Single-serving beverage machine with high-capacity and compact cooling-carbonation system

What is claimed is: 1. A beverage machine system comprising: an insulated potable liquid storage tank having an interior volume defined by one or more potable liquid retaining surfaces and retaining a chilled potable liquid within the interior volume at about ice bath temperature; a liquid carbonator spaced within the interior volume of the insulated potable liquid storage tank and submerged therein and wherein the liquid carbonator is in fluid communication with a pressurized carbon dioxide source tank via a carbon dioxide supply conduit; a high pressure potable liquid pump configured to pump potable liquid from the interior volume of the insulated potable liquid storage tank through a potable liquid conduit to a spray nozzle within an interior volume of the liquid carbonator such that carbon dioxide is supplied at a carbon dioxide pressure from the carbon dioxide tank and carbonation occurs as potable water is delivered to the interior of the liquid carbonator by utilizing the high pressure potable liquid pump and wherein the high pressure potable liquid pump delivers the potable liquid from the interior of the insulated potable liquid storage tank at a variable, but increasing pressure via the spray nozzle at a pressure greater than the carbon dioxide pressure throughout the process of carbonating the water in the liquid carbonator; a cooling coil positioned in a spaced apart relationship but wound around the liquid carbonator such that the cooling coil does not physically touch an exterior surface of the liquid carbonator submersed within the chilled potable liquid and an amount of space between the cooling coil and the liquid carbonator is at least substantially free of any other structure other than periodic frozen potable liquid adjacent the cooling coil; and a mechanical stirring device positioned within the interior volume of the insulated potable liquid storage tank and wherein carbon dioxide gas is constantly provided to the liquid carbonator from the carbon dioxide tank and wherein the liquid carbonator further comprises a carbonated water outlet positioned at the bottom of a rigid intake portion and extending upwardly from a position proximate a bottom of an interior of the liquid carbonator; wherein the stirring device is a motor driven magnetically coupled impeller assembly and wherein at least the bottom of the stirring device positioned within the interior volume of the insulated potable liquid storage tank has a plurality of radially outwardly extending and angled blades or a plurality of paddle surfaces. 2. The beverage machine system of claim 1 , wherein a carbonated potable liquid produced within the liquid carbonator is substantially and constantly provided from an outlet of the liquid carbonator and regulated using a carbonated potable liquid water valve and thereafter a flow controller both positioned along a carbonated potable water delivery conduit between the carbonated water outlet and a beverage dispensing pod positioned within a pod receiving mechanism within the beverage machine system. 3. The beverage machine system of claim 1 further comprising a cooling subsystem that comprises a compressor, a condenser, a condenser fan associated with the condenser, a plurality of coolant conduits, and wherein the cooling coil is an evaporator coil in coolant fluid communication with the other components of the cooling subsystem. 4. The beverage machine system of claim 3 , wherein the chilled potable liquid within the volume is chilled, filtered, uncarbonated water and the insulated potable liquid storage tank is hermetically sealed. 5. The beverage machine system of claim 3 , wherein the insulated potable liquid storage tank includes an interior metal liner, insulative layer and exterior housing and wherein the cooling coil positioned in a spaced apart relationship but wound around the liquid carbonator is a first evaporator coil and wherein the beverage machine system further comprises a second evaporator coil engaged with the exterior surface of the interior metal liner of the insulated potable liquid storage tank and spaced between the interior metal liner and the exterior housing. 6. The beverage machine system of claim 3 , wherein the compressor is a dual suction compressor where a first compressor suction inlet is operably connected via a first compressor suction inlet coolant conduit with a first evaporator and wherein a second compressor suction inlet is operable connected via a second compressor suction inlet coolant conduit with a second evaporator such that the compressor can regulate a cooling capacity balance between both the first evaporator and the second evaporator. 7. The beverage machine system of claim 1 further comprising a water filter positioned within the system and spaced within a housing of the system and wherein the system is either operably connected to a potable liquid source having enough natural pressure to deliver potable liquid through the filter and to the system or associated with a potable liquid delivery pump that provides the potable liquid at a pressure sufficient to deliver potable liquid through the filter and to the system. 8. The beverage machine system of claim 7 , wherein the water filter further removes dissolved oxygen using a crystallized hydrated aluminosilicate made from 21% by weight of alumina hydrate Al(OH)3 and 68% to 72% sodium silicate Na2O 3.22-2.88 SiO2, which is mixed with 11% to 14% by weight sodium hydroxide NaOH in a 5% concentration and wherein the crystallized hydrated aluminosilicate has particle sizes of about five microns for about 75% of the material, and fifty microns for about 25% of the material. 9. The beverage machine system of claim 1 , wherein the system is free of any thermal storage substance other than the potable liquid and wherein the about ice bath temperature is above the freezing point of the potable liquid within the interior volume of the potable liquid tank, but below about 33 degrees Fahrenheit and wherein the interior volume of the potable liquid tank is at a potable liquid pressure from a potable liquid source and wherein the potable liquid is provided from a pressurized municipal water source. 10. The beverage machine system of claim 1 further comprising a pod system that receives a single serve beverage pod and wherein the pod system and when the single serve beverage pod is in an engaged position within the pod system, the single serve beverage pod are each in fluid communication to receive one of: (1) filtered potable fluid at about ice bath temperature, (2) a carbonated potable fluid at about ice bath temperature, or (3) a filtered hot potable fluid. 11. A single serving beverage machine system comprising: an insulated potable liquid storage tank having an interior volume that receives and retains a chilled potable liquid within the interior volume at about ice bath temperature; a liquid carbonator spaced within the interior volume of the insulated potable liquid storage tank and submerged therein and wherein the liquid carbonator is in fluid communication with a pressurized carbon dioxide source tank via a carbon dioxide supply conduit; a high pressure potable liquid pump configured to pump potable liquid from the interior volume of the insulated potable liquid storage tank through a potable liquid conduit to a spray nozzle within an interior volume of the liquid carbonator such that carbon dioxide is supplied at a carbon dioxide pressure from the carbon dioxide tank and carbonation occurs as the chilled potable liquid is delivered to the interior of the liquid carbonator by utilizing the high pressure potable liquid pump and wherein the high pressure potable liquid pump delivers the chilled potabl