The invention relates to an attachment for a heat exchanger, in particular to a heat exchanger assembly for an electronic control unit, applicable in automotive field.
Electronic control units are known to require thermal management. Integrated circuits, or other electronic or electric components, generate heat during operation. In case of integrated circuits, the power is dissipated on a small surface. The heat generated this way needs to be effectively evacuated, especially when the components operate under high loads. High performance units require dedicated cooling devices to enable their effective operation. One known way of addressing the issue is to utilize air for direct cooling of the heat sources.
Automotive industry increasingly depends on high performance electronic control units to ensure safe and effective operation of vehicles. More and more of electronic control units, in various forms and configurations, are utilized to perform functions such as controlling the vehicle's battery systems, handling the driver assistance systems or performing autonomous driving function.
There is a need to provide an effective heat exchange solution, which could be used for thermal management of an electronic control unit, in particular one used in a vehicle.
The object of the invention is, among others, an attachment for a heat exchange plate, comprising an attachment base plate extending within a base plane, having a bottom side and a top side between which a thickness of the attachment base plate extends, with a plurality of contact portions extending away from the top side independently from each other, wherein the attachment base plate is of rectangular, elongated outline extending along an attachment longitudinal axis and an attachment lateral axis, the extension along the attachment longitudinal axis being predominant, wherein at least one contact portion has a different longitudinal length than another contact portion, the longitudinal length being measured along the attachment longitudinal axis.
In one embodiment, the plurality of contact portions are made of a solid material.
In one embodiment, the attachment is made of a material of high thermal conductivity.
In one embodiment, the plurality of contact portions extend from the top side perpendicularly to the base plane.
In one embodiment, the top side has a distancing section between neighboring contact portions, the distancing section maintaining the thickness.
In one embodiment, at least one contact portion extends from the attachment base plate farther than another contact portion.
In one embodiment, the contact portions are connected to the attachment base plate by means of an adhesive.
In one embodiment, the attachment base plate and the contact portions are a single machined piece.
In one embodiment, at least one contact portion has a different lateral length than another contact portion, the lateral length being measured along the attachment lateral axis.
In one embodiment, at least one contact portion has a rectangular outline.
In one embodiment, at least one contact portion has a rounded outline.
In one embodiment, the attachment is made of metal.
In one embodiment, the contact portions are connected to the attachment base plate by brazing.
In one embodiment, the contact portions have flat top contact surface.
In one embodiment, the top side of the attachment base plate and the flat top contact surfaces of the contact portions are connected by side walls of the contact portions, the side walls being perpendicular to the top side and the flat top contact surfaces.
In one embodiment, the attachment base plate has connection section adapted for clinching.
Another object of the invention is a heat exchanger comprising a first fluid channel for a heat exchange fluid, having a channel wall formed by a heat exchange plate, an attachment, including an attachment base plate extending within a base plane, having a bottom side and a top side between which a thickness of the attachment base plate extends, a plurality of contact portions extending away from the top side independently from each other, wherein the attachment is attached to the channel wall by the bottom side, wherein the attachment base plate is of rectangular, elongated outline extending along an attachment longitudinal axis and an attachment lateral axis, the extension along the attachment longitudinal axis being predominant, wherein at least one contact portion has a different longitudinal length than another contact portion, the longitudinal length being measured along the attachment longitudinal axis.
In one embodiment, the top side of the attachment base plate has a distancing section between the contact portions, the distancing section maintaining the thickness of the attachment base plate, wherein the attachment base plate is clinched to the channel wall at the distancing section.
The present invention will be described in greater detail below with reference to the drawings. In the drawings:
In order to simplify the description of the invention, a Cartesian reference is formed (o, x, y, z), and the direction o-x is defined as being the direction of the length, o-y is the direction of the height, and o-z is the direction of the width, as shown in
The heat exchanger 200 can further include a terminal tube 220 for a heat exchange fluid, connected fluidically to the primary tube 210. The primary tube 210 and the terminal tube 220 can be connected by one or more interconnectors 260 enabling fluid flow therebetween.
The heat exchanger assembly 100 includes at least a first heat source module 410. In the embodiment shown in
The first heat source module 410 abuts the primary tube 210, so that heat from the first heat source module 410 can be dissipated to the primary tube 210.
In the shown embodiment, the first and second heat source modules 410, 420 abut the primary tube 210. The terminal tube 220 is abutted by the third and fourth heat source modules 430, 440. In other words, the primary tube 210 is sandwiched between the first and second heat source modules 410, 420, while the terminal tube 220 is sandwiched between the third heat source module 430 and the fourth heat source module 440. By the term “sandwiched” it is meant that the primary tube 210 and terminal tube 220 are in contact with and are located between respective heat source modules, taking into account presence of any thermal paste that could be used between their surfaces to improve heat exchange.
In the shown embodiment, the primary tube 210 and the terminal tube 220 extend predominantly along axis X and to a lesser degree along axis Z, meaning their length is greater than their width. Their height is substantially smaller than the two other dimensions.
The first heat source module 410 and the third heat source module 430 similarly extend predominantly along axis X and to a lesser degree along axis Z, meaning their length is greater than their width. Their height is substantially smaller than the two other dimensions.
The second heat source module 420 and the fourth heat source module 440 extend predominantly along axis Y and to a lesser degree along axis Z, meaning their width is greater than their length (the opposite arrangement is also envisaged). Their height is substantially smaller than the two other dimensions.
It should be noted that there can be a plurality of the second heat source modules 420 arranged along the primary tube 210, as well as a plurality of fourth heat source modules 440 arranged along the terminal tube 220. Similarly, a plurality of the first heat source modules 410 and the third heat source modules 430 could be arranged along the primary and terminal tubes 210, 220, depending on the configuration of the unit.
The second heat source module 420 includes at least one second heat source 421.
In the shown embodiment, the second heat source module 420 is in form of a cartridge 422, as it will be shown in detail in
The third heat source module 430 includes at least one third heat source 431. In the shown embodiment, the third heat source module 430 includes a plurality of third heat sources 431. Preferably, the plurality of the third heat sources 411 extends parallel to the predominant extension axis of the terminal tube 220 so that this single terminal tube 220 can address the heat exchange needs of the whole third heat source module 430. In one embodiment, the third heat source module 430 is a PCB board. The third heat sources 431 can be integrated circuits.
The fourth heat source module 440 includes at least one fourth heat source 441. In one embodiment, the fourth heat source module 440 is in form of a cartridge 422 in which a PCB board with at least one integrated circuit is located.
The chassis 500 preferably includes a housing 501, which can define an internal volume 502. The first heat source module 410 can be located within the internal volume 502. Preferably, the third heat source module 430 is also located inside the internal volume 502. The chassis 500 with the housing 501 allows to have the first and third heat source modules 410, 430 in form of PCBs without other protective arrangements, as the housing 501 can be configured to constitute a standalone enclosure protecting the internal components from outside detrimental factors as moisture, debris or moving elements of the vehicle. The housing 501 can include housing apertures 511 enabling connectors (not shown) of the first and third heat source modules 410, 430 to be exposed so that they can be connected to external signal and/or power lines, as well as connection between the second and fourth heat source modules 420, 440 to the components located inside of the housing 501.
In the shown embodiment, the primary tube 210 is located externally with respect to the housing 501. The terminal tube 220 can be located externally with respect to the housing 501 as well. Consequently, any heat source modules external to the housing 501 can also be cooled by the heat exchanger 200 of the heat exchanger assembly 100. In particular, the second heat source module 420 can be attached to the chassis 500 externally with respect to the housing 501. Similarly, the fourth heat source module 440 can be attached to the chassis 500 externally with respect to the housing 501.
The housing 501 can have a primary separation wall 504 between the primary tube 210 and the first heat source module 410. As explained in detail in relation to further figures, the heat exchanger 200 can include attachments 300 attached to and protruding substantially perpendicularly from the primary tube 210 and/or the terminal tube 220. In such case, the primary separation wall 504 can include at least one primary attachment opening 505 through which such attachment 300 protrudes. In the shown embodiment, there are two attachments 300 placed on the primary tube 210. Consequently, there are two primary attachment openings 505 as well. The two primary attachment openings 505 can be of different sizes to accommodate differently sized attachments 300.
In one embodiment, the housing 501 has an interconnector cut-out 510 at least partially enveloping one or more interconnectors 260 extending between the primary tube 210 and the terminal tube 220. In other words, the interconnector cut-out 510 constitutes a depression within the housing 501 in which said one or more interconnectors 260 can be placed. This allows improving compactness of the assembly.
As shown in
The housing 501 can have a terminal separation wall 507 between the terminal tube 220 and the third heat source module 430. The terminal separation wall 507 can include one or more terminal attachment openings 508 through which any attachment 300 of the terminal tube 220 can protrude. The terminal attachment openings 508 can be of different sizes to accommodate differently sized attachments 300.
The housing 501 can include housing attachment points 512 to enable direct fixation of the primary tube 210 and terminal tube 220 if needed. For example, the housing attachment points 512 can be in form of a base with opening for a screw, while the primary and terminal tubes 210, 220 can have corresponding tube attachment tabs 202 (as shown in
The first and second flat plates 211, 221 and the first and second shaped plate 212, 222 include fluid openings 250 (as better seen in
The heat exchanger 200 can include an inlet spigot 251 and an outlet spigot 252. Preferably, the inlet spigot 251 and the outlet spigot 252 are attached to the first flat plate 211.
Preferably, the terminal tube 220 includes one or more attachments 300 with a plurality of contact portions 305 exposed to the plurality of third heat sources 431. The attachments can be mounted on the terminal tube 220 adjacent to the second fluid channel 223.
In the shown embodiment, the first shaped plate 212 and the second shaped plate 222 face each other.
In the shown example, the third shaped plate 232 faces the first shaped plate 212 and faces away from the second shaped plate 222.
The primary tube 210 can include collars to receive the inlet and outlet spigots 251, 252, in particular flat tube collars 261 located on the first flat tube 210, which in such case would be facing the inlet and outlet spigots 251, 252.
The primary tube 210 and the terminal tube 220 can include collars to receive the interconnectors 260, in particular the first and second shaped plates 211, 221 can include shaped plate collars 262, which in such case would be facing the interconnectors 260.
As can be seen in
Preferably, one end of the first fluid channel 213 has two fluid openings 250 for enabling the fluid flow to the primary tube 210, while the other end of the first fluid channel 213 has two fluid openings 250 for enabling the fluid flow out of the primary tube 210 (on both sides of the primary tube 210). In such case, each pair of fluid openings 250 includes one fluid opening 250 in the first flat plate 211 and one fluid opening 250 in the first shaped plate 212.
In the shown embodiment, the first fluid channel 213 forms a U-flow path having a first arm 214 and a second arm 215. The fluid openings 250 can be arranged at the opposite ends of the U-flow path.
In relation to
The first arm 214 can be split into at least two parallel sub-conduits 216. The second arm 215 can be formed by a single conduit 217. The split can be used to help balance the flow in the plate. It can also focus the flow to specific got spots to achieve better heat transfer coefficient.
The first arm 214 can be separated from the second arm 215 by a first wall 253 extending away from the ends of the U-flow path. The at least two sub-conduits 216 can be separated from each other by a second wall 254 extending away from the ends of the U-flow path. The first wall 253 can extend farther away from the ends of the U-flow path than the second wall 254. This as well can help management of the heat exchange as explained above. Preferably, the at least two parallel sub-channels 216 terminate in common fluid openings 250.
In the shown embodiment, the first shaped plate 212 can include a stamped depression 218 forming together with the surface of the first flat plate 211 the first fluid channel 213. The stamped depression 218 can have a flat surface at the bottom, located away from the first flat plate 211.
Preferably, one end of the second fluid channel 223 has two fluid openings 250 for enabling the fluid flow to the terminal tube 220, while the other end of the second fluid channel 223 has two fluid openings 250 for enabling the fluid flow out of the terminal tube 220. In such case, each pair of fluid openings 250 includes one fluid opening 250 in the second flat plate 221 and one fluid opening 250 in the second shaped plate 222.
In the shown embodiment, the second fluid channel 223 forms a U-flow path having a first arm 214 and a second arm 215. The fluid openings 250 can be arranged at the opposite ends of the U-flow path.
The second fluid channel 223 can form a U-flow path having a first arm 214 and a second arm 215. The fluid openings 250 can be arranged at the opposite ends of the U-flow path.
The first arm 214 can be split into at least two parallel sub-conduits 216. The second arm 215 can be formed by a single conduit 217.
The first arm 214 can be separated from the second arm 215 by a first wall 253 extending away from the ends of the U-flow path. The at least two sub-conduits 216 can be separated from each other by a second wall 254 extending away from the ends of the U-flow path. The first wall 253 can extend farther away from the ends of the U-flow path than the second wall 254. Preferably, the at least two parallel sub-channels 216 terminate in common fluid openings 250.
In the shown embodiment, the second shaped plate 222 can include a stamped depression 218 forming together with the surface of the second flat plate 221 the second fluid channel 223. The stamped depression 218 can have a flat surface at the bottom, located away from the second flat plate 221.
In the shown embodiment, the second shaped plate 222 includes fluid openings 250 for the fluid to enable fluid flow to and from the terminal tube 220, while the second flat plate 221 lacks any fluid openings 250 for the fluid.
As described above, an inlet spigot 251 and an outlet spigot 252 for the heat exchange fluid can be attached to the openings 250 of the primary tube 210.
The attachment 300 can have a single contact portion 305 or a plurality of contact portions 305 extending away from a top side 303, preferably independently from each other. By a contact portion 305 it is here understood a dedicated part of the attachment 300 intended to be in contact with a specific heat source so that heat can be exchanged therebetween in a facilitated manner. It is intended for the contact portion 305 to receive bulk of the energy from the heat source as opposed to sections of the attachment 300 where contact portion 305 is not present.
As shown in
In one embodiment, the attachment base plate 301 and the contact portions 305 are a single machined piece. Alternatively, the contact portions 305 can be connected to the attachment base plate 301 by means of an adhesive. Preferably, the plurality of contact portions 305 are made of a solid material. Preferably, the attachment 300 is made of a material of high thermal conductivity. Preferably, the attachment 300 and the contact portions 305 are made of metal. In such case, the contact portions 305 can be connected to the attachment base plate 301 by brazing.
In the shown embodiment, there is a distancing section 304 between the contact portions 305. Here, the distancing section 304 is a region of the base plate 301, in particular of its top side 303, where the contact portions 305 are not present. The distancing section 304 can allow to reduce the amount of material needed for the attachment 300 in areas more remote with respect to heat sources than the contact portions 305. The distancing sections 304 however, in particular the region of the attachment base plate 301 at its bottom side 302, can contribute to secure connection of the attachment 300 to any heat exchange plate 201 (in these cases a first flat plate 211, a first shaped plate 212, a second flat plate 221, a second shaped plate 222), as sufficient contact surface between the attachment 300 and said heat exchange plate 201 is ensured.
In any case, it is preferable for the contact portions 305 to have a contact surface adapted for intermediate surface of a heat source that they are intended to face to maximize heat exchange efficiency. Preferably, the contact portions 305 have flat top contact surface 306, especially when they are matched with integrated circuits, which themselves tend to have flat surfaces.
Any contact portion 305 can have a rectangular outline, e.g. square outline (as shown in
In one embodiment, at least one contact portion 305 extends from the attachment base plate 301 farther than another contact portion 305. In other words, one contact portion 305 can have different height than another contact portion 305.
In one embodiment, at least one contact portion 305 has a different longitudinal length Lg than another contact portion 305, the longitudinal length Lg being measured along the attachment longitudinal axis L1.
The top side 303 of the attachment base plate 301 and the flat top contact surfaces 306 of the contact portions 305 can be connected by side walls 307 of the contact portions 305, the side walls 307 being perpendicular to the top side 303 and the flat top contact surfaces 306. Alternatively, the side walls 307 can be oblique with respect to the top side 303 and/or the flat top contact surfaces 306.
Other variations to the disclosed embodiments can be understood and effected by those skilled in the art in practicing the claimed invention, from a study of drawings, the disclosure, and the appended claims. The mere fact that certain measures are recited in mutually different dependent claims does not indicate that a combination of these measures cannot be used to the advantage.
Number | Date | Country | |
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63385459 | Nov 2022 | US |