Abstract:
A refrigerator incorporating in its door a water dispenser within a compartment present on the outside of the door, the dispenser being connected to a water container of given capacity carried by the door and provided to enable the contained water to be carbonated via a connection to a cylinder that contains the carbonating gas and is also disposed in the door.

Description:
BACKGROUND OF THE INVENTION 
   The present invention relates to a refrigerator incorporating in its door a water dispenser, the water being withdrawn by the user at a compartment present on the outside of the door. 
   DESCRIPTION OF THE RELATED ART 
   In traditional refrigerators, there is no provision for dispensing carbonated water in addition to still water. 
   SUMMARY OF THE INVENTION 
   The present invention relates to a refrigerator configured to dispense both carbonated water and still water. 
   Another embodiment of the present invention concerns a refrigerator that enables a given quantity of water to be carbonated in situ, i.e. within the door. 
   Furthermore, an additional embodiment of the present invention includes a refrigerator of the indicated type in which the water can be carbonated by technical processes and expedients which are simple and hence economical even though reliable. 
   These embodiments, in addition to others that will be apparent from the ensuing detailed description, are realized by a refrigerator according to the technical teachings of the accompanying claims. 

   
     BRIEF DESCRIPTION OF THE DRAWINGS 
       FIG. 1  is a schematic partial view of a refrigerator door shown in vertical section through the compartment from which the water present in the door is withdrawn, and 
       FIG. 2  is a schematic view of the components involved in the dispensing of the water. 
   

   DETAILED DESCRIPTION 
     FIG. 1  depicts a refrigerator door  1 , shown partially in vertical section. In the door there is provided a conventional compartment  2  open towards the outside and usable by the user to fill any container, for example a glass, with ice via a conventional dispenser for that purpose, or with cooled water which, according to the invention can be carbonated or still. 
   The water is dispensed via a nozzle  4  intercepted by a valve  5  conventionally operated by the user who for this purpose acts on a dispensing handgrip operationally connected to the valve. 
   The nozzle  4 , valve  5  and handgrip  6  form a dispenser and are situated at the lower end of a water container, of given capacity,  7  mounted in a tubular seat  8 , which extends into the compartment  2  and forms part of the lining of this compartment  2 . 
   A chamber  10  of the compartment  2  (compartment to which access can be gained from the outside or from the inside of the door and which is closed by a shutter, not shown) removably houses a CO 2  cylinder, indicated by  11  and connectable to the container  7  to carbonate the water quantity contained therein, as described hereinafter with particular reference to  FIG. 2 . 
   This latter figure shows a more detailed construction of that already described. In  FIG. 2  equal or corresponding parts carry the same reference numerals as already used. 
   The CO 2  cylinder is screwed or tightly pressed into a port  20  forming part of a support piece  21  fixed to the roof  22  of the compartment  2 . The cylinder  11  is closed by a seal  23  that is perforated by a needle valve  24  mounted in the support piece  21  and located at the entry to a conduit  25  that extends into the support piece  21  and to which a solenoid valve  26  is connected via a pipe  27 . The exit of the solenoid valve  21  is connected via a pipe  28  to an inlet port  29  present in a cover  30  fixed in any known manner to the support piece  21 . 
   The cover  30  forms the seal for the water container  7  (which defines the carbonation environment) that, in this example, is integral with the support piece  21 . The cover presents a nozzle  31  that passes through the cover, and at one end is connected to a conduit  32  for feeding water, for example tap water. At its other end the nozzle  31  is provided with a controlled valve  32 A. A pressure gauge  33  can also be connected to the cover. The cover  30  also carries: a conventional level sensor  34  which extends into the container  7 , and a safety (overpressure) valve  35  which acts on an electrical microswitch controlling a carbonated water indicator lamp (not visible) indicating that carbonation has taken place. Although not shown, there is also provided a pushbutton, which by operating (in the sense of opening) the solenoid valve  26  connects the container  7  filled with water to the cylinder  11  for carbonating this water. 
   Initially the container is empty. The level sensor  34  senses this situation and causes water to enter the container through the electrically operated valve  32 A or alternatively through a solenoid valve, not shown, positioned in the conduit  32 . The cooled still water is hence fed into the container  7 . When a predetermined water level is reached, the level sensor  34  halts the feed of water (by acting on the valve  32 A or on the alternative valve) and lights an indicator lamp that warns the user that the desired water level has been attained. The still water can however be withdrawn continuously even if the desired level has not been reached and the relative indicator lamp is not lit. Withdrawal is achieved in conventional manner by acting on the nozzle  4 , valve  5  and handgrip  6 . 
   When the level indicator lamp is lit, the user can, if desired, initiate the carbonation phase by pressing a pushbutton (not shown) which activates the solenoid valve  26 , enabling the CO 2  to flow from the cylinder  11  to the container  7  and to carbonate the water contained therein. 
   As already stated, the container  7  presents a safety and overpressure valve  35  provided with a electrical switch which when the required pressure has been attained in the container  7  closes the solenoid valve  26  and lights the indicator lamp to advise the user that the now carbonated water is ready to be drawn off. 
   In the case of operating anomalies, for example overpressure, the safety valve  35  opens to discharge the excess CO 2  into the atmosphere and at the same time closes the solenoid valve  26  to prevent the danger of explosion of the container  7 . 
   The following advantages derive from the invention: the user no longer has to physically purchase large quantities of still or carbonated water, transport it and then store it in the home; this signifies a saving of time and fatigue; in addition empty bottles do not have to be retained for their recycling, there is less refuse and from an economical viewpoint there is a saving in the cost of the water, in addition to having it always available when required by the user. 
   The reference numeral  50  indicates a pressure sensor (pressure switch) that measures the pressure of the cylinder  11  and acts on an indicator lamp (not shown) to warn the user that the cylinder is empty.