may shut off carbonation pump 106 when the pressure in pressure tank 204 is above an upper threshold pressure.
As shown in
In some embodiments, the upper threshold pressure 512 may be pressure near an upper pressure limit of the pressure tank. The lower threshold pressure 506 may be greater than a minimum pressure required to operate the beverage dispenser. In some embodiments, it may only be necessary to intermittently operate carbonation pump 106. Operating carbonation pump 106 only when necessary to charge the pressure in the pressure tank may contribute to operational savings and energy efficiencies because the excess energy generated by the carbonation pump 106 may be stored in the pressure tank. In some embodiments, carbonation pump 106 may be configured to engage for minimum intervals to reduce power waste during carbonation pump 106's startup operations. In some embodiments, the carbonation pump may charge the pressure tank to a pressure between 30 to 40 PSI for low pressure beverage dispensing and between 60 to 120 PSI for high pressure beverage dispensing.
According to some methods of converting a carbonated beverage dispenser to a non-carbonated beverage dispenser, a pressure regulator 220 may also be installed before mixing nozzle 154. Pressure regulator 220 may lower the pressure of the beverage before it is dispensed by mixing nozzle 154. This prevents the beverage from being dispensed at too high of a pressure. Pressure regulator 220 also allows carbonation pump 106 to pressurize the pressure tank to a higher level without concern that the excess pressure will be quickly released when the dispensing mechanism is activated. This enhances the user experience by protecting the user from expected blasts of water. In some embodiments, pressure regulator 220 is integral to solenoid valve 152. That is, solenoid valve 152 not only controls the release of the carbonated water to mixing nozzle 154, it also ensure that the carbonated water is released at an appropriate pressure.
The foregoing descriptions of the specific embodiments described herein are presented for purposes of illustration and description. These exemplary embodiments are not intended to be exhaustive or to limit the embodiments to the precise forms disclosed. All specific details described are not required in order to practice the described embodiments.
It will be apparent to one of ordinary skill in the art that many modifications and variations are possible in view of the above teachings, and that by applying knowledge within the skill of the art, one may readily modify and/or adapt for various applications such specific embodiments, without undue experimentation, without departing from the general concept of the present invention. 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.
The Detailed Description section 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 as contemplated by the applicant, and thus, are not intended to limit the present invention and the claims.
The phraseology or terminology used herein is for the purpose of description and not limitation, such that the terminology or phraseology of the present specification is to be interpreted by the skilled artisan.
The breadth and scope of the present disclosure should not be limited by any of the above-described exemplary embodiments, but should be defined only in accordance with the claims and their equivalents.
Number | Date | Country | Kind |
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201841015764 | Apr 2018 | IN | national |
This application is a continuation of U.S. application Ser. No. 17/046,602, filed Oct. 9, 2020, which is a national stage entry of PCT/US2019/027497, filed Apr. 15, 2019. Each of these applications is incorporated herein in their entirety by reference thereto.
Number | Date | Country | |
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Parent | 17046602 | Oct 2020 | US |
Child | 18167646 | US |