This disclosure relates to the thermal management of photonic and/or electronic integrated circuits, in particular, passive thermal management using heat pipes.
Many photonic and electronic components have properties sensitive to changes in temperature and are at risk of degrading in performance or becoming altogether nonoperational unless they are thermally managed to stay within an operation range of acceptable temperatures. Therefore, thermal management systems are often utilized to control the temperature of such photonic/electronic components. Typically, thermal management includes removing heat generated by these components themselves during operation, although active heating may also be used in some circumstances to achieve a minimum temperature. Accordingly, thermal management systems typically include a heat sink and/or a heater, as well as means of heat transfer between the components to be temperature-controlled and the heat sink or heater.
One approach to thermal management, which is sometimes employed in packages containing integrated circuits, is the use of a heat pipe, that is, a sealed chamber filled with a working fluid that evaporates in a high-temperature region in contact with a heat source and condenses in low-temperature region in contact with a heat sink, transferring heat by a combination of convection and phase change, in addition to heat conduction through the pipe wall. Without further measures, however, a heat pipe can result in overcooling of the components to be thermally managed, for instance, when the temperature of the heat sink drops too low. An alternative approach that addresses this problem is active thermal management, for example, with a thermoelectric cooler. A thermoelectric cooler exploits the Peltier effect to transfer heat in a direction and at a rate controllable by an electric current. If combined with a temperature sensor, a thermoelectric cooler can, thus, actively control the temperature of a thermally managed component. This capability comes, however, at the cost of increased power requirements, complexity, and expense for the package that includes the thermally managed components and heat management system.
Various example embodiments are herein described in conjunction with the accompanying drawings, in which:
Disclosed herein are variable conductance heat pipes for thermal management of photonic and/or electronic subassemblies (e.g., including integrated circuits) configured within larger assemblies, especially packages that impose spatial constraints, such as, for example, Quad Small Form-factor Pluggable (QSFP) or other pluggable packages. The use of variable conductance heat pipes is particularly beneficial to manage the temperature of optical packages, such as optical transceiver packages for data communications applications or optical sensor packages.
In general, a heat pipe is in thermal contact with a heat source at one end and with a heat sink at the other end. At the end in thermal contact with the heat source, the working fluid of the heat pipe, which may, e.g., be water, evaporates; this end is hereinafter also referred to as the “evaporator end.” At the end in thermal contact with the heat sink, the working-fluid vapor (e.g., water vapor) condenses; this end is hereinafter also referred to as the “condenser end.” The vapor flows inside the pipe from the evaporator end to the condenser end. After condensation, the working fluid in the liquid state is drawn back from the condenser end to the evaporator end via capillary forces in a wick structure lining the interior surface of the pipe wall.
A variable conductance heat pipe includes, in addition to the working fluid achieving the desired heat transfer, a non-condensable gas, which generally has low thermal conductivity. During operation of the heat pipe, the non-condensable gas tends to be pushed towards and accumulate at the condenser end, where it inhibits condensation of the working-fluid vapor by partially blocking the vapor from reaching the interior pipe surface in the condenser region, thereby diminishing cooling. This effect is temperature-dependent, resulting in a temperature-dependent heat conductance of the pipe that is generally lower for lower temperatures in the evaporator and/or condenser regions. In scenarios where a conventional heat pipe with fixed conductance might overcool a heat-generating component, the addition of a non-condensable gas to form a variable conductance heat pipe may cause cooling to halt at a certain temperature (above the temperature of the heat sink) where the diminished heat transfer from the evaporator end to the condenser end balances the heat generation at the source. At the same time, the higher thermal conductance at higher temperatures can cause effective cooling even at relatively high temperatures of the heat sink. Thus, for a given temperature range associated with the heat sink and, thus, the condenser region, it is possible, with a properly configured variable conductance heat pipe, to keep the temperature of the heat source and, thus, the evaporator region within a range whose lower limit is substantially higher than the lower limit of the temperature range of the condenser region, and whose upper limit is not that much higher (if at all) than the higher limit of the temperature range of the condenser region. In other words, the temperature range experienced by the integrated circuits or other device being cooled is smaller than the temperature range experienced by the heat sink. For example, in some embodiments, where the temperature of the heat sink (e.g., as provided by a heat sink contact area of a housing) can vary from 0° C. to 70° C., the heat pipe has a thermal conductance that varies by a factor of at least two across that range, allowing the temperature in the evaporator region to be kept within the range from 20° C. to 85° C., in some embodiments within the range from 40° C. to 85° C.
In various embodiments, a variable conductance heat pipe is used to cool one or more photonic and/or electronic components (e.g., photonic and/or electronic integrated circuits within a multi-chip module) contained within a standard small housing. Optical components, whether provided as discrete devices or integrated in a photonic integrated circuit(s), may, for instance, form part of an optical subassembly within a compact hot-pluggable optical package (e.g., a QFSP transceiver or optical sensor module). In this case, spatial constraints may prevent the heat pipe to be oriented along the direction separating the integrated circuits constituting the heat source from the heat sink contact area on the housing. Instead, the heat pipe, which needs to exceed a certain length to transfer heat at a sufficient rate, may be oriented with its axis (herein understood to correspond to the longest dimension of the heat pipe and the direction along which condenser and evaporator are separated, that is, the general direction of fluid flow in operation) generally parallel to the heat sink contact area and the integrated circuits. Referring to opposite surfaces along the heat pipe that are separated along a direction perpendicular to the axis of the heat pipe as first and second exterior surfaces, the first exterior surface may be in thermal contact with the integrated circuits, and the second exterior surface may be in thermal contact with the heat sink contact area. The heat pipe may be positioned such that thermal contact with the integrated circuits is limited to a region at the evaporator end. The heat sink contact area, however, is generally so long in standard packages that it would contact the heat pipe along its entire length. To confine condensation to a region at the condenser end, therefore, a thermal insulation structure may be interposed between the heat pipe and the heat sink contact area, extending from the evaporator end to the beginning of the condenser region.
The foregoing will be more readily understood from the following description, with reference to the accompanying drawings, of various aspects and example embodiments.
The cavity 104 is filled, at sub-atmospheric pressure, with a working fluid that changes phase within the operating temperature/pressure range of the heat pipe 100 (the gaseous phase of the working fluid being labeled 108) and with a non-condensable gas 110 (i.e., a gas that does not condense within the operating range of the heat pipe 100). Sub-atmospheric pressure can be achieved in the heat pipe 100 by first evacuating it, and then back-filling a small amount of the working fluid and non-condensable gas. Working fluids commonly used for cooling electronic and photonic components include, without limitation, water, ammonia, acetone, and methanol. Suitable non-condensable gases for some embodiments include, for example, nitrogen and noble gases such as argon.
The heat pipe 100 is generally characterized by a high aspect ratio defining an axial direction, indicated in
The exact locations of the evaporator and condenser regions 118, 120 along the circumference of the heat pipe 110 (meaning, the angular location in a cross-sectional plane perpendicular to the axis 112) is generally not important for purposes of operation of the heat pipe 110, but may depend, instead, on the geometric configuration of the package in which the heat pipe 100 is to be used. In
When the heat pipe 100 is operating, a pressure gradient is generated between a high pressure in the evaporator region 118 and a low pressure in the condenser region 120, causing the vapor 108 of the working fluid to flow towards the condenser region 120, as indicated by the arrows 128 in
Variable conductance heat pipes, such as the heat pipe 100 of
The heat pipe subassembly 204 includes a heat pipe 100, configured as conceptually shown in
As a consequence of the orientation of the heat pipe 100 in parallel with the heat sink contact area 212 and the integrated circuits 208, 210, the evaporator region 118 is formed at the bottom surface 124 (herein also referred to as a first exterior surface portion) of the heat pipe 100, and the condenser region 120 is formed at the top surface 126 (herein also referred to as a second exterior surface portion) of the heat pipe 100. In the condenser region 120, the top surface 126 of the heat pipe 100 may be flattened and glued (with a suitable adhesive) to the heat sink contact area 212 to provide good thermal contact.
To establish thermal contact between the evaporator region 118 and the integrated circuits 208, 210, a thermal interface structure is disposed between and in mechanical contact with (i.e., touching) both the integrated circuits 208, 210 and the bottom surface 124 in the evaporator region 118. As shown, the thermal interface structure may be a layered structure that includes, for instance, a thermally conductive adapter plate 216 and a soft thermal interface material layer 218. The adapter plate 216 may be made, e.g., of copper, aluminum, steel, zinc, diamond, aluminum nitride, or boron nitride. It is placed directly adjacent and in mechanical contact with the bottom surface 124 of the heat pipe 100 at the evaporator end 114 (the contact area between heat pipe 100 and adapter plate 216 defining the evaporator region 118 of the heat pipe 100), and is often fixedly adhered to the heat pipe 100, forming part of the heat pipe subassembly 204. For example, in some embodiments, the adapter plate 216 is made of a metal and soldered to the heat pipe 100 to create the evaporator region 118. The other side of the metal adapter plate 216 is, in the completed assembly, in direct contact with the thermal interface material layer 218, which, in turn, is placed directly on top of the optical subassembly 202. The thermal interface material layer 218 is made of a soft, deformable thermally conductive material, such as a conductive thermoplastic, gel, or grease. When placed in contact with the optical subassembly 202, the thermal interface material layer 218 tends to conform to the surface structure, providing good mechanical and, thus, thermal contact with the surface features of the optical subassembly 202 (such as the integrated circuits 208, 210). As shown, the adapter plate 216 and thermal interface material layer 218 may be sized and shaped to cover an area fully encompassing all integrated circuits 208, 210 to be cooled.
The top surface 126 of the heat pipe 100 faces, as noted, the heat sink contact area 212 of the housing 206. To prevent condensation of the working-fluid vapor 108 from happening along the entire length of the heat pipe 100, the heat pipe subassembly 204 further includes a thermal insulation structure 220 interposed between the heat pipe 100 and the heat sink contact area 212. The thermal insulation structure 220 covers, and thereby thermally insulates, the top surface 126 of the heat pipe 100 from the evaporator end 114 all the way to the beginning of the condenser region 120. The thermal insulation structure 220 may be made, for example, from a plastic (e.g., mylar), foam, or epoxy.
The heat pipe subassembly 204 can be configured, by tuning various parameters, to provide a desired temperature-dependent heat conductance. In general, the performance of the heat pipe subassembly 204 depends on a number of factors, including: the thermal resistance of the heat pipe wall 102 as determined by the thermal conductivity of the wall material, the wall thickness, the length of the heat pipe 100, as well as the wicking structure (which can have a significant effect on the thermal performance of the heat pipe 100 due to its thickness and speed of capillary action); the amount of non-condensable gas 110 and working fluid 108; the size of the contact areas defining the evaporator and condenser regions 118, 120, which govern the heat flow through the heat pipe 100; and insulation of the heat pipe 100 with air or solid insulation except in the contact areas of the evaporator and condenser regions 118, 120 with the heat sources and sink, respectively (which is important to ensure that the heat flows primarily from the evaporator end 114 to the condenser end 116). In addition, the temperature range of the heat sink affects the performance of the working fluid in the heat pipe 100.
In one example embodiment, the heat pipe wall is made of copper and has a thickness of 0.18 mm, a copper mesh is used for the wick structure, the working fluid is water, and the non-condensable gas is nitrogen (used in a quantity of about 1·10−12 moles). The length of the heat pipe is about 36 mm, with a 10-mm long evaporator region and a 15-mm long condenser region. Using this structure, at a temperature of the heat sink of about 0° C., the integrated-circuit temperature can be kept at a desired level of about 35° C., with a thermal resistance of the heat pipe across the walls and adiabatic region of about 10° C./W and power dissipation of about 3.5 W.
Evaporation of the working fluid and its flow towards the condenser region (processes 402, 404) furthermore cause the non-condensable gas to be pushed to and compressed at the condenser end (process 410), where the non-condensable gas partially blocks working fluid from reaching the condenser region. Depending on the temperature of the evaporator and resulting vapor pressure, the volume of the non-condensable gas relative to the volume of the working-fluid vapor, and thus the degree of blockage at the condenser, varies, causing a corresponding adjustment in the thermal conductance of the heat pipe and the degree of cooling. This mechanism allows cooling the evaporator region while always keeping it within a temperature range whose lower limit is substantially (e.g., by at least 15° C.) above the lowest temperature of the condenser region.
Having described different aspects and features of variable conductance heat pipes and their packaging with integrated-circuit subassemblies, the following numbered examples are provided as illustrative embodiments:
A thermally managed optical package comprising: an optical subassembly comprising a photonic integrated circuit; a housing surrounding the optical subassembly, the housing comprising a heat sink contact area; and a heat pipe subassembly disposed between the optical subassembly and the heat sink contact area. The heat pipe subassembly comprises a variable conductance heat pipe having first and second ends, the heat pipe containing a working fluid and a non-condensable gas, an evaporator region of the heat pipe at the first end being in thermal contact with the photonic integrated circuit, and a condenser region of the heat pipe at the second end being in thermal contact with the heat sink contact area, the heat pipe cooling the photonic integrated circuit at least by evaporation of the working fluid in the evaporator region and condensation of the working fluid in the condenser region, and the non-condensable gas partially blocking, to a varying extent, the working fluid from reaching the condenser region so as to adjust a thermal conductance of the heat pipe; and a thermal insulation structure insulating an exterior surface portion of the heat pipe from the heat sink contact area in a region excluding the condenser region.
The optical package of example 1, wherein the first and second ends are separated along a direction substantially perpendicular to a direction along which the optical subassembly is separated from the heat sink contact area.
The optical package of example 1 or example 2, wherein the evaporator region is located at a first exterior surface portion of the heat pipe and the condenser region is located at a second exterior surface portion of the heat pipe that is opposite to the first exterior surface portion in a direction along which the optical subassembly is separated from the heat sink contact area, the insulated exterior surface portion being a portion of the second exterior surface portion.
The optical package of example 3, wherein the heat pipe subassembly further comprises a thermally conductive adapter plate in mechanical contact with an exterior surface of the first exterior surface portion in the evaporator region.
The optical package of example 4, further comprising a soft thermal interface material layer disposed between and in mechanical contact with the photonic integrated circuit and the adapter plate.
The optical package of any one of examples 1-5, wherein the optical transceiver further comprises an electronic integrated circuit.
The optical package of example 7, wherein the evaporator region is further in thermal contact with the electronic integrated circuit.
The optical package of any one of examples 1-7, wherein the heat pipe has a thermal conductance that varies by a factor of at least two for temperatures of the condenser region within the range from 0° C. to 70° C.
The optical package of any one of examples 1-8, wherein the heat pipe subassembly is configured to maintain a temperature of the evaporator region within the range from 20° C. to 85° C. for temperatures of the condenser region within the range from 0° C. to 70° C.
A heat pipe subassembly for cooling an optical subassembly, the heat pipe subassembly comprising: a variable conductance heat pipe having first and second ends, the heat pipe comprising a wall defining an axis between the first and second ends, first and second exterior surface portions on opposite respective sides of the axis, and an interior surface defining a cavity, a wick structure lining the interior surface of the wall of the heat pipe, and a phase-changing working fluid and a non-condensable gas contained within the cavity (wherein the phase-changing working fluid is operatively cooling the optical subassembly by evaporation in an evaporator region at the first end and condensation in a condenser region at the second end, and the non-condensable gas is operatively adjusting a thermal conductance of the heat pipe by at least partially blocking, to a varying extent, the working fluid from reaching the condenser region); a thermally conductive adapter plate adhered to the first exterior surface portion in the evaporator region; and a thermal insulation structure operatively insulating the heat pipe from a heat sink contact area in a region excluding the condenser region, the thermal insulation structure covering the second exterior surface portion across a region extending from the first end up to, but not including, the condenser region.
The heat pipe subassembly of example 10, wherein thermally conductive adapter plate is a metal plate soldered to the heat pipe.
The heat pipe subassembly of example 10 or example 11, wherein the heat pipe has a thermal conductance that varies by a factor of at least two for temperatures of the condenser region within the range from 0° C. to 70° C.
The heat pipe subassembly of any of examples 10-12, wherein the heat pipe subassembly is configured to maintain a temperature of the evaporator region within the range from 20° C. to 85° C. for temperatures of the condenser region within the range from 0° C. to 70° C.
A thermally managed optical package comprising: an optical subassembly; a housing surrounding the optical subassembly, the housing comprising a heat sink contact area; and a heat pipe subassembly disposed between the optical subassembly and the heat sink contact area, the heat pipe subassembly comprising a variable conductance heat pipe having first and second ends, the heat pipe containing a working fluid and a non-condensable gas, an evaporator region of the heat pipe at the first end being in thermal contact with the optical subassembly, and a condenser region of the heat pipe at the second end being in thermal contact with the heat sink contact area, wherein the heat pipe subassembly is configured, for temperatures of the condenser region between a lower first temperature and an upper second temperature, to adjust the thermal conductance of the heat pipe to maintain a temperature of the evaporator region within a temperature range between a lower third temperature and a higher fourth temperature, the third temperature being higher than the first temperature by at least 15° C. and the fourth temperature being not lower than the third temperature.
The optical package of example 14, wherein a difference between the fourth and third temperatures is smaller than a difference between the second and first temperatures.
The optical package of example 14, wherein the heat pipe subassembly comprises a thermally conductive adapter plate adhered to the heat pipe in the evaporator region and in thermal contact with the optical subassembly.
The optical package of example 16, further comprising a soft thermal interface material layer disposed between and in mechanical contact with the photonic integrated circuit and the adapter plate.
The optical package of example 17, further comprising a thermal insulation structure operatively insulating the heat pipe from a heat sink contact area in a region excluding the condenser region.
The optical package of any one of examples 14-18, wherein the optical subassembly is a transceiver subassembly.
The optical package of any of examples 14-19, wherein the optical subassembly comprises one or more integrated circuits.
Although the inventive subject matter has been described with reference to specific example embodiments, it will be evident that various modifications and changes may be made to these embodiments without departing from the broader spirit and scope of the inventive subject matter. Accordingly, the specification and drawings are to be regarded in an illustrative rather than a restrictive sense.
Number | Name | Date | Kind |
---|---|---|---|
3225820 | Riordan | Dec 1965 | A |
3693374 | Juvonen et al. | Sep 1972 | A |
5253260 | Palombo | Oct 1993 | A |
5771967 | Hyman | Jun 1998 | A |
6230790 | Hemingway | May 2001 | B1 |
6771498 | Wang | Aug 2004 | B2 |
7299859 | Bolle | Nov 2007 | B2 |
8587945 | Hartmann et al. | Nov 2013 | B1 |
20030103880 | Bunk | Jun 2003 | A1 |
20040226695 | Bolle et al. | Nov 2004 | A1 |
20070064397 | Chiba | Mar 2007 | A1 |
20080156460 | Hwang | Jul 2008 | A1 |
20080308259 | Garner et al. | Dec 2008 | A1 |
20090294117 | Hodes | Dec 2009 | A1 |
20100051254 | Ipposhi et al. | Mar 2010 | A1 |
20110127013 | Kawamura et al. | Jun 2011 | A1 |
20120140403 | Lau | Jun 2012 | A1 |
20130279115 | Blumenthal | Oct 2013 | A1 |
20150013936 | Mack | Jan 2015 | A1 |
20150179617 | Lin et al. | Jun 2015 | A1 |
20160181676 | Nubbe | Jun 2016 | A1 |
20160248521 | Streshinsky et al. | Aug 2016 | A1 |
20160269119 | Blumenthal | Sep 2016 | A1 |
Number | Date | Country |
---|---|---|
1937905 | Mar 2007 | CN |
100449244 | Jan 2009 | CN |
102047415 | May 2011 | CN |
103591568 | Feb 2014 | CN |
104409913 | Mar 2015 | CN |
107636263 | Jan 2018 | CN |
110658594 | Jan 2020 | CN |
60202291 | Oct 1985 | JP |
2007088282 | Apr 2007 | JP |
20050045542 | May 2005 | KR |
200618221 | Jun 2006 | TW |
202006908 | Feb 2020 | TW |
WO-2017127059 | Jul 2017 | WO |
Entry |
---|
“European Application Serial No. 19180815.3, Extended European Search Report dated Nov. 6, 2019”, 12 pgs. |
“A passive variable thermal resistance device is proposed which utilizes a flexible heat pipe switch”, SBIR Proposal, [Online]. [Accessed Aug. 16, 2018]. Retrieved from the Internet: <URL: https://www.sbir.gov/sbirsearch/detail/150312>, 4 pgs. |
Ababneh, Mohammed T., “Thermal-Fluid Modeling for High Thermal Conductivity Heat Pipe Thermal Ground Planes”, Published in Journal of Thermophysics and Heat Transfer (AIAA), (Apr. 2014), 22 pgs. |
Geng, Xiaobao, et al., “A Self-Adaptive Thermal Switch Array to Stabilize the Temperature of MEMS Devices”, 2010 IEEE, (2010), 148-151. |
Lesieutre, George, et al., “Variable Thermal Conductivity Structures for Spacecraft Thermal Control”, AFOSR Grantees' / Contractors' Meeting (Dr. Les Lee, yr 1) “Mechanics of Multifunctional Materials & Microsystems”, (Aug. 3, 2012), 24 pgs. |
Stavely, Rebecca Lee, “Design of Contact-Aided Compliant Cellular Mechanisms for Use as Passive Variable Thermal Conductivity Structures”, Master Thesis—Dec. 2013—Pennsylvania State University, 180 pgs. |
“Chinese Application Serial No. 201910548082.6, Voluntary Amendment filed Apr. 27, 2020”, (w/ English Translation of Claims), 13 pgs. |
“Taiwanese Application Serial No. 108120634, Office Action dated Feb. 12, 2020”, (w/ English Translation), 7 pgs. |
“Taiwanese Application Serial No. 108120634, Response filed May 7, 2020 to Office Action dated Feb. 12, 2020”, (w/ English Translation of Claims), 25 pgs. |
“European Application Serial No. 19180815.3, Response filed Jul. 1, 2020 to Extended European Search Report dated Nov. 6, 2019”, 16 pgs. |
“Korean Application Serial No. 10-2019-0074938, Notice of Preliminary Rejection dated Aug. 18, 2020”, w/English Translation, 20 pgs. |
“Taiwanese Application Serial No. 108120634, Office Action dated Sep. 9, 2020”, w/ Partial English Translation, 11 pgs. |
“Korean Application Serial No. 10-2019-0074938, Response filed Nov. 16, 2020 to Notice of Preliminary Rejection dated Aug. 18, 2020”, w English Claims, 28 pgs. |
“Chinese Application Serial No. 201910548082.6, Office Action dated Dec. 3, 2020”, w Concise Statement of Relevance, 11 pgs. |
“Chinese Application No. 201910548082.6, Response filed Apr. 15, 2021 to Office Action dated Dec. 3, 2020”, w/English Claims, 15 pgs. |
“Korean Application Serial No. 10-2019-0074938, Notice of Preliminary Rejection dated Mar. 19, 2021”, w/English Translation, 19 pgs. |
“Taiwanese Application Serial No. 108120634, Response filed Mar. 11, 2021 to Office Action dated Sep. 9, 2020”, w/English Claims, 30 pgs. |
Number | Date | Country | |
---|---|---|---|
20200008321 A1 | Jan 2020 | US |