Abstract:
A liquid cooling module has a sealed unit and a heat dissipating module connected by multiple flexible pipes. The sealed unit has a contacting surface attached to an electronic element. The heat dissipating module has a radiator, coolant tanks and a pump all mounted compactly together. The radiator has multiple fins and tubes to allow the coolant to flow through and dissipate heat and may have a fan to increase airflow. The coolant tank is formed on the radiator. The pump circulates the coolant along the coolant pipes. Accordingly, the liquid cooling module has a compact structure and the coolant pipes are flexible, so the liquid cooling module can be mounted simply in a computer case, and is installed easily by home users and professionals alike.

Description:
BACKGROUND OF THE INVENTION 
       [0001]    1. Field of the Invention 
         [0002]    The present invention relates to a cooling system, and more particularly to a liquid cooling module that can cool a processor of a computer efficiently, is compact and easily fitted to a computer case. 
         [0003]    2. Description of Related Art 
         [0004]    As computer hardware is developing rapidly to provide faster performance, processor overheating is becoming a significant problem. 
         [0005]    The most common solution for cooling a computer processor is to use a heat dissipater utilizing air, such as a fan, a heat sink assembly or a combination therein to take away heat generated by the computer processor. However, as computer hardware becomes faster and smaller, more heat is generated by the processor. Therefore, conventional heat dissipaters using air are being replaced by heat dissipaters using a coolant and may comprise a sealed unit, a coolant, multiple rigid pipes, a pump, a radiator and a tank. The sealed unit is mounted adjacent to the processor and is sealed against coolant leakage. The coolant is a non-flammable coolant. The pipes are rigid, full of the coolant and connect the compressor to the sealed unit that the coolant passes over to remove heat. Then the coolant passes through the pipes to the coolant tank and onto the radiator where excess heat is removed from the coolant. The coolant in the radiator then flows to the compressor to complete another cooling cycle. 
         [0006]    However, the radiator, coolant tank and compressor are separately mounted in a computer case and connected to each other using the rigid pipes. In such an arrangement, the structure may be complicated to install and occupies much space. Installation is further complicated since the rigid pipes must be tailored to correct lengths during installation, especially since any coolant leaks may damage the computer or surrounding area. The complicated installation is therefore, performed by professionals and prevents many home users from upgrading to this technology. 
         [0007]    To overcome the shortcomings, the present invention provides a liquid cooling module to obviate or mitigate the aforementioned problems. 
       SUMMARY OF THE INVENTION 
       [0008]    The main objective of the present invention is to provide a liquid cooling module having excellent cooling capability and is compact and easily adjustable to fit a variety of computer cases. 
         [0009]    To achieve the objective, the liquid cooling module in accordance with the present invention comprises a sealed unit, a heat dissipating module, and multiple flexible pipes connected between the sealed unit and the heat dissipating module to allow coolant to flow inside. 
         [0010]    The sealed unit has a contacting surface attached to an electronic component of a computer to absorb heat. 
         [0011]    The heat dissipating module has a radiator, coolant tanks and a pump all mounted compactly together. The radiator has multiple fins and tubes to allow the coolant to flow through and dissipate heat and may comprise a fan to increase airflow. The coolant tank is formed on the radiator. The pump circulates the coolant along the coolant pipes. Accordingly, the liquid cooling module has a compact structure, because the coolant pipes are flexible, the liquid cooling module is mounted simply in a computer case, and is installed easily by home users or professionals alike. 
         [0012]    Other objectives, advantages and novel features of the invention will become more apparent from the following detailed description when taken in conjunction with the accompanying drawings. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0013]      FIG. 1  is a perspective view of a liquid cooling module in accordance with the present invention; 
           [0014]      FIG. 2  is an exploded perspective view of the liquid cooling module in  FIG. 1 ; 
           [0015]      FIG. 3  is a cross sectional rear view of the liquid cooling module in  FIG. 1 ; and 
           [0016]      FIG. 4  is a cross sectional top view of the liquid cooling module in  FIG. 1 ; and 
           [0017]      FIG. 5  is a perspective view of the liquid cooling module in  FIG. 1 , shown mounted in a computer casing. 
       
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
       [0018]    With reference to  FIG. 5 , an electronic element ( 61 ) may be a processor mounted in a computer casing ( 60 ) and has an upper surface. 
         [0019]    With further reference to  FIGS. 1 to 4 , a liquid cooling module in accordance with present invention comprises a sealed unit ( 30 ), a heat dissipating module, an outlet pipe ( 50 ) and an inlet pipe ( 51 ). 
         [0020]    The sealed unit ( 30 ) has multiple fasteners ( 31 ), a chamber, a contacting surface ( 330 ), a lid, an outlet seat ( 32 ), an inlet seat ( 35 ), a mounting board ( 33 ) and multiple inner fins ( 34 ). 
         [0021]    The fasteners ( 31 ) are mounted through the sealed unit ( 30 ) to hold the sealed unit ( 30 ) in contact with the electronic element ( 61 ) and each may be implemented with a spring. The chamber is formed inside the sealed unit ( 30 ). The outlet seat ( 32 ) and the inlet seat ( 35 ) are formed separately through the lid of the sealed unit ( 30 ) and communicate with the chamber. The mounting board ( 33 ) is mounted sealably on the lid, and may be metal. The contacting surface ( 330 ) is formed on the sealed unit ( 30 ), may be on the mounting board and is in contact with the upper surface of the electronic element ( 61 ) to absorb heat. The inner fins ( 34 ) are formed on the mounting board ( 33 ) in the chamber of the sealed unit ( 30 ) 
         [0022]    The heat dissipating module is connected to the sealed unit ( 30 ) and comprises a radiator ( 10 ), a fan ( 20 ), an upper tank ( 13 ), a lower tank ( 40 ) and a pump ( 46 ). 
         [0023]    The radiator ( 10 ) is mounted on the lower tank ( 40 ) and has a front, a rear, a top, a bottom, a bottom cover ( 45 ), multiple tubes ( 12 ) and multiple fins ( 11 ). The bottom cover ( 45 ) is mounted sealably on the bottom of the radiator. The tubes ( 12 ) may be metal, are formed parallelly to each other from the top to the bottom of the radiator, may be between the upper and lower tanks ( 13 ,  40 ) and through the bottom cover and each tube ( 12 ) has a flow channel ( 120 ) and two sides. Each flow channel ( 120 ) is formed longitudinally through each tube ( 12 ) to allow coolant to flow inside. The fins ( 11 ) are mounted perpendicularly to and adjacent to both sides of each tube ( 12 ) and increase heat dissipating efficiency of each tube ( 12 ). 
         [0024]    The fan ( 20 ) is securely mounted adjacent to the front of the radiator ( 10 ) to increase airflow through the fins ( 11 ) of the radiator ( 10 ) to increase heat dissipation. 
         [0025]    The upper tank ( 13 ) is mounted securely on the top of the radiator ( 10 ) and has a top and a barrier ( 14 ) and may further have a coolant input ( 18 ) and a cap ( 17 ). The barrier ( 14 ) is mounted securely in the upper tank ( 13 ), to separate the tubes ( 12 ) into two equal groups of warm tubes ( 12 ) and cold tubes ( 12 ) and defining a warm chamber ( 15 ) and a cold chamber ( 16 ) that communicate respectively with corresponding flow channels ( 120 ) of the warm and cold tubes ( 12 ). The coolant input ( 18 ) is formed through the top of the upper tank ( 13 ) for adding coolant and may be threaded. The cap ( 17 ) is securely mounted detachably on the coolant input ( 18 ) of the upper tank ( 13 ) and may be threaded and correspond to the threaded coolant input ( 18 ). 
         [0026]    The lower tank ( 40 ) is mounted securely on the bottom of the radiator ( 10 ) and sealably to the bottom cover ( 45 ) and has a side wall ( 41 ), an inlet ( 411 ), an outlet ( 410 ) and a partition ( 42 ). The inlet ( 411 ) and the outlet ( 410 ) are separately formed through the side wall ( 41 ). The partition ( 42 ) is mounted securely in the lower tank ( 40 ) to define a cool chamber ( 43 ) and a hot chamber ( 44 ). 
         [0027]    The cool chamber ( 43 ) communicates with half of the flow channels ( 120 ) of the warm and cold tubes ( 12 ) 
         [0028]    The hot chamber ( 44 ) communicates with half of the flow channels ( 120 ) of the warm tubes ( 12 ) and with the inlet ( 411 ). 
         [0029]    The pump ( 46 ) may be an impeller, a compressor or the like, is mounted on the radiator ( 10 ), is mounted in the cool chamber ( 43 ) of the lower tank ( 40 ) and has a pump case ( 47 ) and a pump assembly. The pump case ( 47 ) has a top surface, a pump chamber, a pump exhaust ( 470 ), a pump inlet ( 472 ) and a pump partition ( 471 ). 
         [0030]    The pump partition ( 471 ) is mounted sealably in the cool chamber ( 43 ), between the bottom cover ( 45 ) of the radiator ( 12 ) and the pump case ( 47 ). The pump chamber is defined between the pump case ( 47 ), pump partition ( 471 ) and bottom cover ( 45 ) of the radiator ( 12 ) and communicates with half of the cold tubes ( 12 ). The pump inlet ( 472 ) is formed through the top surface of the pump case ( 47 ) and communicates with the pump chamber. The pump exhaust ( 470 ) is formed on and protrudes from the pump case ( 47 ), communicates with the pump chamber via the pump inlet ( 472 ) and is mounted sealably in the outlet ( 410 ) of the lower tank ( 40 ) 
         [0031]    The pump assembly is mounted sealably on the pump case ( 47 ) and has an impeller ( 48 ) and a driver ( 49 ). The impeller ( 48 ) is mounted rotatably in the pump case ( 47 ) and has multiple spiral vans ( 480 ). The driver ( 49 ) drives the impeller ( 48 ) to rotate and thereby pumps the coolant from the pump chamber through the pump exhaust ( 470 ) to the outlet ( 410 ) of the lower tank ( 40 ). 
         [0032]    The outlet pipe ( 50 ) is flexible and is connected between the sealed unit ( 30 ) and the heat dissipating module, may has two ends be respectively connected to the outlet seat ( 32 ) of the sealed unit ( 30 ) and pass through the outlet ( 410 ) of the lower tank ( 40 ) to connect to the pump exhaust ( 470 ). 
         [0033]    The inlet pipe ( 51 ) is flexible and is connected between the sealed unit ( 30 ) and the heat dissipating module, may be between the inlet seat ( 35 ) of the sealed unit ( 30 ), and the inlet ( 411 ) of the lower tank ( 40 ). 
         [0034]    With reference to  FIGS. 3 and 4 , coolant such as water, distilled water, a dielectric solvent or the like well known in the art is added, may be through the coolant input ( 18 ) to fill the tubes and pipes. The pump ( 46 ) forces the coolant out of the pump exhaust ( 470 ) of the pump ( 46 ), passes through the outlet pipe ( 50 ) and enters the sealed unit ( 30 ). The coolant passes through the chamber of the sealed unit ( 30 ) and absorbs heat from the mounting board ( 33 ), then passes through the inlet pipe ( 51 ) and enters the hot chamber ( 44 ) of the lower tank ( 40 ). 
         [0035]    With further reference to  FIG. 3 , the coolant inside the hot chamber ( 44 ) of the lower tank ( 40 ) flows up the flow channels ( 120 ) of one half of the warm tubes ( 12 ) and is cooled by air flow enhanced by the fan ( 20 ) and enters the warm chamber ( 15 ), before flowing down the other half of the warm tubes ( 12 ) and is further cooled until reaching the cool chamber ( 43 ). Then the coolant flows through one half of the warm tubes ( 12 ), is again cooled until entering the cold chamber ( 16 ). The coolant flows through the other half of the cold tubes ( 12 ), is further cooled and enters the pump chamber, where the coolant is forced out of the pump chamber. Therefore, the coolant is thoroughly cooled before being used to cool again, this greatly enhances efficiency of heat dissipating. 
         [0036]    With further reference to  FIG. 5 , because the pipes ( 50 ,  51 ) are flexible, the sealed unit ( 30 ) of the liquid cooling module can be easily and conveniently mounted onto the electronic element ( 61 ) of the casing ( 60 ). Since, the pump ( 47 ), radiator ( 12 ), fan ( 20 ) and coolant upper and lower tanks ( 13 ,  40 ) are all formed together this unit is both compact and easily installed. Therefore, the liquid cooling module in accordance with the present invention is compact and convenient to use. 
         [0037]    Even though numerous characteristics and advantages of the present invention have been set forth in the foregoing description together with details of the structure and function of the invention, the disclosure is illustrative only. Changes may be made in detail especially in matters of shape, size and arrangement of parts within the principles of the invention to the full extent indicated by the broad general meaning of the terms in which the appended claims are expressed.