Not applicable
Water dispensers of different sizes and features are nowadays available in homes, offices and restaurants. But there are several beverages that current dispensers do not dispense and there is thus a need for dispensers that dispense a wider and different variety of waters with different chemical characteristics, such as alkaline waters, or water at different temperatures with different carbonation levels.
Some water dispensers typically provide carbonated water by mixing carbon-dioxide gas with chilled water that is injected at high pressure—using a pump—inside a pressurized canister (i.e., a metal vessel under pressure). When the pressurized canister is full of water mixed with gas, users can dispense the carbonated water contained in the pressurized canister until it is empty and the cycle repeats, per batches. There is a need for a dispenser that can create carbonated water or other carbonated beverages instantaneously, on demand and continuously (i.e., not per batches), without using a pressurized canister to hold a specific volume of carbonated water (pre-carbonated), but using instead a small, efficient, continuous and no-energy consuming in-line flash carbonator, such as the carbonator using electrostatic charging as in U.S. patent application Ser. No. 16/329,043, filed Feb. 27, 2019 and published as Publication No. 2019/0217256 on Jul. 18, 2019. While current art carbonated beverage dispensers use a pressurized canister to combine carbon dioxide gas with water, the space occupied by such vessel under pressure increases the overall dimensions of its chiller and reduces the energy efficiency of its chiller. There is therefore a need for a dispenser whose carbonation system is small and efficient and whose refrigeration system can also be compact and efficient.
Commercial-grade water dispensers that are able to dispense carbonated water and carbonated beverages must have very powerful refrigeration systems because it is a well-known principle of physics that the solubility level of carbon-dioxide gas in water and the formation of carbonic acid is related to the temperature of water: solubility is maximum when the temperature of the water approaches the water-freezing temperature (i.e., 0° C.).
Chillers have refrigerated evaporator coils immersed in a water-bath inside a chilled water reservoir, with water dispenser cooling coils in the same water bath to refrigerate the drinking water that is produced by the dispenser. Such water dispensers use the so-called “water-bath/ice-bank” technology, where the latent heat of the ice that it is formed all around the evaporator coils is used to flash refrigerating the drinking water that enters the chiller. There is further the need of refrigerators for water dispensers to have an efficient chilling system.
Chillers are normally shipped with their chilled water reservoir empty to avoid the weight and leakage of the water during shipping. Thus, during installation and setup of a dispenser, the installer or the user must fill manually the chilled water reservoir with large volumes of water and associated spilling, splashing and overfilling errors. If, overtime, water evaporates from the reservoir, it must also be manually refilled. There is thus a need for a light water dispenser suitable for shipping that avoids the problems associated with manual filling and refilling of the chilled water reservoir. There is a further need for emptying such chilled water reservoirs when the water dispensers must be moved or discarded.
Further, the cooling evaporator coils freezes the water in the chilled water reservoir and temperature sensors are used to limit the amount of ice formed. When the ice growth is such that it touches the temperature sensor then if the compressor does not stop working the entire water-bath inside the chiller might freeze-up and, consequently, the drinking water that flows inside a stainless steel drinking water chill water coil immersed inside the chiller reservoir whose water bath freezes up completely and cannot be dispensed. There is a need for more accurate control over the amount of ice formed so the latent-heat of ice can be used to increase the cooling efficiency of the cooling coils in the water reservoir and so that agitators inside the chiller are controlled by the temperature of the drinking water in the chiller water coil, rather than based upon the growth of the ice, or any other time-related variable.
Water dispensers with evaporator cooling coils immersed in the chilled water reservoirs provide a limited supply of cooled water contained in the dispenser, that supply may be depleted during periods of high demand. There is thus a need to increase the capacity for cooled water by increasing the heat-exchange between the surfaces at the interface between the ice and the water, creating the necessary agitation of the water inside the chiller while avoiding unnecessarily melting the ice when the temperature of the drinking water inside the water chiller coil is low enough. There is further the need of water-bath agitators that increase heat transfer by convection by directing water in the appropriate direction.
There is the need to avoid too much agitation and consequent consumption and premature melting of the ice bank because of uninterrupted circulation of the water inside the chilled water reservoir. There is further the need of optimizing the use of the latent heat of the ice bank based on demand.
Hot water heaters for beverage dispensers typically use resistance heaters to create hot water in a reservoir, with gravity and water pressure helping dispense the heated water from a spigot in the bottom or side of the dispenser and below the reservoir or a large portion of the hot water reservoir. The hot water can make the spigot hot to the touch. There is a need for an improved water heater that dispenses hot water but with spigot that does not get hot as in the prior art.
In addition, there is believed to be a need that no water remains in the water line between the hot water tank and the spigot at the moment the dispensing of hot water is halted or immediately thereafter. If hot water remains in the outlet line between the tank and the spigot the temperature of the water in the line will decrease over time and when the spigot is opened to dispense hot water again, the hot water dispensed from the spigot would have an inconvenient lower temperature because it will be mixed with the cooler water that has remained in the outlet line. It is, therefore, useful that all the hot water that remains in the outlet line outside the hot water tank and that it is not dispensed, flows back into the hot water tank as soon as the spigot closes, so that the water will remain hot (heated by the heater), instead of stagnating in the outlet line and gradually reducing its temperature.
There is also a need for a hot water tank to be able to dispense heated water upwards (i.e., against gravity), so that the hot water tank could be located below the level of the dispensing nozzle and the resulting design of the entire drink station dispenser is not too high.
Hot water tanks for water dispensers have temperature sensors that shut off power to the electrical resistance heater when steam is generated because that indicates the hot water reservoir is out of water or low on water, and such heaters avoid steam because the steam temperature can result in dispensing water that is too hot. But because steam holds more heat than water, the efficiency of heaters that do not use steam is less lowered. There is a need for a more efficient hot water heating system and for an improved temperature control system for hot water tanks.
Electrical resistance heaters for hot beverage dispensers may overheat when due to the evaporation of water over a certain period of time of no use, the water level in the hot water reservoir becomes too low so that part of the resistance heater is no longer covered with water. There is thus a need for an improved way to avoid overheating of hot water heaters.
The taste of alkaline water is believed to improve if it is consumed at a temperature below ambient. There is thus a need for a compact beverage dispenser that can provide unlimited chilled alkaline water without requiring a large reservoir of chilled alkaline water.
There is also believed to be a need for a constant release of minerals from alkaline chambers containing alkaline ceramic balls and, a need to control and stabilize the release of minerals into the drinking water in order to avoid sudden release of minerals when the dispenser is not used for one day or more.
A number of features are provided in an improved beverage drink station. These improvements include, but are not limited to, a drink station having an alkaline filter cartridge in fluid communication with an ambient temperature water line to dispense alkaline water at a spigot on the dispenser. A chilled water line is in fluid communication with the same spigot, so a mixture of chilled water and alkaline water is provided at the spigot to improve the taste of the alkaline water by slightly reducing its temperature. A hot water tank with heater is located below the spigot so hot water flows upward for dispensing from the spigot to provide hot water at the spigot. A vent line between the hot water tank and spigot help hot water to flow from the spigot, back to the hot water tank and avoid heating the spigot. An external carbon dioxide gas tank provides carbonation to a chilled line of sparkling or carbonated water, and in-line carbonators, immersed in a water-bath that is cooled down by the refrigeration system, provide supplemental carbonation to produce different carbonation levels at the spigot. A figure eight evaporator coil provides two cylindrical ice-banks and two drinking water chiller water coils to increase the chilled water capacity of the drink dispenser. Up to two submersible agitator pumps are used to create a spherical flow path in the opposing top and bottom ends of the chilled water bath to control the water bath temperature, with a drinking water temperature sensor controlling the agitators.
In more detail, a drink station is shown which has a housing containing a first main water inlet port in fluid communication with a water delivery pump inside the housing to provide water to the delivery pump during use of the apparatus. The dispenser has at least one stainless steel drinking water chiller coil where drinking water is cooled down, in fluid communication with the water delivery pump and the spigot. In order to cool down the incoming water, the stainless steel drinking water chiller coil is at least partially inserted into, and cooled by, a heat exchanger having a low temperature portion to chill incoming water from the water delivery pump to a temperature between the ambient temperature of the water at the delivery pump and just above 32° F. during use of the dispenser.
Such beverage dispenser has an optional first water line splitter that is placed in fluid communication with the drinking water chiller coil, a normally-closed chilled water valve positioned downstream with respect to the drinking water chiller coil and downstream of and in fluid communication with the first water line splitter. A normally closed sparkling water valve may be positioned downstream of the chiller coil and downstream of, and in fluid communication with, the first water line splitter. The sparkling water valve is in fluid communication with a downstream dispensing outlet. At least one normally closed carbon dioxide gas valve may be placed in fluid communication with a carbon dioxide gas tank. At least one first static venturi-restriction device is located downstream of, and in fluid communication with, the carbon dioxide gas valve and is also located downstream of and in fluid communication with the chilled water line splitter. The venturi improves the mixing of chilled water and carbon dioxide gas. One or more static, in-line carbonation devices are optionally located downstream of, and in fluid communication with, at least one first static venturi-restriction device to further carbonate chilled water flowing through at least one first static venturi-restriction device. The in-line venturi-restriction device is at least partially inserted into, and cooled by, the heat exchanger to provide cold carbonated water. The in-line carbonation chambers are in fluid communication with the dispensing outlet which is downstream of the carbonation chambers to dispense that chilled and carbonated water.
The beverage dispenser has an electronic control module that is in electrical communication with the water delivery pump, the water valve, the sparkling water valve, the carbon dioxide gas valve and the chilled water valve to open and close those valves and to power the deliver pump on or off. A chilled water selector is placed in electrical communication with the electronic control module to dispense chilled still water. When the chilled water selector is activated, the controller sends electrical signals to the various parts so that the water delivery pump is powered on and the chilled water valve is excited to open and allow chilled still water to flow to the dispensing outlet during use of the apparatus. A carbonated water selector in also electrical communication with the electronic control module to dispense chilled carbonated water. When the carbonated water selector is activated, the control module sends electrical signals to the various parts so that the water delivery pump is powered on, the sparkling water valve and the carbon dioxide gas valve are both excited to open to allow carbonated water to flow to the dispensing outlet during use of the apparatus.
The above beverage dispensing apparatus includes a normally closed main inlet valve positioned downstream of the main inlet port into the drink station and in electrical communication with the control module to open and close the main inlet valve anytime a selector is activated. When the chilled water selector, or the carbonated water selector is activated, the main inlet valve is excited open. The dispensing apparatus includes a flow-meter in fluid communication with the main inlet port and electrically connected to the control module, to monitor the quantity (e.g., volume) of water dispensed by the dispenser because, except for potential evaporation, the water in the dispenser should equal the water dispensed out of the dispenser.
In still further variations, the dispenser includes an ambient water line that includes a normally closed ambient water valve in fluid communication with the main valve and the dispensing outlet and in electrical communication with the control module to open and close the ambient water valve. An ambient water selector is in electrical communication with the electronic control module to dispense ambient temperature water. When the ambient water selector is activated the controller powers the water delivery pump on and opens the ambient water valve to allow ambient temperature water to be dispensed during use of the apparatus.
In further variations, the beverage dispensing apparatus also dispenses alkaline water. In this case, a normally closed ambient water valve in is in fluid communication with the main water inlet port to receive water during use and further in electrical communication with the control module to open and close the ambient water valve. An alkaline cartridge has an inlet downstream of and is in fluid communication with the ambient water valve and further has a cartridge outlet in fluid communication with an alkaline water line. The alkaline cartridge contains at least one and preferably several different alkaline minerals and a downstream bed of activated granular carbon that is in fluid communication with the alkaline cartridge outlet. A filter membrane is interposed between the alkaline mineral and the charcoal bed to separate the materials, avoid sudden release of alkaline minerals and filter out larger mineral particles. In this configuration, the beverage dispenser has an alkaline selector in electrical communication with the electronic control module to dispense alkaline water by opening both the chilled water valve and the ambient water valve to allow ambient temperature water to flow through the alkaline cartridge and into the alkaline water line. The chilled water line is also in fluid communication with the alkaline water line (preferably at the dispensing outlet) to dispense a mixture of chilled water and alkaline water at the dispensing outlet during use of the dispensing apparatus in order to reduce the temperature of the dispensed alkaline water while contemporarily diluting the amount of minerals released at the spigot.
In further variations, the controller has a timing circuit that opens and then closes the chilled water valve for a time interval which is shorter than the time interval during which the ambient water valve is opened and then closed. Additionally, the alkaline chamber includes a cartridge containing mineral alkaline crystal balls. The cartridge is removably connected to a manifold having a manifold inlet in fluid communication with and downstream of the ambient water valve. Connections of the type used with water filters are believed suitable. The manifold has a manifold outlet that is fluid communication with the alkaline water line at the dispensing outlet.
In still further variations, the drink station dispenses hot water, and addresses a prior problem of not efficiently using the steam that collects in hot water heaters but is never dispensed with the hot water. An improved hot water tank which includes a heater includes a normally closed hot water valve in fluid communication with the main valve and in electrical communication with the control module to open and close the hot water valve and the main valve. A hot water tank is provided having a hot water reservoir in a bottom portion of the tank and a vapor chamber at a top portion of the tank with a dividing wall separating the hot water reservoir from the vapor chamber. A discharge opening in the dividing wall places the hot water reservoir in fluid communication with the vapor chamber, so steam can flow into the vapor chamber whether the water reservoir is full, or partially full. A tube with a slotted bottom connects the discharge opening to an outside of the tank. The tank has a fluid inlet at a bottom of the tank in fluid communication with both the hot water valve and the hot water reservoir. The tank also has a hot water outlet at a top of the tank in fluid communication with the hot water reservoir and the vapor chamber, so water flows into the bottom of the tank through the control tube and out the top of the tank during use of the apparatus, sucking steam into the control tube as water flows through the tube. The hot water outlet is in fluid communication with the dispensing outlet through a hot water line. The hot water tank for the dispenser may have an electrical resistance heater in thermal communication with the hot water reservoir in the tank to heat water in the hot water tank during use of the apparatus. The heater is in electrical communication with the control module to control the heater. A hot water selector is provided on the dispenser and placed in electrical communication with the electronic control module to dispense hot water. When the hot water selector is activated the control module sends electrical signals to excite the hot water valve open and the main valve open, so water flows into the hot water tank and it is accelerated upward by the restriction of the slotted control tube where the water from the hot water reservoir flows out the hot water outlet to the dispensing outlet during use of the apparatus.
In further variations of the hot water dispenser, the dispensing outlet is higher than the hot water outlet so hot water flows upward to the dispensing outlet from the hot water tank which is positioned at a lower level. A vapor line is in fluid communication with the dispensing outlet and the vapor chamber to provide a vent path allowing hot water to flow from the discharge opening back into the hot water tank when dispensing stops and the hot valve is closed. The hot water dispensing outlet may be in fluid communication with both the chilled water outlet and the sparkling water outlet as the temperature of the dispensing outlet is not in continuous contact with hot water. Further, the tube advantageously comprises a control tube having a slotted bottom encircling the discharge opening and further having a top forming the hot water outlet. The slots are sized to suck vapor from the vapor chamber when hot water flows through the control tube at a predetermined flow rate of 1 liter per minute minimum. The heater advantageously includes a safety thermostat in contact with the heating element and in electrical communication with the control module to shut off the heating element if the temperature of the hot water is too high or the water level in the water reservoir is too low.
In further variations of the beverage dispensing apparatus, a water filter is placed in fluid communication with and upstream of both the chilled water valve and the sparkling water valve.
To cool down the drinking water the heat exchanger uses a water-bath and ice-bank refrigeration device. Such a device includes a chilled water reservoir having top and bottom walls and sidewalls forming an enclosed water reservoir of predetermined volume, with all walls being thermally insulated. The device has a freezer expansion line with an evaporator coil inside and adjacent to the chilled water reservoir sidewalls. The evaporator coil has sufficient cooling capacity during the use of the apparatus to freeze the water inside the chilled water reservoir which is in contact with the evaporator coil and create an ice bank around a majority of the evaporator coils with the rest of the water-bath inside the chilled water reservoir to remains in its liquid state. The ice-bank is created around all, or almost all the evaporator coils. The device has a drinking water chiller coil located inside the chilled water reservoir and it is at least partially submerged by the water-bath in the reservoir. During use of the drink station, the drinking water inside the chiller coil is cooled down thanks to the ice-bank that is formed on the evaporator coil. One or more static, in-line carbonation chambers are located inside the chilled water reservoir at a location where the carbonation devices are at least partially immersed in the water-bath during use of the dispensing apparatus.
In further variations, the water-bath and ice-bank refrigeration device has the first splitter for the chilled water line and the carbonated water line located inside the chilled water bath during use of the apparatus. Additionally, a first temperature sensor may be placed in electrical communication with the controller and positioned within the chilled water reservoir at a location selected to contact the ice bank along a majority of the length of the sensor during use of the apparatus. The temperature sensor is also in electrical communication with the control module. By measuring the resistivity values that differ significantly between water and ice, the temperature sensor is able to recognize when ice has grown, sends a signal to the electronic control module so that the power to the compressor and fans of the dispenser's refrigeration system is interrupted. The evaporator coils stop freezing water and the growth of ice is interrupted so as to avoid the total freezing of the water inside the chilled water reservoir and of the drinking water inside the stainless steel chiller coil and inside the pipes and connections immersed in the water-bath of the chiller.
In further variations, improved water-bath agitation is done through the use of at least one agitator pump which is proved much more effective in increasing the heat transfer between the ice bank and the water bath than ordinary stirrers or other agitators. In further variations the agitation of the water-bath is done with a first submersible agitator pump having a first pump having a first axial flow path the inflow along a longitudinal axis of the of the drinking water chiller coil while the outflow direction is horizontally directed. The water intake being longitudinally directed towards the pump body on a longitudinal axis, while the water flow is accelerated by the agitator pump and the outflow is directed radially in one, or multiple radial outward directions, on a plane that is orthogonal to that longitudinal axis. More than one agitator pump can be used, so the dispensing device may include a second submersible agitator pump having a submersible pump having a third axial flow path along the longitudinal axis of the drinking water chiller coil and in a direction opposite to the first axial flow path. The second submersible agitator pump and its pump have fourth radial flow path orthogonal to that longitudinal axis and in the same direction as the second radial flow path.
In further variations, the agitators include first and second submersible agitators with pumps with each agitator pump at least partially submerged in the water-bath of the chilled water reservoir. Each submersible pump has first and second respective nozzles extending along a longitudinal axis of the drinking water chiller coil and forming the inflow port. Each submersible agitator pump has a plurality of second ports forming the outflow port directing the water outward in a radial way, with each submersible agitator's inflow and outflow ports creating a circular flow path in a portion of the chilled water reservoir.
In further variations, an improved temperature control for the ice bank is provided. At least one agitator pump is at least partially inside the drinking water chiller coil and in electrical communication with the controller. The at least one agitator pump is preferably at least partially submerged. An ice contact temperature sensor located in the chilled water reservoir at a location that contacts the ice bank during use of the apparatus which sensor is also in electrical communication with the controller. During use of the apparatus the ice bank grows and contacts the ice contact temperature sensor which then sends a signal to the controller, and in response to that signal the controller activates or de-activate the compressor and the fans of the refrigeration system.
In further variations, an improved chilled water reservoir is provided. The chilled water reservoir is advantageously sealed to contain the chilled water in a sealed environment that reduces water spillage and evaporation. A normally closed, chilled water reservoir filling valve is provided having an upstream end in fluid communication with the main flow valve and a downstream end in fluid communication with a chilled water reservoir fill line that is in fluid communication with the chilled water reservoir. A water level sensor is located to detect the water level in the chilled water reservoir. The bucket fill valve and the water level sensor are each in electrical communication with the controller which has circuitry configured to open the chilled water reservoir filling valve when the water level sensor reaches a predetermined low level determined by the sensor and to close the reservoir filling valve when the water level sensor is at a maximum fill level determined by the sensor signal. A float sensor is believed suitable. In further variations, the chilled water reservoir comprises top and bottom walls and sidewalls forming a sealed enclosed of predetermined volume, with all walls being thermally insulated and at least a majority of the fluid communication lines and electrical communication lines extending through sealed fluid connections in the top of the chilled water reservoir. Advantageously, a drain is provided in the bottom of the water reservoir to remove the water bath from inside the reservoir when the dispenser is deinstalled and moved from one location to another.
A beverage dispensing apparatus with increased capacity is also provided. A beverage dispenser housing has a first main water inlet port in fluid communication with a water delivery pump in the housing to provide water to the delivery pump during use of the apparatus. A chilled water reservoir has top and bottom walls and sidewalls forming an enclosed water reservoir of predetermined volume, with all walls being thermally insulated and advantageously, but optionally, sealed to provide a sealed enclosure for the chilled water reservoir. If the lid is removable, a ring seal, such as an O-ring seal, is provided. The apparatus has an evaporator freezer having an evaporator coil inside and connected to the chilled water reservoir sidewalls. Advantageously, the evaporator coil forms a figure eight configuration having a first vertical evaporator coil at a first end of the figure eight configuration and a second vertical evaporator coil at a second end of the figure eight configuration. The evaporator coils have interleaved connecting segments extending between the first and second vertical evaporator coils. The evaporator coil has sufficient cooling capacity during use of the apparatus to freeze water in contact with the evaporator coil and create a wall ice bank around at least a majority of the area of the sidewalls and to create a center ice bank extending between two opposing sidewalls of the water reservoir where the interleaved segments of the first and second evaporator coils are interleaved.
The improved capacity dispensing device also has a first vertical chiller water coil located inside the first evaporator coil. The first chiller water coil has an upstream end in fluid communication with the water delivery pump and a downstream end in fluid communication with a first dispensing outlet. A second vertical chiller water coil is located inside the second evaporator coil. The second chiller water coil has an upstream end in fluid communication with the water delivery pump and a downstream end in fluid communication with a second dispensing outlet. This figure eight configuration is believed to provide twice the volume of chilled water as a single coil. Advantageously, each drinking water chilled water coil contains 0.5 to 0.8 liters of chilled water, for a total capacity of 1 to 1.6 liters of chilled water in the drinking water chilled coils.
There is also provided a hot water tank for use in a beverage dispenser having a water inlet and a hot water outlet, and a plurality of beverage selector buttons associated with different beverages. The selector buttons are in electrical communication with a controller to active appropriate valves in the beverage dispenser to dispense the different beverages associated with the respective selector buttons through a discharge opening. One of the selector buttons includes a hot water button. The hot water tank includes a tank housing containing a hot water reservoir in a bottom portion of the housing and a vapor chamber at a top portion of the housing with a dividing wall separating the hot water reservoir from the vapor chamber. A discharge opening extends through the dividing wall with the discharge opening advantageously located in the bottom of a recess in the dividing wall. The hot water housing has a water inlet at a bottom of the housing. A control tube extends from the discharge opening through the vapor chamber and through a top of the housing. A slotted bottom on the control tube encircles the discharge opening at the dividing wall. The slotted bottom has a plurality of longitudinal slots sized to inhibit water that flows through the control tube at a flow rate of, minimum, 1 liter per minute from also flowing through the slots while allowing any steam in the vapor chamber to be sucked into the water flowing through the control tube at a speed determined by the area of the restrictor in the slotted tube and the pressure of the incoming water. The slots are also sized to allow steam from the hot water reservoir to enter the vapor chamber. The tank also advantageously, but optionally, includes a vent tube having a first end in fluid communication with the vapor chamber and a second end outside the housing, with the second end configured to connect to a fluid line during use of the heater. The tank may also have an electrical resistance heater in thermal communication with the hot water reservoir in the housing to heat water in the hot water reservoir during use of the tank. Advantageously, the tank also has a temperature regulating thermostat in thermal communication with the hot water reservoir.
There is also provided a beverage dispenser that has an improved hot water tank for use in dispensing hot water. The beverage dispenser has a water inlet, a hot water outlet, and a plurality of beverage selector buttons associated with different beverages and with each button in electrical communication with a control module to activate appropriate valves in the beverage dispenser to dispense the different beverages associated with the respective selector buttons through a beverage dispensing outlet. One of the selector buttons is a hot water button. The improved beverage dispenser includes a normally closed hot water valve in fluid communication with a normally closed main valve that is in fluid communication with the beverage dispenser's water inlet. The hot water valve is in electrical communication with the control module to open and close the hot water valve. The dispenser has an improved hot water tank that has a hot water reservoir in a bottom portion of the tank and a vapor chamber at a top portion of the tank with a dividing wall separating the hot water reservoir from the vapor chamber. The dividing wall has a discharge opening placing the hot water reservoir and the vapor reservoir in fluid communication. The tank has a water inlet at a bottom of the tank in fluid communication with the hot water valve and the hot water reservoir. The tank having a control tube extending from the discharge opening through a top of the tank and in fluid communication with the hot water reservoir and the vapor chamber, so water can flow into the bottom of the tank and out the top of the tank during use of the apparatus. The tank has a water deflector at the bottom of the hot water reservoir to favor mixing of the ambient temperature water entering the hot water tank during use of the apparatus with the hot water present inside the hot water reservoir. The deflector being able to direct incoming water flow towards the heater. The hot water outlet is in fluid communication with the beverage dispensing outlet through a hot water line, with the beverage dispensing outlet being above the tank's hot water outlet in the vertical direction. The control tube has a slotted bottom encircling the discharge opening at the dividing wall. The slotted bottom has a plurality of slots extending along a length of the control tube and configured to inhibit water that is flowing through the control tube at a flow rate of at least 1 liter per minute from also flowing through the slots while sucking at least some of any steam in the vapor chamber into the water flowing through the control tube. The slots are sized to allow steam from the hot water reservoir to enter the vapor chamber. The dispenser advantageously has an electrical resistance heater in thermal communication with the hot water reservoir in the tank to heat water in the hot water reservoir during use of the apparatus. The heater is in electrical communication with the control module to regulate the operation of the heater. The operation of the heater is regulated by signals from the control module such that when the hot water valve is excited to open, water flows into the hot water reservoir and upward and out the hot water outlet to the dispensing outlet during use of the apparatus.
In further variations, the hot water heater includes a vent tube having a first end in fluid communication with the vapor chamber and a second end outside the heater tank with that second end configured to connect to a fluid line during use of the heater to provide a vent path avoiding air locks and allowing hot water to drain back into the hot water reservoir through the control tube. Advantageously, the heater includes a temperature regulating thermostat in thermal communication with the hot water reservoir, and a thermistor contacting the heater to provide a safety shut off if the water level falls below the level at which the thermistor contacts the heater.
There is also provided an improved agitator pump for a chilled water bath in a beverage dispensing apparatus using a water bath/ice bank cooling system for the dispensed water. The system has a drinking water chiller coil extending along a longitudinal axis of the chilled water reservoir and located in the chilled water bath and an ice-bank surrounding a portion of the chilled water bath inside an insulated water reservoir having an evaporator coil of the refrigeration system that forms the ice bank. The improved agitator pump including first and second submersible agitators each having a submersible agitator pump with at least one intake port creating a first flow path during use that extends along the longitudinal axis of the chiller coil. Both the first ports face each other along that longitudinal axis. Each submersible pump also has a plurality of second outlet ports orientated outward from the longitudinal axis and creating an outflow path during use that extends outward from the longitudinal axis. The intake port and the outlet openings in each of the two agitator pumps cooperate during use to intake water longitudinally through the intake port and expel water on an orthogonal plane, radially, through the outlet openings. Both ports are located in the chilled water bath inside the chilled water coil during use. Further, the two ports cooperate to create a spherical flow pattern in the portion of the chilled water reservoir by each agitator pump which flow pattern keeps the drinking water chiller coil from freezing and controls the thickness of the ice bank. Advantageously, each spherical flow pattern extends to about half the height of the drinking water chiller coil.
In further variations, the at least one agitator pump operates in cooperation with a temperature sensor which controls the temperature of the water inside the drinking water chiller coil, to send an electrical signal indicating when the temperature of the drinking water exceeds a certain upper value or is reduced below a lower value. The two values are used to turn the agitator pump(s) on and off, or to change their speeds or, alternatively, to turn off one agitator pump while keeping the other working.
Yet a further beverage dispensing apparatus is disclosed herein. Such apparatus comprises a chilled water reservoir; a refrigeration system comprising an evaporator coil, wherein the evaporator coil is arranged within the chilled water reservoir and is configured to freeze water within the chilled water reservoir to form an ice bank; an ice sensor configured to detect a presence of ice within the chilled water reservoir; a controller in communication with the ice sensor, wherein the controller is configured to deactivate the refrigeration system when the presence of ice is detected; a chiller coil arranged within the chilled water reservoir configured to circulate drinking water; an agitator pump arranged within the chilled water reservoir and configured to circulate the chilled water in the chilled water reservoir; and a temperature sensor arranged adjacent to the chiller coil and in communication with the controller, wherein the controller operates the agitator pump based on a temperature determined by the temperature sensor.
In further variations, the beverage dispensing apparatus may further include, at least one first static venturi-restriction device located downstream the sparkling water valve of and in fluid communication with the carbon dioxide gas valve and also located downstream of and in fluid communication with the chilled water line splitter. Further, the apparatus may also include one or more static, in-line carbonation devices downstream of and in fluid communication with the at least one first static venturi-restriction device to further carbonate water flowing through the at least one first static venturi-restriction devices. The in-line venturi-restriction device is at least partially inserted into and cooled by the heat exchanger and the carbonation devices are in fluid communication with the dispensing outlet downstream of the carbonation devices. There is also provided a beverage dispensing apparatus for alkaline drinks that includes a normally closed ambient water valve in fluid communication with the main water inlet port of the dispensing apparatus to receive water during use and in electrical communication with the control module to open and close the ambient water valve. The alkaline drink dispensing apparatus also has an alkaline cartridge having an inlet downstream of and in fluid communication with the ambient water valve and also having a cartridge outlet in fluid communication with an alkaline water line.
The apparatus further includes an alkaline cartridge containing at least one alkaline mineral and a downstream bed of activated granular carbon that is in fluid communication with the alkaline cartridge outlet. An alkaline selector is in electrical communication with an electronic control module to dispense alkaline water by opening the ambient water valve to allow ambient temperature water to flow through the alkaline cartridge and into the alkaline water line.
In further variations, the alkaline water dispensing apparatus has an alkaline chamber that includes a cartridge containing mineral ceramic balls. The cartridge is removably connected to a manifold having a manifold inlet in fluid communication with and downstream of the ambient water valve. The manifold also has a manifold outlet that is fluid communication with the alkaline water line. In still further variations, the alkaline water dispensing apparatus has a refrigeration system to refrigerate and chill water, with a normally closed chilled water valve that can be activated by a controller to dispense chilled water from the refrigeration system. The dispensing apparatus also has an outlet in fluid communication with both the alkaline water line and the chilled water line. The controller also opens and then closes both the ambient water valve and the chilled water valve to dispense a mixture of chilled water and alkaline water at the dispensing outlet during use of the dispensing apparatus. In still further variations, the alkaline water dispensing apparatus has the chilled water valve opening for a time interval which is shorter than the time interval during which the ambient water valve is opened and then closed.
There is also provided a beverage dispensing apparatus having a hot water dispensing outlet for hot water drinks that includes a normally closed hot water valve in fluid communication with a hot water tank positioned downstream with respect to the hot water valve. The hot water valve is in electrical communication with an electronic control module. The hot water tank has a hot water reservoir in a bottom portion of the tank and a vapor chamber at a top portion of the tank with a dividing wall separating the hot water reservoir from the vapor chamber and a discharge opening in the dividing wall. The tank has a fluid inlet at a bottom of the tank in fluid communication with the hot water valve and the hot water reservoir. The beverage dispensing apparatus also has an electrical resistance heater in the hot water reservoir in electrical communication with the electronic control module. The electrical heater is operated by a temperature sensor, wherein when the temperature sensor detects a temperature below a certain value the heater is powered on and when the temperature sensor detects a temperature above a certain value is powered off, so that the heater's electrical power is cycling between an upper and a lower temperature. The electrical heating element may be enclosed in a stainless-steel protective cylinder in thermal contact with the water inside the hot water reservoir and heating the water inside the reservoir in a way that its temperature is always kept in between the cycling temperatures. The hot water tank has a hot water outlet at a top of the tank in fluid communication with both the hot water reservoir and the vapor chamber, so water flows into the bottom of the tank and out the top of the tank during use of the apparatus. The hot water outlet is in fluid communication with the hot water dispensing outlet through a hot water line. With the dispensing outlet for the hot water located at higher level than the hot water tank so hot water must flow upward to the hot water dispensing outlet during operation of the apparatus.
The beverage dispensing apparatus also has a vapor line in fluid communication with the dispensing outlet and the vapor chamber in the hot water tank to provide a vent path allowing hot water to flow from the discharge opening to the outlet and back into the vapor chamber and into the hot water tank after the hot water valve is closed. Further, a control tube is provided having a slotted bottom encircling the discharge opening and further having a top forming the hot water outlet, the slots sized to suck vapor from the vapor chamber when hot water flows through the control tube at a predetermined flow rate. A hot water selector is placed in electrical communication with the electronic control module to dispense hot water, wherein when the hot water selector is activated the control module sends electrical signals to excite the hot water valve open, so water flows into the hot water reservoir and upward and out the hot water outlet to the dispensing outlet during use of the apparatus.
In further variations, the beverage dispensing apparatus may include a safety thermostat positioned on the external walls of the hot water tank and in electrical communication with the control module to shut off the heating element if the temperature in the hot water tank is too high. In still further variations, the apparatus includes a hot water tank, a hot water valve and a hot water line in fluid communication with the hot water dispensing outlet. Still further, an alkaline water chamber, an alkaline water valve and an alkaline water line may be placed in fluid communication with the hot water dispensing outlet, with the hot water dispensing outlet in fluid communication with at least one of a chilled water outlet, a sparkling water outlet and an alkaline water outlet.
In still further variations, the beverage dispensing apparatus has each of the outlets in fluid communication with the hot water outlet. The beverage dispensing apparatus may use a heat exchanger using a water-bath and ice-bank refrigeration device. The refrigeration device may include a chilled water reservoir having top and bottom walls and sidewalls forming an enclosed water reservoir of predetermined volume, with all walls being thermally insulated. The refrigeration device also includes a freezer expansion line having an evaporator coil inside the chilled water reservoir and connected to the chilled water reservoir sidewalls, the evaporator coil having sufficient cooling capacity during use of the apparatus to freeze water in contact with the evaporator coil and create an ice bank around a substantial majority of the freezer coils with a chilled water bath inside the ice bank. A drinking water chiller water coil is located inside the chilled water bath and inside the ice bank to chill water flowing through the chiller coil during use. One or more static, in-line carbonation devices are located inside the chilled water reservoir at a location where the carbonation devices are at least partially immersed in the water bath during use of the apparatus.
In further variations of the beverage dispensing apparatus, at least one agitator pump is provided that includes a submersible pump having a first axial flow path along a longitudinal axis of the chiller coil in an inflow direction, and having a second radial flow path orthogonal to that longitudinal axis and in the outflow direction. The beverage dispensing apparatus may include first and second agitator pumps that are each at least partially submerged in the chilled water reservoir during use, each agitator pump having first and second respective inlet ports extending along a longitudinal axis of the chiller coil and forming their inflow ports, each agitator pump having a plurality of outlets forming the outflow ports with each agitator pump's inflow and outflow ports creating a circular flow path in a portion of the chilled water reservoir.
Further variations of the beverage dispensing apparatus may include at least one agitator pump at least partially inside the chiller coil and in electrical communication with the controller and an ice contact temperature sensor located in the chilled water reservoir at a location that contacts the ice bank during use of the apparatus which sensor is also in electrical communication with the controller. During use of the apparatus the ice bank grows and contacts the ice contact temperature sensor which then sends a signal to the controller, and in response to that signal the controller activates the refrigerator device by powering off a compressor and fans of the refrigerator device when the growth of the ice-bank reaches the temperature sensor.
In still further variations, the beverage dispensing apparatus may include a normally closed, chilled water reservoir filling valve having an upstream end in fluid communication with the main water source and a downstream end in fluid communication with a chilled water reservoir fill line that is in fluid communication with the chilled water reservoir. A water level sensor is located on top of the chilled water reservoir to detect the water level in the chilled water reservoir. The chilled water reservoir filling valve and the water level sensor are each in electrical communication with the controller which has circuitry configured to open the chilled water reservoir filling valve when the water level sensor reaches a predetermined low level determined by the sensor and to close the chilled water reservoir filling valve when the water level sensor is at a maximum fill level determined by the sensor.
There is also provided a beverage dispensing apparatus for dispensing a plurality of beverages that includes a housing having a first main water inlet port in fluid communication with a water delivery pump in the housing to provide water to the delivery pump during use of the apparatus. This apparatus also includes a chilled water reservoir having top and bottom walls and sidewalls forming an enclosed water reservoir of predetermined volume, with all walls being thermally insulated. A freezer expansion line has an evaporator coil inside and connected to the chilled water reservoir sidewalls. The evaporator coil forms a figure eight configuration having a first vertical coil at a first end of the figure eight configuration and a second vertical coil at a second end of the figure eight configuration. The evaporator coils have interleaved connecting segments extending between the first and second vertical coils, the evaporator coil has sufficient cooling capacity during use of the apparatus to freeze water in contact with the evaporator coil and create a wall ice bank around at least a majority of the area of the sidewalls and to create a center ice bank extending between two opposing sidewalls of the water reservoir where the interleaved segments of the first and second freezer coils are interleaved.
This apparatus also includes a first vertical drinking chiller water coil located inside the first evaporator coil and having an upstream end in fluid communication with the water delivery pump and a downstream end in fluid communication with a dispensing outlet. A second vertical drinking water chiller coil is located inside the second evaporator coil and has an upstream end in fluid communication with the water delivery pump and a downstream end in fluid communication with a dispensing outlet.
There is also provided a hot water tank for use in a beverage dispenser apparatus having a water inlet and a hot water outlet, and a plurality of beverage selector buttons associated with different beverages, the selector buttons being in electrical communication with a controller to activate appropriate valves in the beverage dispenser to dispense the different beverages associated with the respective selector buttons through a discharge opening, and with one of the selector buttons including a hot water button. This hot water tank includes a hot water tank housing containing a hot water reservoir in a bottom portion of the housing and a vapor chamber at a top portion of the housing with a dividing wall separating the hot water reservoir from the vapor chamber, and with a discharge opening in the dividing wall, and with the housing having a water inlet at a bottom of the housing. A control tube extends from the discharge opening through the vapor chamber and through a top of the housing. The control tube has a slotted bottom encircling the discharge opening at the dividing wall. The slotted bottom has a plurality of slots configured to inhibit water that flows through the control tube at a flow rate above 1 liter per minute from also flowing through the slots while sucking any steam in the vapor chamber into the water flowing through the control tube. The slots are sized to allow steam from the hot water reservoir to enter the vapor chamber. An outlet is provided for the hot water dispensing from the apparatus, with the outlet positioned at a higher location with respect to the hot water tank housing and the control tube so that hot water is flowing out of the hot water reservoir in an upward direction. A vent tube has a first end in fluid communication with the vapor chamber and a second end outside the housing, with the second end configured to connect to a vapor line during use of the heater. An electrical resistance heater is placed in thermal communication with the hot water reservoir in the housing of the hot water tank to heat water in the hot water reservoir during use of the tank. A temperature sensor, preferably a temperature regulating thermostat having a negative temperature coefficient (NTC) sensor, is in thermal communication with the hot water reservoir.
In further variations, this hot water tank also may include a control tube having a restricted opening at its bottom in fluid communication with the hot water reservoir and having a cross-sectional area of fluid passage that is less than half the cross-sectional area of the control tube. The physical distance between the heater inside the hot water reservoir and a temperature sensor of the NTC is preferably less than 2 mm.
There is also provided a beverage dispensing apparatus having a hot water tank for use in dispensing hot water from the apparatus where the beverage dispenser has a water inlet, a hot water outlet, and a plurality of beverage selector buttons associated with different beverages such that each button is in electrical communication with a control module to activate appropriate valves in the beverage dispenser to dispense the different beverages associated with the respective selector buttons through a beverage dispensing outlet. One of the selector buttons including a hot water button. This beverage dispenser comprises a normally closed hot water valve in fluid communication with a normally closed, main valve that is in fluid communication with the beverage dispenser's water inlet with the hot water valve being in electrical communication with the control module to open and close the hot water valve. A hot water tank has a hot water reservoir in a bottom portion of the tank and a vapor chamber at a top portion of the tank with a dividing wall separating the hot water reservoir from the vapor chamber with the dividing wall having a discharge opening placing the hot water reservoir and the vapor reservoir in fluid communication. The tank has a water inlet at a bottom of the tank in fluid communication with the hot water valve and the hot water reservoir. The tank has a control tube extending from the discharge opening through a top of the tank and in fluid communication with the hot water reservoir and the vapor chamber, so water can flow into the bottom of the tank and out the top of the tank during use of the apparatus. The hot water outlet is in fluid communication with the beverage dispensing outlet through a hot water line, with the beverage dispensing outlet being above the tank's hot water outlet in the vertical direction. The control tube has a slotted bottom encircling the discharge opening at the dividing wall, with the slotted bottom having a plurality of slots extending along a length of the control tube and configured to inhibit water that flows through the control tube at a flow rate of at least 1 liter per minute or above from also flowing through the slots while sucking at least some of any steam in the vapor chamber into the water flowing through the control tube. The slots are sized to allow steam from the hot water reservoir to enter the vapor chamber. An electrical resistance heater is in thermal communication with the hot water reservoir in the tank to heat water in the hot water reservoir during use of the apparatus and the heater is in electrical communication with the control module. Also, a temperature regulating negative temperature coefficient (NTC) sensor is in thermal communication with the hot water reservoir. When the hot water valve is excited to open, water flows into the hot water reservoir and upward and out the hot water outlet to the dispensing outlet during use of the apparatus.
Further variations of this beverage dispensing apparatus include a vent tube having a first end in fluid communication with the vapor chamber and a second end outside the heater tank, with the second end configured to connect to a fluid line during use of the heater. Further a safety thermostat may be provided on the external walls of the hot tank and in electrical communication with the heater, along with a control module and an on/off switch, wherein when the temperature of the hot tank walls exceed a certain value the thermostat opens the electrical circuit avoiding the hot tank to overheat.
Still further variations of this beverage dispensing apparatus include a water deflector in the water inlet port, positioned at the bottom of the hot water reservoir And in fluid communication with a hot water valve, wherein the water deflector deviates the flow path of the incoming water when the hot water valve is open, so as to direct the incoming water towards the heater in order to avoid inlet water to directly flow through the control tube and out, without first mixing with the hot water inside the hot water reservoir, during use of the dispensing apparatus. Still further variations may include a protective stainless-steel shirt around the heater to avoid scale deposit to reduce the thermal efficiency of the heater.
There is also provided an agitator pump that may be completely submerged in a chilled water-bath inside a chilled water reservoir in a beverage dispensing apparatus, where the apparatus has a drinking water chilled coil located at least substantially inside in the chilled water-bath and an ice-bank surrounding a portion of the chilled water bath inside an insulated chilled water reservoir having an evaporator coil with refrigerant fluid that absorbs heat and forms an ice bank. The agitator pump includes a submersible pump with at least one intake port orientated to create an intake flow path during use that is oriented longitudinally with respect to the drinking water chiller coil axis to direct the water-bath surrounding the internal walls of the drinking water chiller coil, towards the inlet port of the agitator. The agitator pump has a plurality of second outlet ports oriented in an orthogonal plan with respect to the intake flow path during use, with the outlet ports extending outward with respect to an intake longitudinal axis. The plurality of outlet ports oriented in a way to direct the outflow path of the water bath towards the ice-bank and the evaporator coil. The at least one inlet port and the plurality of outlet ports cooperate during use of the agitator pump to contemporarily intake and expel the water from the water-bath of the chilled water reservoir.
In further variations, this agitator pump includes an inlet port with the intake flow of this inlet port directed vertically, wherein the agitator pump is located inside the drinking water chilled coil, which extends along a longitudinal axis and is located in the chilled water. The agitator pump has its intake port creating an intake flow path during use that extends along the same longitudinal as the longitudinal axis of the chiller coil with the intake port located inside the chiller coil. The plurality of second outlet openings are orientated outward from the longitudinal axis and create an outflow path during use, extending outward from the longitudinal axis and through the coils of the drinking water chiller coil.
In still further variations, the agitator pump has a plurality of ports oriented to direct the outflow path towards the ice-bank and the evaporator coil, but away from temperature sensors inside the chilled water reservoir. The outlet tubes are preferably connected to the outlet ports bringing the water flow from the agitator pump outlets to the ice-bank, so as to avoid the outlet water path accidentally flowing to and around the temperature sensors inside the water bath.
In still further variations, the agitator pump includes a second agitator pump, wherein the two agitator pumps have their respective inlet ports facing each other, each intake flow oriented vertically, each agitator pump having a plurality of outlet ports orientated outward from the longitudinal axis and creating a second flow path during use extending outward from the longitudinal axis, the ports in each agitator pump cooperating during use to expel chilled water through at least one outlet ports. The inlet and outlet ports are located in the chilled water reservoir to place them completely immersed in the chilled water-bath during use, and both of the two agitator pumps are located inside the same chilled water coil.
In still further variations, the agitator pump may include an ice contact temperature sensor located in the chilled water reservoir at a location that contacts the ice bank during use of the apparatus which sensor sends an electrical signal indicating when the ice bank is in contact with the sensor and when the ice bank is not in contact with the sensor. A drinking water temperature sensor may be placed inside the water bath to control the temperature of drinking water inside the chiller coil, with the sensor sending a first electrical signal to an electronic control module which activates the agitator pump in case the temperature of the drinking water is above a certain upper temperature point and sending a second electrical signal to deactivate the agitator pump when the temperature is below a certain lower temperature point.
In further variations, when the temperature of the drinking water is between the upper temperature point and the lower temperature point, the electronic control module maintains the agitator in its pre-existing conditions: working if it was working, idling if it was not working. In still further variations, the speed of the water outflow expelled varies based on the temperature of the drinking water, with the speed of the one or two agitators starting from zero when the temperature is at or below a certain lower temperature point and increasing in a proportional way as the temperature of the drinking water increases above the lower temperature point.
In still further variations, a second agitator pump as described in any of the above variations may be provided, with the actuation of each agitator pump depending upon the temperature of the drinking water with both agitator pumps working when the temperature of the drinking water inside the chiller coil is above a first predetermined value corresponding to the upper temperature point, and neither of the two agitator pumps is working when the temperature of the drinking water inside the chiller coil is below a second predetermined value corresponding to the lower temperature point, with only one of the two agitator pumps working when the temperature of the drinking water is in between the two temperature points. Preferably, the upper temperature point is 1.2° C. and the lower temperature point is 0.6° C., including a range of +/−0.5° C. from each value.
There is also provided a cup alignment device for a drink dispenser. The drink dispenser has a housing, a spigot for dispensing at least one consumable liquid, a cup support below the spigot and upon which a beverage cup may be placed to receive the liquid dispensed from the spigot and a housing wall located between the spigot and cup support and behind a vertical line between the cup support and the spigot. An illuminated light bar is connected to the housing wall and extends along a vertical path between the spigot and the cup support so that a user can visualize the path of the liquid as it is dispensed from the spigot into a cup resting on or above the cup support. A plastic shield covers the light bar is also connected to the housing wall and extends along the path to shield the light bar from the liquid during use of drink dispenser.
In further variations, the cup alignment device may include a light bar having a plurality of LEDs in electrical communication with a timer and an electrical control circuit configured to sequentially and separately activate each LED. The drink dispenser may have a plurality of spigots with separate cup support below each spigot or a continuous cup support below a plurality of spigots, with a vertical light bar extending downward along the housing wall from each spigot toward the cup holder below that spigot.
These and other advantages and features of the invention will be better appreciated in view of the following drawings and descriptions in which like numbers refer to like parts throughout, and in which:
As used herein, the relative terms upstream and downstream refer to the direction in which fluid flows through the various parts and fluid connections. The fluid generally flows downstream from the building water line, to the spigot, and upstream in the opposite direction.
As used herein, the following part numbers refer to the following parts: 20—drink station; 22—cabinet-stand; 24—door; 26—carbon dioxide gas tank; 28—shut-off valve of the carbon-dioxide gas tank; 30—carbon dioxide gas pressure and flow regulator; 32—water filter; 40—filling/dispensing area; 42—sidewall of the dispensing area; 44—spigot/nozzle; 46—drain pan; 48—drain grate; 50—drain pipe; 51—drain exit port; 52—carbonated water button; 54—alkaline water button; 56—chilled water button; 58—hot water button; 60—auto-fill button; 62—indicator lights; 64—controller; 68: dotted line simulating the housing of a drink station; 70—compressor; 72—freezer expansion line; 74—chilled water reservoir; 76—insulation; 77—evaporator coil; 78—condenser; 79—fans; 80—water pipeline; 82—water pre-filter; 84—water carbon-filter; 86—water inlet port; 88—flow meter; 90—main valve; 92—water delivery pump; 94—drinking water chiller coil; 96—chilled water valve; 97—chilled water electrical communication line; 98—chilled water line; 99—water drain outlet on drink station housing; 100—ambient water valve; 102—alkaline cartridge; 104—alkaline water line; 105—alkaline water electrical communication line; 108—internal carbon dioxide canister; 110—carbon dioxide gas inlet port; 112—carbon dioxide gas valve; 113—carbon dioxide gas electrical communication line; 114—carbon dioxide gas line; 116—carbonated water valve; 118—first splitter; 119—second splitter; 120—carbonator device; 121—second carbonator device; 122—carbonated water line; 124a, b—check valves; 126—drain line in chilled water reservoir; 130—internal water filter; 132—chilling water coil splitter; 134—first carbonation water line; 138—second carbonation water line; 140—first connector gas-liquid; 142—second connector gas-liquid; 144a, b—venturis; 146—main power switch; 147—filter reset button; 148—power reset button; 150—hot water valve; 152—hot water tank; 154—heater; 156—temperature sensor; 158—thermistor; 160—hot water line; 162—vapor line; 163—heater electrical communication line; 164—hot water off switch; 166 child safety switch; 170—agitator pump; 171—electrical motor; 172—intake port; 174—outlet openings; 175—agitator pump electrical communication line; 178—ice bank; 180—ice temperature sensor; 182—drinking water temperature sensor; 183—temperature sensor electrical communication line; 186—outlet tube; 188—water level sensor; 190—float; 192—shaft; 194—water level; 196—chilled water reservoir filling valve; 198—filling line; 200—capillary tube; 202—dryer; 204—main power inlet electrical connection; 206 transformer; 210—alkaline cartridge housing; 212—cartridge cap; 214—inlet; 216—outlet; 218—cammed mounting lugs; 220—nozzle of the alkaline cartridge; 222—inlet disk; 224—bed of alkaline material; 226—filter membrane; 228—bed of activated charcoal; 230—outlet disk; 232—bottom of cartridge; 234—central tube; 240—manifold; 242—door of the drink station; 244—manifold inlet port; 246—manifold outlet port; 248—manifold cartridge inlet; 250—manifold cartridge outlet; 260—hot tank's housing; 261—insulation; 262—hot water reservoir; 264—vapor chamber; 274—dividing wall; 276—control tube; 278—slotted end; 280—slots opening; 282—vent opening; 284—restrictor opening; 286—seating recess; 288—vent tube; 290—water inlet; 292—deflector; 294—hot water drain fitting; 296—mounting bracket; 298—hot water tank drain on the drink station housing; 322—first chamber input port; 324—first chamber output port; 325—first glass beads; 326—second chamber input port; 327—cartridge; 328—second chamber output port; 329—base; 333—glass beads second chamber; 334—first micromesh net; 336—second micromesh net; 350—drink alignment; 352—light bar; 354 drink cup; 356—LED; 401—figure eight evaporator coil; 402—first tubular coil; 402a—first side of coil 402; 402b—opposing side of coil 402; 402c—joining side of coil 402; 402d—connecting segment of coil 402; 404—second tubular freezer coil; 404a—first side of coil 404; 404b—opposing side of coil 404; 404c—joining side of coil 404; 404d—connecting segment of coil 404; 406—water reservoir; 408a—first reservoir side wall; 408b—second reservoir side wall; 408c—first reservoir end wall; 408d—second reservoir end wall; 408e—bottom reservoir wall; 410—insulation; 411a—inlet; 411b—outlet; 412—first chilled water reservoir; 414—second chilled water reservoir; 416—wall ice bank; 418—center ice bank; 419—outlet of water booster reservoir; 420—inlet of water booster reservoir; 422—first drinking water chiller coil; 424—second drinking water chiller coil; 426—water inlet valve; 428—leak detector.
As used herein, the relative directions above and below, top and bottom, upstream and downstream are with respect to the vertical direction when the container shown in
Referring to
The drink station 20 has a filling/dispensing area 40 that is preferably recessed into a front side of the drink station. The filling area 40 has a top and bottom joined by a sidewall 42 that is typically vertical. A dispensing outlet, referred to as spigot (or nozzle) 44 for convenience (but not by way of limitation), is at the top of the filling area and a drain pan 46 at the bottom of the filling area. The drain pan 46 takes the form of a container with an open top over which a drain grate 48 is removably placed. The drain pan 46 is in fluid communication with a drain line during use, typically by a drainpipe 50 (
Above the top of the filling area 40 are a plurality of pushbuttons or touch-buttons in electrical communication with internal components described later that result in dispensing different beverages from the spigot 44 of the drink station. The depicted embodiment has push or touch button 52 for dispensing carbonated water, button 54 for dispensing alkaline water, button 56 for dispensing chilled water, button 58 for dispensing hot water, and button 60, the auto-fill button, for automatically filling a pre-determined volume (a calibrated quality) of water on a cup, bottle or container from the drink station. One or more indicator lights 62 may be provided to provide a visual indication related to the fluid being dispensed through the spigot, such as whether the water is hot, the water filter lifespan is terminated and other usage information. The touch buttons may be physically movable and displaceable buttons to send activating signals, or touch screen buttons using contact between two adjacent sheets to send activating signals, or other types of buttons that send signals when pressed.
The electrical communication of each dispenser button or activator 52, 54, 56, 58, 60 with the component or components used to dispense the selected type of beverage, is achieved through electrical communication with a controller 64, whose functioning is later described in
Referring to
A compressor 70 compresses any suitable refrigerant to create a cold fluid for the refrigeration system that freezes a portion of the water-bath inside a reservoir. The refrigerants are usually rapidly expanded through a nozzle to reduce the temperature of the expanding refrigerant that passes through the freezer expansion line 72. The refrigerant line 72 may pass into and out of the chilled water reservoir 74 through sealed openings located at the top of the chilled water reservoir that are conceived in such a way as to prevent the passage of the water-bath from inside the reservoir and prevent any spillage if the drink station is moved. The chilled water reservoir 74 is typically a watertight, container defining a volume that is filled with a suitable fluid such as water that forms an ice-bank. The chilled water reservoir 74 advantageously has insulation 76 placed over the various laterally located sides or walls, top lid or cover, and bottom, of the chilled water reservoir 74.
The chilled water reservoir 74 is sealed in order to reduce heat-dispersion and increase its efficiency, it forms a fluid tight container and does not have a lid or cover that may be readily removed without at least unfastening a plurality of threaded fasteners. A cover with star drive fasteners holding the cover to the reservoir body may be used, or the reservoir may be permanently sealed. The freezer expansion line 72 typically forms a serpentine path around the inner walls of the reservoir creating an evaporator coil 77—to increase the heat transfer from the cold freezer lines to the walls of the reservoir and freeze the water bath in contact with the coils of the evaporator coil 77.
After passing through the chilled water reservoir, the refrigerant in the freezer line 72 enters the suction line and then is compressed by the compressor 70, after being compressed and returning to its liquid form, it passes through the condenser 78 which typically has one or more fans 79 blowing cooling air over the condenser 78.
The freezer expansion line 72 freezes a portion of the water in the chilled water reservoir 74 forming an ice-bank in proximity of the evaporator coil 77 and maintains the remainder of the liquid water in the reservoir (the water-bath) at a temperature that is preferably near, but above freezing so that the water bath in the reservoir does not freeze solid. The chilled water inside the chilled water reservoir 74 may be circulated to reduce localized freezing and to improve chilling as described later. Stirrers, water jets, moving paddles or rotating propeller-type blades may be used to circulate the water-bath in the chilled water reservoir.
Referring to
Referring further to
A cold water drain line is in fluid communication with drain in the bottom of the chilled water reservoir, which is in fluid communication with a cold water drain outlet 99 (
The flow meter 88 measures the volume of fluid or water entering the drink station and sends signals reflective of that information to the control module 64. The main valve 90 can stop or allow all flow through the fluid chilled water button 56 on the drink station. The delivery pump 92 pressurizes the fluid lines so water flows through the fluid lines depending on which valves are opened or closed in various combinations. The water delivery pump 92 pumps or forces water at a predetermined pump pressure through various fluid lines of the drink station, including through the drinking water chiller coil 94, while the chilled water valve 96 regulates the flow of chilled (and filtered) water through the spigot 44. The chilled water valve 96 is actuated by various means, including electrical, pneumatic, or mechanical. Preferably, the chilled water valve 96 is an electrically actuated valve in electrical communication with the button 56 so that a user may press the button and the chilled water valve 96 will open to dispense chilled water to the spigot 44 for as long as the button maintains electrical communication, or for a predetermined time interval determined by an electrical circuit, or until a weight sensor or a proximity sensor, or a volume level sensor positioned below the drink container to send a shut-off signal when the sensor indicates the weight reaches a predetermined level or the sensor reaches a termination level, or a proximity position.
Referring to
Referring further to
Advantageously, the controller 64 opens both the ambient water valve 100 and the chilled water valve 96 so that both alkaline water and ambient temperature water are dispensed at the spigot at the same time. The relative time that the alkaline control valve 100 is left open or closed, compared to the relative time that the chilled water control valve 96 is left open or closed, with adjust both the temperature of the water dispensed by the spigot 44 and the amount of alkalinity. The addition of chilled water to the ambient alkaline water achieves cooler but less alkaline water than if only alkaline water was dispensed.
The ambient water valve 100 and the chilled water valve 96 and the main valve 90 and the alkaline activation button 54 are in electrical communication to open the appropriate valves and simultaneously dispense alkaline water and chilled water from the spigot 44. The taste of alkaline water is believed improved if consumed below ambient temperature, and preferably if 6° F.-15° F. below room temperature, and more preferably served between 50° F.-70° F. Adding alkaline water to chilled water, or vice versa, may adjust the temperature as desired.
The ambient water valve 100 is in electrical communication with controller 64 through alkaline electrical communication line 105 (
In a further variation, the alkaline cartridge 102 may be omitted or bypassed in the manifold 240, so that ambient temperature water flows through the ambient water valve 100, and out what is normally the alkaline water line 104, so as to dispense filtered, ambient temperature water at the spigot 44. If the alkaline cartridge 102 and manifold 240 are omitted, then the alkaline water line 104 is more aptly referred to as an ambient water line.
Referring to
A first splitter 118 is upstream of the chilled water valve 96 (
The carbon dioxide gas valve 112 and carbonated water valve 116 regulate the amount of carbon dioxide gas and chilled water flowing to the carbonators 120 and 121 and out the carbonated water line 122 to the spigot 44. The valves 112, 116 may be actuated by various means, including electrical, pneumatic, or mechanical. Preferably, the valves 112, 116 are electrically actuated and in electrical communication with the carbonation button 52 so that a user may press the button and the carbon dioxide gas valve 112 and carbonation valve 116 will open main valve 90 will open too and the water delivery pump 92 will be powered on to provide predetermined or adjustable volumes of chilled carbon dioxide gas and chilled water to the carbonators 120 and 121 which generate the sparkling or carbonated water flowing to the spigot 44 for as long as the button maintains electrical communication, or for a predetermined time interval determined by an electrical circuit, or until a weight sensor positioned below the drink container, or until a level sensor or proximity sensor sends a shut-off signal when the sensor indicates the weight reaches a predetermined level or the sensor reaches a termination level or a proximity position.
Referring to
In addition (
In
As seen in the enlarged portions of
The four venturis 144a, 144b intermix the chilled water and chilled carbon dioxide which exits out the downstream end of the first carbonation line 138 and is in fluid communication with the carbonator chambers 120 and 121. Two venturi devices 144b are aligned with a fluid line in communication with the carbonators 120, 121 while two venturi devices 144a are aligned perpendicular to that fluid line, and the outlet of each pair of venturi devices 144a, 144b are adjacent to each other and perpendicular to each other to achieve what is believed to be maximum intermixing. In some embodiments, only one venturi device is sufficient to accelerate the water from the second carbonated water line 138 and mix it with the carbon dioxide gas from line 114: this is the venturi 144b located at juncture 142. This venturi 144b located in the downstream of second carbonated water line 138 is believed to achieve superior intermixing of the carbon dioxide gas and chilled water and thus achieve improved carbonation. Orienting the juncture of the water line 138 and carbon dioxide line 114 at right angles to each other is believed to further improve the intermixing and further increase the carbonation of the water. Placing a venturi 144a, 144b at the two junctures 140 and 142 of the two lines and adjacent the other venturi is believed to further improve the intermixing and further increase the carbonation of the water.
While two sets of intersecting lines with the two connections 140 and 142 are shown and described, one set is believed sufficient. Carbonated water line 122 places the carbonator(s) 120, 121 in fluid communication with the spigot 44 to dispense chilled, carbonated water upon activation of carbonated water button 52 as previously described. As seen in the enlarged portion of
Referring to
The hot water valve 150 is in fluid communication with hot water tank 152 that heats the water to a predetermined temperature and is in fluid communication with the spigot 44 through a hot water line 160 and through a vapor line 162. Heated water flows to the spigot 44 through hot water line 160. The vapor line 162 acts as a vent line to allow hot water to flow back to the hot water tank 152 after dispensing is finished so that a column or fluid line full of hot water is not in constant fluid contact with the spigot 44, thus avoiding a spigot that is continually heated and hot. In addition, it avoids that a mass of hot water remains in line 160 when the dispenser is not in use and cools down over time. Therefore, the next user selecting hot water from the dispenser will first get the water remaining in line 160 that has cooled down and, therefore, when dispensed, this portion of remaining water in line 160 would reduce the temperature of the hot water dispensed at the spigot. The vent line 162 avoids this undesirable possibility. A further description of the hot tank 152 and construction is provided later.
The hot water valve 150 regulates the amount of water flowing to the hot water tank 152 and ultimately the volume of water available to flow out of the spigot 44. The hot water valve 150 may be actuated by various means, including electrical, pneumatic, or mechanical. Preferably, the hot water valve 150 is electrically actuated and in electrical communication with the hot water button 58 so that a user may press the button and the hot water valve 150 will open to provide predetermined or adjustable volumes of hot water to the spigot 44 for as long as the button maintains electrical communication, or for a predetermined time interval determined by an electrical circuit, or until a weight sensor positioned below the drink container, or a volume level sensor, or a proximity sensor, to send a shut-off signal when the sensor indicates the weight reaches a predetermined level or the sensor reaches a termination level, or a proximity position.
Referring further to
Referring to
An agitator pump, preferably contains a submersible agitator electrical motor 171 (
The agitators 170 are responsible of enhancing the heat exchange between the ice-bank and the water-bath inside the chilled water reservoir. The water in the reservoir is kept just above freezing. The thickness of the ice-bank 178 and, in general the amount of ice formed around the evaporator coil inside the chilled water reservoir is controlled by the NTC 180 in
Prior art drink stations use agitators 170 that are activated for predetermined periods of time after liquid is dispensed from the spigot, or simply based on the ice-bank 178 growth. Advantageously, the operation of the agitators 170 is controlled based on the temperature of drinking water chiller coil measured in the water-bath adjacent to the drinking water chiller coil 94. To measure the drinking water temperature a second NTC thermistor 182 is used. Referring to
The second temperature sensor 182 is advantageously an NTC sensor having an electrical resistance that decreases as temperature increases, but other sensor types could be used. When the water temperature approaches freezing at the location of the drinking water chiller coil 94 as detected by the drinking water temperature sensor 182, the electrical power to the agitator electrical motor 171 is shut off so the agitators 170 stop circulating water inside the chilled water reservoir 74. Controlling the operation of the agitators 170 is believed unusual and advantageous, as it stops circulation of the chilled water and thus stops carrying heat away from the drinking water chiller coil 94, preventing freezing of the drinking water that must flow inside the drinking water chiller coil 94. At the same time, if the agitators 170 continue working, they will gradually reduce the thickness of the ice-bank when dispenser is not in use.
The first temperature sensor 180 inside the chilled water reservoir 74, also called the ice temperature sensor 180, is located parallel to the wall of the chilled water reservoir 74 and spaced a predetermined distance from the wall and from the evaporator coil 77 in a position as to allow ice to grow around the evaporator coil, but stop the refrigeration by powering off the freezer's compressor 70 electrically connected to the controller 64 (see
The agitator electrical motor(s) 171 is/are in electrical communication with controller 64 through the agitator electrical communication line 175 (
The drinking water temperature sensor 182 which is positioned adjacent or inside the drinking water chiller coil 94 measure the temperature of the drinking water inside the coil 94 either directly (if inside) or indirectly by way of calculating the conductivity coefficient of the stainless steel which is the material the water chiller coil's walls are made of. At a water temperature above a certain threshold water temperature called Lower Temperature Point (LTP) (which is a temperature between 0.01° C. and 1.5° C., preferably between 0.1° C. and 1.1° C. and in particular preferably right at 0.6° C.) the agitator(s) operates. At a water temperature below a certain threshold temperature called Upper Temperature Point (UTP) (between 0.3° C. and 3.0° C., preferably between 0.7° C. and 1.7° C. and in particular preferably right on 1.2° C.) the agitator(s) 170 are powered off by the controller 64. Therefore, preferably, above the LTP the agitator(s) 170 work, below the UTP the agitator(s) 170 do not work; this is believed to avoid consuming latent heat from the ice-bank without this latent heat being efficiently used to lower the temperature of the drinking water. In the range of temperatures between LTP and UTP, called the ear-band, the agitator(s) do not work if they were not working and continue not to work until the temperature of the drinking water inside the chiller coil 94 reaches the UTP at which point the agitator(s) receive a signal to start working. The agitator pump will continue to work until the temperature of the drinking water goes back down. In this process when the temperature decreases from a temperature above the UTP, the agitator(s) 170 will continue to work until the LTP is reached. At this point the controller 64 shuts off the agitator(s). In summary, below LTP the agitator(s) do not work. Above the UTP the agitator(s) work. In the ear-band of temperatures between the LTP and the TP, the agitator(s) will continue to work if they were working before (because the drinking water temperature was above the UTP), while the agitator(s) will continue to idle if they were not working before (because the drinking water temperature was below the LTP). In the range of temperatures between UTP and LTP the agitator(s) remain in its pre-existing working or non-working conditions.
In another variation, the agitator speed varies depending on the drinking water temperatures. The speed of the agitator increases as the temperature increases. Below the LTP the agitator(s) do not work. Above the LTP agitator starts working at a speed that is proportional to the rising of the temperature of the drinking water inside the chiller coil as detected by temperature sensor 182. The speed variation of agitator's electric motor 171 is controlled by the controller 64.
Referring to
Referring to
The rotor of the agitator pump (
Four fins or outlet tubes 186 are shown in
A single agitator pump is shown with four fins or outlet tubes 186, one aimed for the middle of each wall of the rectangular reservoir 74 and the ice bank 178 associated with each wall and between each pair of temperature sensors (e.g., 180, 182). While a single agitator pump is shown in
Referring to
Referring to
The drink station 20 is shipped without water in the chilled water reservoir 74. The chilled water reservoir 74 is preferably sealed so no fluid enters or leaves unintentionally, even when the drink station is inclined the fluid inside the chilled water reservoir 74 does not spill out. The water level sensor 188, and the water reservoir filling solenoid valve 196 and filling line 198 allow water to be automatically added and thus avoid manually carrying water to pour it into the chilled water reservoir, and avoiding the attendant, when the apparatus is installed, set up, or serviced, splashing and spilling of water on electronic and mechanical components. When electrical power to the drink station 20 is activated, the water level sensor 188 indicates that the chilled water reservoir is low on water, resulting in opening of the chilled bucket valve 196 until the chilled water reservoir 74 is filled until the float 190 rises to a predetermined level and an electrical signal is sent that results in the valve 196 being closed to shut off the water. If water is lost through evaporation and the water level 194 in the reservoir 74 falls then the water level sensor 188 can send a signal to the controller 64 to automatically add more water to maintain the water level 194 within a predetermined range of water levels.
A user may push the auto-fill button 60, or any pre-determined sequence of buttons (
The various water lines and electrical connections for components contained inside the reservoir 74 preferably pass through sealed openings in the top of the reservoir 74 and through the insulation on that top. Some electrical wires for such electrical communication are shown in the figures, and various fluid lines are shown in the figures. Such sealed connections are known and not described in detail herein. The sealed chilled water reservoir 74 is believed to offer advantages other than avoiding the risks of adding water to a reservoir surrounded by electrical connections and fluid lines. It makes performance more consistent because the water level 194 in the chilled water reservoir is controlled so the ice bank 178 has a more uniform thickness and volume which maintain the temperature of chilled water in the reservoir at a more constant temperature, and that maintains the temperature of the dispensed beverages at a more uniform temperature. Further, the sealed water reservoir 74 also reduces leakage of water from the reservoir into the surrounding environment, including its electrical and fluid connections, as may occur if the drink station 20 were tilted during repositioning of the drink station, or as may occur if the drink station were on a vehicle, boat or ship that tilts and sways.
The details of forming a sealed water reservoir 74 are not disclosed in detail. Advantageously though, a container may be formed with welded seams, and a top lid with appropriate sealed passages for the fluid lines and electrical wires may be provided. Rubber or silicon or other elastomeric sealing passages are known, and viscous sealant that hardens with time can also be used to seal such passages for fluid lines and electrical lines in the lid or container. A ring seal such as an O-ring seal or a labyrinth seal may encircle the lid or top of the reservoir to provide a fluid tight seal with the sidewalls of the container/reservoir.
Referring to
Referring to
Alkaline Cartridge
Referring to
The alkaline cartridge 102 has cartridge housing 210 that is typically cylindrical and extends along a longitudinal axis. The alkaline cartridge 102 has a cap 212 with a fluid inlet 214 and a fluid outlet 216. In the depicted embodiment the cap 212 is cylindrical and extends from the top end of the cartridge with a cammed mounting lugs 218 extending radially outward from at least two opposing sides of the cap. Each cammed lug 218 has a contoured top surface configured to mate with a corresponding surface in a manifold in the drink station that is described later. The fluid inlet and outlet 214, 216 are coaxial and extend along the longitudinal axis of a nozzle 220 extending from the center of the cap along the longitudinal axis of the cartridge. The nozzle 220 typically has one or more ring seals such as O-ring seals, encircling the nozzle to form a fluid seal with a mating surface in the manifold as described later. In the depicted embodiment the inlet 214 is an annular flow path encircling the cylindrical and centrally located outlet flow path 216, but the order and flow direction can be reversed. Also, other nozzle configurations can be used, including physically separated nozzles on different parts of the cap for each of the inlet and outlet.
The water inlet 214 is preferably in fluid communication with an inlet dispersing disk 222 that is shown as having a circular periphery with a plurality of axially aligned passages extending through the disk. An annular rim extends upward around the periphery of the disk. The disk and rim are sized to fit in a fluid tight manner with the inside of the (preferably cylindrical) housing 210. Inflowing water from inlet 214 hits the disk 222 and spreads outward and passes axially through the disk. The annular rim confines outwardly flowing water to the top surface of the disk and redirects water inward and through the axially aligned passages.
A bed of alkaline material 224 is located below the disk 222 and the disk advantageously restrains the top of the bed of material to retain it in position within the cartridge housing 210. The bed of alkaline material 224 advantageously comprises ceramic mineral balls made of alkaline materials, sometimes referred to as tourmaline balls, although the balls are advantageously manmade with porous ceramics. Various alkaline minerals may be intermixed with ceramic material or other binders and sintered to form particles, preferably spherical balls. Binders such as silica sol, polyvinyl alcohol and kaolin are believed suitable. A ceramic composition comprising 10-30 wt % of Al2O3; 10-30 wt % of SiO2; 0.1-1 wt % of P2O5; 0.1-5 wt % of K2O; 0.1-5 wt % of TiO2; 0.1-0.5 wt % of Fe2O3; 1-10 wt % of ZrO2; 0.1-1 wt % of AgO; 0.1-1 wt % of ZnO; 1-5 wt % of Na2O; 0.5-10 wt % of CaSO3; 5-20 wt % of a calcium oxide antibacterial agent; and 0.1-2 wt % of a binding agent is believed suitable. The binding agent may include silica sol, poly (vinyl alcohol) and kaolin.
Various alkaline minerals and/or electrolytes may be made into a powdered form, rolled into spheres or balls, preferably with suitable binders, and sintered or fired to fasten the materials together. Water dissolves the alkaline materials as it passes through the alkaline bed 224. Alkaline materials include calcium, magnesium, manganese, potassium, iron, phosphorous, sodium and zinc. Others may be used. The alkaline bed 224 is designed so that the water passing through the bed and out the alkaline cartridge 102 has a PH of 7.2 to 10.0.
After passing through the alkaline bed 224, the alkaline water passes through a filter 226, preferably an ultra-filtration layer, and/or a nano-filtration layer or membrane. The filter 226 is layered between the bed of alkaline material 224 and a bed of activated carbon 228, preferably granular activated carbon (GAC). A second, bottom disk 230 is located below and holds the bottom of the bed of activated charcoal 228. The bottom disk 230 advantageously seals against the inner surface of the housing 210 and has a plurality of passages extending through the disk and axially aligned with the longitudinal axis of the cartridge 102. The bottom disk 230 advantageously has a downwardly extending annular rim encircling the periphery of the bottom disk 230, to form a chamber between the portion of the disk with passages and a closed bottom 232 of the cartridge 102.
A central tube 234 extends along the longitudinal axis of the alkaline cartridge 102 and places the chamber at the bottom of the cartridge in fluid communication with the outlet 216. During use, water flows into the inlet 214 and downward. The water is spread by the top disk 222 over the top of the bed of alkaline materials 224. The filter layer 210 removes mineral particulates from the water and as the water passes downward through the activated carbon layer 228 to further polish the water and improve its taste. Additionally, the GAC slows the flow of alkaline minerals and avoids or reduces sudden changes in alkalinity due to a sudden release of minerals in the water. After passing through the charcoal bed 228 the filtered collects in the bottom chamber between the bottom disk 230 and the bottom of the cartridge 102 where it flows up the central tube 234 and out the outlet 216.
The alkaline cartridge 102 is removably connected to a manifold 240 mounted in the drink station. As seen in
Referring to
During use, the access door 242 (
Hot Water Tank
Referring to
The heater 154 extends a predetermined distance upward into the hot water reservoir. A temperature sensor 156, preferably a thermistor and more preferably an NTC sensor, extends from the end wall into the hot water reservoir. The temperature sensor is preferably an NTC sensor in a stainless-steel housing and is advantageously located very close to (within 1 mm) the flat top of the heater 150, and preferably located so it physically contacts the top of the heater 150. If the temperature sensor 156 contacts or nearly contacts the heater 156, a spike in the temperature at the sensor 156 can indicate a low water level in the hot water reservoir 262. The temperature sensor 156 is in electrical communication with a controller 64 that uses the sensor's signal to either apply or shut off electrical power to the heating element 268 to maintain the temperature of the water in the hot water reservoir 262 within a predetermined rage of temperatures. A controller 64 that activates the heating element 26° F. at 170° F. and shuts off the electrical power at 210° F. or 99° C. is believed suitable.
A thermostat 158 is located in the end wall of the tank housing 260 adjacent the heater 150. In the event the temperature sensor in the thermostat 158 fails and the water in hot water reservoir 262 gets above a predetermined threshold, the thermistor 156 sends a signal to the controller 64 that results in cutting off electrical power to the heating element. A layer of water separates the thermostat 158 from the adjacent heater 150 so the thermostat senses the temperature of the water, preferably the temperature at the bottom end of the heater and the hot tank. The thermostat 158 regulates the temperature of the heater 154. The thermostat 158 may be attached at any other locations within the hot water reservoir as long as it measures the water temperature and is immersed most of the time. The thermostat 158 normally opens an electric circuit interrupting power to heater 154 when the temperature of hot tank exceeds 100° C. The maximum temperature can be varied, and it is not uncommon for other water heaters in drink stations to have the maximum temperature at 120° C.
The vapor chamber 264 is separated from the hot water reservoir 262 by a dividing wall 274 that separates the hot water reservoir 262 from the vapor chamber 264. A first tube, control tube 276, has a first end that extends through the top side of the hot tank housing 260 so the first end is located outside the tank housing 260 where it may be connected to the hot water line 160. The control tube 276 has an opposing, second end referred to a slotted end 278, which is in fluid communication with both the hot water reservoir 262 and the vapor chamber 264. The slotted end 278 has a plurality of slots 280 extending along a longitudinal axis of the control tube 276 and extending through the wall of the hollow tube. Four, equally spaced slots 280 are used in the depicted embodiment. The control tube 276 is preferably of stainless steel to reduce corrosion and scaling that may alter the slot dimensions over time.
A vent opening 282 also extends through the wall of the control tube 276 near the end of the slots 280. The vent opening 282 is small enough that water does not drip out of it when the control tube is filled with hot water, and it provides an air path to ensure hot water does not get air-locked in the control tube 276 and hot water line 160 when the spigot 44 is shut off or closed, as the pressure pulse in the hot water line from shutting off or closing the spigot 44 to stop dispensing hot water will vent through the vent opening 282 and assure immediate venting and backflow of hot water through the control tube into the hot water reservoir 262 in a continuous flow of hot water, and reduces or avoids dripping of water out of the control tube into the hot water reservoir. This vent opening 282 is optional. The slots 280 and vent opening 282 are located inside the vapor chamber 264. The slotted end 278 is in fluid communication with the hot water reservoir 280 through a discharge opening 284 in the dividing wall 274 which discharge opening is advantageously, but optionally, in an alignment structure.
In the depicted embodiment of
A second tube, vent tube 288 extends through the top of the hot tank housing 260 and insulation 261 to be placed in fluid communication with the vent tube 262 and spigot 44. A water inlet 290 is located in the bottom of the hot water reservoir 262 to place the hot water reservoir 262 in fluid communication with the hot water valve 150 to supply water to the hot water reservoir. The water inlet 290 is shown as a tubular fitting extending downward and sideways to connect to the fluid line from the hot water valve 150. Optionally, the water inlet 288 may have a deflector or directional device 292 inside the hot water reservoir to direct incoming water parallel with the bottom of the hot water reservoir 262, so the hot water reservoir fills from the bottom up, pushing the hot water toward the discharge opening restrictor 284. The deflector brings the incoming water closer to the heater and favor the mixing of the incoming water at room temperature with the rest of the water inside the hot water reservoir 262. A hot water drain fitting 294 (
Mounting brackets 296 are connected to the housing 260 to connect the hot water tank 152 to supporting structure within the drink station 20. The depicted mounting brackets 296 are shown as two L-brackets fastened to the bottom of the hot water tank 152, with the water inlet 290 passing through an opening in one of the brackets
In use, steam from the heated water in the hot water reservoir 262 rises and passes through the discharge opening 284 and into the vapor chamber 264. If steam condenses into water in the vapor chamber 264, the condensed hot water passes through the slots 280 in the slotted end 278 of the control tube 276 and through the discharge opening 284 and into the hot water reservoir 262.
In use, pressing the hot water button 58 opens the hot water valve 150, which opens to pass water through the water inlet 240 in the bottom of the water tank 152, where the deflector 292 directs the incoming water parallel to the bottom of the hot water reservoir 262 and forces the hot water at the top of the reservoir up and into through the discharge opening restrictor 284 and through the control tube 276 and into the hot water line 160 to the spigot 44 for discharge. As water is forced through the discharge opening restrictor 284 and into the hot water line 160 it creates a suction effect that draws steam from the vapor chamber through the slots 280 and into the stream of water passing through the hot water line and through the spigot 44. The steam contains more energy than hot water and provides a more efficient heating system to provide hot water at the spigot 44 and provides extra heat energy to compensate for the heat loss as the hot water passes through the hot water line 160 which is preferably hot actively heated, although it is insulated. All of the chilled water lines in the drinking station may be insulated.
When the spigot 44 closes, the cessation of fluid flow causes a reflux pressure which can push hot water into the vapor line 162 and back toward the hot water tank 152. The vapor line 162 acts as a ventilation line so that a vacuum lock in the hot water line 160 does not prevent the hot water from flowing back into the hot water tank 152, but instead air pressure urges the hot water to flow back along fluid passage 160 (and if water enters it, along vapor line 162) from the spigot 44 through the hot water line 160 and into the hot water tank 152. The vent opening 282 also allows fast reflux or return of hot water to the hot water reservoir 162 as the pressure pulse from closing the hot water dispensing spigot 44 may ensure the water in the control tube 276 is not air locked and instead flows out of the tube and into the hot water reservoir. Hot water returning through the hot water line 160 passes into the hot water reservoir 262 while hot water from the vapor line 162 passes into the vapor chamber. The vent opening 282 also reduces small volumes of water from being trapped by an air lock in the control tube 276 or slotted end 278. Water in the vapor chamber from any source passes though the slots 280 in the slotted end 278 of the control tube 276 and passes through the discharge opening 284 and into the hot water reservoir 262. The hot water line 160 from the hot water tank 152 to the spigot 44 is advantageously inclined at least slightly upward, so that gravity urges the hot water to flow backwards from the spigot to the hot water tank.
The volume of the hot water tank 152 is selected based mostly on the volume of hot water demand, with a larger tank 152 used when a large volume of hot water is expected to be dispensed at spigot 44. The relative volumes of the vapor chamber 264 and hot water reservoir 262 are also important because the vapor chamber 264 reduces the usable volume of hot water in the hot water reservoir 262, and if the volume in the vapor chamber 264 is too small then reflux water from shutting off or closing the spigot 44 can enter the vapor chamber 264. Similarly, the inflow of water into the hot water reservoir 262 is important so that hot water flows through the control tube 276 and spigot 44 rather than flow into the vapor chamber 264. The relative flow through the discharge opening restrictor 284 and input fitting 294 are regulated to achieve optimum operation, with the discharge opening 284 acting as a flow restrictor to ensure pressure to force hot water through the discharge tube and create a vacuum in the vapor chamber 264 that sucks out the hot vapors rather than flood the vapor chamber with hot water flowing through the slots 280. In a sense, the flow through the control tube 276 is regulated so the hot water passes through the restrictor 284 at a flow rate sufficient to create suction at the slots 276 rather than flowing water through the slots and into the vapor chamber.
Conceptually, the volume and pressure of water entering the hot water tank 152 and the volume and pressure of water exiting through the control tube 276 are balanced to create a suction at the slotted end 284 located inside the vapor chamber 264 that entrains steam from the vapor chamber into the hot water flowing upward to the spigot 44, with sufficient pressure to flow the hot water upward to the spigot. In one preferred embodiment, the water inlet 294 has a diameter of 4.4 mm to provide a flow rate of 1 liter per minute through the discharge opening 284 so that the hot water from the chamber will pass through the smaller sized flow restrictor formed by discharge opening 284 which has a diameter of 3 mm at a flow rate sufficient to suck hot water vapor through the slots 280 and into the water stream entering the hot water line 160 and to the spigot 44 which is at an elevation higher than the hot water tank 152 and the hot water outlet 276. The slots 280 are advantageously sized to create a venturi effect when the minimum desired flow rate is achieved. Four slots 1 mm wide and 4-5 mm long are believed suitable in the preferred embodiment. A vent opening 282 about 2-3 mm diameter is believed suitable for the above described slotted end 278. Advantageously, the flow rate of 1 liter per minute is a minimum flow rate at a line pressure of 40 psi and is selected as a design criteria because most municipal water lines have a line pressure that is 40 psi or greater.
Using a hot water tank 152 located below the dispensing spigot 44 is believed to offer several advantages in connection with the design of the beverage dispensing system. The discharge opening 284 is sized smaller than the fluid inlet 290 which increases the discharge pressure with which hot water is forced from the hot water tank 152 and that increased pressure is used to push the hot water to the spigot 44 which is higher than the hot water tank. That increased discharge pressure is used to create the venturi effect which sucks steam from the vapor chamber 264 and entrains it in the stream of water directed to the spigot 44. The inflow of water through the inlet 290 at the line pressure (or other regulated pressure above 40 psi) is directed by deflector 292 to force the hottest water at the top of the hot water reservoir 262 out the discharge opening. The location of the hot water tank 152 below the spigot 44 allows water to drain with gravity and return to the tank (once the vent line 162 releases the vacuum that might hold the water in the line) and thus allows the spigot to be cooler than if it remained in thermal contact with the hot water in the hot water line 160 even when no water was being dispensed.
Carbonators
Referring to
More specifically, in reference to
The carbonated water lines from the cold water and carbon dioxide mixed in the venturi in the splitter 119 (
The first carbonation chamber 120 defines an interior preferably having a 100 μm micromesh 334 and a plurality of 5 mm glass beads disposed within the carbonation chamber 120. The micromesh 334 can vary in size. The second carbonation chamber 121 preferably defines a 400 μm micromesh net, within which are plurality of 1 to 3 mm glass beads. The micromesh nets are preferably cylindrical.
Each carbonation chamber 120, 121 thus advantageously has a cap 325 and a base 329, with the chambers 120, 121 defined by the cap portion 325 and the base portion 329. The cap and base are shown as having elongated portions with mating threaded portions at the joined ends so the long body of the cap and base form the respective chambers 120, 121. But the cap 325 and base could be shorter and on opposing ends of an elongated tube which forms the main portion of the chamber.
The micromesh net 334 extends about the interior chamber and is shown as forming a cylindrical tube with the glass beads 325 disposed inside the micromesh net 334. Micromesh net 334 advantageously has a top and bottom support ring (
Fluid flow into and out of the carbonation chambers may be varied. In use, carbonated water output from the second carbonation chamber 121 communicate to the carbonated fluid line 122 or communicated to a flow compensator which in turn is in fluid communication with the carbonated fluid line 122 and the outlet spigot.
As the water molecules pass through the micromesh net 334, 336 the charge on the net is believed to influence water molecules orientation because it is known in the art that water molecules are polarized. Such passive polarization, created as a consequence of the interaction of the molecules and the net, thereby enhances the dipole bonding between the water and carbon dioxide molecules.
Alternatively, the micromesh net may be implemented as a pair of concentric nets 334 (
As indicated above, the first carbonator 120 and its carbonation chamber 120, may include the micromesh net 334, through which the input water and gas mix passes, is preferably formed of one or more independent rings of micromesh metal, such as stainless steel. The passage of the carbonated water through the micromesh net 334, breaks the long molecule compounds of water while creating a weak electrostatic field due to the high-speed passage of more polarized molecules which, within a short period of time (less than one second) the more polarized molecules of the fluid mix (water and carbon dioxide) so the short (broken) chains of water molecules have a higher likelihood of forming dipole to dipole electrostatic connections with the carbon dioxide molecules. In the present embodiment, static electric fields are self-induced by the passage of polarized molecules: creating electrical induction. Other embodiments of the same apparatus may utilize a process in which electric fields are artificially generated externally, through a common DC power supply, or multiple DC power supplies, resulting in highly polarized water and gas molecules that are immediately oriented, in accordance with the electrical filed generated on the net. Whichever is the solution adopted (induced electrical field or artificially generated), the result is high polarization and orientation of the molecules of liquid and gas. In case of passively induced electrical fields, not only does the induced static electric field contribute to the polarization of molecules transiting within, but the polarization itself modifies the electric field that is generated.
Although the electrostatic field herein generated by the passage of polarized molecule is expected to be relatively weak, the resulting increase in the polarization of water molecules increases the likelihood of the formation of bonds between the water molecules and the carbon dioxide molecules, whose bonds, as known in the art, are particularly weak. This is because as the degree of polarization of each water molecule is increased the total number of water molecules with a high degree of polarization is increased. By breaking the long chains of molecules and gradually orienting the same, in response to the electrostatic field, there is an increase in the (temporary) formation of carbonic acid inside the water, and the resulting water has been found to be more highly carbonated. In addition, the water molecules have been found to retain a bond with the carbon dioxide molecules that mitigates dispersion of the carbon dioxide molecules, (i.e., bubbling, when the carbonated water is exposed to air during dispensing). As bonds are increased, the carbonization in water is higher and more durable over time, as the carbonated water sits in an open glass or bottle.
In the illustrated embodiments, the micro mesh nets are formed of thin stainless-steel strands of approximately 2 to 100μ in diameter, having an open mesh area of approximately 5 to 800μ. A micro mesh net 334, 336 may be formed of other materials, and the size of the strands/open mesh areas and may be varied as suited for specific pressure levels, flow rates, desired levels of carbonation and other factors.
Beverage Container Alignment Light
Referring to
Advantageously, a single spigot 44 is used to dispense all of the beverages, as in the drink station of
The light bar 352 advantageously takes the form of an elongated, lighted member that is electrically controlled to create a visual light that moves from the top of the filling area 40 downward toward the bottom of the drink station and drain pan 46 in a repeating pattern, and with the visual length of the light bar aligned in a vertical plane through the spigot and parallel to the opposing, rectangular sides of the drink station 20 as shown in
Advantageously, the light bar 352 includes a plurality of LED's 356 close enough together that each individual LED may be separately and sequentially activated by a timer and control circuit to create a repeating pattern of lights extending from the top of the light bar to the bottom of the light bar. Advantageously, the LED's are located behind a strip of clear or translucent plastic that forms a shield, so the LED's 356 are shielded from the dispensed beverages being splashed on the LED's. Advantageously, an elongated slot in the sidewall 42 may be formed with the plastic shield filling the slot for easy cleaning. The illuminated light bar 352 allows a user to visualize the stream of liquid dispensed from the spigot 44 and assists in aligning a beverage cup with the dispensed liquid.
As indicated by the dashed lines in
Each of the LED's 356 or other light source for each of the light bars 352 is in electrical communication with the controller 64 which contains electrical circuitry to activate the lights in a stationary or repeating pattern when electrical power is provided to the controller 64, or when a drink selection button 52, 54, 56, 58 or 60 is activated. The controller may contain a timer circuit that shuts off the lights after a predetermined time of illumination without intervening activation of one of the drink selection button. If a light bar 352 is provided for each spigot the light bar only for that spigot may be activated to provide the described lamination.
System Operation
There is thus advantageously provided a dispensing apparatus (
A normally closed sparkling carbonation, such as water valve 116 is positioned downstream of the drinking water chiller coil 94 and downstream of the water line splitter 132. At least one normally closed carbon dioxide valve 112, preferably a valve, is positioned on the gas line from the internal carbon dioxide gas canister 108 to a static venturi-restriction device 144 (
An electronic controller 64 is configured to control the water delivery pump 92, and the three normally-closed valves 96, 116 and 112 and is in communication with these valves and with the drink selection buttons 52, 56 associated with those valves and the dispensing of chilled water and carbonated water from the spigot 44. Advantageously, the controller 64 is in electrical communication with the identified valves and buttons through the electrical communication lines described herein, or such other electrical communication lines as are appropriate to the specific application. These three valves are normally closed so drink dispensing apparatus has a the normally closed chilled water valve 96, a normally closed sparkling water valve 116 and a normally closed carbon dioxide gas valve 112.
The beverage dispensing apparatus 20 has at least two selectors, such as buttons 52, 56 to alternatively dispense either chilled still water or chilled carbonated water. When the chilled still water selector 56 is activated, the water delivery pump 92 is powered on by the controller 64, and the normally closed, chilled water valve 96 is excited electrically to open and allow chilled still water to be dispensed from spigot 44. When the chilled sparkling selector 52 is activated, the water delivery pump 92 is powered on, the sparkling water valve 116 and the carbon dioxide gas valve 112 are both excited to open to allow carbonated water to be dispensed from spigot 44.
While the beverages are described as being dispensed from the same spigot 44, they could be dispensed from separate spigots or from other dispensing devices. Further, when the electricity used to open the normally closed valves described herein is removed or shut off, the valves close. Thus, they are described as being “excited to open.” The closed valve may be considered to be shut off or turned off, and an open valve may be considered as being turned on as with a water faucet in a sink. Thus, open and closed valves correspond to opening and closing valves or turning valves on and off. But regardless of the detailed operation, the controller 64 or control module 64 contains opens and closes the various valves and turns power to various pumps on and off and applies power to and receives signals from various sensors. The basic control schematics for the electrical controls are described herein, but other control circuits and control logic and modules are believed usable.
In further variations of the above described beverage dispensing apparatus 20, the normally closed main inlet valve 90 is positioned downstream of the main inlet port 86 and controlled by the controller 64 such that when any selector button 52, 54, 56, 58 or 60 is activated, the main inlet valve 90 is excited and opens. The apparatus 20 preferably includes a flowmeter 88 electrically connected to the controller 64 that allows the controller 64 to measure the quantity of water passing through the flowmeter, and thus to indicate the volume or quantity of water being dispensed through the spigot 44. Such control, communication and volume measuring is known in the art and not described in detail herein. The apparatus 20 also may have an ambient temperature water line 104 in fluid communication with a normally closed ambient water valve 100, in communication with the controller 64, and preferably in electrical communication with the controller 64 and an ambient water selector button mounted adjacent the other buttons. When the ambient water selector button is activated, a signal is sent to the controller 64, opens the ambient water valve 90 to allow ambient temperature water to be dispensed when the valve 90 is in fluid communication with the spigot 44, without any intervening devices that change the character of the ambient temperature water.
There is also provided a beverage dispensing apparatus for chilled, sparkling and alkaline water production that includes the beverage dispensing apparatus described above, including the main water inlet port 86 in fluid communication with the water delivery pump 92, at least one stainless steel drinking water chiller coil 94 that is at least partially inserted into a heat exchanger shown in the drawings as chilled water reservoir 74. The dispensing apparatus 20 also includes the chilled sparkling water line with at least one carbonation system at least partially inserted into the same heat exchanger, with the carbonation system including the canister 108 of carbon dioxide gas, at least one venturi 140 in the splitter 119 or intersecting fluid lines 114, 138, 140, 142, and/or the carbonation chambers 120, 121. The dispensing apparatus includes the normally closed chilled water valve 96, the normally closed sparkling water valve 116, the least one normally closed carbon dioxide gas valve 112 positioned on a gas line from the carbon dioxide gas tank 108.
This dispensing apparatus further advantageously include an ambient temperature water line 104 in fluid communication with filtered water at the input port 86 or in fluid communication with water filter 130, both of which (when present) are in fluid communication with the normally-closed ambient temperature water valve 90. This apparatus further advantageously includes an alkaline chamber 102 that release pre-selected minerals into the water and positioned in fluid communication with the ambient water line 104, downstream of the normally closed ambient temperature water valve 100. When the alkaline selector 54 is activated, the electronic controller 64 opens both the ambient water valve 100 and also opens the chilled water valve 96 so that both ambient water from the alkaline chamber 102 (i.e., alkaline water) and chilled water are both dispensed and mixed at the outlet, such as spigot 44.
In further variations of the alkaline water dispensing apparatus, the controller 64 opens and then closes the chilled water valve 96 for a time interval which is shorter than the time interval that the ambient water valve 100 stays open. That provides more chilled water to the fluid outlet (e.g., spigot 44) which both cools the water at the outlet and reduces the alkalinity of that water. In still further variations of the alkaline water dispensing apparatus, the alkaline chamber includes a cartridge containing mineral crystal balls inside a bed having granular activated carbon (GAC). Advantageously, the cartridge is configured so that it is releasably fastened to a fluid manifold in the apparatus 20, and is preferably configured so the cartridge can be easily be changed by rotating it to unlatch the cartridge from the fluid manifold after which the cartridge is moved axially out of the manifold. Other releasable connections are known for connecting water filter cartridges to refrigerators and those releasable connections may be used with the alkaline cartridge.
In still further variations on the above beverage dispensers 20 with the internal carbon dioxide gas canister 108 and the carbonators 120, 121, and the alkaline canister 102, the dispenser may contain a hot tank 152 with a hot water reservoir 262 in fluid communication with the main water valve 90, preferably a normally closed valve 90, and hot water valve 150, which is also preferably a normally closed valve. The valves 90, 150 and hot water selector 58 are in communication with the controller 64. When the hot selector 58 is activated, the hot water valve 150 and the main water valve 90 are excited to open and allow inflowing ambient temperature water from the main valve to force hot water from the top of the hot water tank into hot water line 160 which is in fluid communication with an outlet, such as spigot 44. Advantageously, the hot tank includes a vapor chamber in fluid communication with a hot water reservoir so that steam may collect in the vapor chamber. The hot water flows through a control tube passing through the vapor chamber which tube has a venturi that sucks steam from the vapor chamber into the hot water stream that is ultimately dispensed at the outlet. Advantageously, a return vapor line places the vapor chamber in fluid communication with the outlet, such a spigot 44, to provide a pressure release that allows the hot water to drain back along the hot water line and into the hot water reservoir in the hot tank. The hot tank 152 advantageously has a heating element 154 inside which is configured to heat the water at temperatures ranging between 205° F. and 170° F., and a temperature sensor NTC 156, both controlled by the controller 64 to control the heating element and maintain the water temperature within that temperature range. Advantageously the NTC 156 is immediately adjacent to and preferably contacting the heating element to provide a heater shut off if the temperature suddenly changes which is reflective of a water level below the thermistor.
When the water inside the hot water reservoir 262 is at a temperature, as detected by the temperature sensor, at or below the lower setting point, the controller 64 powers on the heating element 154 and keeps it powered on until the temperature of the water reaches the upper setting point as detected by the temperature sensor when the controller 64 stops powering the heating element. If the temperature sensor in the thermistor 158 does not work, the temperature of the wall of the hot tank will increase and the thermostat 156 opens the electric circuit 163 to cut the power to the heating element 154. The sudden increase of temperature that arise when the water level is low is detected immediately by the thermistor adjacent to the heater and a signal to the controller 64 is sent to cut the power to the heater.
The above described beverage dispensing apparatus 20, the dispensing nozzle or spigot is in fluid communication with any combination of chilled water through the chilled water line 98, carbonated water through the carbonated water line 122, both ambient temperature alkaline water and chilled alkaline water through the alkaline water line 104, and hot water through the hot water line 160. These different types of water may be dispensed sequentially, or simultaneously, in any combination by the controller 64 which opens and closes the appropriate valves, including main flow valve 20, hot water valve 150, chilled water valve 96, and carbonation valves 112 and 116. Additionally, the amount of carbonation can be varied depending on the activation of the carbonators 120, 121. The inlet water at inlet port 86 may be filtered or unfiltered, and whether filtered or not, may have one or more internal filters 130, or external 82, 84 in fluid communication with the water inlet 86 to further purify the water.
Referring to
Referring to
The agitator pump 170 advantageously includes a submersible pump inside the chilled water reservoir 74 and advantageously located at one of the bottom or top of the drinking water chiller coil 94, and advantageously aligned with a central, longitudinal axis of that drinking water chiller coil 94. Preferably, there are two agitators 170 each with a water intake located on that central, longitudinal axis and each with a plurality of radial water outlet ports which outlet ports are preferably in a plane orthogonal to that longitudinal axis. More preferably, the water flow of each of the two agitators 170 creates a spherical circulation flow pattern extending from the agitator pump outlet ports to about halfway to the other agitator.
Advantageously, the controller 64 is in communication, and preferably in electrical communication with a water level sensor 188 that senses the water level 194 of the chilled water reservoir and when the water level reaches a predetermined low level, the sensor sends an electrical signal (or other type of signal) to the controller 64 which sends a signal that opens the normally closed chilled water valve 196 to fill the water level 194 up to a maximum water level determined by the sensor.
Referring to
Referring to
Figure Eight Evaporative Freezer Coil
A single tube 401 of the refrigeration system's evaporative line that freezes water on the outside of the evaporative line advantageously forms the figure eight cooling coil 401, with that single tube 401 bent to form a series of figure eights extending in a serpentine manner with each successive figure eight stacked above the prior ones to form a figure-eight coil extending upward along the vertical axis. The material of the freezer coil is made in copper or other suitable metals. The refrigeration system forming a figure eight evaporator coil 401, is thus bent to form first and second, interconnected, tubular coils 402, 404. First freezer coil 402 forms one portion of the figure eight coils and the second freezer coil 404 forms the other portion of the stacked figure eight coil 401.
The tubular arrangement of the coils 402, 404 is advantageously formed with two opposing, straight and parallel sides. Each figure eight is formed by plurality of coil segments with parallel and opposing sides 402a, 402b (or 404a, 404b) joined by a straight back 402c (or 404c) that is perpendicular to those opposing sides, and with the juncture of the two opposing sides and back having rounded corners. The tubular coils 402, 404 are connected by first and second, preferably straight, connecting coil segments 402d, 404d. Connecting coil segment 402d extends from tube 402a to tube 404a in the adjacent level or layer of the figure eight coils, while second connecting coil segment 404d extends from tube 404b to tube 402b in the adjacent level or layer of figure eight coils. The connecting segments 402d, 404d are interleaved where they cross between the two coils 402, 404. The opposing sides of the coils 204, 404 are formed by a plurality of coil segments 402a, 402b, 404a, 404b, respectively and a majority of the coil segments 402a through 402d and 404a through 404d are advantageously parallel and slightly inclined upward to allow for the intersecting segments 402d, 404d.
As seen in
The connecting segments 402d, 404d extend between opposing walls 408a, 408b and extend across the width of the water reservoir 406. At the location where the connecting segments 402d, 404d cross each other, the crossing coil segments advantageously form a substantially continuous stack of freezing coil segments 402d, 404d as seen in
The reservoir walls 408a-e form a fluid tight, thermally insulated enclosure with sealed openings for the various fluid connections and electrical connections described with respect to the first embodiment and additional ones for the second chilled water reservoir 414. The reservoir walls 408a-e are advantageously insulated by insulation 410, with any fluid communications or electrical communications also passing through the insulation as well as the water reservoir. A lid may be removable to allow physical (e.g., repair) access to the inside of the reservoir, but if so, the lid is advantageously sealed to the remaining portions of the water reservoir walls in a fluid tight manner, so water does not leak out the water reservoir.
The single freezer expansion line that is coiled to form the figure eight configuration 401 is shown in
Referring to
But where the connecting segments 402d, 404d of the evaporator coil 401 approach each other and cross the, the water forms a middle or center ice bank 418. Depending on the dimensions of the water reservoir 406 and the construction and temperature of the figure eight cooling coil, the middle or center ice bank 418 can advantageously extend entirely across the width of the water reservoir 406.
The crossing of the connecting segments 402d, 404d increases the cooling capacity and freezing capacity at the location where the connecting segments cross each other, and as shown in
Referring to
As seen in
A refrigeration system with the figure eight coil 401 provides a larger volume of chilled water than does the single coil freezer design, while doing so with a single compressor and expansion coil. Moreover, the center ice bank 418 can be thicker in the end-to-end direction between reservoir walls 408c and 408d because the connecting segments 402d, 404d of the freezer coils 402, 404 may be configured to create a thicker ice bank in that direction. The thicker center ice bank 418 allows a larger reserve of ice to melt if the chilled water in the reservoirs 412, 414 becomes warm because of high demand resulting in high flow of water through the two drinking water chiller coils 420, 422. The melting ice banks 416, 418 provide a thermal reserve to stabilize temperature variations as the ice melts when the water in the chilled water heats up and the melting ice. The thicker center ice bank 418 thus allows more temperature stability in the chilled water contained inside each chilled water reservoir 412, 414.
Referring to
Referring to
The electronic control module 64 of the beverage dispensing apparatus also allows a user at any time to change the “factory window setting” of the three main NTC temperature sensors 156, 180 and 182. By commands directed to the controller 64, the setting of the either or both the maximum temperature and the minimum temperature of each of the three main temperature sensors may be changed. Each of these three temperature sensors 156, 180 and 182 control the operation of other components to maintain temperatures at the location of the sensor between a maximum and a minimum setting points. Sensor 156 advantageously operates from 96° C. and 80° C.; sensor 180 advantageously operates from 0.6° C. and 1.2° C.; and sensor 182 operates from 0.4° C. and −1.8° C. Each of the above settings can be modified manually by holding the FR button 147 for a predetermined minimum time (e.g., more than 10 seconds) until the buttons 52, 54, 56 and 58 start flashing and, by touching each of them, in accordance with a predetermined software code, user can selectively change, increasing or reducing the max and min temperature settings of each of the temperature sensors 156, 180 and 182. By changing the temperature setting of sensor 156, a user can increase the temperature of the hot water dispensed by the apparatus in accordance with personal preferences. By changing the temperature setting of sensor 180, a user can produce less ice or more ice, for example making the apparatus produce a lot of extra ice to build a thicker ice-bank which provides a larger energy storage and a lot of latent heat to meet a high consumer demand, as may arise when the apparatus is installed in a busy restaurant during rush hour. By changing the temperature setting of sensor 182, one can vary the setting temperatures of the agitator pump 170, allowing, for example, the agitator pump to work in a larger range of temperatures and extract more heat from the ice bank, as may arise when the apparatus is installed in a busy restaurant compared to a residential home.
The above description is given by way of example, and not limitation. Given the above disclosure, one skilled in the art could devise variations that are within the scope and spirit of the invention, including various ways of varying the dimensions such as the angle of the crossing freezer coil segments 402d, 404d. A number of valve types are believed suitable for use for the various valves described herein, including solenoid valves. Further, the various features of this invention can be used alone, or in varying combinations with each other and are not intended to be limited to the specific combination described herein. Thus, the invention is not to be limited by the illustrated embodiments.
This application is a continuation of U.S. application Ser. No. 16/875,975 filed May 15, 2020, which application claims priority to U.S. Provisional Application No. 63/006,652 filed Apr. 7, 2020, and to U.S. Provisional Application No. 62/849,796 filed May 17, 2019, the disclosures of each of which applications are incorporated herein by reference in their entireties.
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Number | Date | Country | |
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20230054529 A1 | Feb 2023 | US |
Number | Date | Country | |
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Number | Date | Country | |
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Parent | 16875975 | May 2020 | US |
Child | 18048750 | US |