Abstract:
A lighting module has an array of light emitters, a heat sink having a first surface, the array of light emitters being mounted to the first surface, a microchannel cooler arranged on a second surface of the heat sink on an opposite side of the heat sink from the first surface, the microchannel cooler arranged to transport a liquid through a channel on the second surface of the heat sink, and a cooling unit thermally coupled to a microchannel cooler and arranged to remove heat from the liquid.

Description:
CROSS REFERENCE TO RELATED APPLICATIONS 
     The present application is a continuation of U.S. patent application Ser. No. 13/153,322, filed Jun. 3, 2011 and entitled MICROCHANNEL COOLER FOR LIGHT EMITTING DIODE LIGHT FIXTURES, which claims priority to U.S. Provisional Patent Application No. 61/351,215, filed Jun. 3, 2010 and entitled MICROCHANNEL COOLER FOR LIGHT EMITTING DIODE LIGHT FIXTURES, the entire contents of both of which are incorporated herein by reference for all purposes. 
    
    
     BACKGROUND AND SUMMARY 
     Solid-state light emitting devices, such as light-emitting diodes (LEDs), have become more common in curing applications such as those using ultra-violet light. Solid-state light emitters have several advantages over traditional mercury arc lamps including that they use less power, are generally safer, and are cooler when they operate. 
     However, even though they generally operate at cooler temperatures than arc lamps, they do generate heat. Since the light emitters generally use semiconductor technologies, extra heat causes leakage current and other issues that result in degraded output. Management of heat in these devices allows for better performance. As the demand rises for higher irradiance output from these devices heat management becomes more important. 
     One traditional cooling technique uses a heat sink, which generally consists of thermally conductive materials mounted to the substrates upon which the light emitters reside. Some sort of cooling or thermal transfer system generally interacts with the back side of the heat sink, such as heat dissipating fins, fans, liquid cooling, etc., to draw the heat away from the light emitter substrates. The efficiency of these devices remains lower than desired, and liquid cooling systems can complicate packaging and size restraints. However, transferring the heat from the LED to the liquid allows the liquid to transport the heat away from the LED resulting in efficient cooling. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  shows an embodiment of a large area array of light emitters with a microchannel cooler. 
         FIG. 2  shows a back view of a microchannel cooler. 
         FIG. 3  shows an embodiment of an air-cooled microchannel cooler. 
         FIG. 4  shows an example of a series, liquid cooler. 
     
    
    
     DETAILED DESCRIPTION 
       FIG. 1  shows an embodiment of a lighting module  10  mounted to a heat sink in which resides a microchannel cooler. The term ‘microchannel’ refers to a channel that has a width in a micrometer scale. In one embodiment, the channels are in the range of 100 micrometers to 50 micrometers wide. 
     In this particular embodiment, the lighting module  10  consists of 5 individual LED arrays such as  12  and  14 . These 5 LED arrays may each be a Silicon Light Matrix™ (SLM™) manufactured by Phoseon Technology, Inc., but are not limited to that specific type of LED array. The LED arrays may consist of many different configurations from a line of single LEDs, to multiple LEDs on a substrate, possibly multiple substrates arranged together. 
     In this embodiment, each LED array has it own microchannel cooler with the fluid flow in parallel with the other microchannel coolers. For example, the microchannel cooler manifold  22  behind the LED array  12  will have an input port and an output port for fluid to flow through microchannels on the back side of the heat sink  16 . This liquid may travel from the region adjacent the LED to a chiller that cools the liquid and returns independent of the other microchannel coolers such as  24 , which resides adjacent the LED array  14 . 
     One advantage of this approach lies in its modularity. The LED array, such as the SLM™ discussed above, residing on its own heat sink with its own integrated microchannel cooler becomes a module. If some component of that module fails, such as the LED array or the microchannel cooler, the module can be replaced without affecting the other modules in the overall light module. 
     The heat sink  16  has channels in the back side, as oriented in the drawing. The heat sink  16  typically consists of a material having a high thermal conductivity, such as copper. The channels are formed such that there is a thinner layer of copper between the LED array and the liquid in the channel. This allows for more efficient heat transfer between the LED substrate and the liquid. 
     Generally, the microchannel units consist of a stack of very thin copper plates. Each plate is etched, laser machined or otherwise patterned with an array of features such that when the plates are stacked, the features align to form the microchannels. The stacking of the plates generally consists of heat-treating, diffusion bonding or otherwise bonding the plates together to form a single piece of copper. The plate in the stack that ends up next to the LED array is the thin layer of copper mentioned above. 
       FIG. 2  shows the liquid ports in the back side of the heat sink  16 . One port  30  allows the liquid to be brought into the microchannel cooler/heat sink and the other port  32  takes the liquid out of the heat sink and allows it to be routed to the cooler. The selection of which port is for which is left up to the system designer, as is the positioning of the ports. They could be parallel horizontally, vertically, offset, etc. 
     In addition, the channels may have one or more curves or bends to route the liquid across a greater surface area of the heat sink, thereby increasing the amount of heat that transfers to the liquid in the microchannel. Another adaptation may include structures to increase the turbulence in the liquid as it flows in the channel. The increased turbulence ‘mixes’ the liquid to allow it to absorb more heat. These structures may include a roughened surface of the microchannel in the heat sink, or using multiple bends and curves in the channel structure. 
     As mentioned above, the liquid in the microchannel is cooled when it is routed by a chiller of some sort.  FIG. 3  shows an embodiment of an air microchannel cooler,  40 . The LED arrays would mount to the front of the individual microchannel coolers  42 , of which there are  9  in this example. Each of these would have ports on the back such as those shown in  FIG. 2 . The liquid from each microchannel cooler would be routed to the radiators  44 . 
     In this embodiment, there are two radiators  44 , each of which has two fans  46 . However, one skilled in the art will recognize that the number of radiators and fans are design choices left up to the system designer and may depend upon the space available, the size requirements, the power consumption of the fans, etc. 
     The liquid from the microchannel coolers passes through the radiators  44  and the fans  46  take the heat away from the liquid. This allows the liquid to cool, and it then passes by the LED arrays to provide cooling. The liquid from each microchannel cooler travels in parallel with the liquid from the other microchannel coolers in the unit  40 . This allows for more efficient cooling. 
     In experiments, the microchannel cooler performance was compared to a current implementation of a liquid cooler. For contrast purposes,  FIG. 4  shows an example of a cooler used in the experiments. The cooler  50  is a liquid cooler having an input port  54  and an output port  56 . Each LED array mounts to the front of the heat sinks such as  52  and  58 . 
     During operation, the liquid enters through the input port  54  and passes behind the heat sinks of the individual LED arrays in series. This means that the heat sink  58  has the liquid passing behind it holding the heat from the LED array at heat sink  52  and the LED arrays between heat sinks  52  and  58 . The liquid must either be cooled much more than would be necessary in a parallel cooling arrangement as in  FIG. 3 , or the heat absorbed by the liquid at heat sink  58  will be far less than desired. 
     In the experiments, the same LED array was mounted to a current implementation of a heat sink and cooler, and a heat sink and a microchannel cooler. The flow rate of the liquid was varied from 0.5 to 1.5 liters per minute. The LED array was powered to generate 8 Watts/centimeter squared light output. The junction temperature for the LED was 64° C. for the current cooler and 35° C. for the microchannel cooler. 
     In addition, the maximum irradiance increased by 40%. Because LEDs are semiconductor devices, they are sensitive to temperature changes. Higher temperatures cause leakage current, reducing the overall efficiency of the device. Using the microchannel cooler, the efficiency of the LED array increased by 1%, and the maximum output irradiance increased by 40%. 
     In this manner, a lighting module can employ a heat sink having microchannel coolers to dissipate heat away from the array of light emitters. This allows the light emitters to operate more efficiently at cooler temperatures, using less power with more consistent performance and with a longer lifetime. 
     Although there has been described to this point a particular embodiment for a solid-state light emitter light module using a microchannel cooler, it is not intended that such specific references be considered as limitations upon the scope of these embodiments.