Abstract:
A method and apparatus for rapidly chilling a cool pack associated with a refrigeration system wherein slush-like medium is introduced into the pack in a first step and frozen to a substantially solid state in a second step.

Description:
BACKGROUND OF THE INVENTION 
     The present invention relates to a method and apparatus for freezing a liquid medium and more particularly to a method and apparatus for freezing a preselected liquid medium to be introduced into a heat transfer chamber in the form of a cool pack utilized in a cool suit clothing such as that worn by personnel to confront oppressive heat conditions. 
     Cool suits worn by military ground crews, armorers and the like include cool packs which comprise unit heat transfer chambers containing a liquid medium that has been frozen in the unit chambers at a central refrigeration station. In the past these unit chambers have been bulky to extend the cooling capacity when the packs have been inserted in a cool suit, utilized in the heated area and returned for recharging, with extensive amounts of time being required. Further complications have arisen by the need to have several spare cool packs so that in the freezing process at the central refrigeration area some packs can already be frozen and some can be in the process of freezing--while still others can be in use. 
     The present invention, recognizing these problems of the past, provides a straight forward method and apparatus for preparing cool packs for field use which require a minimum of steps, time and parts and which prove economical in both operation and maintenance. Because of the rapid manner in which the cool packs can be prepared for field use by the present invention, the number of cool packs carried can be reduced, as can the overall energy requirements. 
     It is to be understood that the method and apparatus of the present invention should not be considered as limited to use only for military purposes but also can be utilized in any other environment including commercial situations where it is desirable to quickly and efficiently provide frozen heat transfer medium such as in ice making for beverage cooling. 
     Various other features of the present invention will become obvious upon reading the inventive method and apparatus set forth hereinafter. 
     SUMMARY OF THE INVENTION 
     More particularly the present invention provides a method for quickly freezing a liquid medium by cooling the medium in a first cooling zone to a slush-like state and then introducing the slush-like medium into a second cooling zone and cooling it to a frozen state. In addition, the present invention provides a novel refrigeration assembly and cool pack assembly utilized therewith including first and second liquid chillers, each having evaporators associated therewith, one having a temperature control to bring a liquid medium therein to a slush-like state and the other having a temperature control to bring a second liquid medium therein to a temperature below the slush-like medium with the cool pack assembly including a heat transfer unit therein to allow the second medium to quickly freeze the slush-like medium when both mediums have been pumped into heat transfer relationship in the pack. 
     It is to be understood that various changes can be made by one skilled in the art in the arrangement, form, construction and several steps setforth hereinafter without departing from the scope or spirit of the present invention. 
    
    
     DESCRIPTION OF THE DRAWINGS 
     Referring to the drawings which disclose one advantageous embodiment of the present invention: 
     FIG. 1 is a schematic view of the refrigeration system of the present invention; 
     FIG. 2 is a schematic end view of the novel cool pack assembly unit; and, 
     FIG. 3 is a side view of the cool pack unit of FIG. 2 taken in plane passing through line 3--3 of FIG. 2. 
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENT 
     As can be seen in FIG. 1 of the drawings, the refrigeration system 1 includes a compressor 2, a condenser 3 and parallel disposed evaporators 4 and 6 which respectively form part of &#34;brine-type&#34; chiller chambers 7 and 8 respectively. The chillers and evaporators, which are shown schematically, can be any one of several well known commercial types manufactured by companies such as Carrier Air Conditioning Co., Dunham-Bush Inc., Trane Co., Borg Warner Corp. and Westinghouse Electric Corp. 
     Each evaporator 4 and 6 is respectively arranged to include a temperature regulator control 9 and 11 which can be any one of several types known in the art and sold by such manufacturers as Honeywell, Inc., Robertshaw Controls Co., Johnson Service Co. and Penn Controls, Inc. As is conventional in a refrigeration system, each evaporator 4 and 6 also is proceeded respectively by a thermal expansion valve 12 and 13. 
     Each chiller 7 and 8 is provided with fluid inlet and outlet conduit sets 14 and 16 respectively. Suitable liquid pumps 17 and 18 are provided with each of the conduit sets 14 and 16. These liquid pumps are also shown schematically and can be selected from anyone of several pump manufacturers such as Bell &amp; Gossett, ITT, Sarco and Peerless Pump Div., FMC Corp. Each pump can be arranged to be actuated by suitable switching mechanisms when the fluid inlet and outlet sets 14 and 16 of the chillers are connected with the fluid outlet and inlet sets 19 and 21 of the novel cool pack 22 described hereinafter. It is to be understood that the temperature regulator controls 9 and 11 are set to control suitable liquid mixtures such as preselected quantities of ethylene glycol and water disposed in each chiller 7 and 8 so that the evaporator 4 in chiller 7 causes the mixture to form into a slush-like state, advantageously at approximately 0° F. and the evaporator 6 in chiller 8 causes the mixture therein to be held at a temperature below the temperature of the mixture held in a slush-like state in chiller 7. Advantageously, the freeze point of the mixture in chiller 8 can be preselected to be at minus (-) 32° F. 
     The unit cool pack 22 which can be arranged to be made in compact form from any one of a number of suitable heat transfer materials formed from polystyrene or polyethylene in any one of a number of suitable shapes includes the aforedescribed fluid inlet and outlet conduit sets 19 and 21 which are respectively sized and shaped to engage with sets 14 and 16 of chillers 7 and 8. It is to be understood that the conduit sets 14 and 16 and 19 and 21 aforedescribed can be provided with any one of several quick connect and disconnect arrangements (not shown) which are available on the commercial market from coupling manufacturers such as Aeroquip Corp., Nibco, Inc. and Midland-Ross Corp. 
     It is to be noted that fluid inlet and outlet set 19 of cool pack 22 is connected to the main chamber 23 of pack 22 and fluid inlet and outlet set 21 is connected to a heat exchange tubular element 24 disposed within chamber 23. Element 24 is schematically disclosed as including heat exchange fins 26 but it is to be understood that these fins can be eliminated and that various tubular conformations can be utilized. 
     In a typical operation of the method and apparatus of the arrangement disclosed a cool pack is brought to refrigeration system 1 which can be centrally located. Fluid inlet and outlet set 19 communicating with chamber 23 is quickly connected to fluid inlet and outlet set 14 of chiller 7 with pump 17 being actuated to cause a slush-like state fluid medium to be introduced into chamber 23 of cool pack 29. Once cool pack chamber 23 is filled, the cool pack 22 is disconnected from chiller 7, turned around and connected through fluid inlet and outlet sets 16 and 21 to chiller chamber 8. This actuates pump 18 for chiller chamber 8 and liquid medium at a temperature below the freeze point of the slush-like medium now in chamber 23 is circulated through heat exchange conduit 24 to cause the slush-like medium to quickly freeze. Cool pack 22 can then be disconnected for use in a cool suit or other heat zone environment. Thus, in a straightforward, economical manner the fluid, medium in chamber 23 can be brought to freeze state quickly over and over again with the fluid mediums being reutilized as they are circulated in their chiller chambers 7 and 8 by the respective pumps 17 and 18.