As shown in
The major portion of body-shell of the cooling vessel can be made of non-metal material to save cost. The heat transfer in this boiling cooler is basically taking place within the cooler vessel by TCMC enhanced liquid boiling and additional vapor heat-spreading throughout the open space 160 of the cooling vessel. Therefore, it is not critical for the boiling cooler to have highly conductive metal body-shell as in many conventional coolers including heat sinks for various heating electronics element/device. Highly thermally conductive material, usually metal such as copper or aluminum, must be used for the body-shells of those conventional coolers because conducting heat through the shell to the surface, then cooling by using forced air convection, is their prominent way of cooling. In one embodiment, the major portion of body-shells of the vessel chambers including extruded fins and extended plate can be made of non-metal material comprising plastic, vinyl, or paper, which is much less expensive than any metal. Not only the material cost is lower, capability of plastic molding for those extruded fin structure also reduces the manufacturing cost comparing to processing metal. In addition, the non-metal body-shells can also be electrically insulating which provides an important advantage over the conventional cooler with electrically conducting metal shells for certain electronics cooling applications.
In yet another embodiment of this cooler in combination with nucleate boiling, the chamber shells including fins can be constructed by utilizing molded and baked copper powder, which provides better thermal conductivity than those modules using all-plastic materials but still costs less than those using all-machined metals. Similarly, thermally conductive plastic composite material can be used for constructing the boiling cooler according to current invention. For cooling some devices/systems with relatively large thermal load, in addition to the nucleate boiling heat transfer within the cooling vessel, conductive body-shell is necessary for more efficient heat exchange with cooler's environment.
In one embodiment, the TCMC can be a microporous coat or a boiling surface enhancement. In one implementation, a coating technique combines the advantages of a mixture batch type and thermally-conductive microporous structures. The microporous surface is created using particles of various sizes comprising any metal which can be bonded by the soldering process including nickel, copper, aluminum, silver, iron, brass, and various alloys in conjunction with a thermally conductive binder. The coating is applied on the surface of a substrate while mixed with a solvent. The solvent is vaporized after the application prior to heating the surface sufficiently to melt the binder to bind the particles. The mixture batch type application is an inexpensive and easy process, not requiring extremely high operating temperatures. The coating surface created by this process is insensitive to its thickness due to high thermal conductivity of the binder. Therefore, large size cavities can be constructed in the microporous structures for some poorly wetting but potentially low cost fluids, such as water, without causing serious degradation of boiling enhancement. This makes the boiling cooler keep its high cooling efficiency for various types of liquid coolants simply by adjusting the size of metal particles to allow the size range of porous cavities formed fit well with the surface tension of the selected liquid to optimize boiling heat transfer performance.
In one embodiment, the cooler of
The system enables cooling of mobile devices such as laptops and other mobile applications where the orientation of the system that uses our thermal solution is not fixed. The system can also be used in embodiment that serves graphics cards mounted with the component side face downward in a desktop computer. The system can also be used in situations where the system is completely ‘upside down’ so that none of the liquid will otherwise touch any part of the base plate of the chamber.
The extruded (extended) surface may be a block or fins or pin fins. As shown in
As shown in
The first phase of the coolant 150 can be a liquid phase and the second phase can be a vapor phase. The coolant 150 can be water or any suitable coolant. Additionally, boiling heat transfer can be done with direct component immersion in a dielectric liquid as a means of providing heat transfer coefficients large enough to meet forecasted dissipation levels, while maintaining reduced component temperatures. Dielectric liquids (3M Fluorinert family) can be used because they are chemically inert and electrically non-conducting. Their use with boiling heat transfer introduces significant design challenges which include reducing the wall superheat at boiling incipience, enhancing nucleate boiling heat transfer rates, and increasing the maximum nucleate boiling heat flux (CHF). Water can also be used for low cost.
The boiling enhancement coating provides a surface enhancement which creates increased boiling nucleation sites, decreases the incipient superheats, increases the nucleate boiling heat transfer coefficient and increases the critical heat flux. This surface enhancement is particularly advantageous when applied to microelectronic components such as silicon chips that cannot tolerate the high temperature environment required to bond existing heat sinks onto the chip, or mechanical treatments such as sandblasting, and is also particularly advantageous when applied to phase change heat exchanger systems that require chemically stable, strongly bonded surface microstructures. The boiling enhancement coating can be a composition of matter such as a glue, a solvent and cavity-generating particles. This composition is applied to a surface and then cured by low heat or other means, including but not limited to air drying for example, which evaporates the solvent and causes the glue with embedded particles to be bonded to the surface. The embedded particles provide an increased number of boiling nucleation sites. As used herein, “paint” means a solution or suspension which is in liquid or semiliquid form and which may be applied to a surface and when applied, can be cured to adhere to the surface and to form a thin layer or coat on that surface. The paint may be applied by any means such as spread with a brush, dripped from a brush or any other instrument or sprayed, for example. Alternatively, the surface may be dipped into the paint. By curing, is meant that the solvent will be evaporated, by exposure to the rays of a lamp, for example and the remaining composition which includes the suspended particles will adhere to the surface. As used herein, “glue” means any compound which will dissolve in an easily evaporated solvent and will bond to the particles and to the target surface. Some types of glue will be more compatible with certain applications and all such types of such glue will fall within the scope of the present claimed invention. The glue to be used in the practice of the claimed invention would be any glue which exhibits the above mentioned characteristics and which is preferably a synthetic or naturally occurring polymer. Examples of types of glue that could be used in the present invention include ultraviolet activated glue or an epoxy glue, for example. Epoxy glues are well known glues which comprise reactive epoxide compounds which polymerize upon activation. Ultraviolet glues are substances which polymerize upon exposure to ultraviolet rays. Preferably such glues would include 3M 1838-L A/13 and most preferably the thermally conductive epoxies Omegabond 101 or Omegatherm 201 (Omega Engineering, Stamford, Conn.) and the like or any glue which would adhere to the surface and to the particles. Another preferred glue is a brushable ceramic glue. Brushable ceramic glue is a low viscosity, brushable epoxy compound. Preferred brushable ceramic glues have a viscosity of about 28,000 cps and a maximum operating temperature of about 350.degree. F., and most preferred is Devcon Brushable Ceramic Glue. Thermally conductive epoxies are those with thermal conductivities in the range of about 7 to about 15 BTU/(ft.sup.2) (sec) (.degree.F./in). The particles of the present invention may be any particles which would generate cavities on the surface in the manner disclosed herein. As used herein, “cavity-generating particles” means particles which when applied to a surface, or when fixed in a thin film on a surface, form depressions in the surface of from about 0.5 .um to about 10 um in width, which depressions are suitable for promoting boiling nucleation. Preferred particles disclosed herein include crystals, flakes and randomly shaped particles, but could also include spheres or any other shaped particle which would provide the equivalent cavities. The particles are also not limited by composition. Such particles could comprise a compound such as an organic or inorganic compound, a metal, an alloy, a ceramic or combinations of any of these. One consideration is that for certain applications, the particles should be electrically non-conducting. Some preferred particles might comprise silver, iron, copper, diamond, aluminum, ceramic, or an alloy such as brass and particularly preferred particles are silver flakes or, for microelectronic applications, diamond particles, copper particles or aluminum.
In one embodiment, a boiling enhancement composition can include solvent, glue and cavity-generating particles in a ratio of about 10 ml solvent to about 0.1 ml of glue to from about 0.2 grams to about 1.5 grams of cavity-generating particles. Alternatively, the preferred composition is in a ratio of about 10 ml solvent to 0.1 ml of glue to about 1.5 grams of cavity-generating particles. It is understood that compositions of different ratios will be applicable to different utilities and that the ratios disclosed herein are not limiting in any way to the scope of the claimed invention. For example, an embodiment of the present invention is a composition of matter comprising solvent, glue and cavity-generating particles wherein the composition is 85-98% (v/v) solvent, 0.5-2% (v/v) glue and 1.5-15% (w/v) cavity-generating particles. By % (v/v) is meant liquid volume of component divided by total volume of suspension. By % (w/v) is meant grams of component divided by 100 ml of suspension.
The boiling enhancement composition may be added to the surface in any manner appropriate to the particular application. For example, the composition may be painted or dripped onto the surface, or even sprayed onto the surface. Alternatively, the surface or object may be dipped into the composition of the present invention. Following any of these applications, the enhancing composition would then be cured. It is contemplated that the composition of the present invention may also be incorporated into the surface as it is being manufactured and the boiling heat transfer enhancement would be an integral part of the surface. More details on the boiling enhancement coating is described in U.S. Pat. No. 5,814,392, the content of which is incorporated by reference.
Non-Dielectric liquid coolant such as water is preferred due to low cost and low environmental issues. Dielectric liquid coolants can also be used. Aromatics coolant such as synthetic hydrocarbons of aromatic chemistry (i.e., diethyl benzene [DEB], dibenzyl toluene, diaryl alkyl, partially hydrogenated terphenyl) can be used. Silicate-ester such as Coolanol 25R can be used. Aliphatic hydrocarbons of paraffinic and iso-paraffinic type (including mineral oils) can be used as well. Another class of coolant chemistry is dimethyl- and methyl phenyl-poly (siloxane) or commonly known as silicone oil—since this is a synthetic polymeric compound, the molecular weight as well as the thermo-physical properties (freezing point and viscosity) can be adjusted by varying the chain length. Silicone fluids are used at temperatures as low as −100° C. and as high as 400° C. These fluids have excellent service life in closed systems in the absence of oxygen. Also, with essentially no odor, the non-toxic silicone fluids are known to be workplace friendly. However, low surface tension gives these fluids the tendency to leak around pipe-fittings, although the low surface tension improves the wetting property. Fluorinated compounds such as perfluorocarbons (i.e., FC-72, FC-77) hydrofluoroethers (HFE) and perfluorocarbon ethers (PFE) have certain unique properties and can be used in contact with the electronics.
Non-dielectric liquid coolants offer attractive thermal properties, as compared with the dielectric coolants. Non-dielectric coolants are normally water-based solutions. Therefore, they possess a very high specific heat and thermal conductivity. De-ionized water is a good example of a widely used electronics coolant. Other popular non-dielectric coolant chemistries include Ethylene Glycol (EG), Propylene Glycol (PG), Methanol/Water, Ethanol/Water, Calcium Chloride Solution, and Potassium Formate/Acetate Solution, among others.
The cooler can operate fanless or with a fan to provide extra heat removing capability, as illustrated in more details next.
A plurality of manually operable keys 18 are provided on top of the housing 12, and collectively define a computer keyboard. In the disclosed embodiment, the keyboard conforms to an industry-standard configuration, but it could alternatively have some other configuration. The top wall of the housing 12 has, in a central portion thereof, a cluster of openings 21 which each extend through the top wall. The openings 21 collectively serve as an intake port. The housing 12 also has, at an end of the right sidewall which is nearest the lid 13, a cluster of openings 22 that collectively serve as a discharge port. Further, the left sidewall of the housing 12 has, near the end remote from the lid 13, a cluster of openings 23 that collectively serve as a further discharge port.
A circuit board 31 is provided within the housing 12. The circuit board 31 has a large number of components thereon, but for clarity these components are not all depicted in
A cooling assembly 41 is mounted on top of the integrated circuit 36, in thermal communication therewith. The cooling assembly 41 may be mounted on the integrated circuit 36 using a thermally conductive epoxy, or in any other suitable manner that facilitates a flow of heat between the integrated circuit 36 and the cooling assembly 41.
The cooling assembly 41 draws air into the housing 12 through the intake port defined by the openings 21, as indicated diagrammatically at 43. This air flow passes through the cooling assembly 41, and heat from the cooling assembly 41 is transferred to this air flow. Respective portions of this air flow exit from the cooling assembly 41 in a variety of different horizontal directions, and then travel to and through the discharge port defined by the openings 22 or the discharge port defined by the openings 23. The air flow travels from the cooling assembly 41 to the discharge ports along a number of different flow paths. Some examples of these various flow paths are indicated diagrammatically in
The pattern of air flow from the cooling assembly 41 to the discharge ports depends on the number of discharge ports, and on where the discharge ports are located. Further, when there are two or more discharge ports, the relative sizes of the discharge ports will affect the pattern of air flow, where the size of each port is the collective size of all of the openings defining that port. For example, if the collective size of the openings in one of the discharge ports exceeds the collective size of the openings in the other discharge port, more air will flow to and through the former than the latter. With this in mind, hot spots can be identified in the circuitry provided on the circuit board 31, and then the location and effective size of each discharge port can be selected so as to obtain an air flow pattern in which the amount of air flowing past each identified hot spot is more than would otherwise be the case.
The integrated circuit 38 has a heat sink 61 mounted on the top surface thereof, in a manner so that the heat sink 61 and the integrated circuit 38 are in thermal communication. In the embodiment of
The above arrangement is used for laptop cooling. A similar arrangement can be used for cooling graphics cards that mount active ICs up-side down and such application is contemplated by the inventor as well.
While the present invention has been described with reference to particular figures and embodiments, it should be understood that the description is for illustration only and should not be taken as limiting the scope of the invention. Many changes and modifications may be made to the invention, by one having ordinary skill in the art, without departing from the spirit and scope of the invention. For example, additional heat dissipation layers may be added to enhance heat dissipation of the integrated circuit device. Additionally, various packaging types and IC mounting configurations may be used, for example, ball grid array, pin grid array, etc. Furthermore, although the invention has been described in a particular orientations, words like “above,” “below,” “overlying,” “beneath,” “up,” “down,” “height,” etc. should not be construed to require any absolute orientation.
The foregoing described embodiments are provided as illustrations and descriptions. They are not intended to limit the invention to the precise form described. In particular, it is contemplated that functional implementation of invention described herein may be implemented equivalently in hardware, software, firmware, and/or other available functional components or building blocks. Other variations and embodiments are possible in light of above teachings, and it is thus intended that the scope of invention not be limited by the description, but rather by the following claims