The present application claims priority from European Patent Application No. 19315108.1, filed on Aug. 30, 2019, the entirety of which is incorporated herein by reference.
The present technology relates generally to heat exchanger stacks as well as to methods for mounting heat exchanger panels to a rack structure.
Buildings are often equipped with heat management systems to regulate heat within the building. In certain types of buildings, heat management may be a particularly crucial consideration due to the intended use of the building. For instance, data centers, which store an extensive amount of heat-generating electronic equipment, typically implement a sizable heat management system to evacuate heat from the data center.
For example, data centers are often equipped with dry coolers installed on the roof of the building that houses the data center. Heated fluid (e.g., heated water) extracted from the data center (e.g., collected at the server level) is circulated to the dry coolers where the fluid transfers its heat into the ambient air pulled into the dry coolers. The heated air is then discharged into the ambient air and the now cooled fluid is recirculated back into the data center and the process is repeated.
It has been proposed to build a dry cooler tower including vertical dry cooler stacks, whereby various dry coolers are stacked vertically one on top of the other such that their respective fan assemblies are oriented to discharge heated air horizontally instead of vertically as is more typical. This has been shown to minimize recycling of heated air by adjacent dry coolers as the heated air is discharged into a common zone that is surrounded by the dry cooler stacks. However, such dry cooler towers can be difficult to assemble, as a rack structure has to be provided and the different components of each dry cooler separately mounted thereto, including the heat exchanger panels of the dry coolers which are typically heavy (e.g., 300-400 kg) and therefore require heaving machinery to manipulate. In addition, as the heat exchanger panels are of a considerable size, installing the heat exchanger panels onto (or dismounting the heat exchanger panels from) the rack structure usually requires a significant amount of space to be kept clear on the side of the rack structure from which it is intended to install/remove the heat exchanger panels. Thus, while the dry cooler stacks may not be too big in size, they may still have a significant footprint in the environment in which they are installed as additional space has to be kept clear to allow the installation or removal of the heat exchanger panels.
Thus there is a desire for a heat exchanger stack and a method for mounting a heat exchanger panel to a rack structure that alleviates at least in part some of these drawbacks.
It is an object of the present technology to ameliorate at least some of the inconveniences present in the prior art.
According to one aspect of the present technology, there is provided a heat exchanger stack. The heat exchanger stack includes a rack structure and a plurality of heat exchangers supported by the rack structure. The rack structure includes: a plurality of vertical legs; a plurality of laterally-extending horizontal members extending between and interconnecting laterally-adjacent ones of the vertical legs; a plurality of longitudinally-extending horizontal members extending between and interconnecting longitudinally-adjacent ones of the vertical legs; a plurality of lower wheel guiding members, each lower wheel guiding member having a horizontal portion extending horizontally and an angled portion that is angled relative to the horizontal portion; and a plurality of upper wheel guiding members vertically spaced from the lower wheel guiding members, each of the upper wheel guiding members extending at least partly horizontally. The heat exchangers are disposed above one another. Each heat exchanger includes a fan assembly mounted to the rack structure and a heat exchanger panel mounted to the rack structure. The fan assembly includes a fan impeller rotatable about a fan rotation axis extending horizontally. The heat exchanger panel includes: a frame having an upper end and a lower end opposite the upper end; a tubing arrangement supported by the frame and configured to circulate fluid therein, the tubing arrangement having an inlet and an outlet; a plurality of fins in thermal contact with the tubing arrangement, the fins being spaced apart from one another for air to flow therebetween and through the heat exchanger panel; and a plurality of wheels mounted to the frame. Each of the wheels is rotatable about a respective axis extending generally laterally. The wheels are configured to engage respective ones of the lower and upper wheel guiding members of the rack structure for guided mounting of the heat exchanger panel on the rack structure. The wheels include: an upper set of wheels mounted to the upper end of the frame, the upper set of wheels including a first upper wheel and a second upper wheel spaced apart from one another; and a lower set of wheels mounted to the lower end of the frame, the lower set of wheels including a first lower wheel and a second lower wheel spaced apart from one another. Each upper wheel engages a corresponding upper wheel guiding member and each lower wheel engages the horizontal portion of a corresponding lower wheel guiding member so that the heat exchanger panel is translatable horizontally.
In some embodiments, the first upper wheel and the second upper wheel are spaced apart from one another by a first distance, and the first lower wheel and the second lower wheel are spaced apart from one another by a second distance. The first distance is different from the second distance.
In some embodiments, the first distance is greater than the second distance.
In some embodiments, a ratio of the first distance over the second distance is between 1.1 and 1.5.
In some embodiments, for each heat exchanger panel: the frame has a first lateral end and a second lateral end; the first and second upper wheels are spaced laterally outwardly from the first and second lateral ends of the frame; and the first and second lower wheels are disposed laterally inwardly from the first and second lateral ends of the frame.
In some embodiments, for each heat exchanger panel, the frame includes: an upper frame member defining the upper end of the frame, the upper frame member defining a channel extending laterally, and a lower frame member defining the lower end of the frame, the lower frame member defining a channel extending laterally. For each heat exchanger panel, the heat exchanger panel also includes a plurality of wheel mounts for mounting at least one of the wheels to the frame. Each of the wheel mounts includes: an elongated rail inserted within the channel defined by one of the upper and lower frame members, the elongated rail being removably connected to the one of the upper and lower frame members; and at least one mounting bracket interconnecting one of the at least one of the wheels to the elongated rail.
In some embodiments, the elongated rail is connected to the one of the upper and lower frame members by a plurality of fasteners extending from a front face to a rear face of the one of the upper and lower frame members.
In some embodiments, each of the at least one mounting bracket has a first portion extending parallel to the elongated rail and a second portion extending perpendicularly to the first portion, the one of the at least one of the wheels being connected to the second portion.
In some embodiments, at least one of the wheel mounts includes at least one lifting bracket; each of the at least one lifting bracket is connected to a corresponding one of the at least mounting bracket; and each of the at least one lifting bracket defines an opening for connecting a lifting device to the heat exchanger panel and lift the heat exchanger panel therefrom.
According to another aspect of the present technology, there is provided a method for mounting a heat exchanger panel to a rack structure. The method includes: lifting the heat exchanger panel via lifting brackets connected to a frame of the heat exchanger panel; lowering the heat exchanger panel until lower wheels mounted to a lower end of the frame of the heat exchanger panel are received and supported by respective lower wheel guiding members of the rack structure; rolling the heat exchanger panel downwardly by engagement of the lower wheels with the lower wheel guiding members, a portion of each of the lower wheel guiding members being inclined to guide the lower wheels downwardly; supporting upper wheels mounted to an upper end of the frame on upper wheel guiding members of the rack structure that are disposed vertically higher than the lower wheel guiding members; and translating the heat exchanger panel horizontally on the lower and upper wheel guiding members into a final position of the heat exchanger panel whereby the heat exchanger panel is in an inclined position such that a longitudinal axis of the heat exchanger panel, extending from the upper end to the lower end of the frame, is angled relative to a vertical axis.
In some embodiments, the method also includes, prior to lifting the heat exchanger panel, connecting the lifting brackets to a hoist mounted to an upper part of the rack structure in order to lift the heat exchanger panel via the hoist.
In some embodiments, the method also includes, prior to lowering the heat exchanger panel, affixing upper and lower extension portions of respective ones of the upper and lower guiding members to the rack structure, the upper and lower extension portions extending rearwardly of the rack structure; and after the upper wheels are supported by the rack structure, removing the upper and lower extension portions from the upper and lower guiding members.
In some embodiments, in the final position of the heat exchanger panel, the upper wheels and the lower wheels are adjacent to vertical legs of the rack structure so that the vertical legs support a load of the heat exchanger panel.
In some embodiments, the method also includes, prior to lifting the heat exchanger panel, removably connecting wheel mounts to the upper and lower ends of the frame of the heat exchanger panel, the wheel mounts interconnecting the wheels to the frame of the heat exchanger panel, said removably connecting comprising: inserting a rail of each wheel mount into one of: an upper channel defined by an upper frame member of the frame defining the upper end of the frame; and a lower channel defined by a lower frame member of the frame defining the lower end of the frame; and affixing the rail of each wheel mount to one of the upper frame member and the lower frame member via fasteners extending from a front face to a rear face of the one of the upper frame member and the lower frame member.
In some embodiments, while lowering the heat exchanger panel, an axis of the lower wheels describes a downward and generally vertical lower wheel path. The method also includes: prior to supporting the upper wheels on the upper wheel guiding members, reclining the heat exchanger panel so that the upper end of the frame of the heat exchanger panel pivots about the axis of the lower wheels, an axis of the upper wheels thereby describing an arcuate wheel path that intersects the lower wheel path.
Embodiments of the present technology each have at least one of the above-mentioned object and/or aspects, but do not necessarily have all of them. It should be understood that some aspects of the present technology that have resulted from attempting to attain the above-mentioned object may not satisfy this object and/or may satisfy other objects not specifically recited herein.
Additional and/or alternative features, aspects and advantages of embodiments of the present technology will become apparent from the following description, the accompanying drawings and the appended claims.
For a better understanding of the present technology, as well as other aspects and further features thereof, reference is made to the following description which is to be used in conjunction with the accompanying drawings, where:
The dry cooler stack 10 includes a rack structure 14 supporting the dry coolers 12 on a support surface. In use, the rack structure 14 is anchored to the support surface by fasteners. The support surface may be any suitable support surface. For instance, in this embodiment, the support surface is a surface surrounding a building. However, in other embodiments, the support surface could be part of a structure purposefully built to support the rack structure 14. The rack structure 14 will be described in greater detail further below.
The dry coolers 12 of the dry cooler stack 10 are installed on the rack structure such that their respective fan assemblies 16 are on a front side of the dry cooler stack 10 and therefore the dry coolers 12 of the dry cooler stack 10 discharge heated air toward the front side of the dry cooler stack 10.
More specifically, as shown in
As will be described in greater detail below, the heat exchanger panels 42 of the dry coolers 12 are configured to facilitate mounting of the heat exchanger panels 42 to the rack structure 14. In particular, the heat exchanger panels 42 are provided with rack-engaging members that engage respective guiding members of the rack structure 14.
Returning now to
Both rack units 18 are configured similarly and thus only one of the rack units 18 will be described in detail below. It is to be understood that the description applies to the other rack unit 18 as well.
The rack unit 18 includes four vertical legs 20 positioned at the corners of the rack unit 18 to define the rectangular shape of the rack unit 18. A flange 31 is provided at the lower end of each vertical leg 20 for anchoring the rack unit 18 to the support surface on which the rack unit 18 is mounted. The vertical legs 20 are linked by laterally-extending horizontal members 22 which extend between and interconnect laterally-adjacent ones of the vertical legs 20. The horizontal members 22 define the number of stories of the rack structure 14. In this embodiment, each rack unit 18 has five horizontal members 22. The rack unit 18 also has longitudinally-extending horizontal members 24 extending between and interconnecting longitudinally-adjacent ones of the vertical legs 20. The horizontal members 22, 24 are generally vertically aligned with one another. Moreover, each rack unit 18 also has a plurality of diagonal connecting members 26 which extend diagonally between vertically-adjacent ones of the longitudinally-extending horizontal members 24. As such, the diagonal connecting members 26 are disposed on each lateral side of the rack unit 18.
The components of the rack unit 18 can be fastened to one another in any suitable way. In this embodiment, the components of the rack sub-unit 18 are bolted to one another. It is contemplated that, in other embodiments, the components of the rack sub-unit 18 could be welded to one another.
As mentioned above, the connectors 40 interconnect the two rack units 18 to one another. In particular, two ends of each X-shaped connector 40 are fastened (e.g., bolted or welded) to one of the vertical legs 20 of one of the rack units 18 and the two other ends of the X-shaped connector 40 are fastened to an adjacent vertical leg 20 of the other rack unit 18.
As will be described in greater detail below, the rack structure 14 and the heat exchanger panels 42 of the dry coolers 12 are configured so as to facilitate mounting of the heat exchanger panels 42 onto the rack structure 14 to assemble the dry coolers 12. Notably, as shown in
As shown in
As best seen in
As shown in
The lower wheel guiding members 70 are configured to receive and guide the wheels of the heat exchanger panel 42. Therefore, in this embodiment, the angled and horizontal portions 71, 73 have a generally U-shaped cross-sectional profile. Specifically, in this embodiment, as shown in
As shown in
As shown in
For instance, with reference to
As shown in
The angled and horizontal portions 71′, 73′ have a generally U-shaped cross-sectional profile. Notably, the horizontal portion 73′ has two parallel opposite walls 78′ and a channel defined therebetween. Similarly, the angled portion 71′ has two parallel opposite walls 85′ and a channel defined therebetween. When a heat exchanger panel 42 is being mounted to the rack structure 14, lower wheels of the heat exchanger panel 42 roll on bottom surfaces 83′, 79′ extending between the walls 78′, 85′ while the parallel walls 78′, 85′ guide the lower wheels, thereby preventing the wheels from disengaging the lower wheel guiding members 70′.
The upper wheel guiding members 74′ are substantially similar to the upper wheel guiding members 74 described above except that they are size so as to not extend rearward from the rearmost vertical legs 20. The upper wheel guiding members 74′ will therefore not be described in detail herein.
The removable lower guide extensions 77′ and removable upper guide extensions 76′ have a generally U-shaped cross-sectional profile for receiving wheels of the heat exchanger panels 42 therein. As shown in
The heat exchanger panels 42, which are configured to transfer heat from the fluid circulating therein into the air flowing therethrough, will now be described in greater detail below with reference to
The heat exchanger panel 42 has a frame 43 for supporting the various components of the heat exchanger 42. The frame 43 has an upper end 44 and a lower end 46 opposite the upper end 44, as well as opposite lateral ends 47, 48. Together, the ends 44, 46, 47, 48 define a generally rectangular shape of the frame 43 and of the heat exchanger panel 42. The tubing arrangement 60 of the heat exchanger panel 42, which as mentioned above is configured to circulate fluid therein, is supported by the frame 43. As can be seen in
The heat exchanger panel 42 is provided with a plurality of rack-engaging members 50, 52 which are mounted to the frame 43 and which, as will be described in greater detail below, are configured to engage respective guiding members of the rack structure 14 for guided mounting of the heat exchanger panel 42 on the rack structure 14. In this embodiment, the rack-engaging members 50, 52 are wheels 50, 52 which are configured to roll on respective wheel guiding members of the rack structure 14. The wheels 50, 52 are mounted to the frame 43 in such a way as to be rotatable about a respective axis 51, 53 that extends generally laterally (i.e., in a side-to-side direction of the heat exchanger panel 42). The wheels 50, 52 include an upper set of wheels 50 mounted to the upper end 44 of the frame 43 and a lower set of wheels 52 mounted to the lower end 46 of the frame 43. The upper set of wheels 50 includes two upper wheels 50 spaced apart from one another by a distance D1. The wheels 50, 52 also include a lower set of wheels 52 mounted to the lower end 46 of the frame 43. The lower set of wheels 52 includes two lower wheels 52 spaced apart from one another by a distance D2.
It is contemplated that the wheels 50, 52 could be other types of rack-engaging members such as, for example, anti-friction members that slide on the guiding members 70, 74 of the rack structure 14.
In order to ensure that a path of the heat exchanger panel 42 when being mounted to the rack structure 14 is relatively compact such that the heat exchanger panel 42 stays relatively close to the rack structure 14 when being mounted thereto, the heat exchanger panel 42 is designed such that the distances D1 and D2 are different from one another (i.e., unequal to one another). As such, as shown in
As will be shown below when describing the path of the heat exchanger panel 42 when being mounted to the rack structure 14, this difference between the distances D1, D2 ensures that the upper wheels 50 and the lower wheels 52 move along different planes when the heat exchanger panel 42 is being mounted to the rack structure 14 and therefore that the path of the axis of the upper wheels 50 can intersect the path of the axis of the lower wheels 52 during installation on the rack structure 14. This may provide a compact installation path of the heat exchanger panel 42 as it is being installed onto the rack structure 14 which results in a relatively small amount of space being required on a rear side 15 of the rack structure 14 to mount the heat exchanger panels 42 to the rack structure 14. In turn, this results in footprint savings in the environment in which the dry cooler stack 10 is being installed as less space is required to remain unused behind the rack structure 14 to install the heat exchanger panels 42 thereto. This is particularly useful for example along a facade of a building or the roof of a building such as that housing a data center where a considerable amount of equipment has to be provided on the roof to service the data center properly.
With reference to
As shown in
As shown in
As will be understood, the wheel mounts 90 allow the wheels 50, 52 to be selectively removable from the heat exchanger panel 42 simply by removing the fasteners 102 and removing the removable connector 94 from the channel 49. This may facilitate maintenance and/or replacement of the heat exchanger panel 42. Notably, if the heat exchanger panel 42 is defective or otherwise needs replacement, the wheels 50, 52 can be easily removed from the heat exchanger panel 42 and installed on a replacement heat exchanger panel having the same configuration suitable for the removable connector 94 of each wheel mount 90 to be inserted into a corresponding frame member of the frame 43.
Returning to
The upper wheel mount 90 also includes a lifting bracket 93 connected to each mounting bracket 91. Each lifting bracket 93 extends perpendicularly from the first portion 98 of the corresponding mounting bracket 91 and defines an opening for connecting a lifting device, such as the hoist system 57, to lift the heat exchanger panel 42 from the lifting bracket 93. A locking member 95 is also provided as part of the upper wheel mount 90 to secure the heat exchanger panel 42 in its final position on the rack structure 14 (via fasteners).
The lower wheel mount 90 is configured in substantially the same manner as the upper wheel mount 90. However, the lower wheel mount 90 does not include the lifting brackets 93 since the heat exchanger panel 42 is intended to be lifted from its upper end.
Although in this embodiment, each wheel mount 90 mounts two of the wheels 50 or 52 to the frame 43 of the heat exchanger panel 42, it is contemplated that, in other embodiments, each wheel mount 90 may mount a single one of the wheels 50 or 52 to the frame 43. For instance, in such embodiments, four wheel mounts 90 may be provided to mount one of the upper wheels 50 or one of the lower wheels 52 to the frame 43. Moreover, it is contemplated that in such embodiments, the removable connector 94 may extend along an end portion of the width of the frame 43.
Other configurations of the wheel mounts 90 are contemplated. For instance, it should be noted that
Turning now to
As an initial step, the heat exchanger panel 42 is brought to a position behind the rack structure 14. For example, the heat exchanger panel 42 can be brought there by a pallet jack. Notably, due to the ease of mounting provided by the wheeled heat exchanger panel 42 and the rack structure 14 of the present technology, a heavier machine such as a forklift (which occupies more space and is significantly heavier) is not needed to mount the heat exchanger panel 42 to the rack structure 14 as would typically be the case for mounting a conventional heat exchanger panel to a conventional rack structure. Moreover, this affords more space behind the rack structure 14 as space does not have be reserved for allowing the forklift behind the rack structure 14. In addition, a concrete slab which would typically be provided behind the rack structure for a forklift can be foregone.
Once the heat exchanger panel 42 is in position behind the rack structure, in this embodiment, first, in order to lift the heat exchanger panel 42, the lifting brackets 93 of the heat exchanger panel 42 are connected to the hoist system 57 which is mounted to the upper part of the rack structure 14.
With reference to
Next, the heat exchanger panel 42 is lowered until the lower wheels 52 are received and supported by the lower wheel guiding members 70. During this lowering motion, the axis 53 of the lower wheels 52 describes a downward and generally vertical lower wheel path PL. In embodiments in which the upper and lower removable guide extensions 76′, 77′ are used, prior to lowering the heat exchanger panel 42 onto the lower and upper wheel guiding members, the upper and lower removable guide extensions 76′, 77′ of the upper and lower wheel guiding members 74′, 70′ are affixed to the rack structure 14.
With reference to
After the heat exchanger panel 42 has been moved forward (i.e., further down on the lower wheel guiding members 70) and reclined backward sufficiently, the upper wheels 50 are supported on the upper wheel guiding members 74. At this stage, if the upper and lower removable guide extensions 76′, 77′ were used, they can be removed from the upper and lower wheel guiding members 74′, 70′.
Next, as shown in
Modifications and improvements to the above-described implementations of the present technology may become apparent to those skilled in the art. The foregoing description is intended to be exemplary rather than limiting. The scope of the present technology is therefore intended to be limited solely by the scope of the appended claims.
Number | Date | Country | Kind |
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19315108 | Aug 2019 | EP | regional |
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Entry |
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Number | Date | Country | |
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20210063095 A1 | Mar 2021 | US |