Abstract:
A cooling device having a common cooling distribution unit with multiple compliant cooling elements. Mechanisms are built in to ensure the cooling elements are in good thermal contact with heat generating semiconductor chips of different heights and sizes on a common carrier. The cooling distribution unit has protection structures to prevent the leakage of coolant from the unit. Further reduction of the risk of accidental coolant leakage is provided with the onboard storage of coolant absorbent materials in the coolant distribution unit. The cooling elements have serpentine coolant channels to enhanced the cooling capacity. The compliance of the cooling elements can also be achieved by using concentric tubing to connect the coolant distribution unit to cooling heads on the cooling elements.

Description:
FIELD OF THE INVENTION  
         [0001]    This invention is in the field of heat transfer and cooling of semiconductor chips used in computer and telecommunication equipment. More particularly, this invention is directed to the constructing of a cooling device for semiconductor circuit chips soldered or socketed on a common carrier such as a printed-wiring board or multichip module, and for a method of assembly of such a device and with the devices to be cooled.  
         BACKGROUND OF THE INVENTION  
         [0002]    The problem that this invention intends to solve is an improved heat conduction device to carry heat from a plurality of heat generating semiconductor devices on a common carrier. The size and height of the semiconductor devices vary as well as the top surfaces of the semiconductor devices are also not in the same plane.  
           [0003]    Specifically, in the case of semiconductor integrated circuits, the circuit chips are interconnected to the next level of printed-wiring card/boards assembly using any type of chip packaging methods such as column, ball, or land grid arrays. The variation of the height among the many interconnecting elements can be as large as 0.25 mm. Such variations can cause uneven surface requirements for a common cold plate or heat sink solutions mentioned in previously issued patents. Such patents includes the following U.S. Pat. Nos. 5,239,443, 5,309,319, 5,023,695, 5,294,830, 5,170,319, 5,420,753, 5,537,291, 5,016,090, 6,111,749, 5,052,481, and 4.498,530.  
         SUMMARY OF THE INVENTION  
         [0004]    It is therefore an object of the present invention to provide a cooling device for semiconductor circuit chips soldered or socketed on a common carrier such as a printed-wiring board or multichip module.  
           [0005]    It is a further object of the invention to provide a method of constructing such a cooling device.  
           [0006]    The exemplary cooling device according to the invention may comprise one coolant distribution unit and multiple compliant cooling elements in contact with multiple semiconductor chips on a common carrier. The invention uses a flexible structure inside the coolant distribution unit coupling with the cooling elements to provide the needed compliance when the cooling elements are in contact with the semiconductor chips. Mechanisms are included in the cooling device to prevent coolant leakage to the outside of the cooling device. Flexible concentric tubing may be used to deliver and collect coolant from the cooling elements while providing the needed compliance.  
           [0007]    In accordance with the invention, an apparatus for cooling a plurality of devices, comprises a bottom plate; a cover; a first flexible member supported in the cover, the first flexible member having first openings therein; a second flexible coolant blockage member supported between the cover and the bottom plate, the second flexible coolant blockage member having second openings aligned with the first openings; respective cooling elements having first portions extending through the first openings and second portions extending through the second openings, each of the cooling elements having a cooling surface for contacting a device to be cooled; coolant tight seals for sealing the first portions of the cooling elements to the support member and the second portion of the cooling elements to the coolant blockage member; and coolant flow channels formed in the cover and the cooling elements to allow flow of coolant to cool the cooling elements.  
           [0008]    The apparatus can further comprise a mechanical bias element for biasing the cooling elements away from the cover. The cooling elements may further comprise a motion stop portion for interacting with the bottom plate to limit movement of the cooling element away from the cover caused by the bias element. The cover may comprise a cover plate; and a frame member, the first flexible member being supported between the cover plate and the frame member.  
           [0009]    The coolant flow channels in each cooling element include an opening for receiving cooling fluid from the cooling channels in the cover, a serpentine coolant flow passage adjacent the surface contacting the devices to be cooled, and a coolant outlet passage for discharging coolant to flow through an outlet passage in the cover. The cooling elements comprise a first part having a series of fins and a second part having a series of grooves. The grooves in the first part and the groves in the second part mate together to form a serpentine channel for the passage of coolant.  
           [0010]    The coolant tight seals comprise first annular grooves in the first portions of the cooling elements and second annular grooves in the second portions of the cooling elements; and first annular projections extending from the first flexible member into the first annular grooves, and second annular projections extending from the second flexible member into the second annular grooves. The coolant tight seals may further comprise annular seal bands surrounding portions of the first flexible member and portions of the second flexible member in proximity to the projections.  
           [0011]    The second flexible member, the bottom plate, and the cooling elements may define cavities or chambers in which coolant absorbent material may be placed. The coolant absorbent material may be selected from any type of desiccants such as silica gel, calcium aluminosilicate, polyacrylamide, etc.  
           [0012]    The apparatus may be combined with a carrier having thereon a plurality of devices to be cooled, at least some of the devices being disposed on the carrier so as to come into contact with the cooling surfaces of the cooling elements.  
           [0013]    The invention is also directed to an apparatus for cooling a plurality of devices, comprising a housing; a bottom plate disposed in the housing, the bottom plate having first openings therein; a cover plate for closing the housing; a second plate supported in the housing between the bottom plate and the cover plate to define a first space between the cover plate and the second plate and a second space between the second plate and the bottom plate, the second plate having second openings therein, the second openings being aligned with respective first openings; an outer cooling element for contacting each of the devices to be cooled; an outer tube for connecting each of the outer cooling elements to the bottom plate, each of the outer tubes being received in a respective one of the second openings; an inner cooling element received within the outer cooling element, each of the inner cooling elements having a connecting opening; an inner tube within each of the outer tubes for connecting each of the second cooling elements to the second openings so as to define a flow space between the inner tube and the outer tube; whereby a path for flow of coolant is defined extending along the first space, the inner tube, the connecting opening, the flow space, and the second space.  
           [0014]    The second openings have an enlarged region to define an annular space between the outer tube and the bottom plate. The apparatus further comprises a seal disposed between the outer cooling element and a wall of the enlarged region so as to close the annular space. A coolant absorbing material may be disposed in the annular space. The coolant absorbent material is selected from any type of desiccants such as silica gel, calcium aluminosilicate, polyacrylamide, etc.  
           [0015]    The outer cooling elements and the walls of the opening may each be configured with corresponding annular grooves, and the seal comprises an O-ring having portions disposed in the grooves. The inner tubes and the outer tubes are comprised of a resilient material.  
           [0016]    The invention is also directed to a method of assembling a cooling apparatus to a carrier having devices to be cooled. The method comprises partially evacuating at least one chamber in the cooling apparatus so as to move cooling elements in a direction and to a position wherein cooling surfaces of the cooling devices can not contact the devices when the cooling apparatus and the carrier are assembled; placing the cooling apparatus over the carrier; and allowing fluid to enter the at least one chamber so that the cooling surfaces are forced into contact with the devices.  
           [0017]    The cooling apparatus may be placed over the carrier by sliding the cooling apparatus and the carrier with respect to one another in a direction parallel to a plane of the carrier. 
       
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
       [0018]    These and other aspects, features, and advantages of the present invention will become apparent upon further consideration of the following detailed description of the invention when read in conjunction with the drawing figures, in which:  
         [0019]    [0019]FIG. 1 is an enlarged cross-sectional view of a portion of the cold plate with compliant cooling elements in accordance with the invention, assembled to a circuit board having devices which are cooled.  
         [0020]    [0020]FIG. 2 is an enlarged cross-sectional view of the compliant cooling elements of shown in FIG. 1.  
         [0021]    [0021]FIG. 3 is an enlarged cross-sectional view of another embodiment of the invention. 
     
    
     DESCRIPTION OF THE INVENTION  
       [0022]    As shown in FIG. 1, a multiple chip carrier  11  has a circuit board  12  having several layers of printed-wires (not shown) to electrically connect multiple chips  14   a  and  14   b  to each other and/or to external circuitry (not shown). The chips  14   a  and  14   b  are placed in their respective sockets  13   a  and  13   b . As shown in FIG. 1, the size and height of the chips are quite different, but in general, at least a portion of, and in some cases all of the chips on circuit board  12  may need to be cooled.  
         [0023]    A common coolant distribution unit  21  in accordance with the invention is mounted on the multiple chip carrier  11 . The coolant distribution unit  21  may comprise a main top cover  22 , a main central frame member  23 , and one main bottom plate  24 . These components may be formed of a metal or polymer. Top cover  22  has one or more coolant inlet ports  28 , while frame member  23  has one or more coolant outlet ports  27 , to which coolant delivery and removal conduits (not shown), attached by appropriate fittings (also not shown) bring coolant to and remove coolant from unit  21 . The coolant may be one of several fluids, such as water, an appropriate oil (such as a silicone oil), or helium as is well known in the art.  
         [0024]    Coolant distribution unit  21  may comprise a flexible inner plate  31  to separate the cool and warm coolant flows, and a coolant blockage plate  32 . Although characterized as plates, these actually may be flat thick members formed of a tough material such as a rubber, polymer, or preferably polyurethane. Alternatively, plates  31  and  32  may be comprised of a thin, flexible, metal, such as aluminum, steel, or other metal alloys compatible with the coolant.  
         [0025]    Multiple compliant cooling elements  41  are inserted into the coolant distribution unit  21  at various locations through openings in inner plate  31  and coolant blockage plate  32 , at positions which allow the cooling elements  41  to contact devices on carrier  11  which need to be cooled. Grooves  29 , in cooling elements  41  accept mating projections  36  of inner plate  31  and coolant blockage plate  32  to form a tight seal, due to the elastic nature of inner plate  31  and coolant blockage plate  32 . In addition, seal rings  33  and  35 , which may be O-rings, are installed around upwardly extending portions  39  of the openings in the flexible inner plate  31  and the coolant blockage plate  32  to push the material of the plates forcefully against cooling elements  41 , thus providing intimate contact and further assisting in preventing leakage of the coolant. Each compliant cooling element  41  is biased downward by a spring  34  at the tip of the compliant cooling element  41 . There is an optional stopper  49  on the compliant cooling elements  41  to limit the displacement of the compliant cooling elements  41 . Because of the flexibility of the inner plate  31  and coolant blockage plate  32 , the compliant cooling elements  41  are held in place in a somewhat floating manner and free to move laterally and perpendicularly to make good thermal contact with the chips on the multichip carrier  11 .  
         [0026]    Main bottom plate  24  is configured with cavities  51  under the coolant blockage plate  32 . Cavities  51  may be used to place coolant absorbent materials  52  to reduce the chance of further coolant leakage, should a  8  small quantity of coolant seep past seal rings  35 . Such coolant absorbent materials may be any type of desiccants such as silica gel, calcium aluminosilicate, polyacrylamide, etc.  
         [0027]    The invention provides the advantage that the compliant cooling elements  41  can be recessed during assembly by pumping out some of the air inside the coolant distribution unit  21 . This may be accomplished by temporarily blocking all of coolant inlet ports  28 , and coolant outlet ports  27 , except for one port. A vacuum line is connected to the one unblocked port by a suitable fitting. A partial vacuum is created within unit  21 , thus causing atmospheric pressure to act upon cooling elements  41 , and force them toward top cover  22 , thus compressing springs  34 . This is a useful feature when the coolant distribution unit  21  is to be inserted into a frame  100 , which houses the multichip carrier  11  and the coolant distribution unit  21 , in a direction which is parallel to the plane of circuit board  12 . After coolant distribution unit  21  is in place, air is allowed back into the internal chambers of coolant distribution unit  21 , thus allowing springs  34  to force the cooling surfaces of cooling elements  41  into contact with the chips  14   a  and  14   b  to be cooled.  
         [0028]    It will be understood that if coolant distribution unit  21  is to be assembled to carrier  11  in this manner, a cut out portion of bottom plate  24  must be provided, as for example, along one of its four sides that form a rectangle, so that coolant distribution unit  21  can slide over the chips on carrier  11  without striking bottom plate  24 . It will also be understood that prior to assembly, a suitable heat conductive compound is applied to the cooling surfaces of cooling elements  41  to assure imitate thermal contact, and thus the lowest possible thermal resistance, as is well known in the art. For example, a heat conductive oil may be used.  
         [0029]    As an alternative to working with air, the internal chambers of coolant distribution unit  21  may be filled with a liquid, such as, for example the liquid to be used for cooling, to perform the above assembly procedure. A device such as a power activated syringe (not shown) may be used to withdraw a predetermined volume of fluid, to recess the cooling elements by a known amount during the assembly procedure.  
         [0030]    The coolant distribution unit  21  including the inner plates  31  and  32  can be made of materials compatible with the coolant such as metals or plastics.  
         [0031]    The detailed structure of the compliant cooling elements  41  is shown in FIG. 2, in which only major components are depicted. The compliant cooling element  41  has a main body  42  with a coolant passage  46  at the center and a coolant passage  47  at the outer edge. The main body  42  can be cylindrical, rectangular, or other suitable shape. Elements  41  may be configured with fin-like structures  43  protruding out at the bottom of the main body  42 . A cooling head member  44  has multiple grooves  45  matching to the fin-like structures  43 . When the cooling head member  44  is brought together with the main body  42 , the fin-like structures  43  and the grooves  45  will interdigitate to form a narrow coolant path  48  as shown in FIG. 1. The main body  42  and the cooling head member  44  are made of thermally conductive materials such as copper, and mounted together by wielding, soldering, or brazing. Alternatively, the main body  42  is made of a polymer and the cooling head member  44  may be made of copper, with the two being bonded together with a suitable adhesive.  
         [0032]    In practice, the apparatus in accordance with the invention is assembled in the following manner, with reference again to FIG. 1. First cooling elements  41  are assembled to plate  32 , and seal rings  35  are put in place. This assembly is placed in bottom plate  24 .  
         [0033]    Frame member  23  is placed over bottom plate  24 , capturing plate  32 . Then plate  31  and seal rings  33  are installed. Springs  34  are placed over cooling elements  41 . Finally, main top cover  22  is placed over the assembly. The entire assembly is bolted or otherwise secured in place by fasteners or adhesive (not shown) to form coolant distribution unit  21 .  
         [0034]    In a cooling apparatus in accordance with the invention, with a water coolant flowing at 2 cc/second, at a pressure drop of 2 psi (13.8 Kpa), thermal resistance is approximately 0.27 degrees centigrade per watt per chip, for chips of 20 mm×20 mm, with an oil interface to the chips.  
         [0035]    At an initial ambient temperature of 20 degrees centigrade, the following changes in temperature are observed as a function of power dissipated in the chips.  
                                                             Chance in       Power (watts)   Temperature (C.)   Temperature (C.)                                20   25.4   5.4       30   28.1   8.1       40   30.8   10.8       50   33.5   13.5       60   36.2   16.2       100   47.0   27.0                          
 
         [0036]    [0036]FIG. 3 shows another embodiment of the invention, wherein only one of a plurality of cooling elements is shown. The coolant distribution unit  120  comprises a cover  123 , an inner plate  131  to separate the cool and warm coolant flows, and a bottom plate  121 . The compliant cooling element comprises one inner tube  142 , one outer tube  146 , one inner cooling head  143 , and one outer cooling head  144 . Unheated coolant  128  comes into the inner cooling head  144  through the inner tube  142  and goes out through the passage  147  between the inner tube  142  and outer tube  146 . The warm coolant from multiple compliant cool elements is collected by the warm coolant channel  127 . The narrow channel  145  between the inner and outer cooling heads  143  and  144  can be designed to provide the required cooling capacity for a given coolant flow. The compressive force needed to force the outer cooling heads into good thermal contact with the chips is provided by the resilient nature of the flexible inner and outer tubes,  142  and  146  respectively. An O-ring  148 , partially disposed in suitable grooves in outer cooling head  144  and the wall of an enlarged portion of the opening in bottom plate  121 , is used to provide an additional barrier to prevent coolant leakage. The cavities  151  can be used to receive coolant absorbent materials  152  to mitigate any coolant leakage.  
         [0037]    The technique described above, wherein fluid is temporarily withdrawn from the cooling apparatus during assembly to a device carrier, may also be used with this embodiment of the invention.  
         [0038]    It is noted that the foregoing has outlined some of the more pertinent objects and embodiments of the present invention. The concepts of this invention may be used for many applications. Thus, although the description is made for particular arrangements and methods, the intent and concept of the invention is suitable and applicable to other arrangements and applications. It will be clear to those skilled in the art that other modifications to the disclosed embodiments can be effected without departing from the spirit and scope of the invention. The described embodiments ought to be construed to be merely illustrative of some of the more prominent features and applications of the invention. Other beneficial results can be realized by applying the disclosed invention in a different manner or modifying the invention in ways known to those familiar with the art. Thus, it should be understood that the embodiments has been provided as an example and not as a limitation. The scope of the invention is defined by the appended claims.