Computing devices include various components, including processors and graphics processing units (GPUs) that generate heat. To dissipate the heat generated by such components, computing devices often include one or more cooling elements. Such cooling elements include, for example, fluid-cooled systems, heat pipes, vapor chambers, heat sinks, fans, and the like.
Removing heat from an integrated circuit (IC), such as a central processing unit (CPU), accelerated processing unit (APU), a graphics processing unit (GPU), application specific IC (ASIC), field programmable gate array (FPGA), or the like, is becoming more difficult with an increased demand for greater processing power. A continuous push exists to increase power consumption and power density in ICs. For example, in processors, higher power consumption often correlates to higher performance. In addition, as processor technology advances, the number and density of transistors in a processor generally increase, resulting in faster and more power efficient processors. As transistor density increases, heat generation is more concentrated in an area and removal of heat from the processor becomes more difficult. Similar advances are occurring in other types of ICs which result in similar concentrated and increased heat generation.
Thermal cooling solutions are usually employed to assist in heat removal from components of a computing device such as ICs. Maintaining a cooler IC potentially equates to higher performance. More efficient thermal solutions (such as a cooler) for removing heat typically result in lower IC temperatures. Computing devices often include one or more cooling elements to dissipate heat generated by various ICs, such as processor cores. Such cooling elements include, for example, heat sinks, fluid cooling systems (e.g., water cooling systems), vapor chambers, heat pipes, fans, and the like to conduct heat generated by ICs of the computing device to fans that dissipate the heat out of the computing device. However, existing solutions may not adequately cool components of a computing system due to utilizing ambient temperature air to cool and/or lack of sufficient thermal contact between heat generating components and heat dissipating components.
This specification sets forth a component cooler for a computing device. In one or more implementations, the component cooler utilizes multiple heat pipes to split a heat load generated by a component, through multiple conduction paths between multiple heat transfer elements to facilitate heat removal from the component. The component cooler includes multiple fluid flow paths across multiple surfaces to facilitate heat removal from the component. The component cooler can also incorporate one or more thermoelectric coolers (TECs) in contact with one or more of the heat transfer elements to provide sub-ambient cooling to the heat transfer elements and facilitate heat removal from the component.
In some implementations, power provided to one or more TECs of a component cooler is controlled in or to adapt the cooling capability to suit a variety of workload use cases. In some implementations, the component cooler utilizes one or more thermoelectric coolers (TECs) in contact with one or more heat transfer elements to provide sub-ambient cooling to the heat transfer elements to facilitate heat removal from the component. Accordingly, more effective and efficient cooling of components within a computing device is provided by subcooling airflow used to cool components of the computing device using a TEC to more effectively remove heat from the components of the computing device.
In some implementations, the component cooler utilizes one or more thermoelectric coolers (TECs) in contact with one or more heat transfer elements to provide sub-ambient cooling to the heat transfer elements to facilitate heat removal from the component. In some implementations, a component cooler having a TEC is thermally coupled to a processor, and an airflow is directed over the component cooler and TEC. In some implementations, the processor is operated at a relatively low power level and the TEC is operated at a relatively high power level. A cold side of the TEC removes an amount of heat from the airflow and dissipates the heat using a hot side of the TEC to a heat exchanger such as a radiator. As a result, the airflow is sub-cooled below an ambient temperature and the sub-cooled airflow passes over one or more downstream components, such as a GPU. The sub-cooled air flow consequently further cools the downstream components. An example use case for which sub-cooling of airflow is beneficial is during graphically-intensive applications such as gaming in which a CPU is consuming a relatively low amount of power while the GPU is consuming a relative high amount of power.
In some implementations, a TEC device thermally coupled to a heat dissipation device is placed at a front of a chassis of a computing device and functions to cool an airflow directed into the chassis to a sub-ambient temperature. The sub-cooled airflow passes over electronic components of the computing device such as a CPU and a GPU to provided improved cooling of the electronic components.
In some implementations, an apparatus for sub-cooling an electronic component includes a component cooling device; a processor thermally coupled to the component cooling device; an electronic component; and a fan configured to direct an airflow across the processor and the electronic component. The apparatus further includes a thermoelectric cooling device thermally coupled to the component cooling device, the thermoelectric cooling device configured to cool the airflow from a first temperature to a second temperature.
In some implementations, the apparatus further includes a heat exchanger thermally coupled to the thermoelectric cooling device. In some implementations, the heat exchanger comprises a radiator. In some implementations, the heat exchanger is thermally coupled to the thermoelectric cooling device by a closed loop having a heat transfer medium contained therein. In some implementations, the closed loop is further coupled to the electronic component, wherein the thermoelectric cooling device is further configured to cool the heat transfer medium contained within the closed loop.
In some implementations, the processor comprises at least one of a central processing unit (CPU) or an accelerated processing unit (APU). In some implementations, the electronic component comprises a graphical processing unit (GPU). In some implementations, the second temperature is a sub-ambient temperature.
In some implementations, an apparatus for sub-cooling an electronic component includes a first electronic component; a thermoelectric cooling device; and a fan configured to direct an airflow across the thermoelectric cooling device and the first electronic component. The thermoelectric cooling device is configured to cool the airflow from a first temperature to a second temperature before being directed to the first electronic component.
In some implementations, the apparatus further includes a first heat exchanger thermally coupled to the thermoelectric cooling device, the first heat exchanger configured to receive a first portion of heat from the thermoelectric cooling device.
In some implementations, the apparatus further includes a second heat exchanger thermally coupled to the first heat exchanger, the second heat exchanger configured to receive a second portion of heat from the first heat exchanger. In some implementations, the first heat exchanger is thermally coupled to the second heat exchanger by a first closed loop having a heat transfer medium contained therein.
In some implementations, the first electronic component comprises at least one of a central processing unit (CPU), an accelerated processing unit (APU), or a graphical processing unit (GPU).
In some implementations, the apparatus further includes a second electronic component, wherein the fan is further configured to direct the airflow across the second electronic component.
In some implementations, the thermoelectric cooling device, the first electronic component, and the second electronic component are thermally coupled by a closed loop having a heat transfer medium contained therein, and wherein the thermoelectric cooling device is further configured to cool the heat transfer medium contained within the closed loop.
In some implementations, the second electronic component comprises at least one of a central processing unit (CPU), an accelerated processing unit (APU), or a graphical processing unit (GPU).
In some implementations, wherein the thermoelectric cooling device is thermally coupled to the first electronic component by a component cooler.
In some implementations, a method for sub-cooling an electronic component includes directing an airflow across a thermoelectric cooling device and a first electronic component; and cooling, by the thermoelectric cooling device, the airflow from a first temperature to a second temperature before being directed to the first electronic component.
In some implementations, the method further includes directing the airflow across a second electronic component after the first electronic component.
In some implementations, the method further includes thermally coupling a heat exchanger to the thermoelectric cooling device; and receiving, by the heat exchanger, a first portion of heat from the thermoelectric cooling device.
Various implementations of a component cooling apparatus are described with reference to drawings beginning with
The example component cooling apparatus 100 of
A top surface of the processor 106 is thermally coupled to a bottom surface of a first base plate 108A. A base plate is a component of a heat pipe assembly through which various heat pipes conduct heat. The first base plate 108A is connected to the substrate 102 via a mounting plate 107. A top surface of the first base plate 108A is coupled to a bottom surface of a second base plate 108B. The first base plate 108A and the second base plate 108B may be constructed of a conductive metal, such as copper. In some implementations, the first base plate 108A and the second base plate 108B are replaced with a single base plate.
A top surface of the second base plate 108B is thermally coupled to a bottom surface of a first thermoelectric cooler (TEC) 110A. A TEC is a semiconductor device having two sides which function to transfer heat from one side to the other when current is passed through the TEC. A top surface of the first TEC 110A is thermally coupled to a first cold plate 112A. A cold plate is a device that uses a fluid to transfer heat from a device to a remote heat exchanger. Although various implementations are described as using cold plates as heat transfer elements, in other implementations, other suitable heat transfer elements are used such as base plates or heatsinks.
The component cooling apparatus 100 also includes a second cold plate 112B having a top surface thermally coupled to a bottom surface of a second TEC 110B. A top surface of the second TEC 110B is thermally coupled to a bottom surface of a third base plate 108C. A top surface of third base plate 108C is coupled to a bottom surface of a fourth base plate 108D. The third base plate 108C and the fourth base plate 108D are constructed of a conductive metal such as copper. In an implementation, the third base plate 108C and the fourth base plate 108D are replaced with a single base plate.
The component cooling apparatus of
The component cooling apparatus 100 also includes multiple heat pipes 114A, 114B, 114C, and 114D. Each of the heat pipes 114A-114D has a first end disposed between and in thermal contact with the first base plate 108A and the second base plate 108B, and a second end disposed between and in thermal contact with the third base plate 108C and the fourth base plate 108D. Each of the heat pipes 114A, 114B, 114C, and 114D include a middle portion between the first end and the second end that is external to each of the base plates 108A, 108B, 108C, and 108D. In one or more implementations, each of the heat pipes 114A, 114B, 114C, and 114D are formed in a half-loop configuration as further illustrated in
The component cooling apparatus 100 also includes a fluid manifold. The fluid manifold includes a manifold inlet portion 116A and a manifold outlet portion 116B disposed on opposing sides of the component cooling apparatus 100. The manifold inlet portion 116A includes a fluid inlet 118A, and the manifold outlet portion 116B includes a fluid outlet 118B. In an implementation, the fluid inlet 118A and the fluid outlet 118B are each positioned in opposite directions. In other implementations, the fluid inlet 118A and the fluid outlet 118B are each positioned in the same or any direction.
The fluid manifold includes a first fluid passage 120A extending from the manifold inlet portion 116A to the manifold outlet portion 116B. The first fluid passage 120A is in thermal contact with the first cold plate 112A. The fluid manifold includes a second fluid passage 120B extending from the manifold inlet portion 116A to the manifold outlet portion 116B and in thermal contact with the second cold plate 112B. The fluid manifold also includes a third fluid passage 120C extending from the manifold inlet portion 116A to the manifold outlet portion 116B and in thermal contact with the third cold plate 112C. During operation of the component cooling apparatus 100, a fluid loop that includes a fluid pump and a radiator (not shown) is coupled between the fluid inlet 118A and the fluid outlet 118B via tubing or the like. The fluid pump causes a flow of a cooling fluid within the fluid manifold into the manifold inlet portion 116A. The cooling fluid is split through each of the first fluid passage 120A, the second fluid passage 120B, and the third fluid passage 120C. The separate flows are merged within the manifold outlet portion 116B and output from the fluid outlet 118B to the radiator.
In an implementation, the flow of fluid through each of the first fluid passage 120A, the second fluid passage 120B, and the third fluid passage 120C is varied by constructing the sizes of one or more the first fluid passage 120A, second fluid passage 120B, and the third fluid passage 120C to be different from one another to achieve a desired flow rate through each of the fluid passages 120A, 120B, and 120C. In a particular example, the first fluid passage 120A is sized to have a greater flow rate than the second fluid passage 120B and the third fluid passage 120C due to an expectation of the amount of heat transferred to the first fluid passage 120A being greater than that of the second fluid passage 120B and the third fluid passage 120C. In an implementation, a diameter of the first fluid passage 120A is greater than that of the second fluid passage 120B or the third fluid passage 120C. In another implementation, one or more controllable valves are positioned within one or more of the first fluid passage 120A, the second fluid passage 120B, and the third fluid passage 120C to allow varying of the flow rates through the fluid passages. Although the implementation illustrated in
The component cooling apparatus 100 includes a first spring mechanism 122A and second spring mechanism 122B. The first spring mechanism 122A is disposed between the manifold inlet portion 116A and the third cold plate 112C. The first spring mechanism 122A is rigidly coupled to a sidewall of the manifold inlet portion 116A and exerts a first upward force to the manifold inlet portion 116A and a first downward force to the third cold plate 112C. The terms ‘upward’ and ‘downward’ are used here for ease of explanation only and are relative to the example depicted in
The component cooling apparatus 100 of
Each of the first spring mechanism 122A, the second spring mechanism 122B, the third spring mechanism 122C, and the fourth spring mechanism 122D are coupled to a side portion of fluid manifold. In the implementation illustrated in
The third spring mechanism 122C has a rigid coupling to the sidewall of the manifold inlet portion 116A and exerts an upward force to the second cold plate 112B and a downward force to the first cold plate 112A. Similarly, the fourth spring mechanism 122D has a rigid coupling to the sidewall of the manifold outlet portion 116B and exerts an upward force to the second cold plate 112B and a downward force to the first cold plate 112A. As a result, thermal contact is maintained between the first cold plate 112A and the first TEC 110A, and between the second cold plate 112B and the second TEC 110B.
Typical thermal solutions that utilize spring mechanisms to maintain thermal contact between surfaces do not rigidly attach the spring mechanism to a surface. As a result, maintaining positioning of the spring mechanisms during assembly of the component cooler is more difficult. In addition, the spring mechanisms are more likely to become displaced during use of the component cooler when not rigidly attached to a surface. In the component cooler of
In this example, the spring mechanisms all have substantially the same widths and spring constant so that the distance between the two objects upon which the spring mechanism exerts a force is substantially the same. A spring constant defines a ratio of the force affecting a spring to the displacement caused by the spring. When two springs have the same spring constant and width, the two springs will exert substantially the same force on two objects of similar mass, creating the same distance between the two objects. For example, the first spring mechanism 122A has a width and spring constant that is substantially similar to that of the third spring mechanism 122C. As such, the distance between the manifold inlet portion 116A and the third cold plate 112C (maintained by the first spring mechanism's force), is substantially equivalent to the distance between the second cold plate 112B and the first cold plate 112A (maintained by the second spring mechanism's force). The widths and spring constant of the spring mechanisms may be selected so that, when the spring mechanisms are compressed, the distances between cold plates, and between manifold portions and cold plates, may provide various sized gaps according to desired thermal characteristics. Larger gaps, for example, provide additional airflow across surfaces (such as the cold plate surfaces) which, in some cases, results in additional cooling through greater heat dissipation relative to a smaller gap. In other cases, a smaller gap between two components (such as two cold plates) may result in additional cooling efficiency of the components.
The example component cooling apparatus 100 of
The first TEC 110A is controlled to remove an amount of heat from the second base plate 108B and transfer the heat to the first cold plate 112A. In an implementation, the amount of heat transferred by the first TEC 110A is controlled by adjusting a current provided to the first TEC 110A. The first TEC 110A provides sub-ambient temperature cooling to the second base plate 108B. The second TEC 110B is controlled to remove an amount of heat from the third base plate 108C and transfer the heat to the second cold plate 112B. The amount of heat transferred by the second TEC 110B is controlled by adjusting a current provided to the second TEC 110B. The second TEC 110B provides sub-ambient temperature cooling to the third base plate 108C. In one or more implementations, the amount of power provided to one or more of the first TEC 110A or the second TEC 110B is adapted based on monitored system parameters, such as processor activity, to control the amount of cooling provided by the respective TEC.
A fluid pump (not shown) causes a flow of a cooling fluid to enter the manifold inlet portion 116A through the fluid inlet 118A. The fluid is split to flow through each of the first fluid passage 120A, the second fluid passage 120B, and the third fluid passage 120C. The first fluid passage 120A is in thermal contact with the first cold plate 112A, the second fluid passage 120B is in thermal contact with the second cold plate 112B, and the third fluid passage 120C is in thermal contact with the third cold plate 112C. As fluid flows through the first fluid passage 120A, a portion of heat is transferred to the fluid from the first cold plate 112A. Similarly, as fluid flows through the second fluid passage 120B, a portion of heat is transferred to the fluid from the second cold plate 112B. As fluid flows through the third fluid passage 120C a portion of heat is transferred to the fluid from the third cold plate 112C. The separate flows from each of the first fluid passage 120A, the second fluid passage 120B, and the third fluid passage 120C are merged within the manifold outlet portion 116B and output from the fluid outlet 118B to one or more radiators (not shown).
For further explanation,
For further explanation,
For further explanation,
For further explanation,
For further explanation,
For further explanation,
For further explanation,
For further explanation,
For further explanation,
For further explanation,
A top surface of the second base plate 1108B is thermally coupled to a bottom surface of a fluid block 1110. The fluid block 1110 includes a fluid inlet 1112A and a fluid outlet 1112B. The fluid block 1110 includes a fluid passage extending from the fluid inlet 1112A to the fluid outlet 1112B and in thermal contact with the second base plate 1108B. During operation of the component cooling apparatus 1100, a fluid loop including a fluid pump and a radiator (not shown) is coupled between the fluid inlet 1112A and the fluid outlet 1112B via tubing or the like. The fluid pump causes a flow of a heat transfer medium, such as water, within the fluid block 1110 from the fluid inlet 1112A to the fluid outlet 1112B to facilitate removal of heat from the second base plate 1108B to the radiator.
The component cooling apparatus 1100 further includes a heat sink fin stack 1114 having a top surface coupled to a bottom surface of a cooling fan assembly 1116 configured to direct an air flow to the heat sink fin stack 1114. In an implementation, the heat sink fin stack 1114 includes a plurality of fins to facilitate removal of heat from the heat sink fin stack 1114 via the air flow. The heat sink fin stack 1114 is supported from the substrate 1102 via a support frame 1118. In an implementation, the heat sink fin stack 1114 is substantially larger than either of the first base plate 1108A or the second base plate 1108B.
The component cooling apparatus 1100 further includes multiple heat pipes 1120A, 1120B, 1120C, and 1120D. Each of the heat pipes 1120A, 1120B, 1120C, and 1120D has a first end disposed between and in thermal contact with the first base plate 1108A and the second base plate 1108B, and a second end in thermal contact with the heat sink fin stack 1114. Each of the heat pipes 1120A, 1120B, 1120C, and 1120D include a middle portion between the first end and the second end that is external to each of the base plates 1108A, 1108B and the heat sink fin stack 1114.
In one or more implementations, each of the heat pipes 1120A, 1120B, 1120C, and 1120D are formed in a half-loop configuration. In the implementation illustrated in
The example component cooling apparatus 1100 of
In another implementation the component cooling apparatus 1100 further includes a TEC positioned between and in thermal contact with the second base plate 1108B and the fluid block 1110. In another implementation, the component cooling apparatus 1100 further includes a TEC positioned between and in thermal contact with the heat sink fin stack 1114 and the cooling fan assembly 1116.
The iGPU 1207 and dGPU 1208 each include one or more video cores 1212. A video core 1212 is a discrete processing unit, core, or other unit of hardware resources dedicated to encoding and decoding video data. For example, each video core 1212 facilitates video encoding or decoding operations such as decoding streaming video content, encoding video for video conferencing applications, encoding video files for later playback, and the like. In some implementations, the video core 1212 implements particular hardware architectures or configurations for video encoding and decoding, such as Video Core Next (VCN).
The iGPU 1207 and dGPU 1208 also each include one or more compute units 1214. Each compute unit 1214 includes one or more cores that share a local cache, allowing for parallel processing and cache access for each core within a given compute unit 1214. The compute units 1214 facilitate various calculations and processing jobs submitted to the iGPU 1207 and dGPU 1208, including rendering operations, machine learning operations, and the like.
The iGPU 1207 and dGPU 1208 also each include a display engine 1216. Each display engine 1216 manages the presentation of video or image content to a display of the computing device 1200 (e.g., an internal mobile device display or an external display coupled to a display interface 1210). In some implementations, the display engines 1216 implement display core technology such as Display Core Next (DCN) and the like. The APU 1202 also includes an audio co-processor (ACP) 1206. The ACP 1206 is a core, processor, or other allocation of hardware components dedicated to audio encoding and decoding.
The computing device 1200 also includes memory 1220 such as Random Access Memory (RAM). Stored in memory 1220 is an operating system 1222 and a voltage configuration module 1224. The operating system 1222 and voltage configuration module 1224 in the example of
The voltage configuration module 1224 is a module for controlling the voltage allocated to the APU 1202 and dGPU 1208. For example, the voltage configuration module 1224 implements SmartShift technology to allocate voltage in order to increase performance for particular applications. Depending on the particular workload executed in the computing device 1200, the voltage configuration module 1224 increases or decreases the voltage used by the APU 1202 and dGPU 1208. As an example, for a workload that relies on the dGPU 1208 heavily, such as complex graphics rendering, the voltage configuration module 1224 will increase the voltage to the dGPU 1208. As another example, for a workload that relies on the APU 1202 more than the dGPU 1208 such as audio encoding, or when the computing device 1200 is in a low power consumption state, the voltage configuration module 1224 will increase the voltage to the APU 1202. In some implementations, an increase to the voltage of one component (e.g., to the APU 1202 and dGPU 1208) will cause or be performed in response to a decrease in the voltage of the other component.
In some implementations, a modification to the voltage of a given component will cause or be performed in response to a modification in operating frequency of the given component. For example, assume that a command or request is issued to increase the operating frequency of the dGPU 1208 in response to a rendering job being submitted to the dGPU 1208. The voltage configuration module 1224 will then increase the voltage provided to the dGPU 1208 so that the dGPU 1208 is able to operate at the increased frequency. In some implementations, the frequency of a given component is defined according to a frequency voltage curve. A frequency voltage curve defines a relationship between the frequency of a component and its corresponding voltage. In other words, the frequency voltage curve defines, for a given frequency, a corresponding voltage for the component.
One skilled in the art will appreciate that the voltage configuration module 1224 operates within various constraints for voltages in the computing device 1200. For example, in some implementations, the APU 1202 and dGPU 1208 have defined minimum and maximum safe voltages. One skilled in the art will appreciate that the particular voltage limits for the APU 1202 and dGPU 1208 are dependent on particular cooling and thermal solutions implemented in the computing device 1200.
One skilled in the art will also appreciate that the approaches described herein for a component cooler provide for increased cooling capabilities for the APU 1202 and dGPU 1208, allowing for increased maximum safe operational voltages for both the APU 1202 and dGPU 1208. Thus, a computational performance increase is achieved though the improved cooling approaches described herein.
Various implementations utilize TEC devices and heat exchanger technologies to decrease inlet temperatures into critical cooling zones. Lower inlet temperatures typical result in cooler components and increased performance. For example, a graphics card (e.g., GPU) cooling zone benefits from reduced temperatures as lower temperatures typically result in higher performance and increased longevity of the graphics card. In some implementations, the component cooler utilizes one or more thermoelectric coolers (TECs) placed at the airflow exit of a radiator or other heat exchanger to provide sub-ambient cooling to the airflow as it passes over the component cooler. The sub-cooled airflow is directed over the component cooler and TEC to one or more downstream components, such as the GPU. The sub-cooled air flow consequently further cools the downstream components. The increased cooling of the GPU results in greater performance.
The chassis 1302 of the computing device 1300 further includes a controller 1316 configured to control an amount of power provided to the TEC device 1308 and thereby controlling the heat removal capabilities of the device TEC device 1308. In an implementation, the controller 1316 is a separate hardware or software component of the computing device 1300. In another implementation, the functions of the controller 1316 are integrated with and performed by the CPU/APU 1304. In still another implementation, the functions of the controller 1316 are integrated with and performed by a CPU/APU system management component (SMU). The chassis 1302 further includes a fan 1318 configured to direct an airflow 1320 from an intake port on the front of the chassis 1302 to an exit port on the back of the chassis 1302.
In an implementation, the TEC device 1308 cools the airflow 1320 passing over the component cooler 1306 from a first temperature to a second temperature (e.g., a sub-ambient temperature), and the cooled airflow 1320 at the second temperature further passes over the GPU 1310. As a result, the GPU 1310 is further cooled by the airflow 1320.
In some implementations, the CPU/APU 1304 is determined to be operating at a relatively low power and thus the heat generated by the CPU/APU 1304 is relatively low and is not a significant contributor of heat to the component cooler 1306. As a result, the airflow 1320 passing over the component cooler 1306 is not significantly affected by the heat generated by the CPU/APU 1304. The TEC device 1308 controlled to operate at a power level so as to further cool the component cooler 1306 and the airflow 1320 to a sub-ambient temperature. Although the implementation illustrated in
In another implementation, the GPU 1310 has another component cooler coupled thereto, and the component cooler 1306 of the CPU/APU 1304 and the other component cooler of the GPU 1310 are connected together in a closed fluid loop including a heat transfer medium with the heat exchanger 1312. In this implementation, the TEC device 1308 of the CPU/APU 1304 cools the heat transfer medium in the coolant loop so that both the CPU/APU 1304 and the GPU 1310 are cooled by the heat transfer fluid.
The chassis 1402 of the computing device 1300 further includes a first heat exchanger 1404A having a first surface coupled to a first intake fan 1406A near a front of the chassis 1402, and a second surface thermally coupled to a TEC device 1408. In one or more implementations, the first heat exchanger 1404A is an air-to-liquid radiator. The first heat exchanger 1404A is further connected to a second heat exchanger 1404B via a closed loop 1410 for circulating a heat transfer medium between the first heat exchanger 1404A and the second heat exchanger 1404B. The chassis 1402 further includes a second intake fan 1406B coupled to the second heat exchanger 1404B.
The chassis 1402 of the computing device 1300 further includes a controller 1412 configured to control an amount of power provided to the TEC device 1408 and thereby controlling the heat removal capabilities of the TEC device 1408. In an implementation, the controller 1412 is a separate hardware or software component of the computing device 1400. In another implementation, the functions of the controller 1412 are integrated with and performed by the CPU/APU 1304. In still another implementation, the functions of the controller 1412 are integrated with and performed by a CPU/APU system management component (SMU).
During operation, the first intake fan 1406A directs a first airflow 1414A from an intake port on the front of the chassis 1402 to an exit port on the back of the chassis 1402. The TEC device 1408 transfers heat from the first airflow 1414A to the first heat exchanger 1404A, and a portion of the heat received by the first heat exchanger 1404A is transferred to the second heat exchanger 1404B by the heat transfer medium of the closed loop 1410. As a result, the first airflow 1414A is cooled from a first temperature to a second temperature (e.g., a sub-ambient temperature) and the cooled first airflow 1414A passes over the component cooler 1306 and CPU/APU 1304 to cool the CPU/APU 1304. The cooled first airflow 1414A further passes over the GPU 1310 to cool the GPU 1310. The second intake fan 1406B directs a second airflow 1414B from the front of the chassis through the second heat exchanger 1404B to the back of the chassis 1402 to remove a portion of the heat received by the second heat exchanger 1404B from the first heat exchanger 1404A. Accordingly, both the CPU/APU 1304 and the GPU 1310 are cooled by the sub-cooled first airflow 1414A. Although the implementation illustrated in
In another implementation, the GPU 1310 includes another component cooler coupled thereto, and the component cooler 1306 of the CPU/APU 1304 and the other component cooler of the GPU 1310 are connected together in a closed fluid loop including a heat transfer medium with one or more of the first heat exchanger 1404A and the second heat exchanger 1404B. In this implementation, the TEC device 1308 thermally coupled to the first heat exchanger 1404A cools the heat transfer medium in the coolant loop so that both the CPU/APU 1304 and the GPU 1310 are cooled by the heat transfer fluid.
For further explanation,
Exemplary implementations of the present disclosure are described largely in the context of a fully functional computer system for a component cooler for computing devices. Readers of skill in the art will recognize, however, that the present disclosure also can be embodied in a computer program product disposed upon computer readable storage media for use with any suitable data processing system. Such computer readable storage media can be any storage medium for machine-readable information, including magnetic media, optical media, or other suitable media. Examples of such media include magnetic disks in hard drives or diskettes, compact disks for optical drives, magnetic tape, and others as will occur to those of skill in the art. Persons skilled in the art will immediately recognize that any computer system having suitable programming means will be capable of executing the steps of the method of the disclosure as embodied in a computer program product. Persons skilled in the art will also recognize that, although some of the exemplary implementations described in this specification are oriented to software installed and executing on computer hardware, nevertheless, alternative implementations implemented as firmware or as hardware are well within the scope of the present disclosure.
The present disclosure can be a system, a method, and/or a computer program product. The computer program product can include a computer readable storage medium (or media) having computer readable program instructions thereon for causing a processor to carry out aspects of the present disclosure.
The computer readable storage medium can be a tangible device that can retain and store instructions for use by an instruction execution device. The computer readable storage medium can be, for example, but is not limited to, an electronic storage device, a magnetic storage device, an optical storage device, an electromagnetic storage device, a semiconductor storage device, or any suitable combination of the foregoing. A non-exhaustive list of more specific examples of the computer readable storage medium includes the following: a portable computer diskette, a hard disk, a random access memory (RAM), a read-only memory (ROM), an erasable programmable read-only memory (EPROM or Flash memory), a static random access memory (SRAM), a portable compact disc read-only memory (CD-ROM), a digital versatile disk (DVD), a memory stick, a floppy disk, a mechanically encoded device such as punch-cards or raised structures in a groove having instructions recorded thereon, and any suitable combination of the foregoing. A computer readable storage medium, as used herein, is not to be construed as being transitory signals per se, such as radio waves or other freely propagating electromagnetic waves, electromagnetic waves propagating through a waveguide or other transmission media (e.g., light pulses passing through a fiber-optic cable), or electrical signals transmitted through a wire.
Computer readable program instructions described herein can be downloaded to respective computing/processing devices from a computer readable storage medium or to an external computer or external storage device via a network, for example, the Internet, a local area network, a wide area network and/or a wireless network. The network can include copper transmission cables, optical transmission fibers, wireless transmission, routers, firewalls, switches, gateway computers and/or edge servers. A network adapter card or network interface in each computing/processing device receives computer readable program instructions from the network and forwards the computer readable program instructions for storage in a computer readable storage medium within the respective computing/processing device.
Computer readable program instructions for carrying out operations of the present disclosure can be assembler instructions, instruction-set-architecture (ISA) instructions, machine instructions, machine dependent instructions, microcode, firmware instructions, state-setting data, or either source code or object code written in any combination of one or more programming languages, including an object oriented programming language such as Smalltalk, C++ or the like, and conventional procedural programming languages, such as the “C” programming language or similar programming languages. The computer readable program instructions can execute entirely on the user's computer, partly on the user's computer, as a stand-alone software package, partly on the user's computer and partly on a remote computer or entirely on the remote computer or server. In the latter scenario, the remote computer can be connected to the user's computer through any type of network, including a local area network (LAN) or a wide area network (WAN), or the connection can be made to an external computer (for example, through the Internet using an Internet Service Provider). In some implementations, electronic circuitry including, for example, programmable logic circuitry, field-programmable gate arrays (FPGA), or programmable logic arrays (PLA) can execute the computer readable program instructions by utilizing state information of the computer readable program instructions to personalize the electronic circuitry, in order to perform aspects of the present disclosure.
Aspects of the present disclosure are described herein with reference to flowchart illustrations and/or block diagrams of methods, apparatus (systems), and computer program products according to implementations of the disclosure. It will be understood that each block of the flowchart illustrations and/or block diagrams, and combinations of blocks in the flowchart illustrations and/or block diagrams, can be implemented by computer readable program instructions.
These computer readable program instructions can be provided to a processor of a general purpose computer, special purpose computer, or other programmable data processing apparatus to produce a machine, such that the instructions, which execute via the processor of the computer or other programmable data processing apparatus, create means for implementing the functions/acts specified in the flowchart and/or block diagram block or blocks. These computer readable program instructions can also be stored in a computer readable storage medium that can direct a computer, a programmable data processing apparatus, and/or other devices to function in a particular manner, such that the computer readable storage medium having instructions stored therein includes an article of manufacture including instructions which implement aspects of the function/act specified in the flowchart and/or block diagram block or blocks.
The computer readable program instructions can also be loaded onto a computer, other programmable data processing apparatus, or other device to cause a series of operational steps to be performed on the computer, other programmable apparatus or other device to produce a computer implemented process, such that the instructions which execute on the computer, other programmable apparatus, or other device implement the functions/acts specified in the flowchart and/or block diagram block or blocks.
The flowchart and block diagrams in the Figures illustrate the architecture, functionality, and operation of possible implementations of systems, methods, and computer program products according to various implementations of the present disclosure. In this regard, each block in the flowchart or block diagrams can represent a module, segment, or portion of instructions, which includes one or more executable instructions for implementing the specified logical function(s). In some alternative implementations, the functions noted in the block can occur out of the order noted in the figures. For example, two blocks shown in succession can, in fact, be executed substantially concurrently, or the blocks can sometimes be executed in the reverse order, depending upon the functionality involved. It will also be noted that each block of the block diagrams and/or flowchart illustration, and combinations of blocks in the block diagrams and/or flowchart illustration, can be implemented by special purpose hardware-based systems that perform the specified functions or acts or carry out combinations of special purpose hardware and computer instructions.
It will be understood from the foregoing description that modifications and changes can be made in various implementations of the present disclosure. The descriptions in this specification are for purposes of illustration only and are not to be construed in a limiting sense. The scope of the present disclosure is limited only by the language of the following claims.