WO2010110790A1 - Grid heat sink - Google Patents
Grid heat sink Download PDFInfo
- Publication number
- WO2010110790A1 WO2010110790A1 PCT/US2009/038255 US2009038255W WO2010110790A1 WO 2010110790 A1 WO2010110790 A1 WO 2010110790A1 US 2009038255 W US2009038255 W US 2009038255W WO 2010110790 A1 WO2010110790 A1 WO 2010110790A1
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- WO
- WIPO (PCT)
- Prior art keywords
- heat sink
- fins
- grid
- grid heat
- channels
- Prior art date
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Classifications
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01L—SEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
- H01L23/00—Details of semiconductor or other solid state devices
- H01L23/34—Arrangements for cooling, heating, ventilating or temperature compensation ; Temperature sensing arrangements
- H01L23/46—Arrangements for cooling, heating, ventilating or temperature compensation ; Temperature sensing arrangements involving the transfer of heat by flowing fluids
- H01L23/467—Arrangements for cooling, heating, ventilating or temperature compensation ; Temperature sensing arrangements involving the transfer of heat by flowing fluids by flowing gases, e.g. air
-
- H—ELECTRICITY
- H05—ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
- H05K—PRINTED CIRCUITS; CASINGS OR CONSTRUCTIONAL DETAILS OF ELECTRIC APPARATUS; MANUFACTURE OF ASSEMBLAGES OF ELECTRICAL COMPONENTS
- H05K7/00—Constructional details common to different types of electric apparatus
- H05K7/20—Modifications to facilitate cooling, ventilating, or heating
-
- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06F—ELECTRIC DIGITAL DATA PROCESSING
- G06F1/00—Details not covered by groups G06F3/00 - G06F13/00 and G06F21/00
- G06F1/16—Constructional details or arrangements
- G06F1/20—Cooling means
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01L—SEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
- H01L23/00—Details of semiconductor or other solid state devices
- H01L23/34—Arrangements for cooling, heating, ventilating or temperature compensation ; Temperature sensing arrangements
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01L—SEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
- H01L23/00—Details of semiconductor or other solid state devices
- H01L23/34—Arrangements for cooling, heating, ventilating or temperature compensation ; Temperature sensing arrangements
- H01L23/36—Selection of materials, or shaping, to facilitate cooling or heating, e.g. heatsinks
- H01L23/367—Cooling facilitated by shape of device
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F28—HEAT EXCHANGE IN GENERAL
- F28F—DETAILS OF HEAT-EXCHANGE AND HEAT-TRANSFER APPARATUS, OF GENERAL APPLICATION
- F28F3/00—Plate-like or laminated elements; Assemblies of plate-like or laminated elements
- F28F3/02—Elements or assemblies thereof with means for increasing heat-transfer area, e.g. with fins, with recesses, with corrugations
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01L—SEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
- H01L2924/00—Indexing scheme for arrangements or methods for connecting or disconnecting semiconductor or solid-state bodies as covered by H01L24/00
- H01L2924/0001—Technical content checked by a classifier
- H01L2924/0002—Not covered by any one of groups H01L24/00, H01L24/00 and H01L2224/00
Definitions
- the electron flow within the component generates heat. If this heat is not removed, the electronic component may overheat, causing malfunction or damage to the component.
- the heat generated by the electronic component can be dissipated in a number of ways, including using a heat sink which absorbs and dissipates the heat via direct air convection.
- Improvements in integrated circuit design and fabrication techniques are allowing IC manufacturers to produce smaller IC devices and other electronic components which operate at increasingly faster speeds and which perform an increasingly higher number of operations. As the operating speed of an electronic component increases, so too does the heat generated by these components. Further, computer components are being more densely packaged. These factors contribute to the desire for a heat sink which has more thermal and volumetric efficiency in removing heat from these electronic components.
- FIG. 1 is a perspective view of an illustrative heat sink, according to one embodiment of principles described herein.
- Fig. 2 is a perspective view of an illustrative heat sink, according to one embodiment of principles described herein.
- Figs. 3A and 3B are diagrams of an illustrative cooling system, according to one embodiment of principles described herein.
- Fig. 4 is a perspective view of an illustrative grid heat sink according to one embodiment of principles described herein.
- Fig. 5A is an illustrative diagram of a temperature profile within a finned heat sink, according to one embodiment of principles described herein.
- Fig. 5B is an illustrative diagram of a temperature profile within a grid heat sink, according to one embodiment of principles described herein.
- Fig. 6A is an illustrative graph of heat removal as a function of air flux, according to one embodiment of principles described herein.
- Fig. 6B is an illustrative graph of a difference between heat sink surface temperature and air exit temperature as a function of air flux, according to one embodiment of principles described herein.
- Fig. 7 is a front view of an illustrative grid heat sink, according to one embodiment of principles described herein.
- FIG. 8 is a front view of an illustrative grid heat sink, according to one embodiment of principles described herein.
- Fig. 9 is a front view of an illustrative grid heat sink, according to one embodiment of principles described herein.
- Fig. 10 is a cross-sectional view of an illustrative grid heat sink, according to one embodiment of principles described herein.
- FIG. 11 is a front view of an illustrative grid heat sink, according to one illustrative embodiment of principles described herein.
- Fig. 12 is a front view of an illustrative grid heat sink, according to one embodiment of principles described herein.
- Figs. 13A-D show illustrative steps in forming a grid heat sink from a continuous sheet of thermally conductive material, according to one embodiment of principles described herein.
- Fig. 14 is a cross-sectional view of an illustrative grid heat sink formed with a continuous sheet of thermally conductive material, according to one embodiment of principles described herein.
- Fig. 15 is a cross-sectional view of an illustrative grid heat sink formed with a continuous sheet of thermally conductive material, according to one embodiment of principles described herein.
- Fig. 16 is a diagram of an illustrative cooling system which incorporates a grid heat sink, according to one embodiment of principles described herein.
- Fig. 17 is a diagram of an illustrative cooling system which incorporates a grid heat sink, according to one embodiment of principles described herein.
- Fig. 18 is a diagram of an illustrative cooling system incorporated into a blade server, according to one embodiment of principles described herein.
- Fig. 19 is a diagram of an illustrative computer rack containing a number of blade servers, according to one embodiment of principles described herein.
- the electron flow within the component generates heat. If this heat is not removed the electronic component may overheat, causing malfunction or damage to the component.
- the heat generated by the electronic component can be dissipated in a number of ways, including using a heat sink which absorbs and dissipates the heat via direct air convection.
- Improvements in integrated circuit design and fabrication techniques are allowing IC manufacturers to produce smaller IC devices and other electronic components which operate at increasingly faster speeds and which perform an increasingly higher number of operations. As the operating speed of an electronic component increases, so too does the heat generated by these components. [0028] Additionally, computer components are being more densely packaged which can demand more thermal and volumetric efficiency in the heat removal systems. For example, the shrinking sizes and increased functionality of modern electronic devices can result in much more restricted volumes for heat removal systems. In some computing architectures, such as arrays of blade servers, these volume restricted computing devices may be placed in close proximity to each other.
- Fig. 1 is a perspective view of an illustrative heat sink (100) which is in thermal contact with underlying computer chip (115).
- the heat sink (100) includes a base (110) and a number of vertical fins (105). Air passes through the vertical fins (105) and removes heat from the heat sink (100). The air may be moved by natural convention or forced convection. Natural convention utilizes the buoyancy forces of hot air to lift the heated air away from the fins and draw cool air into the heat sink to replace it. In forced convection cooling systems, a fan or other device creates a pressure difference or moving air flow which is channeled through the fins. Natural conventions systems typically have much lower cooling capacities than forced convention cooling systems. [0031] Fig.
- the heat sink (100) includes a base (110) with a thickness "d".
- the heat sink (100) has a number of vertical fins (105) and an overall width "b” and length "L.”
- the air flow (200) passes through the fins (105) parallel to the plane of the base.
- Fig. 3A is an illustrative diagram of a forced air cooling system (300) which includes a fan (305).
- the heat from the chip (115) is transferred into the base (110) which distributes the heat into the vertical fins (105).
- the fan (305) may blow air stream directly into the vertical fins (105) in a process called impingement cooling.
- the fan (305) may create suction by removing air between the fins and blowing it out the top of the fan.
- a suction cooling system has inherent limitations in the amount of pressure differential which can be generated by the fan or blower.
- Fig. 3B is an illustrative diagram of impingement cooling by the fan (305). Cooling air (310) is forced from above the fan (305) into the heat sink (100). A number of inefficiencies can arise in this configuration. First, the distribution of the air over the heat sink surfaces is not uniform. For example, the fan blade velocities are highest at the perimeter of the fan. Consequently, higher pressures and air flow are generated at the perimeter of the fan. In the center of the fan, much lower air flow may occur. The air flow may recirculate beneath the fan. Consequently, the center of the heat sink may not be effectively cooled. [0034] Additionally, heated air may be recirculated.
- air from the heat sink may escape upwards, curve around the housing of the fan (305) and be sucked back into the fan (305).
- This recirculation may be avoided by having a taller duct which encloses the fan.
- a taller duct makes the already tall cooling assembly even taller.
- air which prematurely exits the heat sink is not utilized to its full capacity and reduces the overall cooling efficiency of the heat sink for a given air flow rate.
- Fig. 4 is a perspective view of one illustrative embodiment of a grid heat sink (400) which has significantly greater surface area than similarly sized finned heat sink (300).
- the grid heat sink (400) includes base (420) with a number of vertical fins (410). Horizontal fins (415) intersect the vertical fins (410) to form a grid with a number of channels (405).
- the channels may have a variety of geometries including, but not limited to, square, rectangle, hexagonal, or other geometries.
- the channels may extend through the heat sink and maintain a fairly constant cross-section.
- cross sections of the channels (405) may vary from channel to channel or vary along the length of an individual channel.
- Fig. 5A is a cross-sectional diagram of a finned heat sink (100) which shows the temperature profile (500) in a space between the fins.
- the temperature profile has three segments, a first segment labeled T m which represents the temperature through the conductive base (110).
- Surface temperature, T s represents the temperature of the surface of the heat sink at a given point.
- T(x) represents the air temperature profile through the open space between the fins (105).
- a heat flux, Q moves from the underlying chip into the base. This raises the temperature of the base (110). As shown in Fig. 5A, there is slight decline in temperature profile T m as the heat flux moves through the relatively high thermal conductivity base material. The air flow interacts with the surface of the heat sink (100) at the surface temperature (T s ). The temperature profile, T(x), through the air flow is illustrated as declining along the length of the profile. The measurement locations used to generate the temperature profile T(x) are made along the centerline of the (505) of the heat sink segment. The height of the temperature profile is higher or lower than the centerline (505) to show the relative temperature differences through the temperature profile. Ideally, the air temperature would be equal to the surface temperature T s .
- Fig. 5B is a diagram of an illustrative section of a grid heat sink (400).
- a temperature flux Q enters the base (420) and is conducted up the primary fins (410) and into the cross fins (415).
- a temperature profile forms. The temperatures are measured along the centerline (510). Through the thickness d of the base (420) there is slight decline in temperature.
- the additional surface area provided by the cross fins (415) creates channels (405) with a characteristic dimension a and additional surface area.
- the temperature profile T(x) shows less severe declines and generates higher thermal efficiencies in removing heat from the chip because there is a more uniform heating of the cooling air.
- the grid heat sink allows for a much larger amount of heat removal for the same size of heat sink and the same air flow rate, or the same heat removal for a smaller coolant flow. Consequently, for a given system a grid heat sink may be smaller, thereby reducing the overall volume of the system. Additionally or alternatively, the increased thermal performance may allow for lower operating temperatures of the heat generating component.
- the heat removal of various heat sinks as a function of air flux can be estimated using Eq. 1.
- Fig. 6A is an illustrative graph of the heat removed for a fin system and a grid system as estimated by Eq. 1.
- the vertical axis represents heat removed in units of Watts from the heat sink by the passage of cooling air.
- the horizontal axis is air flux through the heat sink in cubic meters per second.
- the dashed line represents the heat removed in a grid system and the dash- dot line represents the heat removed from a fin system.
- a grid system with comparable size and mass removes significantly more heat than a fin system. For example, at 0.0075 cubic meters of air per second, the fin system removed approximately 45 Watts of heat.
- the grid system removed approximately 85 Watts of heat.
- a measure of the thermal efficiency of the heat sink is the difference between the exit temperature of the air ( ⁇ ) and the surface temperature of the heat sink (T). Ideally, the exit air temperature ( ⁇ ) would be equal to the surface temperature of the heat sink (T). When the exit air temperature equals the surface temperature of the heat sink, the air has absorbed all of the heat possible. To accomplish this level of thermal efficiency is often impractical because the size of the heat sink becomes infinitely larger. However, when comparing two heat sinks of similar size, the thermal efficiency can provide a measure of the efficiency of the heat sink designs. [0043] The difference ( ⁇ T) between the exit air temperature ( ⁇ ) and the surface temperature of the heat sink (T) can be estimated using the Eq. 2, shown below.
- FIG. 6B shows an illustrative graph of the results of Eq. 2 for a grid system and a fin system of comparable size.
- the horizontal axis represents the air flow rate through the heat sinks in cubic meters per second.
- the temperature difference in degrees Celsius is shown along the vertical axis, with lower temperature differences at the bottom of the axis and higher temperature differences shown proportionally higher on the axis.
- the temperature difference between the exit air and the heat sink surface for the grid system is shown as a dotted line.
- the temperature difference for the fin system is shown as a dot-dashed line.
- the temperature differences become smaller for higher volume flow rates.
- There are a number of factors which could produce this result including increased turbulence in higher velocity flows.
- turbulent flows are more efficient in transporting heat away from a surface than more ordered flows. Consequently as turbulence increases, the efficiency of the heat sink can increase.
- the grid system has lower temperature differences than the fin system for all flow rates shown in Fig. 6B.
- the temperature difference for the fin system is approximately 6.5 degrees Celsius and the temperature difference for the grid system is approximately 3 degrees Celsius. Consequently, for a given flux of air through the heat sink, the grid system can be more efficient than the fin system in removing heat.
- the grid heat sink could have a variety of configurations and geometries.
- Fig. 7 shows a grid heat sink (700) which is in thermal contact with an underlying chip (725).
- the grid heat sink (700) includes a base (720) which distributes heat to the various vertical fins (710). These primary vertical fins (710) serve as conduction paths to the overlying structures.
- a number of cross fins (715) intersect the primary vertical fins (710) and provide additional surface area and structural support for the heat sink (700). As discussed above, the intersecting fins create a number of channels (730). Air flow is directed through the channels to provide the desired cooling of the heat sink (700) and underlying chip (725).
- These channels may have a substantially uniform cross-section through the length of the heat sink (700). Additionally or alternatively, there may be various disruptions in the channels, such as surface roughness, offsets of the channel cross-section, etc. These obstructions may generate additional focused cooling by direct impingement of the flow on the obstruction or may serve to create additional turbulent flow within the channel to improve heat transfer.
- the cross section of the channels may increase toward the exit to allow for expansion of the air flow. The volume and temperature of the expanding air flow are physically related such that an expansion of the volume of the air flow results in a lower temperature within the air flow. Consequently, altering the cross-section of the channel may be used to make adjustments to the temperature of the air.
- Fig. 8 is a diagram of an illustrative heat sink (800) which has tapered primary fins (810).
- the primary fins (810) serve as a conduction path for the majority of the heat which is dissipated in the rest of the structure.
- the heat sink temperature can be more uniform.
- the cross fins (815) may be significantly thinner than the primary fins (810).
- the cross fins (815) need only conduct a relatively small amount of heat from the adjoining primary fins through the cross fin area. Consequently, the cross fins could be relatively thin with little performance degradation.
- Increasing the thickness of the fins results in a reduction of the cross area of the air channels (830).
- a quantitative trade off between fin geometry and air flow can be performed for specific designs, heat loads, and fan combinations.
- the cross-section of the channels (830) may vary along through the height of the heat sink (820). For example, if high volume flow rates are desired near the base (820) of the heat sink (800), the cross sectional area of the channels at the base could be increased. Alternatively, if high surface areas are desired at the base, a plurality of smaller channels could be formed near the base (820).
- the grid heat sink may be formed by joining a number of stacked tubes.
- the tubes may be made from a thermally conductive material such as metal and joined using any number of techniques.
- the tubes may be joined using welding, soldering, adhesive, or other techniques.
- the tubes may have various cross- sectional geometries which may vary from tube to tube and/or along the length of the individual tubes.
- Fig. 9 is a diagram of one illustrative embodiment of a grid heat sink (900).
- the grid heat sink (900) includes a number of radial primary fins (910) which extend from a base (920).
- the base (920) is in direct thermal contact with a chip (925).
- the heat flux into the base (920) is concentrated in the center of the base directly over the chip (925).
- the radial primary fins arms (910) connected to the center of the base (920) to more directly conduct the heat from the base (920).
- a number of curved cross fins (915) intersect the radial primary fins (910) to form a number of channels (930).
- the channels (930) can be of any suitable geometry including triangular, rectangular, wedge shaped, or any other suitable geometry.
- Fig. 10 is a cross-sectional diagram of an illustrative heat sink (1000) which includes a number of primary fins (1010) which extend from a base (1020).
- the base (1020) is in thermal contact with an underlying chip (1025).
- the cross fins (1015) extend from the primary fins (1010) but do not intersect the adjacent primary fins.
- the result is a number of open channels (1030) between the primary fins.
- the extension of the cross fins (1015) into the open channels (1030) create a high surface area within the channels.
- higher pressure fluid flow may be applied to one portion of a heat sink than other portions of the heat sink.
- a higher pressure fluid flow may be applied to the lower portion of the open channel (1030) near the base. This could result in a two dimensional fluid flow, with a portion of the fluid passing axially down the open channel and a portion of the fluid passing through the serpentine upper portion of the channel to exit through the top of the heat sink (1000).
- the grid heat sink may also have a number of external fins (1035) which extend beyond the interior grid structure to provide additional cooling by external force or free convention.
- Fig. 11 is a diagram of an illustrative heat sink (1100) which includes a base (1120) which is in thermal contact with an underlying chip (1125). A number of primary fins (1110) extend upward from the base (1120). The primary fins (1110) and base (1120) can be formed using metal extrusion processes.
- the channels (1145) can be created by inserting bent sheet metal forms (1115, 1130, 1135) into the spaces between the primary fins (1110). The shape of the sheet metal form determines the size, number and geometry of the resulting channels (1145).
- a first form (1115) has relatively large channels.
- the second form (1130) creates smaller and more numerous channels. Consequently the second form (1130) creates more surface area within the heat sink (1100).
- a third form (1135) creates smaller channels closer to the base (1120) and larger channels near the lid (1140).
- the sheet metal forms (1115, 1130, 1135) may be thermally and structurally joined to the primary fins (1110) in a number of ways, including, but not limited to welding, soldering, adhesives, or spring forces.
- the lid (1140) could compress the sheet metal forms between the primary fins (1110) and produce appropriate thermal contact between the forms (1115, 1130, 1135) and the primary fins (1110) and base (1120).
- Fig. 12 is an illustrative diagram of a heat sink (1200) which incorporates a continuous thermally conductive sheet (1215) which is bent to form channels (1230).
- the conductive sheet (1215) is placed over the primary fins (1210) and contacts the base (1220).
- a cover (1205) encloses upper portion of the heat sink (1200) and forms some of the surfaces of the channels (1230).
- Figs. 13A-13D are illustrations which show steps in forming a grid heat sink (1300) from a continuous sheet of conductive material (1305).
- two bends 1315, 1310) are made in the sheet (1305) to create a U shaped geometry as shown in Fig. 13A.
- Fig. 13B illustrates additional bends (1325, 1320) being made in the sheet to form a first channel (1330).
- Fig. 13C this process is repeated to form a column which includes two additional channels (1335, 1340).
- Fig. 13D illustrates the formation of additional columns to form a grid which is attached to a base (1345).
- the resulting grid heat sink (1300) is formed from a continuous sheet of conductive material (1305) and a base (1345).
- the type, thickness, and other properties of the conductive material (1305) can be altered according to the specific design needs.
- Fig. 14 is a diagram of an alternative geometry for forming a grid heat sink (1400) from a continuous sheet of thermally conductive material (1410).
- the thermally conductive material (1410) is bent and joined at various contact points (1415) to form channels (1405).
- the entire grid structure is joined to a base structure (1415).
- Fig. 15 is a diagram of an alternative geometry for forming a grid heat sink (1500) from a continuous sheet of thermally conductive material (1510).
- the thermally conductive material (1510) is bent and joined to form relatively open channels (1505).
- the entire grid structure is joined to a base structure (1515).
- Fig. 16 is a diagram of an illustrative cooling system (1600) for a chip (1615).
- the air flow (1605) is directed through two ducted fans (1620), into a manifold (1620), and then through a grid heat sink (1625).
- the grid heat sink (1625) is thermally connected to the chip (1615) and conducts heat away from the chip (1615).
- the air flow (1605) removes the heat from the grid heat sink (1625) by convective heat transfer.
- the ducted fans (1610) are used to create a high air pressure in the manifold (1620) which forces the air through the channels in the grid heat sink (1625).
- This approach may have a number of advantages for over suction systems where the fan creates low pressure to suck air through a heat sink.
- the suction action of the fan is limited in the pressure differential which can be generated.
- a suction fan system can not produce a pressure any lower than zero. Consequently, the maximum pressure differential which can be produced by a suction fan system is equal to the supply pressure, which is typically atmospheric pressure.
- fan systems which create high pressure at the inlet to force air through a heat sink do not have a similar limitation in the maximum pressure which can be generated. Rather, pressure systems are limited only by the mechanics of the cooling system, such as the design of the fans, the available power, the physical strength of the fans, manifold and grid heat sink, etc. Consequently, a pressure system could produce several atmospheres of pressure to drive the air flow through the grid heat sink. This could be particularly advantageous when very small channels are used in the grid heat sink.
- FIG. 17 shows an illustrative embodiment of the a cooling system (1700) which includes a blower fan (1710) which attached to a manifold (1720) which directs the air flow through a grid heat sink (1725).
- the grid heat sink (1725) is used to cool an underlying chip (1715).
- Fig. 18 is a side view of an illustrative cooling system (1700) within a blade server (1800) which is represented by a dotted outline.
- Blade servers (1800) are very compact computers which may have one or more central processor units (CPUs) (1805).
- the grid heat sink (1725) is thermally connected to the CPU (1805).
- An air flow (1810) is generated by the fan (1710).
- the air flow (1810) through openings in the left of the blade server (1800) and enters the fan (1710) where it is compressed and ejected into the manifold (1720).
- the manifold (1720) directs the air flow (1810) through the grid heat sink (1725).
- the air flow (1810) is then vented out of the right of the blade server (1800).
- FIG. 19 is front view of an illustrative rack (1900) of blade servers (1800).
- the rack (1900) contains 16 blade servers (1800), each of which may have multiple processors.
- the front of each of the blade servers (1800) has a number of openings through cooling air is drawn. After passing over the various components within the blade server (1800), the heated air is vented out the back of the rack.
- a variety of fan configurations can be used. According to one illustrative embodiment, one larger fan or array of fans supply pressurized air for multiple grid heat sinks.
- a grid heat sink provides increased thermal and volumetric efficiency when compared to fin heat sinks.
- the channels formed by the primary fins and cross fins provide additional surface area and prevent the premature exit and recirculation of cooling air. Consequently, grid heat sinks may be particularly desirable for more compact systems which have concentrated heat sources.
Abstract
Description
Claims
Priority Applications (7)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
PCT/US2009/038255 WO2010110790A1 (en) | 2009-03-25 | 2009-03-25 | Grid heat sink |
CN2009801588200A CN102405693A (en) | 2009-03-25 | 2009-03-25 | Grid heat sink |
US13/257,390 US20120006514A1 (en) | 2009-03-25 | 2009-03-25 | Grid heat sink |
KR1020117025245A KR20120017029A (en) | 2009-03-25 | 2009-03-25 | Grid heat sink |
JP2012501976A JP2012521657A (en) | 2009-03-25 | 2009-03-25 | Grid heat sink |
EP09842423A EP2412215A1 (en) | 2009-03-25 | 2009-03-25 | Grid heat sink |
TW099105459A TW201037259A (en) | 2009-03-25 | 2010-02-25 | Grid heat sink |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
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PCT/US2009/038255 WO2010110790A1 (en) | 2009-03-25 | 2009-03-25 | Grid heat sink |
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WO2010110790A1 true WO2010110790A1 (en) | 2010-09-30 |
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PCT/US2009/038255 WO2010110790A1 (en) | 2009-03-25 | 2009-03-25 | Grid heat sink |
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US (1) | US20120006514A1 (en) |
EP (1) | EP2412215A1 (en) |
JP (1) | JP2012521657A (en) |
KR (1) | KR20120017029A (en) |
CN (1) | CN102405693A (en) |
TW (1) | TW201037259A (en) |
WO (1) | WO2010110790A1 (en) |
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JP6645915B2 (en) * | 2016-06-24 | 2020-02-14 | 三協立山株式会社 | heatsink |
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Also Published As
Publication number | Publication date |
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KR20120017029A (en) | 2012-02-27 |
CN102405693A (en) | 2012-04-04 |
TW201037259A (en) | 2010-10-16 |
EP2412215A1 (en) | 2012-02-01 |
US20120006514A1 (en) | 2012-01-12 |
JP2012521657A (en) | 2012-09-13 |
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