The present invention is directed to a removable tube heat exchanger and header plate, and, more particularly, to an improved heat exchanger header plate with a retaining assembly for removable tube heat exchangers.
Heat exchangers typically are formed of a plurality of tube and fin assemblies, the ends of which extend through apertures in opposed header plates. A heating or cooling fluid, e.g., oil, air, etc. flows through the tubes. The tube and fin assemblies must be able to withstand system operating pressures without leaking. Elastomeric seals are sometimes used within the apertures in the header plates to seal the tube within the header plate thus forming a tube to header plate joint. Some heat exchanger designs allow the tube and fin assemblies to be removable such that a damaged tube can be replaced without dismantling an entire heat exchanger. According to prior art heat exchangers, the tubes are removed by raising a first end of a tube into the first of two header plates via a first aperture having a cylindrical seal along the entire length of the header plate opening until the second end of the tube clears the second of two header plates. The second end of the tube is swung outwardly to clear the edge of the second header plate and the tube, which is now angled relative to the first header plate, is then pulled from the first header plate, freeing it from the heat exchanger. Prior art aperture and seal designs allow an elastomeric seal to seat within the first header plate in order to seal the tube during heat exchanger operation, and also allow angular movement of a tube for removal and installation from the header plates. See, U.S. Pat. Nos. 3,391,732; 4,344,478; 4,216,824; 4,930,568; and 5,433,268, each of which is hereby incorporated by reference in their entireties.
However, prior art aperture and seal designs do not optimize the ability of the heat exchangers to withstand high operating pressures and temperatures while also allowing easy removal and installation of individual heat exchanger tubes. Accordingly, it would be desirable to provide a seal retaining assembly to improve the ability of a heat exchanger to withstand high operating pressures and temperatures while also allowing easy removal and installation of individual heat exchanger tubes. It would also be desirable to provide a heat exchanger header plate which reduces or wholly overcomes some or all of the difficulties inherent in prior known heat exchangers having field removable heat exchanger tubes such as pressure capabilities, temperature capabilities, seal integrity, and overall heat exchanger life expectancy.
Particular objects and advantages of the invention will be apparent to those skilled in the art, that is, those who are knowledgeable or experienced in this field of technology, in view of the following disclosure of the invention and detailed description of certain preferred embodiments.
Aspects of the present invention may be used to advantageously provide a heat exchanger having advantageous pressure capabilities while facilitating the removal and installation of individual heat exchange tubes without disassembling the frame of the heat exchanger.
In accordance with a first aspect, a header plate assembly for a heat exchanger includes a plate having a tube side and a tank side. A plurality of apertures extends through the plate. Each aperture has a first portion on the tube side of the plate, the first portion having a first cross-dimension, and a second portion adjacent the first portion and having a second cross-dimension that is smaller than the first cross-dimension, with a first shoulder being formed between the first and second portions. Each of a plurality of collars has an aperture extending therethrough, with a portion of each collar being received in the first portion of one of the apertures in the plate. A seal is positioned in each of the first portions of the apertures and between one of the collars and one of the first shoulders. A plurality of fasteners secures the collars to the plate.
In accordance with another aspect, a heat exchanger includes a first header plate having a tube side and a tank side. A plurality of first apertures extends through the first header plate, with each first aperture having a first portion on the tube side of the first header plate, the first portion having a first cross-dimension, a second portion adjacent the first portion and having a second cross-dimension that is smaller than the first cross-dimension, and a first shoulder formed between the first and second portions. Each of a plurality of flow tubes has a first end and a second end and a plurality of fins on an exterior surface thereof. A first end of one of the flow tubes is received in each of the first apertures. Each of a plurality of collars has an aperture extending therethrough, with a portion of the collar being received in the first portion of one of the first apertures in the first header plate. A seal is positioned in each of the first portions of the first apertures in the first header plate, and surrounds one of the flow tubes and is captured between one of the collars and one of the first shoulders. A plurality of fasteners secures the collars to the first header plate.
From the foregoing disclosure, it will be readily apparent to those skilled in the art, that is, those who are knowledgeable or experienced in this area of technology, that the present invention provides a significant technological advance. Preferred embodiments of the heat exchanger header plate of the present invention can provide improved sealing and higher operating pressures while allowing heat exchanger tubes mounted therein to be individually removable, for example without dismantling the heat exchanger. These and additional features and advantages of the invention disclosed here will be further understood from the following detailed disclosure of certain preferred embodiments.
The figures referred to above are not drawn necessarily to scale and should be understood to provide a representation of the invention, illustrative of the principles involved. Some features of the heat exchanger depicted in the drawings have been enlarged or distorted relative to others to facilitate explanation and understanding. The same reference numbers are used in the drawings for similar or identical components and features shown in various alternative embodiments. Heat exchangers as disclosed herein would have configurations and components determined, in part, by the intended application and environment in which they are used.
Referring to
Heat exchanger 2 comprises a plurality of flow tubes 4 having a plurality of fin elements or fins 6 secured to an exterior surface thereof. Tubes 4 are mounted at a first or upper end 8 to a first or upper header plate 10 and at a second or lower end 12 to a second or lower header plate 14. Upper and lower header plates 10, 14 are fixed with respect to one another by a frame of heat exchanger 2 (not shown). Examples of tube and fin element designs useful in the present invention are shown in U.S. Pat. Nos. 4,570,704; 4,344,478; 4,216,824; 3,391,732; 5,433,268; and 5,236,045 each of which are hereby incorporated by reference in its entirety for all purposes.
Heat exchangers within the scope of the present invention include those having a plurality of heat exchanger tubes arranged in columns and rows, and interconnected to receive and pass a heating/cooling fluid (dependent upon application).
The rows extend longitudinally across the heat exchanger, substantially perpendicular to the direction of air or other external fluid flow, and the columns are substantially perpendicular to the rows. The columns, for example, may be “in-line” or “offset” as shown below (top view of tube-and-fin assemblies):
It is to be understood that alternate offset designs are within the scope of the present invention such as where tube-and-fin assemblies of every fourth row are aligned.
In a preferred embodiment, several rows of tubes 4 extend between upper and lower header plates 10, 14 forming columns. An upper end 8 of each tube 4 extends into an aperture 16 in upper header plate 10 and a lower end 12 extends into aperture 18 in lower header plate 14. Liquid flows from a first or upper tank 17 (seen in
As shown in
As seen in
Some heat exchangers are designed so as to allow tubes 4 to be removable without the need for disassembling the frame of heat exchanger 2. This can allow quick replacement of damaged or worn tubes while minimizing the associated costs. To remove a tube 4 from heat exchanger 2, as seen in the embodiment illustrated in
The upper and lower ends 8, 12 of tube 4 are exposed to system fluid at operating pressure in upper and lower tanks 17, 19, for 353535med in part by the upper and lower header plates respectively, and, therefore, the high pressure side of the heat exchanger is that area above upper header plate 10 and below lower header plate 14. Correspondingly, the portion of tube and fin assembly 2 between the header plates that is exposed to air is considered the low pressure side. As used herein, the term “tube side” refers to the low pressure side of upper and lower header plates 10, 14, respectively, that is, the area of the upper and lower header plates typically exposed to the air and not exposed directly to the high pressure fluid in the upper and lower tanks 17, 19. Accordingly, the term “tank side” refers to the high pressure side of upper and lower header plates 10, 14, that is, the area of the upper and lower header plates 10 and 14 exposed to the high pressure fluid in the upper and lower tanks 17, 19.
The construction of aperture 16 is shown in more detail in
Turning now to
In use, seal 50 is compressed a predetermined amount to provide a proper seal between the tube 4 and the header plate aperture. Seal 50 is held in place by shoulders 34 and 38, with shoulders 34 providing support for seal 50 to resist the pressure incurred at the high pressure side of upper header plate 10, and shoulder 38 providing support far seal 50 during the angled installation of tube 4. Aperture 16 is preferably designed to hold seal 50 captive within upper header plate 10 during installation and removal of tube 4. That is, seal 50 is contained entirely within aperture 16 and does not extend above the tank side of the header plate 10 into the upper tank 17 or below the tube side of the header plate 10. Aperture 16 must be able to accommodate tube 4 being positioned at angle α with respect to longitudinal axis L, which is necessary in order for lower end 12 to clear lower header plate 14 or heat exchange frame during installation and removal without dismantling the frame of the heat exchanger.
The actual dimensions of diameters A, B, C, and D, as well as the depth of each portion, that is, its dimensional length along longitudinal axis L, will be determined by the specific application of a given heat exchanger and the desired insertion angle α required far insertion or removal of a heat exchanger tube. Certain factors that will affect the desired insertion angle α include such factors as the diameter of the flow tube, the length of the flow tube, the dimensions of the fin elements of the flow tube, the operating pressure of the heat exchanger, the type of seal used, and beveling of the portions of the aperture, if desired. Diameter A must be large enough to allow tube 4 to be inserted at insertion angle α to axis L without binding the tube within the portion 30 of the header plate and preventing its proper insertion into the header plate, but small enough to provide proper support to retain the seal under system operating pressure. At the limiting tube angle α for a given heat exchanger as shown in
Diameter B must be larger than diameter A in order to provide for seal 50 and shoulder 34 between first and second portions 30, 32. Diameter B and corresponding shoulders fixedly retain seal 50 and is sized to allow seal 50 to be compressed to a designed compression level when tube 4 is in its normal approximately vertical orientation, seen as the left mast tube 4 in
In certain non-limiting embodiments, diameter D is larger than diameter C. Diameter D is sized to provide clearance for tube 4 when tube 4 is at insertion angle α with respect to longitudinal axis L to prevent binding of tube 4. In other embodiments, diameter D is approximately equal to diameter C or the fourth portion 40 may gradually increase in a beveled manner toward the tank side surface of the heat exchanger plate. The depths of each portion may vary as well based on operating conditions of the heat exchanger. Specifically, for example, the depth of first portion 30 and third portion 36 must be sized to provide a sufficient thickness for shoulder 34 and shoulder 38 which can withstand the pressures incurred by seal 50.
As illustrated in
In another preferred embodiment, shown in
It is to be appreciated that in certain embodiments, tubes 4 may have cross-sectional shapes other than circular. For example, tubes 4 may have an oblong cross-section, as opposed to the circular shape in the embodiment illustrated in
In certain embodiments incorporating oblong tubes, such as those seen in
An alternative embodiment incorporating oblong tubes 4 is illustrated in
A retaining assembly 71 is configured to sealingly retain the lower end 12 of tube 4 within lower header plate 14. Retaining assembly 71 includes a collar 72 seated on lower end 12 of tube 4 between the lowermost fins 6 and lower header plate 14. An aperture 74 extends through collar 72, and receives lower end 12 of tube 4. Collar 72 is secured to lower header plate 14 by bolts 76 that extend through apertures 77 in collar 72 and are threadingly received in threaded apertures 78 formed in lower header plate 14. A washer 79 may be positioned on each bolt 76.
A boss 80 extends downwardly from a lower surface 82 of collar 72, with aperture 74 extending through boss 80. The lower end of aperture 74 has a beveled edge 84 within boss 80. In certain embodiments, beveled edge 84 is beveled at angle of about 45°.
A seal 86 is positioned between collar 72 and lower header plate 14. Seal 86 has an aperture 88 extending therethrough, and receives lower end 12 of tube 4. In certain embodiments, seal 86 is a substantially permanently deformable material, which can be compressed within lower header plate 14 when bolts 76 are tightened, providing a good seal about tube 4 within lower header plate 14. In certain applications, seal 86 is formed of a material that is suitable for long term exposure to elevated temperatures, which may degrade elastomeric materials. A flexible graphite type material, for example, may provide a long life span when exposed to elevated temperatures. As illustrated in
An aperture 90 extends through lower header plate 14, and lower end 12 of tube 4 extends into aperture 90. Aperture 90, as seen in
When the lower end 12 of tube 4 is assembled with lower header plate 14 and collar 72 is secured to lower header plate 14, seal 86 is seated on first shoulder 96, and the end of tube 4 is seated on shoulder 100. Bolts 76 are tightened such that seal 86 is deformed into the space defined by shoulder 96, beveled surface 84 of collar 72, the sidewall of first portion 92 and tube 4, as seen in the leftmost tube assembly in
In certain embodiments, when collar 72 is secured to lower header plate 14, lower surface 82 is spaced from lower header plate 14, thereby allowing further tightening of bolts 76 without collar 72 bottoming out on lower header plate 14.
It is to be appreciated that a retaining assembly 71 as depicted in
Another embodiment of a retaining assembly 101 is illustrated in
In the illustrated embodiment, aperture 110 has two different portions along its longitudinal axis N. On a tube side of aperture 110, a first portion 112 has a first width K. In certain embodiments, first portion 112 has a beveled edge 114, which allows seal 106, and boss 105 of collar 103 to be more easily inserted into aperture 110 of lower header plate 14.
A second portion 116 is adjacent first portion 112 and opens into the tank side of lower header plate 14, and has a second width P that is smaller than first width K. A shoulder 118 is formed between first and second portions 112, 116. The width H of tube 4 is slightly smaller than second width P of second portion 116 such that tube 4 can be received within second portion 116.
When tube 4 is inserted into lower header plate 14 and seal 106 is forced into first portion 112 by collar 103, seal 106 is compressed between tube 4 and the wall of first portion 112, providing a seal about tube 4. Under certain conditions, the pressure from the tank side of lower header plate 14 may also compress seal 106 against the lower surface of boss 105. Shoulder 118, being positioned below seal 106, may also serve to retain seal 106 under certain conditions.
It is to be appreciated that a retaining assembly 101 such as that depicted in
It is to be appreciated that the embodiments described in connection with
Retaining assemblies, including the embodiments described above in connection with
Another embodiment of an oblong tube construction is shown in
A second portion 124 of aperture 120 is adjacent first portion 122 and has a second width S that is larger than first width R. A first shoulder 126 is formed between first and second portions 122, 124 at the upper side of second portion 124. A third portion 128 is adjacent second portion 124 and opens into the tube side of upper header plate 10, and has a third width T that is smaller than second width S. A second shoulder 130 is formed between second and third portions 124, 128 at the lower side of second portion 124. Third portion 128 may have a beveled surface 129, which allows for the tilting of tube 4 as it is removed and replaced, as discussed in greater detail above. As seen in
The width H of tube 4 is slightly smaller than third width T of third portion 128 such that tube 4 can be received within upper header plate 10. In certain embodiments, tube 4 has a tapered outer end surface 132.
Seal 106 is captured within second portion 124, and is compressed between the exterior of tube 4 and the wall of second portion 124. It is to be appreciated that seal 106 may also engage one or both of first shoulder 126 and second shoulder 130 of second portion 124.
In light of the foregoing disclosure of the invention and description of the preferred embodiments, those skilled in this area of technology will readily understand that various modifications and adaptations can be made without departing from the true scope and spirit of the invention.
This application is a continuation of PCT application no. PCT/US2007/069240, designating the United States and filed May 18, 2007; which claims the benefit of the filing date of U.S. Provisional Application Ser. No. 60/747,700, filed May 19, 2006; each of which is hereby incorporated herein by reference in its entirety for all purposes.
Number | Date | Country | |
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60747700 | May 2006 | US |
Number | Date | Country | |
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Parent | PCT/US2007/069240 | May 2007 | US |
Child | 12272880 | US |