Patent Document

CROSS-REFERENCE TO RELATED APPLICATION 
       [0001]    This application claims the benefit of U.S. Provisional Patent Application Ser. No. 61/350,123 for an ORIENTATION INSENSITIVE REFRIGERANT DISTRIBUTION TUBE, filed on Jun. 1, 2010, which is hereby incorporated by reference in its entirety. 
     
    
     TECHNICAL FIELD OF INVENTION 
       [0002]    The present disclosure relates to an inlet distributor for an evaporator; more particularly to an inlet distributor having a plurality of orifices arranged along the length of the distributor tube. 
       BACKGROUND OF INVENTION 
       [0003]    Residential and commercial air conditioning and heat pump systems are known to employ modified automotive heat exchangers, which are desirable for its proven high heat transfer efficiency, durability, and relatively ease of manufacturability. Automotive heat exchangers typically include an inlet header, an outlet header, and a plurality of refrigerant tubes hydraulically connecting the headers for refrigerant flow therebetween. Corrugated fins interconnect adjacent refrigerant tubes to increase the available heat transfer area, as well as to increase the structural integrity of the heat exchanger. The coil of the heat exchanger is defined by the refrigerant tubes and interconnecting corrugated fins. 
         [0004]    To meet the demands of residential and commercial applications, the size of the coil of the heat exchanger has to be increased accordingly, which in turn dramatically increased the lengths of the inlet and outlet headers. For a heat exchanger operating in evaporator mode, the increased length of the headers tends to result in refrigerant mal-distribution through the refrigerant tubes. Momentum and gravity effects, due to the large mass differences between the liquid and gas phases, can result in separation of the phases in the inlet header and cause poor refrigerant distribution through the refrigerant tubes. Poor refrigerant distribution degrades evaporator performance and can result in uneven temperature distribution over the coil. To assist in providing uniform refrigerant distribution though the refrigerant tubes, it is known to provide a distributor tube in the inlet header. 
         [0005]    A typical distributor tube extends the length of the inlet header and includes a plurality of uniformly spaced orifices for distributing the two-phase refrigerant throughout the length of the header. The orifices are oriented at a designed angle relative to the center of the cross-section of the refrigerant tube to provide the maximum performance for the coil in a specific application. Typically, the angle of the orifices is selected based on testing a vertical slab coil design with the refrigerant tube aligned in the opposite direction of gravity. 
         [0006]    Indoor evaporators also have the additional challenge of packaging constraints; the evaporators have to fit within the limited volume offered by the plenums of residential HVAC systems. In a slab coil design, the refrigerant tubes lie in a plane much like that of an automotive heat exchanger, and for maximum efficiency it is preferable that the refrigerant tubes are aligned in the direction of gravity with the inlet header lower than the outlet header. To provide the cooling capacity required within a limited space, two smaller slab coils are assembled into an A-Frame design or a single larger slab coil is bent into an ARC design. The A-Frame design or ARC design may need to be installed in various orientations with respect to gravity, in which the refrigerant tubes may not be aligned in the direction of gravity and the inlet header may not be lower than the outlet header. The desired distribution of refrigerant flowing through the coil may be adversely affected due to the orientation of the evaporator. There is a long felt need for an evaporator that provides good refrigerant distribution regardless of its orientation. 
       SUMMARY OF THE INVENTION 
       [0007]    The invention relates to a heat exchanger assembly having an inlet header, an outlet header spaced from the inlet header, a plurality of refrigerant tubes hydraulically connecting the inlet header with the outlet header. A distributor tube having a plurality of orifices disposed in the inlet header, wherein the orifices are arranged along the distributor tube such that at least one orifice is oriented in the liquid phase of a two-phased refrigerant pressed against the internal surface of the distributor tube regardless of the orientation of the evaporator. 
         [0008]    According to one aspect of the invention, the orifices may be substantially uniformly spaced along the length of the distributor tube in pairs or groups of four (4). Within each pair of orifices, one of the orifices may be oriented 90 to 180 degrees apart from the other with respect to the pair&#39;s respective point on a central axis. Each pair of orifices may be rotated 90 to 180 degrees from the adjacent pair of orifices. For groups of four (4) orifices, each of the orifices may be oriented 90 degrees apart from the adjacent orifice with respect to the group&#39;s respective point on a central axis. Each group of four (4) orifices may be rotated 45 degrees from the adjacent group of four (4) orifices. 
         [0009]    In another aspect of the invention, the cylindrical refrigerant distributor tube may have a plurality of orifices spiraled along the tube. With respect to an end view of the central axis, each succeeding orifice may be offset 45 to 180 degrees from the preceding orifice. 
         [0010]    The above configurations of orifices on the distributor tube provide that at least one of the orifices will be located within the liquid phase of the two-phase refrigerant flowing through the distributor tube regardless of the final orientations of the evaporator coil. This provides at least the advantage of improved refrigerant distribution through the refrigerant tube of the heat exchanger assembly resulting in improved heat transfer efficiency. 
     
    
     
       BRIEF DESCRIPTION OF DRAWINGS 
         [0011]    This invention will be further described with reference to the accompanying drawings in which: 
           [0012]      FIGS. 1A-C  show representative end views of an A-type coil or bent coil design evaporator. 
           [0013]      FIG. 2  shows a distributor tube in an inlet header of an evaporator, in which the orifices of the distributor tube are oriented in a direction opposite that of the direction of gravity. 
           [0014]      FIG. 3  shows a distributor tube in an inlet header of an evaporator, in which the orifices of the distributor tube are oriented in the direction of gravity. 
           [0015]      FIG. 4  shows a cross-section of the inlet header having a distributor tube with the liquid phase of refrigerant pressed-up against the interior surface of the distributor tube. 
           [0016]      FIG. 5  shows a refrigerant distributor tube having groups of two (2) orifices along the length of the distributor tube, wherein the orifices in each group are oriented 180 degrees apart from each other and the groups of two (2) orifices are rotated 90 degrees apart from each other. 
           [0017]      FIG. 6  shows a refrigerant distributor tube having groups of four (4) orifices along the length of the distributor tube, wherein the orifices in each group are oriented 90 degrees apart from each other. 
           [0018]      FIG. 7  shows a refrigerant distributor tube having a plurality of orifices spiraled along the tube at an exemplary 90 degrees between adjacent orifices. 
       
    
    
     DETAILED DESCRIPTION OF INVENTION 
       [0019]    For a typical slab coil design evaporator, the desired angle of the orifices of a distributor tube is selected based on testing of a vertical slab coil in which the refrigerant tubes are aligned in the direction of gravity with the inlet header lower than the outlet header. To accommodate the packaging constraints required for residential applications, a residential indoor evaporator may be constructed by using two slab coils in an A-Frame design or a single slab coil bent into an ARC design. Shown in  FIGS. 1A-1C  are representations of an end view of an A-Frame design or ARC design residential indoor evaporator  10  having an inlet header  12   a , an outlet header  12   b  spaced apart from the inlet header  12   a , and a plurality of refrigerant tubes  14  hydraulically connecting the headers  12   a ,  12   b  for refrigerant flow. An evaporator coil  16 , partially shown in  FIGS. 2 and 3 , is defined by the plurality of refrigerant tubes  14  together with external fins  15  interconnecting the adjacent refrigerant tubes  14 . The evaporator  10  includes a distributor tube  20  in the inlet header  12   a , shown in  FIGS. 2-7 , for improved refrigerant distribution. The above mentioned components of the evaporator  10  are typically constructed of a heat conductive material such as aluminum. 
         [0020]    Each of the A-Frame design and ARC design provides an evaporator  10  having at least one apex  18 . The A-Frame or ARC design can be installed within a HVAC plenum in various orientations with respect to the direction of gravity, in which the apex  18  may be up, down, horizontal, and any other orientation therebetween. With these varieties of possible orientations, the inlet header  12   a  may be located above the outlet header  12   b , below the outlet header  12   b , or horizontal with the outlet header  12   b . The headers  12   a ,  12   b  are typically perpendicular to that of the direction of gravity, but the bottom header may be slightly angled toward the direction of gravity to facilitate condensate drainage. 
         [0021]    A standard angle designed for the orifices  22  of the distribution tube  20  relative to the refrigerant tube  14  may not necessarily work efficiently when used in all the various potential orientations of the evaporator  10 . It was found that only certain range of angles of the orifices  22  of the distribution tube  20  relative to the refrigerant tube  14  are acceptable for each of the various evaporator coil  16  orientations. In other words, orifice angles are application specific; therefore, the desired orifice range of angles has to be calculated for each specific orientation of the evaporator  10 . 
         [0022]    With reference to  FIGS. 2-4 , it is believed that the liquid phase  24  of a two-phase refrigerant flowing through the distributor tube  20  tends to migrate to the bottom of the interior surface  28  of the distributor tube  20  due to gravity. It is suspected that the liquid phase  24  does not necessary puddle on the bottom or low spot of the distribution tube  20 , but instead it is pressed against and rides up a portion of the interior surface  28  of the distributor tube  20  by the flow of refrigerant through the distributor tube  20 , thereby forming a liquid refrigerant cross-sectional profile  30  much like a crescent moon with its apex on the bottom. The limit would be annular flow where the liquid distributes around the entire peripheral internal surface  28  of the distribution tube  20 , but more typically a thicker layer would exist on the bottom. 
         [0023]    It was found that if the orifices  22  were facing in a direction other than between 45 to 315 degrees with respect to the opposite direction of gravity being 0 degree, mostly vapor phase refrigerant tend to exits the orifices  22  migrating toward the refrigerant tubes  14 . This is undesirable because optimal heat transfer efficiency is obtained when the refrigerant entering the refrigerant tubes is in a substantially liquid phase. 
         [0024]    With reference to  FIG. 3 , it was surprisingly found that when the orifices  22  are oriented substantially in the direction of gravity, the pressure and momentum of the refrigerant flowing through the distributor tube  20  pushes the liquid phase refrigerant out of the distributor tube  20  through the orifices  22  toward the refrigerant tubes. The refrigerant remains substantially in liquid phase until it reaches the refrigerant tubes  14 , at which point the liquid phase refrigerant starts to absorb heat and vaporizes, thereby providing optimum heat transfer and even temperature distribution across the evaporator coil  16 . With reference to  FIG. 4 , during periods of high refrigerant flow, the liquid refrigerant cross-sectional profile  30  occupies the interior surface  28  of the distributor tube  20  from 45 to 315 degrees with respect to the opposite direction of gravity being 0 degree. During normal operating conditions, the liquid refrigerant cross-sectional profile  30  occupies the interior surface  28  of the distributor tube  20  from 90 to 270 degrees. 
         [0025]    An aspect of the invention provides a means to transport the liquid phase refrigerant from the distributor tube  20  to the refrigerant tubes  14  for efficient boiling and thus improved heat transfer performance regardless of the orientation of the A-Frame or ARC evaporator coil evaporator. This can be achieved by having orifices  22  at angles from 45 to 315 degrees, preferably between 90 to 270 degrees, with respect to the opposite direction of gravity being 0 degree, along the distributor tube  20  to ensure that at least one, but preferably a group, of orifices  22  is substantially oriented within the liquid refrigerant cross-sectional profile  30 . By having one or more orifices within the liquid profile  30 , the refrigerant flowing through the distributor tube  20  will push the liquid phase refrigerant through the orifices  22  and toward the refrigerant tubes. 
         [0026]      FIG. 5  shows a cylindrical refrigerant distributor tube  20  extending along a substantially central axis (A-axis). Pairs of orifices  22  are substantially uniformly spaced along the length of the distributor tube  20 , in which each pair of orifices  22  is located about its respective point on the A-axis. Within each pair of orifices  22 , one of the orifices  22  may be oriented 90 to 180 degrees apart from the other with respect to the pair&#39;s respective point on the A-axis. Furthermore, each pair of orifices  22  may be rotated 90 to 180 degrees from the adjacent pair of orifices  22 . 
         [0027]      FIG. 6  shows a cylindrical refrigerant distributor tube  20  extending along the A-axis. Groups of four (4) orifices  22  are substantially uniformly spaced along the length of the distributor tube  20 , in which each group of orifices  22  is located about its respective point on the A-axis. Within each group of four (4) orifices  22 , each of the orifices  22  may be oriented 90 degrees apart from the adjacent orifice  22  with respect to the group&#39;s respective point on the A-axis. Furthermore, each group of (4) orifices  22  may be rotated 45 degrees from the adjacent group of (4) orifices  22 . 
         [0028]      FIG. 7  shows a cylindrical refrigerant distributor tube  20  having a plurality of orifices  22  spiraled along the tube. With respect to an end view of the A-axis, each succeeding orifice  22  may be offset 45 to 180 degrees from the preceding orifice  22 . 
         [0029]    With the above configurations of orifices  22  on the distributor tube  20  or any configuration that provides at least one orifice  22  in the desired direction regardless of the orientation of the evaporator  10  would improve the distribution of refrigerant though the refrigerant tubes  14 . Therefore, if the evaporator coil  16  is positioned in any one of the various possible orientations, at least one of the orifices  22  would be located within the liquid refrigerant cross-sectional profile  30 . 
         [0030]    While this invention has been described in terms of the preferred embodiments thereof, it is not intended to be so limited, but rather only to the extent set forth in the claims that follow.

Technology Category: 2