Information
-
Patent Grant
-
6749007
-
Patent Number
6,749,007
-
Date Filed
Tuesday, July 24, 200123 years ago
-
Date Issued
Tuesday, June 15, 200420 years ago
-
Inventors
-
Original Assignees
-
Examiners
Agents
- Wood, Phillips, Katz, Clark & Mortimer
-
CPC
-
US Classifications
Field of Search
US
- 165 41
- 165 125
- 165 101
- 165 140
- 165 144
- 165 51
- 123 4149
-
International Classifications
-
Abstract
A compact cooling system including a radial fan directing air flow outwardly and a plurality of heat exchangers disposed around the radial fan. Each heat exchanger has a plurality of tubes extending between an inlet header and an outlet header, with the headers extending generally in the same direction as the fan axis. A system inlet is connected to the inlet headers and a system outlet is connected to the outlet headers, whereby the length of the connection between each heat exchanger and the system outlet and system inlet is generally the same for each heat exchanger.
Description
BACKGROUND OF THE INVENTION
The invention relates to compact cooling systems, and more particularly to a compact cooling system for vehicles having two heat exchangers with collecting tanks for cooling of different fluids.
A compact cooling system typically includes a number of heat exchangers (e.g. radiators), for cooling engine coolant for a vehicle engine. Rather than use one large radiator, a plurality of smaller radiators is used to reduce the space required to package the cooling system. These radiators, often together with at least one other heat exchanger, are located radially outwardly of a radial fan in a box-like configuration.
The use of multiple radiators will typically require that the radiators be connected in parallel rather than in series, since a series arrangement of the radiators would require greater pressure than is desired to ensure that the coolant circulate through all of the radiators (or put another way, will result in an undesirably high pressure drop from the system inlet to the system outlet).
Of course, a parallel arrangement of the heat exchangers introduces the additional problem of properly splitting the engine coolant flow among the plurality of smaller radiators, so that each may operate at maximum efficiency (i.e., without one radiator receiving more coolant than it should and another receiving less than it should). Where the radiators are approximately equal in size and coolant capacity, it is desirable to have approximately equal coolant flow through and heat transfer for each radiator.
The present invention is directed toward overcoming one or more of the problems set forth above.
SUMMARY OF THE INVENTION
A compact cooling system is provided including a radial fan directing air flow radially outwardly away from the fan axis and a plurality of heat exchangers disposed around the radial fan. Each heat exchanger has a plurality of tubes extending between an inlet header and an outlet header, with the headers extending generally in the same direction as the fan axis. A system inlet is connected to the inlet headers and a system outlet is connected to the outlet headers, such that the length of the flow path from the system inlet to the system outlet is generally the same for each heat exchanger.
In one form of the invention, adjacent headers define a corresponding corner of the compact cooling system, and the system inlet is adjacent one corner of one of the system front and system back, and the system inlet is adjacent another corner of the other of the system front and system back, which corners are opposite each other.
In another form of the invention, feed lines connecting the system inlet and system outlet to the inlet headers and outlet headers have substantially the same cross section with substantially rectangular cross sections defining substantially flat outer faces.
In still another form of the invention, there are two heat exchangers, with the system inlet including a short connection to the inlet header of one of the two heat exchangers and a long connection to the inlet header of the other of the two heat exchangers, and with the system outlet including a long connection to the outlet header of the one of the two heat exchangers and a short connection to the outlet header of the other of the two heat exchangers. In this form, the two heat exchangers may be disposed with the outlet header of one of the two heat exchangers adjacent the inlet header of the other of the two heat exchangers to define a corner of the compact cooling system, where one of the system inlet and the system outlet is adjacent the corner and the other of the system inlet and the system outlet is adjacent one of the inlet header of the one of the two heat exchangers and the outlet header of the other of the two heat exchangers. In this form, the two heat exchangers may alternatively be disposed on opposite sides of the compact cooling system, with the system inlet disposed adjacent the inlet header of one of the two heat exchangers and the system outlet disposed adjacent the outlet header of the other of the two heat exchangers.
In yet another form, a substantially rectangular box frame is provided with the system inlet is disposed adjacent one corner of the box frame at one of the front and back and the system outlet disposed adjacent another corner of the box frame at the other of the front and back.
In still another form, three heat exchangers define three of four sides of a box frame, with the system inlet and system outlet being adjacent corners diagonally opposite one another.
In yet other forms, the heat exchangers are substantially identical size, and the compact cooling system inlet receives coolant from a vehicle and discharges coolant to a vehicle from the system outlet.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1
is a rear perspective view of a compact cooling system made in accordance with the present invention;
FIG. 2
is a front elevation view of the compact cooling system shown in
FIG. 1
;
FIG. 3
is a rear elevation view of a second embodiment of a compact cooling system made in accordance with the present invention;
FIG. 4
is a front elevation view of the compact cooling system shown in
FIG. 3
;
FIG. 5
is a rear perspective view of a third embodiment of a compact cooling system made in accordance with the present invention;
FIG. 6
is a front elevation view of the compact cooling system shown in
FIG. 5
;
FIG. 7
is a perspective view of a feed cross piece of the compact cooling system shown in
FIG. 1
; and
FIG. 8
is a sectional view across the discharge line of the compact cooling system shown in
FIG. 1
as viewed from the rear of the compact cooling system.
DETAILED DESCRIPTION OF THE INVENTION
One embodiment of a compact cooling system
10
incorporating the present invention is shown in
FIGS. 1-2
.
The compact cooling system
10
includes a radial fan
12
surrounded by a frame, generally designated
14
, as described hereafter. The fan
12
rotates about an axis
16
to direct air to flow radially out and away from the axis
16
(and therefore through the heat exchangers arranged on the sides of the frame
14
as described hereafter). The compact cooling system
10
also includes a back or rear wall
20
(
FIG. 1
) and a front wall
22
(FIG.
2
).
The frame
14
is in the general shape of a rectangular box which, in the
FIGS. 1-2
embodiment, includes an upper heat exchanger
30
across the top side which operates independently. Specifically, the upper heat exchanger
30
includes a pair of headers
32
,
34
, one with an inlet
36
and one with an outlet
38
. The upper heat exchanger
30
may be, for example, a conventional charge air cooler for cooling turbocharged or supercharged engine combustion air. Though not shown in the Figures, the upper heat exchanger
30
commonly may include a plurality of suitable tubes extending between the headers
32
,
34
, with suitable fins extending between the tubes (e.g., serpentine fins or plate fins), whereby the air flow in the upward direction caused by the fan
12
passes over the fins and tubes to cool them and thereby cool the coolant passing through the tubes such as is well known in the art. Such cooling could be one or two phase, that is, a hot fluid (liquid or gas) in the tubes could be cooled (one phase) or a gas such as a refrigerant could be condensed (two phase). It should also be understood that heat transfer in the opposite direction could occur within the scope of the invention (i.e., a hot gas could be passed over the fins and tubes which convey a cool fluid). Most commonly, however, the compact cooling system
10
may be used with vehicles in which the ambient air is used to cool engine fluids.
In the
FIGS. 1-2
embodiment, the other three sides of the frame
14
comprise three separate heat exchangers
42
,
44
,
46
, each of which may be of generally a similar, generally identical configuration as described for the upper heat exchanger
30
(i.e., with a pair of headers, one with an inlet and the other with an outlet, with tubes extending between the headers and fins between the tubes, such as partially shown at
50
in FIG.
1
). (It should also be understood, however, that within the broad scope of the invention it would be possible to use the present invention with multipass heat exchangers which, as is understood in the art, have the inlet and outlet in the same headers where there are even numbers of passes.) These three heat exchangers
42
,
44
,
46
are, in the disclosed embodiment, substantially the same size with substantially the same tube sizes and numbers, and therefore to maximize the cooling capacity of the compact cooling system
10
it is desirable to maintain a substantially even coolant flow through each. This is accomplished as described hereafter.
Specifically, there is a single coolant inlet
60
on the rear of the compact cooling system
10
. Coolant from whatever the compact cooling system
10
is used with (e.g., a vehicle engine) enters through the inlet
60
and from there is distributed to the heat exchangers
42
,
44
,
46
as follows:
1. Coolant passes (in the direction of arrow
62
) through a relatively long horizontal feed line
64
connected to the inlet header
66
of one of the lateral or side heat exchangers
46
.
2. Coolant passes (in the direction of arrow
70
) through a relatively long vertical feed line
72
connected to the inlet header
74
of the bottom heat exchanger
44
.
3. Coolant passes through a short feed line
76
to the inlet header
78
at the top of the other lateral heat exchangers
42
.
In each of the inlet headers
66
,
74
,
78
, the coolant is distributed such as is known to the previously described tubes and then passes through the tubes for cooling such as is known (in the direction of arrows
80
,
82
in heat exchangers
42
,
44
as shown in FIG.
1
). The coolant exits the tubes into the outlet headers
86
,
88
,
90
, all of which are located at the bottom of the compact cooling system
10
(the outlet headers
86
,
90
are located at the bottom of the lateral heat exchangers
42
,
46
and the outlet header
88
of the bottom heat exchanger
44
is at the end opposite its inlet header
74
).
Each of the outlet headers
86
,
88
,
90
includes an outlet
92
,
94
,
96
from which the cooled coolant exits and from which it is collected at a single coolant outlet
98
as follows:
1. Coolant passes from the outlet header
86
of heat exchanger
42
(in the direction of arrow
100
) through a relatively long generally horizontal feed line
102
connected to coolant outlet
98
.
2. Coolant passes from the outlet header
88
of heat exchanger
44
(in the direction of arrow
104
) through a very short feed line
106
connected to the coolant outlet
98
.
3. Coolant passes from the outlet header
90
of heat exchanger
46
through another short feed line
108
(in the direction of arrow
110
) connected to the coolant outlet
98
.
The various feed lines may be rectangular in cross section to provide a relatively flat outer surface and thereby allow the outer faces of the compact cooling system
10
to be compact with minimal bulges. Further, the feed lines may also be of substantially similar size to provide similar flow resistance. The connection of the feed lines to the headers may be of any suitable configuration.
It should now be appreciated that the radial air flow caused by the fan
12
will cause air to pass through all four heat exchangers
30
,
42
,
44
,
46
for advantageous cooling with all four. It should also be appreciated that the frame
14
can be advantageously manufactured using the four heat exchangers
30
,
42
,
44
,
46
on all four sides. Further, as best seen in
FIG. 2
, the headers of the heat exchangers may be arranged snugly against one another to prevent air flow therebetween, thereby ensuring that maximum air flow generated by the fan
12
may occur where it is desired, through the tubes and fins of the heat exchangers.
Moreover, in accordance with the present invention, it should also be recognized that of the three heat exchangers
42
,
44
,
46
which operate in parallel with a single inlet
60
and a single outlet
98
will all have relatively identical flow paths for the coolant between the inlet
60
and the outlet
98
. That is, the heat exchangers themselves provide substantially the same path (e.g., with similar headers and similar tubes). Further, the flow outside the heat exchangers is also substantially the same with flow through a relatively long and relatively short feed line:
1. For heat exchanger
42
, coolant passes through a relatively short feed line
76
(between the inlet
60
and inlet header
78
) and a relatively long feed line
102
(between the outlet header
86
and outlet
98
).
2. For heat exchanger
44
, coolant passes through a relatively long feed line
72
(between the inlet
60
and inlet header
74
) and a relatively short feed line
106
(between the outlet header
88
and outlet
98
).
3. For heat exchanger
46
, coolant passes through a relatively long feed line
64
(between the inlet
60
and inlet header
66
) and a relatively short feed line
108
(between the outlet header
90
and outlet
98
).
In short, the flow of coolant will be essentially the same through each heat exchanger
42
,
44
,
46
, with flow through similarly configured flow lines of similar length, with the result being that there will be a substantially identical flow resistance in the paths through the different heat exchangers
42
,
44
,
46
and therefore there will be a natural distribution of substantially identical mass flow of coolant through each to provide maximum efficiency among the three heat exchangers
42
,
44
,
46
. Such an operation can be provided through the conjunction of similar feed lines arranged to extend in similar lengths for each heat exchanger. In practice, there will be small variations from identical mass flow dependant upon variations, such as the number of bends, in each flow path but these are tolerable so long as large discrepancies do not exist. As illustrated, the feed lines can be formed from various straight sections, bent sections, elbows, crosspieces, and the like suitably connected by sleeves.
It should also be understood, however, that variances could also be provided, with smaller feed lines, for example, being provided in slightly shorter lengths than relatively larger feed lines.
A second alternative compact cooling system
110
is illustrated in
FIGS. 3-4
, in which two (rather than three as with the
FIGS. 1-2
embodiment) heat exchangers
112
,
114
are joined. (Similar components to those in the
FIGS. 1-2
embodiment are given the same reference numerals as therein and not generally otherwise described here). The other side heat exchanger
116
may then be used for other purposes, for example, as an oil cooler or air conditioning condenser or gas cooler.
With this embodiment, the system inlet
120
(
FIG. 3
) receives coolant from the vehicle
122
(indicated diagrammatically in
FIGS. 3-4
) on the back side. Coolant from the inlet
120
is split, passing through a short feed line
126
to the inlet header
128
of heat exchanger
112
, and through a longer feed line
130
(in the direction of arrow
132
) to the inlet header
136
of the bottom heat exchanger
114
. The split coolant passes through the tubes of both heat exchangers
112
,
114
, exiting into the outlet headers
140
,
142
, and through those headers to the front of the compact cooling system
110
.
At the front as shown in
FIG. 4
, the coolant from heat exchanger
112
exits the outlet header
142
and passes in the direction of arrow
144
through relatively long feed line
146
to the outlet
150
. Coolant from heat exchanger
114
exits its outlet header
140
and passes through the short feed line
154
to outlet
150
as well. Cooled coolant from the outlet
150
them passes back to the vehicle
122
. It should thus be seen that, as with the first embodiment, the feed lines through which coolant for each heat exchanger
112
,
114
pass are roughly the same length, again providing for preferred coolant distribution between the heat exchangers
112
,
114
as previously described.
A third alternative compact cooling system
200
is illustrated in
FIGS. 5-6
, in which two (rather than three as with the
FIGS. 1-2
embodiment) substantially identical heat exchangers
202
,
204
are joined, with these heat exchangers being on opposite sides of the compact cooling system
200
. (Similar components to those in the previously described embodiments are given the same reference numerals as therein and not generally otherwise described here). In this case, the bottom heat exchanger
206
may again be used for other purposes, for example, as an oil cooler or condenser or gas cooler.
With this embodiment, the system inlet
210
(
FIG. 5
) receives coolant on the back side, and the coolant is split so that part passes through a short feed line
214
to the inlet header
216
of heat exchanger
202
, and through a longer feed line
220
and an elbow
222
to the inlet header
224
of the other side heat exchanger
204
. The split coolant passes through the tubes of both heat exchangers
202
,
204
, exiting into the outlet headers
226
,
228
, and through those headers to the front of the compact cooling system
200
.
At the front as shown in
FIG. 6
, the coolant from heat exchanger
202
exits the outlet header
228
and passes through relatively long feed line
234
to the outlet
236
. Coolant from the other side heat exchanger
204
exits its outlet header
226
and passes through the short feed line
240
to outlet
236
as well. It should thus be seen that, as with the previously described embodiments, the flow paths through which coolant for each heat exchanger
202
,
204
pass have roughly the same flow resistance, again providing for preferred coolant distribution between the heat exchangers
202
,
204
as previously described.
FIGS. 7 and 8
illustrate components which may be used to arrange the feed lines of the various embodiments.
Specifically,
FIG. 7
illustrates a T-piece
250
such as could be used at the inlet
60
of the
FIGS. 1-2
embodiment. The T-piece
250
(and other feed line components) can be formed in any suitable manner dependent upon the coolant to be used (e.g., of materials capable of containing the coolant without unacceptable degradation resulting from corrosion and/or expected temperatures). For example, the feed line components could be formed by plastic injection molding. As previously noted and as illustrated in
FIG. 7
, the lines may be flat rather than round to allow them to be located on the face of the compact cooling system without projecting outwardly from the face (e.g., to maintain a generally rectangular box outer shape).
FIG. 8
illustrated in exploded view the multiple components which can be used to form the feed lines, in this case the outlet structure at the bottom front of the
FIGS. 1-2
embodiment (shown specifically in FIG.
2
). In this sample structure, the relatively long feed line
102
is configured from a long bent portion
260
secured at opposite ends by sleeves
266
and seals
268
to an elbow
270
and a cross piece
272
having the coolant outlet
98
. Suitable shorter portions
280
can be used with such components so that the desired lengths of feed lines can be suitably connected to the various heat exchangers in a modular fashion such as described above.
Still other aspects, objects, and advantages of the present invention can be obtained from a study of the specification, the drawings, and the appended claims. It should be understood, however, that the present invention could be used in alternate forms where less than all of the objects and advantages of the present invention and preferred embodiment as described above would be obtained.
Claims
- 1. A compact cooling system comprising:a radial fan having an axis, said radial fan directing air flow outwardly away from said fan axis; first and second heat exchangers disposed around said radial fan, each heat exchanger having a plurality of tubes extending between an inlet header and an outlet header, said headers extending generally in the same direction as said fan axis with said plurality of tubes spaced from a system front to a system back across said air flow, said two first and second heat exchangers being disposed with said outlet header the first heat exchanger adjacent said inlet header of the other of said two second heat exchanger to define a corner of said compact cooling system; and a system inlet connected to said inlet headers and a system outlet connected to said outlet headers, such that the length of the flow path from said system inlet to said system outlet is generally the same for each heat exchanger, wherein said system inlet includes a short connection to the inlet header of the first heat exchanger and a long connection to the inlet header of the second two heat exchanger, and said system outlet includes a long connection to the outlet header of said first heat exchanger and a short connection to the outlet header of the second exchanger.
- 2. The compact cooling system of claim 1, wherein feed lines connect said system inlet and system outlet to said inlet headers and outlet headers, said feed lines having substantially the same cross section.
- 3. The compact cooling system of claim 2, wherein said feed lines have substantially rectangular cross sections whereby said compact cooling system includes substantially flat outer faces.
- 4. The compact cooling system of claim 1, wherein:said cooling system includes a substantially rectangular box frame extending from a front to a back and surrounding said radial fan; said first and second heat exchangers each generally define one side of said box frame; said system inlet is disposed adjacent one corner of said box frame at one of said front and back; and said system outlet is disposed adjacent another corner of said box frame at the other of said front and back.
- 5. The compact cooling system of claim 4, wherein said box frame includes four sides and said at least two heat exchangers define two of said four sides, further comprising a third heat exchanger generally defining a third side of said box frame four sides.
- 6. The compact cooling system of claim 5, wherein said another corner is diagonally opposite said one corner.
- 7. The compact cooling system of claim 5, wherein said first and second heat exchangers are disposed substantially header to header to define at least a portion of said frame surrounding said radial fan.
- 8. The compact cooling system of claim 1, wherein said heat exchangers are substantially the same size.
- 9. The compact cooling system of claim 1, wherein said compact cooling system inlet receives coolant from a vehicle and discharges coolant to a vehicle from said system outlet.
- 10. The compact cooling system of claim 1, wherein said fan axis lies substantially between said system outlet and said system inlet.
Priority Claims (2)
Number |
Date |
Country |
Kind |
100 41 795 |
Aug 2000 |
DE |
|
100 41 794 |
Aug 2000 |
DE |
|
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