Information
-
Patent Grant
-
6364007
-
Patent Number
6,364,007
-
Date Filed
Tuesday, September 19, 200024 years ago
-
Date Issued
Tuesday, April 2, 200222 years ago
-
Inventors
-
Original Assignees
-
Examiners
- Lazarus; Ira S.
- Duong; Tho Van
Agents
- Jones, Day, Reavis & Pogue
-
CPC
-
US Classifications
Field of Search
US
- 165 155
- 165 157
- 165 165
- 165 148
- 165 170
- 165 76
- 165 79
-
International Classifications
-
Abstract
A plastic heat exchanger which is simple and inexpensive. The heat exchanger includes an outer duct and a stack of inner ducts, the inner ducts for establishing a first flow path for cooling air or air to be cooled. Each inner duct includes end portions which are stackable upon one another and a middle portion which has a reduced dimension. A seal is placed about each stack of end portions and a second flow path for cooled air or cooling air is formed within the outer duct, between the seals and around the outside of the middle portions of the inner ducts.
Description
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to a plastic counterflow heat exchanger and more particularly to a counterflow heat exchanger that is inexpensive to manufacture and yet is efficient and effective.
2. Description of the Related Art
Inexpensive plastic heat exchangers are very useful because of low manufacturing cost and because such heat exchangers can be custom molded to fit specific spaces, such as those in crowded, free-standing equipment cabinets commonly used to house telecommunications equipment. In such equipment cabinets, the fluid to be cooled is air from a sealed equipment compartment. The cooling fluid, typically, is ambient air. Hence, the fluids being handled are not usually corrosive, nor is high pressure involved.
Most plastic heat exchangers are of the cross flow type as exemplified by U.S. Pat. Nos. 4,997,031 and 4,858,685; and PCT applications SE82/00393 and GB98/03368. Cross flow heat exchangers are typically constructed of rectangular panels or sheets which are stacked together and which have small projections on one of their major surfaces to space one sheet from the next. The cooled fluid enters from one side of the rectangular stack and exits from an opposite side. In a like fashion the cooling fluid enters the stack from a side 90 degrees removed from the flow of the cooled fluid and exits through an opposite side. The fluid flows alternate between sheets, and seals are provided at the corners of the stack to separate the two flows. Such seals are generally adequate in cross flow heat exchangers.
An example of a plastic counterflow heat exchanger is UK patent application No. GB 2,158,569. However, ducting to and from the heat exchanger is not addressed in the application even though it is an important consideration in the design of such units. Further, seals for plastic counterflow heat exchangers are difficult to arrange. Hence, there is still a need for effective, efficient and low cost counterflow heat exchangers.
BRIEF SUMMARY OF THE INVENTION
The present invention resolves some of the problems of the related art by providing a counterflow heat exchanger comprising in combination a plurality of inner ducts forming a plurality of fluid passages, the inner ducts arranged in a stacked disposition, each of the ducts having a middle portion disposed in a first direction, and first and second end portions wherein the middle portion of each duct has a reduced depth dimension in comparison to the depth of the end portions, an outer duct mounted about the stack of inner ducts and forming with the reduced dimensioned middle portions of the inner ducts a plurality of fluid passageways disposed generally parallel to the first direction, and a first seal about the stack of first end portions and a second seal about the stack of second end portions wherein the fluid passages of the inner ducts are separated from the fluid passageways of the outer duct.
It is an object of the present invention to provide a plastic counterflow heat exchanger which is relatively simple and reliable. Another aim of the present invention is to provide a plastic counterflow heat exchanger having low tooling costs. Yet another aspect of the present invention is to provide a plastic counterflow heat exchanger which allows inexpensive custom designs and dimensions for numerous different applications. Still another aspect of the present invention is to provide a plastic counterflow heat exchanger which is efficient and effective.
A more complete understanding of the present invention and other objects, aspects, aims and advantages thereof will be gained from a consideration of the following description of the preferred embodiments read in conjunction with the accompanying drawings provided herein.
BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS
FIG. 1
is a diagrammatic isometric view, partially broken away, of a plastic heat exchanger.
FIG. 2
is a diagrammatic elevation view of an electrical cabinet illustrating the basic concept of a heat exchanger in such an environment.
FIG. 3
is a front elevation view of an inner duct that may be used in the heat exchanger shown in FIG.
1
.
FIG. 4
is a side elevation view of the inner duct shown in FIG.
3
.
FIG. 5
is a sectional plan view of the inner duct shown in
FIGS. 3 and 4
and taken along the line
5
—
5
of FIG.
3
.
FIG. 6
is a plan view of a heat exchanger similar to that shown in FIG.
1
.
FIG. 7
is a diagrammatic isometric view of a stack of inner ducts.
FIG. 8
is a partial diagrammatic section view of a modified heat exchanger.
FIG. 9
is a front elevation view of mirror image molds for forming an inner duct.
FIG. 10
is a front elevation view of mirror image molds for forming an outer duct.
FIG. 11
is a diagrammatic plan view of a stack of inner ducts disposed in a mold.
FIG. 12
is a diagrammatic plan view of the inner ducts of
FIG. 11
after removal of the mold and after a cutting operation.
FIG. 13
is a diagrammatic isometric view showing the stack inner ducts being received by an open mold.
FIG. 14
is a diagrammatic plan view of a stack of inner ducts disposed in a seal cup.
FIG. 15
is a diagrammatic plan view of the inner ducts after cutting of the seal cup and of a portion of the inner ducts.
FIG. 16
is a diagrammatic isometric view of a stack of inner ducts having a seal press fitted to the stack.
FIG. 17
is a front elevation view of the seal shown in FIG.
16
.
FIG. 18
is a side elevation view of the seal shown in
FIGS. 16 and 17
.
FIG. 19
is a diagrammnatic isometric view of another variation of a stack of inner ducts.
FIG. 20
is a front elevation view of the inner duct shown in FIG.
19
.
FIG. 21
is a side elevation view of the inner duct shown in
FIGS. 19 and 20
.
FIG. 22
is a plan view of the inner duct shown in FIGS.
19
-
21
.
DETAILED DESCRIPTION OF THE INVENTION
While the present invention is open to various modifications and alternative constructions, the preferred embodiments shown in the drawings will be described herein in detail. It is understood, however, that there is no intention to limit the invention to the particular forms disclosed. On the contrary, the intention is to cover all modifications, equivalent structures and methods, and alternative constructions falling within the spirit and scope of the invention as expressed in the appended claims.
Referring now to
FIG. 1
, there is illustrated a heat exchanger
10
with counterflowing fluid paths, one path to be cooled and represented by an arrow
12
as the fluid enters the heat exchanger and another arrow
14
as the cooled fluid exits the heat exchanger, and a fluid path for a fluid doing the cooling represented by an arrow
16
for the cooling fluid entering the heat exchanger and an arrow
18
for the cooling fluid exiting the heat exchanger. For purposes of illustration, the heat exchanger includes an outer duct
20
which is generally tubular in shape and a stack
22
of inner ducts, such as the inner ducts
24
,
26
and
28
. The stacked inner ducts are disposed in an interior chamber
30
formed within the outer duct. As can be seen, the heat exchanger
10
is simply constructed and arranged although a commercial heat exchanger will have many more inner ducts as will be explained below.
As can also be appreciated, the heat exchanger
10
of the present invention is a counterflow heat exchanger even though the cooled fluid path
12
,
14
and the cooling fluid path
16
,
18
begin and end generally perpendicular to each other. The cooled fluid path
12
,
14
establishes a first direction represented by a phantom line
32
. The cooling fluid path
16
,
18
is represented by a curved phantom line
34
which diagrammatically may be divided into an inlet portion
36
, a middle portion
38
and an outlet portion
40
. During the time that the cooling fluid path is in its middle portion, it is disposed substantially parallel to the first direction
32
but opposite to it. In this way a counterflow arrangement is created. As already mentioned, counterflow heat exchangers are more efficient when compared to cross flow heat exchangers, all other variables being equal.
It is contemplated that the heat exchanger
10
may be used in an electrical enclosure or cabinet
50
as shown in diagrammatic form in
FIG. 2
where the heat exchanger is placed in a sealed equipment chamber or compartment
52
. A fan
54
draws air to be cooled from the compartment through an inlet vent
56
, through the heat exchanger along a downward flow path and then back to the compartment through an outlet vent
58
. Meanwhile, cooling air from outside the cabinet is drawn in by a fan
60
through a vent
62
in an outer wall of the cabinet, and through an inlet vent
64
of the heat exchanger. The air moves along an upwardly directed flow path through the heat exchanger in a parallel but opposite direction from the cooled air, and then through a heat exchanger outlet vent
66
. Thereafter, the cooling air is exhausted through a vent
68
in another outer wall of the cabinet. It is noted, that the heat exchanged between the two air flows takes place without the cooling or cooled air ever mixing. Thus, the compartment
52
remains sealed even though its air is cooled.
The cooling and cooled fluid flows may move in an opposite direction from that shown if desired, and the cooling fluid may be represented by the arrows
12
,
14
and the cooled fluid may be represented by the arrows
16
,
18
.
Referring now to
FIGS. 3
,
4
and
5
, another embodiment of an inner duct is shown in more detail. The duct
25
is a curved conduit forming a fluid passage with end portions
80
,
82
and a middle portion
84
. To help understand the relative dimensions of the duct, the vertical distance of the inner duct in
FIG. 3
is defined as the length, the horizontal distance is defined as the width and the vertical distance in
FIG. 5
is defined as the depth. It is quite apparent that the depth dimension of the end portions
80
,
82
is about twice the depth dimension of most of the middle portion
84
. Also, the upper and lower surfaces
86
,
88
,
90
and
92
,
FIG. 5
, of the end portions are planar. This configuration allows the inner ducts to be stacked on the planar end portions as shown in
FIGS. 6 and 7
. When this is done, the end portions present a large area inlet
94
and a similar large area outlet
96
to the flow of fluid, such as the cooling air
16
,
18
.
The passage for fluid formed within the inner duct is initially generally horizontal through the inlet end portion
82
as shown in
FIG. 3
, then generally vertical through the middle portion
84
and then generally horizontal again through the outlet end portion
80
. As can be readily appreciated, the inlet and outlet flow paths of the inner duct are generally perpendicular to the flow path through the middle portion of the duct. This feature allows the flow path through the middle portion
84
of the inner duct to be approximately parallel to the direction
32
,
FIG. 1
, of the flow path through the outer duct. It is to be understood that the specific design of the inner and outer ducts may be varied from what is shown depending upon the availability of space or the specific geometry of the intended enclosure.
The inner duct
25
may also include projecting ribs
81
,
83
,
85
on one side of the middle portion
84
and another set of projecting ribs
87
,
89
,
91
on the opposite side of the middle portion. These ribs strengthen the walls of the inner duct, prevent flexing due to air pressure, may be used to optimize airflow (so as to eliminate dead spots) and provide additional surfaces to contact an adjacent inner duct when stacked as shown in FIG.
6
. The ribs also increase the surface area between air flows which enhances heat transfer. It is to be noted that the inner ducts
24
,
26
,
28
,
FIG. 1
, are a slightly different embodiment from inner duct
25
in that no projecting ribs are formed. Hence, it is understood that more or less ribs may be used, or none at all. Also, the shape of the ribs may be varied without departing from the present invention.
Referring now to
FIGS. 6 and 7
, three inner ducts
25
,
27
and
29
are shown in a stacked disposition. When this is done, the larger end portions ensure that there is a space to each side of the middle portion such as the space
100
between the inner ducts
25
and
27
and the space
102
between the inner ducts
27
and
29
. There are also top and bottom spaces
104
,
106
between the inner duct
25
and the outer duct
20
and the inner duct
29
and the outer duct
20
, respectively. These spaces form fluid passageways within the outer duct, where the passageways are coincident with the spaces
100
,
102
,
104
and
106
. To ensure that there is no leakage of the cooled air flow passing through the outer duct and between the inner ducts, nor mixing of the cooled air and the cooling air, a first seal
110
is provided around the first end portions of the stacked inner ducts and a second seal
112
is provided around the second end portions of the stacked inner ducts. The fluid passages for the cooling air (or cooled air) may begin at the inlet end portions
94
of the stacked inner ducts, continue through the middle portions and exhaust through the stacked outlet end portions
96
. The fluid passageways for the cooled air (or cooling air) are formed by the spaces between the middle portions of the inner ducts inboard of the two seals
110
,
112
. In practice there will be numerous inner ducts within a single outer duct and not just the three or four shown here for illustrative purposes. The large number of inner ducts results in a large number of fluid passageways. In turn, this increases the amount of inner duct surface area between the two fluids and enhances heat transfer between them.
Referring now to
FIG. 8
, yet another embodiment of the inner duct is shown. The inner duct
101
includes upper projecting rib
103
and lower projecting rib
105
. Inboard of these projecting ribs are receding ribs, upper receding rib
107
and lower receding rib
109
. The receding ribs may be used to strengthen the inner duct and to provide regions or webs for attachment, such as by welding. For example, an upper half
111
of the inner duct may be welded to a lower half
113
of the inner duct at the receding ribs
107
,
109
. This may be done to enhance the welds made along upper peripheral lip
115
and lower peripheral lip
117
of the inner duct halves. Greater strength of the walls and of the welds may be required if the pressure of the flowing air is increased. Again, the inner ducts of
FIG. 8
are stacked within the outer duct
20
.
The inner ducts may be inexpensively manufactured using a pair of mirror image molds
120
,
122
,
FIG. 9
, and a blow molding or thermoforming technique. These techniques are well known to those skilled in the art. In a like manner, the outer duct
20
may be made inexpensively using a pair of mirror image molds
130
,
132
,
FIG. 10
, and a blow molding or thermoforming technique. The inner and outer ducts may be split evenly so that the molds are identical except for orientation. Referring to
FIG. 1
, the two halves
140
,
142
of the outer duct are clearly shown. The same is true of the two halves
144
,
146
of the inner duct
24
as shown in FIG.
4
.
Each of the duct halves may include a peripheral lip, such as the lip
150
, FIG.
9
and the lip
152
, FIG.
10
. As mentioned, these are used to attach the duct halves together such as by ultrasonic welding or perhaps by an adhesive. These attachment techniques are also well known by those skilled in the art. Wall thicknesses for both the inner ducts and the outer duct are within the range of 0.010 to 0.020 inches and a thermoplastic plastic material, such as polycarbonate may be used for both ducts. Less expensive plastics may also be used but other characteristics of such plastics may not meet customer requirements for use in outdoor equipment cabinets. Under some circumstances, a heat conductive resin may be desirable, and it may be desirable to use an injection molding technique for forming the ducts.
The actual size of a heat exchanger for an equipment cabinet may fall within the approximate dimensions of thirty inches in length, eighteen inches in width and six inches in depth. Also a heat exchanger may include thirty to sixty inner ducts within one outer duct.
Referring now to
FIGS. 11
,
12
, and
13
, one process for forming the seals about the end portions of the inner ducts is illustrated. A stack of four inner ducts
160
,
162
,
164
,
166
are placed adjoining one another. It is to be noted that the end portions
170
,
172
,
174
,
176
, respectively, of the four ducts are initially sealed. The end portions are formed with peripheral lips
180
,
182
,
184
,
186
,
188
,
190
,
192
and
194
, respectively. After the molded halves of the inner ducts are sealed together, the first end portions are placed into a mold
200
. Thereafter, a castable adhesive sealant
202
is placed into the mold such as by pouring. After the sealant hardens, the mold, which may be in two halves
204
,
206
, is removed. A “cut line” is established, such as represented in
FIG. 11
by the horizontal phantom line
210
and a part of the end portion is removed. By initially closing the end portions, a molding procedure may be used without causing any blockage of the ducts. The cut opens the end portions, and thereby the ducts, while maintaining the seal
212
as shown in FIG.
12
. Molds and castable adhesive sealants are well known by those skilled in the art.
A variation of the process is shown in
FIGS. 14 and 15
. Instead of a mold, a seal cup
220
is used to receive four end portions
222
,
224
,
226
,
228
of four stacked inner ducts
230
,
232
,
234
,
236
, respectively. A castable adhesive sealant
240
is poured into the cup and then the sealant is allowed to cure. A cut line, represented by the phantom line
242
, is established and a cut is made to open the ducts and form the geometry shown in FIG.
15
. The remains of the seal cup are then removed and a seal
244
remains around the stacked inner duct end portions.
FIGS. 16
,
17
and
18
illustrate yet another variation of forming a seal around the end portions of a stacked group of inner ducts. As shown in
FIG. 16
, four end portions
250
,
252
,
254
,
256
of inner ducts are stacked, and a seal
260
is force fitted over and around the stacked inner ducts. In this situation, there may be no need to seal the ends of the inner ducts nor is there a need for a cutting step. The seal itself may be formed from an extrusion that has been cut to the desired thickness. Either variation, molding the seal or press fitting the seal is a relatively inexpensive procedure in which relatively inexpensive elements are employed.
Reference is now made to
FIGS. 19-22
. There is illustrated still another variation of an inner duct
270
having a middle portion
272
and two end portions, an inlet end portion
274
and an outlet end portion
276
. As with the
FIGS. 1 and 3
variations, the end portions have a greater depth than the middle portion to allow the inner ducts to be stacked one upon the other while providing a space between two adjacent inner ducts and between the end inner ducts and the outer duct. This is shown in
FIG. 19
, where four inner ducts
270
,
280
,
282
,
284
are stacked and where the stack has surrounding seals
290
,
292
about the end portions of the inner ducts. An outer duct (not shown) is formed about the stack to form a passageway for cooling fluid flow while the cooled fluid flow passes through the inner ducts. It is to be noted that the outer duct may be formed by portions of the cabinet or enclosure if desired or if suggested by design constraints. Thus, inner walls of the enclosure may be used as the outer duct.
An important feature of the inner duct
270
is that the inlet end portion
274
and the outlet end portion
276
form with the middle portion a relatively straight flow path or passage
277
. Also, the arrangement of the inner ducts, when stacked, continues to exhibit a relatively straight flow path or passageway
279
. It can be seen that the counterflows are roughly parallel along the entire heat exchanger. This is contrasted to the
FIGS. 1 and 3
variations where the inlet and outlet flow paths are generally perpendicular to the flow paths around the middle portions.
To illustrate the flow paths of the
FIGS. 19-22
variation, reference is made to
FIG. 19
where the inlet cooled fluid path is represented by the arrow
300
, the outlet cooled fluid path is represented by the arrow
302
, the inlet cooling fluid path is represented by the arrow
304
and the outlet cooling fluid path is represented by the arrow
306
. Once again, these paths may be reversed and the cooled air and cooling air flow paths exchanged.
The specification describes in detail several embodiments or variations of the present invention. Other modifications and variations will, under the doctrine of equivalents, come within the scope of the appended claims. For example, the halves of the ducts may be sealed without use of the lips. Or, the ducts may be molded as a single piece followed by a trimming step. Sizes and shapes may also vary. All of these are considered equivalent structures. Still other alternatives will also be equivalent as will many new technologies. There is no desire or intention here to limit in any way the application of the doctrine of equivalents.
Claims
- 1. A counterflow heat exchanger comprising in combination:a plurality of inner ducts forming a plurality of fluid passages, said inner ducts arranged in a stacked disposition; each of said inner ducts having a middle portion, a first end portion through which fluid passes and a second end portion through which fluid passes wherein said middle portion has a reduced depth dimension in comparison to depth dimensions of said first and said second end portions; said first and said second end portions of each inner duct for supporting said plurality of inner ducts in said stacked disposition, said first and said second end portions of each inner duct being in direct contact with first and second end portions of an adjacent inner duct; a first seal formed about first end portions of said plurality of inner ducts in said stacked disposition and a second seal formed about second end portions of said plurality of inner ducts in said stacked disposition; and an outer duct mounted about said plurality of inner ducts in said stacked disposition and said first and said second seals, and forming with middle portions of said plurality of inner ducts and between said seals, a plurality of fluid passageways wherein the plurality of fluid passages within said inner ducts are separated from the plurality of fluid passageways.
- 2. An apparatus as claimed in claim 1 wherein:said plurality of fluid passageways define a first flow path in a first direction; and said plurality of fluid passages define a second flow path in a second direction, said second direction being generally parallel to said first direction and opposite thereto.
- 3. An apparatus as claimed in claim 2 wherein:said plurality of fluid passages also define an inlet flow path at an angle to said first direction and an outlet flow path at an angle to said first direction.
- 4. An apparatus as claimed in claim 3 wherein:said angles of said inlet flow path and said outlet flow path are generally perpendicular to said first direction.
- 5. An apparatus as claimed in claim 1 wherein:said depth dimensions of said first and said second end portions of each of said plurality of inner ducts is about twice as large as the depth dimension of said middle portion.
- 6. An apparatus as claimed in claim 1 wherein:said first and said second seals are formed fully around said respective end portions.
- 7. An apparatus as claimed in claim 3 wherein:said depth dimensions of said first and said second end portions of each of said plurality of inner ducts is about twice as large as the depth dimension of said middle portion.
- 8. An apparatus as claimed in claim 7 wherein:said first and said second seals are formed fully around said respective end portions.
- 9. An apparatus as claimed in claim 8 wherein:said angles of said inlet flow path and said outlet flow path are generally perpendicular to said first direction.
- 10. An apparatus as claimed in claim 9 wherein:said inner ducts and said outer duct are formed of a thermoplastic material.
- 11. An apparatus as claimed in claim 1 wherein:said inner ducts and said outer duct are formed of a thermoplastic material.
- 12. An apparatus as claimed in claim 1 wherein:said middle portion of each of said plurality of inner ducts includes a plurality of projecting ribs.
- 13. A counterflow heat exchanger comprising in combination:a plastic outer duct having an interior chamber defining a first fluid flow path disposed in a first direction; a plurality of plastic inner ducts partially filling said interior chamber and defining a second fluid flow path parallel to said first direction and opposite thereto; each of said plurality of inner ducts having an inlet end portion and an outlet end portion and a middle portion, said middle portion having a smaller depth dimension than depth dimensions of said inlet end portion and said outlet end portion; a first seal placed around a stacked plurality of inner ducts at the inlet end portion thereof; and a second seal placed around said stacked plurality of inner ducts at the outlet end portion thereof, said first and said second seals sealing a portion of said interior chamber.
- 14. An apparatus as claimed in claim 13 wherein:said inlet end portion and said outlet end portion defining other fluid flow paths at an angle to said first direction; and said other fluid flow paths are generally perpendicular to said first direction.
- 15. An apparatus as claimed in claim 13 wherein:said plurality of inner ducts are stacked one upon another within said interior chamber.
- 16. An apparatus as claimed in claim 15 wherein:said other fluid flow paths are generally perpendicular to said first direction.
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GB |
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Nov 1985 |
GB |
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Apr 1977 |
JP |
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Dec 1981 |
JP |
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WO |
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