U.S. patent application number 17/146514 was filed with the patent office on 2022-05-19 for active coolant distribution device and electronic apparatus having the same.
The applicant listed for this patent is WISTRON CORP.. Invention is credited to Hua CHEN, CHUAN-YI LIANG, Sheng Yen LIN.
Application Number | 20220159870 17/146514 |
Document ID | / |
Family ID | 1000006316043 |
Filed Date | 2022-05-19 |
United States Patent
Application |
20220159870 |
Kind Code |
A1 |
LIN; Sheng Yen ; et
al. |
May 19, 2022 |
ACTIVE COOLANT DISTRIBUTION DEVICE AND ELECTRONIC APPARATUS HAVING
THE SAME
Abstract
The disclosed embodiments relate to an active coolant
distribution device and an electronic apparatus, where the active
coolant distribution device includes a manifold including a first
and second primary pipes and branches. At least one of the first
and second primary pipes is suitable for accommodating the flow
generator. The second primary pipe includes a first hollow post and
a first and second inner wall portions. The first hollow post has
first liquid inlets. The first and second inner wall portions form
a first channel, a second channel, and an accommodation space
inside the first hollow post. The first inner wall portion has
converging port, the second inner wall portion has ejecting port,
the first channel is located between the first liquid inlets and
the converging port and connected to the accommodation space, the
ejecting port is connected to the accommodation space and the
second channel.
Inventors: |
LIN; Sheng Yen; (New Taipei
City, TW) ; CHEN; Hua; (New Taipei City, TW) ;
LIANG; CHUAN-YI; (New Taipei City, TW) |
|
Applicant: |
Name |
City |
State |
Country |
Type |
WISTRON CORP. |
New Taipei City |
|
TW |
|
|
Family ID: |
1000006316043 |
Appl. No.: |
17/146514 |
Filed: |
January 12, 2021 |
Current U.S.
Class: |
1/1 |
Current CPC
Class: |
H05K 7/20272
20130101 |
International
Class: |
H05K 7/20 20060101
H05K007/20 |
Foreign Application Data
Date |
Code |
Application Number |
Nov 18, 2020 |
TW |
109140372 |
Claims
1. An active coolant distribution device, configured for
circulating a coolant and accommodating at least one flow
generator, comprising: a manifold, comprising a first primary pipe,
a second primary pipe, and a plurality of branches connected to the
first primary pipe and the second primary pipe; wherein at least
one of the first primary pipe and the second primary pipe is
suitable for accommodating the at least one flow generator; and the
second primary pipe comprises: a first hollow post, having a
plurality of first liquid inlets, wherein the plurality of first
liquid inlets are arranged along a long side direction of the first
hollow post and respectively connected to the plurality of
branches; and a first inner wall portion and a second inner wall
portion, arranged in the first hollow post, extending in the long
side direction of the first hollow post, and spaced apart from each
other so as to form a first channel, a second channel, and an
accommodation space which are inside the first hollow post; wherein
the accommodation space is located between the first channel and
the second channel, the first inner wall portion has at least one
converging port, the second inner wall portion has at least one
ejecting port, the first channel is located between and connected
to the plurality of first liquid inlets and the at least one
converging port and is connected to the accommodation space via the
at least one converging port, the at least one ejecting port is
connected to and located between the accommodation space and the
second channel.
2. The active coolant distribution device according to claim 1,
wherein the accommodation space is configured to accommodate the at
least one flow generator.
3. The active coolant distribution device according to claim 1,
wherein the second primary pipe further comprises a second
branching pipe and a third branching pipe, the first hollow post
further has a plurality of first liquid outlets arranged along the
long side direction of the first hollow post, the second branching
pipe has a plurality of second liquid inlets and a plurality of
second liquid outlets arranged along the long side direction and a
third channel located between and connected to the plurality of
second liquid inlets and the plurality of second liquid outlets,
the third branching pipe has a plurality of third liquid inlets
arranged along the long side direction and a fourth channel
connected to the plurality of third liquid inlets, the plurality of
branches are respectively directly connected to the plurality of
second liquid inlets, the plurality of second liquid outlets are
respectively directly connected to the plurality of first liquid
inlets, the plurality of first liquid outlets are respectively
directly connected to the plurality of third liquid inlets.
4. The active coolant distribution device according to claim 1,
wherein the at least one flow generator is a fan or a pump.
5. The active coolant distribution device according to claim 1,
wherein the manifold has an access side, a liquid inlet end, and a
liquid outlet end, the liquid inlet end and the liquid outlet end
are located at the access side and respectively located at the
first primary pipe and the second primary pipe, the at least one
flow generator corresponds to one of the plurality of branches that
is located farthest away from the access side.
6. The active coolant distribution device according to claim 1,
wherein the manifold has an access side, a liquid inlet end, and a
liquid outlet end, the liquid inlet end and the liquid outlet end
are located at the access side and respectively located at the
first primary pipe and the second primary pipe, the at least one
flow generator comprises a plurality of flow generators, L denotes
a distance between one of the plurality of branches located
farthest away from the access side and another one of the plurality
of branches located closest to the access side, the plurality of
flow generators are respectively distanced from the access side by
L/2n, where n is an integer equal to or larger than 0.
7. An electronic apparatus, configured for circulating a coolant
and accommodating at least one flow generator, comprising: an
enclosure; and an active coolant distribution device, disposed on
the enclosure, comprising: a manifold, comprising a first primary
pipe, a second primary pipe, and a plurality of branches connected
to the first primary pipe and the second primary pipe; wherein at
least one of the first primary pipe and the second primary pipe is
suitable for accommodating the at least one flow generator; and
wherein the second primary pipe comprises: a first hollow post,
having a plurality of first liquid inlets, wherein the plurality of
first liquid inlets are arranged along a long side direction of the
first hollow post and respectively connected to the plurality of
branches; and a first inner wall portion and a second inner wall
portion, arranged in the first hollow post, extending in the long
side direction of the first hollow post, and spaced apart from each
other so as to form a first channel, a second channel, and an
accommodation space which are inside the first hollow post; wherein
the accommodation space is located between the first channel and
the second channel, the first inner wall portion has at least one
converging port, the second inner wall portion has at least one
ejecting port, the first channel is located between and connected
to the plurality of first liquid inlets and the at least one
converging port and is connected to the accommodation space via the
at least one converging port, the at least one ejecting port is
connected to and located between the accommodation space and the
second channel.
8. The electronic apparatus according to claim 7, wherein the
accommodation space is configured to accommodate the at least one
flow generator.
9. The electronic apparatus according to claim 7, wherein the
second primary pipe further comprises a second branching pipe and a
third branching pipe, the first hollow post further has a plurality
of first liquid outlets, the second branching pipe further has a
plurality of second liquid inlets, a plurality of second liquid
outlets and a third channel located between and connected to the
plurality of second liquid inlets and the plurality of second
liquid outlets, the third branching pipe has a plurality of third
liquid inlets and a fourth channel connected to the plurality of
third liquid inlets, the plurality of branches respectively
directly connected to the plurality of second liquid inlets, the
plurality of second liquid outlets are respectively directly
connected to the plurality of first liquid inlets, the plurality of
first liquid outlets are respectively directly connected to the
plurality of third liquid inlets.
10. The electronic apparatus according to claim 7, wherein the at
least one flow generator is a fan or a pump.
11. The electronic apparatus according to claim 7, wherein the
manifold has an access side, a liquid inlet end, and a liquid
outlet end, the liquid inlet end and the liquid outlet end are
located at the access side and respectively located at the first
primary pipe and the second primary pipe, the at least one flow
generator corresponds to one of the plurality of branches that is
located farthest away from the access side.
12. The electronic apparatus according to claim 7, wherein the
manifold has an access side, a liquid inlet end, and a liquid
outlet end, the liquid inlet end and the liquid outlet end are
located at the access side and respectively located at the first
primary pipe and the second primary pipe, the at least one flow
generator comprises a plurality of flow generators, L denotes a
distance between one of the plurality of branches located farthest
away from the access side and another one of the plurality of
branches located closest to the access side, the plurality of flow
generators are respectively distanced from the access side by L/2n,
where n is an integer equal to or larger than 0.
13. An active coolant distribution device, configured for
circulating a coolant, comprising: a manifold, comprising a first
primary pipe, a second primary pipe, and a plurality of branches
connected to the first primary pipe and the second primary pipe;
wherein the second primary pipe comprises: a first hollow post,
having a plurality of first liquid inlets, wherein the plurality of
first liquid inlets are arranged along a long side direction of the
first hollow post and respectively connected to the plurality of
branches; and a first inner wall portion and a second inner wall
portion, arranged in the first hollow post, extending in the long
side direction of the first hollow post, and spaced apart from each
other so as to form a first channel, a second channel, and an
accommodation space which are inside the first hollow post; wherein
the accommodation space is located between the first channel and
the second channel, the first inner wall portion has at least one
converging port, the second inner wall portion has at least one
ejecting port, the first channel is located between and connected
to the plurality of first liquid inlets and the at least one
converging port and is connected to the accommodation space via the
at least one converging port, the at least one ejecting port is
connected to and located between the accommodation space and the
second channel; and at least one flow generator, being accommodated
in at least one of the first primary pipe and the second primary
pipe.
14. The active coolant distribution device according to claim 13,
wherein the manifold has an access side, a liquid inlet end, and a
liquid outlet end, the liquid inlet end and the liquid outlet end
are located at the access side and respectively located at the
first primary pipe and the second primary pipe, the at least one
flow generator comprises a plurality of flow generators, L denotes
a distance between one of the plurality of branches located
farthest away from the access side and another one of the plurality
of branches located closest to the access side, the plurality of
flow generators are respectively distanced from the access side by
L/2n, where n is an integer equal to or larger than 0.
15. The active coolant distribution device according to claim 13,
wherein the accommodation space is configured to accommodate the at
least one flow generator.
16. The active coolant distribution device according to claim 13,
wherein the second primary pipe further comprises a second
branching pipe and a third branching pipe, the first hollow post
further has a plurality of first liquid outlets, the second
branching pipe has a plurality of second liquid inlets, a plurality
of second liquid outlets, and a third channel which is located
between and connected to the plurality of second liquid inlets and
the plurality of second liquid outlets, the third branching pipe
has a plurality of third liquid inlets and a fourth channel
connected to the plurality of third liquid inlets, the plurality of
branches are respectively directly connected to the plurality of
second liquid inlets, the plurality of second liquid outlets are
respectively directly connected to the plurality of first liquid
inlets, the plurality of first liquid outlets are respectively
directly connected to the plurality of third liquid inlets.
17. The active coolant distribution device according to claim 13,
wherein the manifold has an access side, a liquid inlet end, and a
liquid outlet end, the liquid inlet end and the liquid outlet end
are located at the access side and respectively located at the
first primary pipe and the second primary pipe, the at least one
flow generator corresponds to one of the plurality of branches that
is located farthest away from the access side.
Description
CROSS-REFERENCE TO RELATED APPLICATIONS
[0001] This non-provisional application claims priority under 35
U.S.C. .sctn. 119(a) on Patent Application No(s). 109140372 filed
in Taiwan (R.O.C.) on Nov. 18, 2020, the entire contents of which
are hereby incorporated by reference.
TECHNICAL FIELD
[0002] The disclosure relates to the field of heat dissipation,
more particularly to an active coolant distribution device and an
electronic apparatus having the same.
BACKGROUND
[0003] With the rapid growth of demand for the interne, artificial
intelligence, and cloud services, servers constantly need to
process a massive amount of data, thus it is necessary to
continuously and effectively dissipate waste heat to maintain or
upgrade the processing speed. Over time, the rise of computing
power and density of servers has brought along higher thermal
dissipation requirements, which has led to more and more people
turning to liquid cooling.
[0004] A typical liquid-cooled system uses liquid as a conductor of
heat and can incorporate a manifold and a pump to achieve a
circulation of the liquid. The most common manifold is the
open-loop manifold, including bottom-in bottom-out manifold or
top-in top-out manifold, both of them can distribute the liquid to
the heat sources at different areas of the system and then eject it
out of the system.
[0005] However, both two types of manifold will cause uneven flow
rate distribution in channels. Taking the bottom-in bottom-out
manifold as an example, the flow rates in channels decreases with
the increase of the distance to the liquid inlet (at the bottom
side) since flowing liquid in pipe or duct may cause pressure drop
due to factors such as frictional loss, local loss, change in
elevation. As a result, different areas of the manifold will have a
significant difference in flow rate, resulting in an insufficient
amount of liquid for cooling some of the heat sources. According to
statistics, in the traditional manifolds for server enclosure, the
flow rates of some pipes will be greatly reduced due to the
pressure drop, and the maximum percentage error compared to the
predetermined average flow rate can even reach 178.4%. This clearly
shows that the flow rate of some areas of the conventional manifold
will be too low to effectively cool the respective heat sources,
causing a great decrease in overall performance and even affecting
the lifespan of the server.
SUMMARY
[0006] Accordingly, the present disclosure provides an active
coolant distribution device and an electronic apparatus that are
capable of achieving a uniform distribution of coolant.
[0007] One embodiment of the disclosure provides an active coolant
distribution device configured for circulating a coolant and
accommodating at least one flow generator. The active coolant
distribution device includes a manifold including a first primary
pipe, a second primary pipe, and a plurality of branches connected
to the first primary pipe and the second primary pipe. At least one
of the first primary pipe and the second primary pipe is suitable
for accommodating the at least one flow generator. The second
primary pipe includes a first hollow post, a first inner wall
portion, and a second inner wall portion. The first hollow post has
a plurality of first liquid inlets. The first liquid inlets are
arranged along a long side direction of the first hollow post and
respectively connected to the plurality of branches. The first
inner wall portion and the second inner wall portion are arranged
in the first hollow post, extending in the long side direction of
the first hollow post, and spaced apart from each other so as to
form a first channel, a second channel, and an accommodation space
which are inside the first hollow post. The accommodation space is
located between the first channel and the second channel, the first
inner wall portion has at least one converging port, the second
inner wall portion has at least one ejecting port, the first
channel is located between and connected to the plurality of first
liquid inlets and the at least one converging port and is connected
to the accommodation space via the at least one converging port,
the at least one ejecting port is connected to and located between
the accommodation space and the second channel.
[0008] Another embodiment of the disclosure provides an electronic
apparatus configured for circulating a coolant and accommodating at
least one flow generator. The electronic apparatus includes an
enclosure and an active coolant distribution device. The active
coolant distribution device is disposed on the enclosure. The
active coolant distribution device includes a manifold including a
first primary pipe, a second primary pipe, and a plurality of
branches connected to the first primary pipe and the second primary
pipe. At least one of the first primary pipe and the second primary
pipe is suitable for accommodating the at least one flow generator.
The second primary pipe includes a first hollow post, a first inner
wall portion, and a second inner wall portion. The first hollow
post has a plurality of first liquid inlets. The first liquid
inlets are arranged along a long side direction of the first hollow
post and respectively connected to the plurality of branches. The
first inner wall portion and the second inner wall portion are
arranged in the first hollow post, extending in the long side
direction of the first hollow post, and spaced apart from each
other so as to form a first channel, a second channel, and an
accommodation space which are inside the first hollow post. The
accommodation space is located between the first channel and the
second channel, the first inner wall portion has at least one
converging port, the second inner wall portion has at least one
ejecting port, the first channel is located between and connected
to the plurality of first liquid inlets and the at least one
converging port and is connected to the accommodation space via the
at least one converging port, the at least one ejecting port is
connected to and located between the accommodation space and the
second channel.
[0009] Another embodiment of the disclosure provides an active
coolant distribution device configured for circulating a coolant.
The active coolant distribution device includes a manifold and at
least one flow generator. The manifold includes a first primary
pipe, a second primary pipe, and a plurality of branches connected
to the first primary pipe and the second primary pipe. The second
primary pipe includes a first hollow post, a first inner wall
portion, and a second inner wall portion. The first hollow post has
a plurality of first liquid inlets. The first liquid inlets are
arranged along a long side direction of the first hollow post and
respectively connected to the plurality of branches. The first
inner wall portion and the second inner wall portion are arranged
in the first hollow post, extending in the long side direction of
the first hollow post, and spaced apart from each other so as to
form a first channel, a second channel, and an accommodation space
which are inside the first hollow post. The accommodation space is
located between the first channel and the second channel, the first
inner wall portion has at least one converging port, the second
inner wall portion has at least one ejecting port, the first
channel is located between and connected to the plurality of first
liquid inlets and the at least one converging port and is connected
to the accommodation space via the at least one converging port,
the at least one ejecting port is connected to and located between
the accommodation space and the second channel. The at least one
flow generator is accommodated in at least one of the first primary
pipe and the second primary pipe.
[0010] According to the active coolant distribution device and the
electronic apparatus as discussed in the above embodiments of the
disclosure, the placement of one or more flow generators in at
least one of the first primary pipe and the second primary pipe can
compensate the pressure drop caused by frictional loss, local loss,
and change in elevation. As a result, the flow rates of the
branches are prevented from decreasing with the increase of the
distance to the liquid inlet, thus achieving a uniform distribution
of coolant of the flow field and ensuring a sufficient amount of
coolant required for cooling each heat source.
BRIEF DESCRIPTION OF THE DRAWINGS
[0011] The present disclosure will become better understood from
the detailed description given hereinbelow and the accompanying
drawings which are given by way of illustration only and thus are
not intending to limit the present disclosure and wherein:
[0012] FIG. 1 is a perspective view of an electronic apparatus
according to one embodiment of the disclosure;
[0013] FIG. 2 is a planar view of an active coolant distribution
device in FIG. 1;
[0014] FIG. 3 is a partial enlarged exploded view of the active
coolant distribution device in FIG. 1;
[0015] FIG. 4 is a partial enlarged flow simulation of the active
coolant distribution device in FIG. 1;
[0016] FIG. 5 is an overall flow simulation of the active coolant
distribution device on the electronic apparatus;
[0017] FIG. 6 is a flow distribution comparison between the
electronic apparatus of one embodiment of the disclosure and a
conventional electronic apparatus;
[0018] FIG. 7 is a mean absolute percentage error (MAPE) comparison
between the electronic apparatus of one embodiment of the
disclosure and a conventional electronic apparatus in terms of flow
rate;
[0019] FIG. 8 is a perspective view of an electronic apparatus
according to another embodiment of the disclosure;
[0020] FIG. 9 is a perspective view of an electronic apparatus
according to yet another embodiment of the disclosure; and
[0021] FIG. 10 illustrates control steps of an active coolant
distribution device of one embodiment of the disclosure with a
sensor.
DETAILED DESCRIPTION
[0022] In the following detailed description, for purposes of
explanation, numerous specific details are set forth in order to
provide a thorough understanding of the disclosed embodiments. It
will be apparent, however, that one or more embodiments may be
practiced without these specific details.
[0023] The following embodiments will be described with reference
to the drawings. For the purpose of clear illustration, some
conventional elements and components may be illustrated in a simple
and clear manner. Some of the features in the drawings may be
slightly exaggerated or illustrated in a larger proportion for the
ease of viewing but are not intended to limit the disclosure. In
addition, for the same reason, some of the elements or components
in the drawings may be illustrated in dotted lines.
[0024] Herein, the terms, such as "end", "part", "portion", "area",
may be used to refer to specific features of or between elements or
components but are not intended to limit the elements and
components. In addition, the terms, such as "substantially" and
"approximately", as used herein may mean a reasonable amount of
deviation of the described term such that the end result is not
significantly changed.
[0025] Further, unless explicitly stated, the term "at least one"
as used herein may mean that the quantity of the described element
or component is one or larger than one but does not necessarily
mean that the quantity is only one. The term "and/or" may be used
herein to indicate that either or both of two stated
possibilities.
[0026] Firstly, referring to FIGS. 1-2, one embodiment of the
disclosure provides an electronic apparatus 9. The electronic
apparatus 9 is, for example, a server, and its type shown in the
drawings is exemplary but not intended to limit the electronic
apparatus 9. In this embodiment, the electronic apparatus 9 is a
high power density system and therefore requires dissipate heat by
liquid cooling to maintain or improve performance. As shown, one
embodiment provides an active coolant distribution device 1 that is
suitable for distributing coolant for the electronic apparatus
9.
[0027] The active coolant distribution device 1 is configured to be
arranged at a side of an enclosure 90 of the electronic apparatus
9, coolant can be injected into the manifold 10 via a liquid inlet
end IL of the manifold 10 so as to be evenly distributed to the
predetermined places on the enclosure 90 to absorb heat and then to
be discharged from a liquid outlet end OL of the manifold 10. The
coolant used herein can be any suitable heat dissipation medium and
is not intended to limit the disclosure. In addition, the active
coolant distribution device 1 can employ one or more typical
coolant distribution units (CDU)(not shown) existing in the market,
such that the flow rate and pressure of the coolant can be
predetermined, but the configuration and number of the CDU are
optional and not intended to limit the disclosure.
[0028] Generally, in fluid flow, friction loss (or skin friction)
is the loss or pressure or "head" that occurs in pipe or duct flow
due to the effect of the fluid's viscosity near the surface of the
pipe or duct, and pressure loss also occurs due to a change in
elevation of the fluid. That is, flowing liquid in pipe or duct may
cause pressure drop due to factors such as frictional loss, local
loss, change in elevation, or diversion. This will cause the
coolant flow rate to decrease with the increase of the distance the
coolant passes through the inlet. To avoid this problem, the active
coolant distribution device 1 is provided.
[0029] Hereinafter, the active coolant distribution device 1 is
described in detail with reference to FIGS. 1-3. In this
embodiment, the active coolant distribution device 1 may include a
manifold 10 and a plurality of flow generators 20, where the
manifold 10 is able to accommodate the flow generators 20 so that
the flow generators 20 can add pressure to the coolant system in
the manifold 10 so as to compensate the pressure drop of coolant.
In specific, the manifold 10 may include a first primary pipe PP1,
a second primary pipe PP2, and a plurality of branches B, the first
primary pipe PP1 and the second primary pipe PP2 are two vertical
pipes spaced apart from each other, the liquid inlet end IL is
located at one end of the first primary pipe PP1, the liquid outlet
end OL is located at one end of the second primary pipe PP2, the
branches B are spaced apart from each other and located between and
connected to the first primary pipe PP1 and the second primary pipe
PP2, in other words, two opposite ends of each branch B are
respectively connected to the first primary pipe PP1 and the second
primary pipe PP2. In such an arrangement, coolant is allowed to
enter into the manifold 10 from one end of the first primary pipe
PP1 (i.e., the liquid inlet end IL) and then be distributed into
the branch B and converged to the second primary pipe PP2 and flow
out of the manifold from one end of the second primary pipe PP2
(i.e., the liquid outlet end OL).
[0030] As shown, the manifold 10 provides a bottom-in bottom-out
coolant circulation, that is, the liquid inlet end IL and the
liquid outlet end OL are both arranged at the bottom of the
enclosure 90, but the disclosure is not limited by the arrangement
of the liquid inlet end IL and the liquid outlet end OL. In some
other embodiments, the liquid inlet end and the liquid outlet end
may be arranged to the top of the manifold so as to provide a
top-in top-out coolant circulation. Note that the manifold 10 has
an access side 11 being a side of the manifold 10 having the liquid
inlet end IL and the liquid outlet end OL. It is also noted that
the arrangements and directions of the below-described components
and elements are defined with reference to a major axis or
longitudinal axis of the first primary pipe PP1 or the second
primary pipe PP2. The `major axis` and `longitudinal axis` (as
indicated by arrow A in FIG. 3) is parallel to an extension
direction or long side of the first primary pipe PP1 and the second
primary pipe PP2.
[0031] Further, in this embodiment, the first primary pipe PP1 is a
hollow pipe body opened at one end (i.e., the liquid inlet end IL)
and closed at the other end, each of the branches B is a hollow
pipe body being opened at two opposite ends, the first primary pipe
PP1 has holes (not shown) respectively connected to the branches B,
such that the coolant can flow into the branches B from the first
primary pipe PP1. It is noted that the configurations of the first
primary pipe PP1 and the branches B may be modified as required and
are not intended to limit the disclosure.
[0032] Further, in this embodiment, the second primary pipe PP2 may
include a first branching pipe 110, a second branching pipe 120 and
a third branching pipe 130. Each of the first branching pipe 110,
the second branching pipe 120, and the third branching pipe 130 has
a hollow pipe body substantially extending in the same direction
(i.e., the long side direction). The first branching pipe 110 is
located between and connected to the second branching pipe 120 and
the third branching pipe 130, and the second branching pipe 120 is
located between and connected to the branched B and the first
branching pipe 110. The opened ends of the first branching pipe
110, the second branching pipe 120, and the third branching pipe
130 together form the liquid outlet end OL of the manifold 10. In
other words, the coolant flowing into the second primary pipe PP2
from the branches B can be distributed into the second branching
pipe 120, the first branching pipe 110, and the third branching
pipe 130 and then converged to the liquid outlet end OL.
[0033] In detail, as shown in FIG. 3, in this embodiment, the first
branching pipe 110 may include a first hollow post 111, a first
inner wall portion 112, and a second inner wall portion 113. The
first hollow post 111 extends in the long side direction (as
indicated by the arrow A). The first hollow post 111 may have a
circular or square column shape, but the shape of the first hollow
post 111 may be modified as required. The first hollow post 111 may
have an inlet side 110a and an outlet side 110b respectively
located at two opposite sides of the first hollow post 111. As
shown, the inlet side 110a and the outlet side 110b are two
opposite sides of the first hollow post 111 that are used to
respectively connect or contact the second branching pipe 120 and
the third branching pipe 130.
[0034] The first hollow post 111 may further have a plurality of
first liquid inlets 110a1 and a plurality of first liquid outlets
110b1. The first liquid inlets 110a1 are arranged at the inlet side
110a. The first liquid inlets 110a1 are arranged along the long
side direction and spaced apart from each other. The first liquid
inlets 110a1 are through holes that connect the internal space of
the first hollow post 111. The first liquid outlets 110b1 are
arranged at the outlet side 110b. The first liquid outlets 110b1
are arranged along the long side direction and spaced apart from
each other. The first liquid outlets 110b1 are through holes that
connect the internal space of the first hollow post 111.
[0035] The first inner wall portion 112 and the second inner wall
portion 113 are located within the first hollow post 111 and extend
in the long side direction so as to divide the internal space of
the first hollow post 111 into a first channel 110c1, a second
channel 110c2, and an accommodation space S that extend in the long
side direction. The accommodation space S is located between the
first channel 110c1 and the second channel 110c2, where the first
channel 110c1 is located at a side of the accommodation space S
close to the first liquid inlets 110a1 and are connected to the
first liquid inlets 110al, the second channel 110c2 is located at a
side of the accommodation space S close to the first liquid outlets
110b1 and are connected to the first liquid outlets 110b1. In other
words, the first channel 110c1 is located between the first liquid
inlet 110a1 and the first inner wall portion 112, and the second
channel 110c2 is located between the first liquid outlet 110b1 and
the second inner wall portion 113.
[0036] In addition, the first inner wall portion 112 may have a
plurality of converging ports 1121, the converging ports 1121 are
spaced apart from each other and arranged along the long side
direction, and the converging ports 1121 are through holes that
connect the first channel 110c1 to the accommodation space S.
Further, the second inner wall portion 113 may have a plurality of
ejecting ports 1131, the ejecting ports 1131 are spaced apart from
each other and arranged along the long side direction, and the
ejecting ports 1131 are through holes that connect the second
channel 110c2 to the accommodation space S.
[0037] The flow generator 20 is, for example, a pump or a fan that
is suitable for operating while being immersed in the coolant. In
this embodiment, the flow generators 20 are arranged within the
accommodation space S and in positions corresponding to the
converging ports 1121 and the ejecting ports 1131, that is, each of
the flow generators 20 is located between the converging port 1121
of the first inner wall portion 112 and the ejecting port 1131 of
the second inner wall portion 113. In such an arrangement, the flow
generators 20 are able to intake the coolant near the converging
port 1121 towards the ejecting port 1131. That is, the flow
generator 20 is able to form a flow field of converging coolant
into the converging port 1121 and discharging coolant out of the
ejecting port 1131 among the first channel 110c1, the accommodation
space S and the second channel 110c2. In other words, the flow
generator 20 can provide the coolant kinetic energy to force it to
flow into the converging port 1121 and then flow out of the
ejecting port 1131.
[0038] The second branching pipe 120 may include a second hollow
post 121 extending in the long side direction. The second hollow
post 121 may have a circular or square column shape, but the shape
of the second hollow post 121 may be modified as required. The
second hollow post 121 may have a third channel 120c extending in
the long side direction. In addition, the second hollow post 121
may have an inlet side 120a and an outlet side 120b respectively
located at two opposite sides of the second hollow post 121. As
shown, the inlet side 120a and the outlet side 120b are two
opposite sides of the second hollow post 121 that are used to
respectively connect or contact the branches B and the first
branching pipe 110.
[0039] The second hollow post 121 may further have a plurality of
second liquid inlets 120a1 and a plurality of second liquid outlets
120b1. The second liquid inlets 120a1 are formed on the inlet side
120a. The second liquid inlets 120a1 are spaced apart from each
other and arranged along the long side direction. The second liquid
inlets 120a1 are through holes that directly connect the third
channel 120c of the second hollow post 121 and respectively
directly connect the branches B. The second liquid outlets 120b1
are formed on the outlet side 120b. The second liquid outlets 120b1
are spaced apart from each other and arranged along the long side
direction. The second liquid outlets 120b1 are through holes that
directly connect the third channel 120c of the second hollow post
121 and respectively directly connect the first liquid inlets 110a1
formed on the inlet side 110a of the first branching pipe 110. That
is, the coolant from the branches B is allowed to sequentially pass
through the second liquid inlets 120a1 on the inlet side 120a of
the second branching pipe 120, the third channel 120c, the second
liquid outlets 120b1 on the outlet side 120b, and the first channel
110c1 and the second channel 110c2 of the first branching pipe
110.
[0040] The third branching pipe 130 may include a third hollow post
131. The third hollow post 131 extends in the long side direction.
The third hollow post 131 may have a circular or square column
shape, but the shape of the third hollow post 131 may be modified
as required. The third hollow post 131 may have a fourth channel
130c extending in the long side direction. In addition, the third
hollow post 131 may have an inlet side 130a. The inlet side 130a is
a side of the third hollow post 131 that is used to connect or
contact the first branching pipe 110. The third hollow post 131 may
have a plurality of third liquid inlets 130a1. The third liquid
inlets 130a1 are arranged at the inlet side 130a. The third liquid
inlets 130a1 are arranged along the long side direction and spaced
apart from each other. The third liquid inlets 130a1 are through
holes that connect the fourth channel 130c of the third hollow post
131 and respectively connect the first liquid outlets 110b1 on the
outlet side 110b of the first branching pipe 110 so as to converge
the coolant coming from the first liquid outlets 110b1 of the first
branching pipe 110 into the fourth channel 130c.
[0041] Referring to FIG. 4, there is shown a partial enlarged flow
simulation of the active coolant distribution device 1. As shown,
in the pipeline arrangement of the active coolant distribution
device 1, the coolant flowing into the second primary pipe PP2 from
the branches B can flow downwardly along the third channel 120c of
the second branching pipe 120, meanwhile, the flow generator 20 can
draw the coolant near the second liquid outlets 120b1 of the second
branching pipe 120 into the first channel 110c1 of the first
branching pipe 110, such that there is part of the coolant flowing
downwardly along the first channel 110c1. Also, the flow generator
20 can draw the coolant into the converging port 1121 and force it
to flow toward the ejecting port 1131. The coolant passing through
the ejecting port 1131 flows downwardly along the second channel
110c2 and can flow through the first liquid outlet 110b1 and the
third liquid inlet 130a1 and then flow downwardly along the fourth
channel 130c of the third branching pipe 130.
[0042] As discussed, the cooperation of the flow generator 20 and
the second primary pipe PP2 can provide force at a side of a part
of the branches B to force part of the coolant to flow in a
direction different from the long side direction before the coolant
downwardly reaches the liquid outlet end OL, in specific, the flow
generators 20 can force part of the coolant to flow in an upward
direction to compensate for the decrease of the flow rate of the
branches B caused by pressure drop. As a result, a uniform
distribution of flow rates among the branches B is obtained.
[0043] Herein, referring to FIG. 5, the overall flow field in the
active coolant distribution device 1 is presented as an arrow plot.
It is noted that the quantity and location of the arrows are for
illustrating the flow of the coolant but not intended to represent
or limit the actual condition of the flow field. As shown, the
coolant entering into the manifold 10 from the liquid inlet end IL
is distributed to the branches B via the first primary pipe PP1,
and the flow generators 20 that are arranged next to the branches B
can draw the coolant so as to ensure a sufficient amount of coolant
to flow through all of the branches B.
[0044] In general, the existence of the flow generators 20 in the
second primary pipe PP2 can compensate the pressure drop caused by
frictional loss, local loss, and change in elevation, thereby
preventing the flow rate from decreasing with the increase of the
distance to the liquid inlet (i.e., the liquid inlet end IL on the
access side 11). That is, the flow rate of coolant among all of the
branches B can be kept in a sufficient amount for cooling the
respective heat sources regardless of the distance to the liquid
inlet.
[0045] The second primary pipe PP2, as shown, only employs three
flow generators 20, but a proper arrangement of the flow generators
20 still can achieve a uniform distribution of flow rates among the
branches B even when the number of the flow generators 20 is way
less than that of the branches B. The detailed explanation is given
below.
[0046] In this embodiment, the enclosure 90 of the electronic
apparatus 9 may have a height of 42U, and the quantity of the
branches B is 42, in order to distinguish different flow generators
20, the locations of the flow generators 20 can be defined using
the length of the range of the branches B on the manifold 10.
Herein, L denotes the distance between the branch B closest to the
access side 11 and the branch B farthest from the access side 11,
in such a definition, at least one flow generator 20 is disposed at
a position L/2n away from the access side 11, where n is an integer
equal to or larger than 0. As shown, one of the flow generators 20
is at a position L away from the access side 11, another flow
generator 20 is at a position L/2 away from the access side 11, and
another flow generator 20 is at a position L/4 away from the access
side 11. Alternatively, the locations of the flow generators 20 can
be defined using the quantity of the branches B, the first branch B
farthest away from the access side 11 denotes 1.sup.st branch B,
the other branches B arranged in a direction towards the access
side 11 is 2.sup.nd branch B, 3.sup.rd branch B, 4.sup.th branch B
. . . and 42.sup.nd branch B, in such a definition, the flow
generators 20 are respectively arranged next to the 1.sup.st branch
B, the 21.sup.st and 22.sup.nd branches B, and the 32.sup.nd branch
B.
[0047] This arrangement of the flow generators 20 in the second
primary pipe PP2 is able to achieve a uniform distribution of
coolant among all of the branches B. In this regard, please refer
to FIGS. 6-7, FIG. 6 a flow distribution comparison between the
active coolant distribution device 1 of one embodiment of the
disclosure and a conventional manifold, and FIG. 7 is a mean
absolute percentage error (MAPE) comparison between the active
coolant distribution device 1 of one embodiment of the disclosure
and the same conventional manifold in terms of flow distribution.
As shown in FIG. 6, the flow rates among the 1.sup.st to 42.sup.nd
branches B in the active coolant distribution device 1 are
substantially uniformly around 1.0 LPM (liter per minute), in FIG.
7, the MAPE of flow rates of all of the branches B in the active
coolant distribution device 1 are less than 10%, the highest value
is around 9.09%. In contrast, in the conventional manifold, in FIG.
6, the flow rate farther away from the inlet is far below 1.0 LPM
but the flow rate closer to the inlet is much higher than 1.0 LPM;
in FIG. 7 shows that the highest MAPE of flow rates of the branches
goes up to 178.4%.
[0048] This is apparent that the above arrangement of the flow
generators 20 in the second primary pipe PP2 can ensure a uniform
distribution of flow rates among all of the branches B so as to
ensure that all of the branches B can obtain a flow rate of coolant
required for cooling heat source.
[0049] It is noted that the quantity of the flow generators 20 can
be adjusted according to actual requirements, such as the height of
the enclosure and the quantity and length of the branches. In some
embodiments, the second primary pipe PP2 may contain a plurality of
flow generators 20 in the number as the same as that of the
branches B; in another embodiment, the number of the flow
generators 20 may be further reduced based on the consideration of
simple design, effectiveness, and cost. In yet another embodiment,
when the enclosure has shorter height and has less number of the
branches, the active coolant distribution device may only employ
one flow generator being arranged next to the branch farthest away
from the access side, which also can achieve a uniform distribution
of flow rates throughout the enclosure.
[0050] In addition, the flow generators 20 are not restricted to be
arranged at the second primary pipe PP2. For example, referring to
FIG. 8, another embodiment of the disclosure provides an electronic
apparatus 9', the electronic apparatus 9' may employ the
aforementioned manifold 10 and flow generator 20, the main
difference between an active coolant distribution device 1' of the
this embodiment and the active coolant distribution device 1 of the
previous embodiments is that the active coolant distribution device
1' has its flow generators 20 arranged in the first primary pipe
PP1. More specifically, there are three flow generators 20 in the
active coolant distribution device 1', and these flow generators 20
can be arranged in the same manner as that of the flow generators
20 in the first primary pipe PP1 of the active coolant distribution
device 1, that is, the flow generators 20 can be respectively
arranged next to the 1.sup.st branch B, the 21.sup.st and 22.sup.nd
branches B, and the 32.sup.nd branch B. In such an arrangement, the
active coolant distribution device 1' also can compensate the
pressure drop caused by frictional loss, local loss, and change in
elevation, thereby ensuring a sufficient amount of coolant for each
branch.
[0051] Further, the first primary pipe and the second primary pipe
may be swapped places as required. For example, referring to FIG.
9, another embodiment of the disclosure provides an electronic
apparatus 9'', the electronic apparatus 9'' may employ the
aforementioned manifold 10 and flow generator 20, the main
difference between an active coolant distribution device 1'' of the
this embodiment and the active coolant distribution device 1 of the
previous embodiments is that the active coolant distribution device
1'' have its first primary pipe PP1 and second primary pipe PP2
swapped places, such that the liquid inlet end IL is located at the
second primary pipe PP2, the liquid outlet end OL is located at the
first primary pipe PP1. This arrangement also can compensate the
pressure drop caused by frictional loss, local loss, and change in
elevation, thereby ensuring a sufficient amount of coolant for each
branch.
[0052] Further, any one of the active coolant distribution devices
in the previous embodiments can employ one or more sensors (not
shown) to achieve automatic control. In detail, one or more sensors
that are suitable for timely detecting physical values of the
coolant (e.g., flow rate or pressure) can be placed within the flow
field of the active coolant distribution device. Note that the
location and number of the said sensors in the active coolant
distribution device can be adjusted as required. The values
detected by the sensors can be fed back to the control center (not
shown) so that the control center can timely adjust the output or
operation mode of the flow generators and therefore each flow
generator become very responsive to the change of the flow field
around. And this help to further reduce the MAPE of flow rate of
each branch to a value under 10%.
[0053] In specific, referring to FIG. 10, there is shown a control
procedure of the active coolant distribution device 1 with one or
more sensors. Firstly, step S100 is to set up the CDU so as to
provide the active coolant distribution device 1 with a coolant in
a fixed flow rate, that is, it is allowed to preset a desired flow
rate for the active coolant distribution device 1 using CDU, and
the preset value of flow rate will be sent to the sensor for the
later calculation of mean absolute percentage error.
[0054] Then, in step S200, the sensor detects the flow
rate/pressure at the exit of branch B every n seconds and transmit
the detected value to the CDU or the control center. The n seconds
may be modified as required. Then or meanwhile, in step S300, the
CDU or the control center can calculate a mean percentage error of
the flow rate of which the sensor is located according to the
received values and the value of the preset flow rate.
[0055] Then, in step S400, CDU determines whether the value of the
mean percentage error falls within .+-.10%, in other words, CDU
determines whether the mean absolute percentage error (MAPE) is
under 10%. The threshold value (i.e., .+-.10%) is exemplary for the
purpose of illustration and can be modified as required.
[0056] If yes, meaning that values of MAPE of the branches B are
determined to be under 10%, step S410 is performed. Step S410 is to
keep the operation mode of the flow generators 20, in other words,
not changing the current operation mode or output setting of the
flow generators 20. In the case that the flow generator 20 is a fan
or a pump, the rotation speed of the flow generator 20 is fixed
when the step S410 is performed. That is, when the MAPE of flow
rate in the specific flow field is under 10%, the difference
between the actual flow rate and the preset value is within an
acceptable range so that there is no need to further change the
operation mode (e.g., the rotation speed) of the flow generator 20
at this moment. Then, returning to step S200 to keep detecting the
flow rate/pressure.
[0057] If no, meaning that values of MAPE of the branches B are
determined to be higher than 10%, then step S420 is performed. Step
S420 is to determine whether the mean percentage error is higher
than 10%. If yes, meaning that the flow rate of the detected area
is too high, then step S510 is performed. Step S510 is to lower the
output of the flow generator 20 (e.g., lower the rotation speed) so
as to lower the flow rate of the detected area. Step S200 is then
performed after performing Step S510 in order to keep detecting the
flow rate/pressure. If no, meaning that the MAPE of the flow rate
of the detected area is neither within 10% nor too high, that is,
the flow rate of the detected area is too low, then step S520 is
performed. Step S520 is to raise the output of the flow generator
20 (e.g., raise the rotation speed) so as to increase the flow rate
of the detected area. Then, step S200 is performed after performing
Step S520 in order to keep detecting the flow rate/pressure.
[0058] Note that the step S420 can be modified to be determining
whether the mean percentage error is lower than -10%; in this case,
if yes, meaning that the flow rate of the detected area is
determined to be too low, then step S520 is performed to raise the
output of the flow generator 20 (e.g., raise the rotation speed) so
as to increase the flow rate of the detected area; if no, meaning
that the MAPE of the flow rate of the detected area is neither
within 10% nor too low, that is, the flow rate of the detected area
is too high, then step S510 is performed to lower the output of the
flow generator 20 (e.g., lower the rotation speed) so as to lower
the flow rate of the detected area.
[0059] According to the controlling steps of the active coolant
distribution device 1 with sensor discussed above, the flow
generators 20 are allowed to be adjusted in response to the actual
condition of the flow field so that the flow generators 20 can
provide required pressure in a dynamic manner to ensure a
sufficient and proper amount of coolant for specific areas, thereby
achieving a uniform distribution of coolant in the overall flow
field.
[0060] Lastly, it is noted that the configuration of the second
primary pipe in the previous embodiments is exemplary and not
intended to limit the disclosure. For example, in other
embodiments, the second primary pipe may omits the second branching
pipe and the third branching pipe; in such a case, the branches are
directly connected to the first liquid inlets of the first
branching pipe, and the first liquid outlets of the first branching
pipe are removed so that the coolant passing through the ejecting
port will then flow toward the liquid outlet end along the second
channel.
[0061] According to the active coolant distribution device and the
electronic apparatus as discussed in the above embodiments of the
disclosure, the placement of one or more flow generators between
the first and second channels that are separated by the first and
second inner wall portions make it possible to draw the coolant to
flow to specific branches, and such an arrangement can compensate
the pressure drop caused by frictional loss, local loss, and change
in elevation. As a result, the flow rates of the branches are
prevented from decreasing with the increase of the distance to the
liquid inlet, thus achieving a uniform distribution of coolant of
the flow field and ensuring a sufficient amount of coolant required
for cooling each heat source.
[0062] It will be apparent to those skilled in the art that various
modifications and variations can be made to the present disclosure.
It is intended that the specification and examples be considered as
exemplary embodiments only, with a scope of the disclosure being
indicated by the following claims and their equivalents.
* * * * *