1. Field of the Invention
The subject invention relates to a heat exchanger and method of fabricating the same, and, more specifically to the method of fabricating a heat exchanger of the type including a plurality of refrigerant tubes extending between an inlet header and an outlet header for transferring a refrigerant from the inlet header to the outlet header and a refrigerant conduit disposed in at least one of the headers for uniformly distributing the refrigerant.
2. Description of Related Art
Due to their high performance, automotive style brazed heat exchangers are being developed for residential air conditioning and heat pump applications. Automotive heat exchangers typically utilize a pair of headers with refrigerant tubes interconnecting the headers. Residential heat exchangers are typically larger than automotive heat exchangers and generally require headers that are two to five times longer than the typical automotive heat exchangers. In such heat exchangers, uniform refrigerant distribution is necessary for optimal performance. Refrigerant conduits can be disposed in the headers to improve refrigerant distribution. An example of such a heat exchanger is disclosed in U.S. Pat. No. 1,684,083 to S. C. Bloom.
The Bloom patent discloses a first header defining a first cavity and extending between a pair of first header ends and a second header defining a second cavity and extending between a pair of second header ends. The second header is an inlet header for receiving liquid refrigerant and the first header is an outlet header for outputting refrigerant vapor. A refrigerant conduit is disposed in each of the headers for conveying the refrigerant therethrough. The refrigerant conduits include a plurality of orifices in fluid communication with the corresponding cavities for transferring the refrigerant between the cavities and the refrigerant conduits. The refrigerant conduit disposed in the inlet header insures a uniform and even distribution of the refrigerant throughout the inlet header while the refrigerant conduit disposed in the outlet header insures only dry gas is withdrawn from the outlet header via the refrigerant conduit by a pump. A plurality of refrigerant tubes each defining a fluid passage extend between the first header and the second header for conveying the refrigerant from the first header to the second header.
Heat exchangers such as the type disclosed in the '083 patent to Bloom are typically manufactured by pressing a plurality of refrigerant tubes into the first header and into the second header so that the refrigerant tubes extend between the first header and the second header. A plurality of orifices can be punched in the refrigerant conduits, and the refrigerant conduits can be inserted into the headers at the header ends.
The method of manufacturing heat exchangers of this type oftentimes includes inserting a closed end cap into each of the headers at one of the header ends to seal the header, and inserting another open end cap defining an aperture at the other header ends. The refrigerant conduits can be inserted through the apertures of the corresponding open end caps. Ideally, the end caps and refrigerant conduits are disposed in a predetermined location relative to the refrigerant tubes. A furnace brazing process is typically used to secure the headers, end caps, and refrigerant conduits in the desired, predetermined location. An example of such an assembly and method of manufacturing the same is disclosed in the U.S. Provisional Application No. 61/020,040 to the present inventor, D. E. Samuelson.
However, it is oftentimes difficult to dispose and align the end caps and refrigerant conduits at the desired location within the headers. It is especially difficult to determine whether the orifices of the refrigerant conduits are in the correct location relative to the refrigerant tubes. Even when the components are initially disposed in the correct location, prior to or during the furnace brazing process the refrigerant conduits oftentimes slide within the open end caps and become disposed outside of the desired location. Also, after the furnace brazing process, it is difficult to check for leakage at the joints between the refrigerant conduits and open end caps located inside the headers. There remains a great need for a heat exchanger assembly and efficient method of manufacturing the same providing for refrigerant conduits and end caps being disposed and remaining at the desired location within the headers upon installation, and throughout the furnace brazing operation.
The subject invention provides for such a heat exchanger assembly and an improved method of manufacturing such a heat exchanger assembly. The method includes forming an inner radial abutment in a first refrigerant conduit for abutting an open end cap, and then inserting the first refrigerant conduit through the open end cap. The method includes forming an outer radial abutment engaging the open end cap and spaced from the inner radial abutment by the open end cap. The open end cap is retained in position between the abutments. The first refrigerant conduit and the open end cap are inserted as a subassembly into the first header. The method includes disposing the first header and a second header in spaced and parallel relationship to one another. A plurality of refrigerant tubes each defining at least one fluid passage are inserted into the first header and the second header so that refrigerant tubes extend between the first header and the second header.
The open end cap and first refrigerant conduit are inserted simultaneously, which improves manufacturing efficiency and reduces manufacturing costs, thus making the heat exchanger assembly conducive to high volume production. The open end cap portion of the subassembly can provide a flat surface so that a tool can engage the flat surface and press the subassembly to the predetermined location relative to the refrigerant tubes extending into the first header.
In an elective or alternative embodiment, the method includes cutting a notch extending a predetermined distance axially to a notch bottom in a first header end of the first header. The tool can be used to press the subassembly into the first header until the tool engages the notch bottom, which insures the first refrigerant conduit is located at the desired predetermined location within the header and relative to the refrigerant tubes.
The radial abutments lock the first refrigerant conduit and corresponding open end cap securely in the desired location relative to one another. The radial abutments can prevent the first refrigerant conduit from sliding along the open end cap prior to and during a furnace brazing process. The open end cap and first refrigerant conduit are held in close contact, which creates the conditions necessary for capillary action to form a braze joint during the furnace brazing process, creating a leak-free joint within the first header. As discussed above, the subject invention provides a simplified two-piece design, eliminating the leak susceptible internal joints associated with the three-piece design disclosed in the prior art.
Advantages of the present invention will be readily appreciated as the same becomes better understood by reference to the following detailed description and the accompanying drawings that set forth an exemplary embodiment wherein:
Referring to the Figures, a heat exchanger assembly 20 for dissipating heat is generally shown in
The method typically includes creating a plurality of header slots 44 extending radially into and at predetermined spaced intervals axially along each of the headers 30, 38. The headers 30, 38 may include a lanced surface 46 being flat and extending parallel to the header axes A1, A2 between the corresponding header ends 32, 40. The lanced surfaces 46 may include a plurality of truncated projections 48 disposed in predetermined spaced intervals axially along the corresponding headers 30, 38 and extending into the corresponding cavities 36, 42 to define the plurality of header slots 44, as shown in
The method includes cutting another generally cylindrical tube to define a first refrigerant conduit 22 extending between a pair of first conduit ends 54. The method typically includes cutting a second refrigerant conduit 56 extending between a pair of second conduit ends 58, as shown in
The method typically comprises creating a plurality of orifices 60 in each of the refrigerant conduits 22, 56. The orifices 60 may be located in a conduit body portion 62 of the refrigerant conduit, as shown in
The method comprises forming an inner radial abutment 24 about the circumference of at least one, but preferably both, of the refrigerant conduits 22, 56. The inner radial abutments 24 are typically formed at or about the conduit outlet portions 66, adjacent to the corresponding conduit transition portions 64, as shown in
The method includes inserting at least one, but preferably both, refrigerant conduits 22, 56 having the inner radial abutments 24 through an aperture 68 of an open end cap 26. The refrigerant conduits 22, 56 are typically inserted so that the corresponding open end caps 26 engage the conduit outlet portions 66 adjacent the conduit transition portions 64 and so that the open end caps 26 abut the corresponding inner radial abutments 24. The open end caps 26 typically comprise a symmetrically shape having a cross-sectional area equal to the cross-sectional area of the cavities 36, 42 of the headers 30, 38. The open end caps 26 may comprise a clad two-sided material.
Upon inserting the open end caps 26, the method comprises forming an outer radial abutment 28 about the circumference of at least one, but preferably both refrigerant conduits 22, 56 having the inner radial abutments 24. The outer radial abutments 28 are typically formed at or about the conduit outlet portions 66 and are spaced from the inner radial abutments 24 by the open end caps 26, as shown in
Upon forming the outer radial abutments 28, the method may include gradually expanding the diameter of the refrigerant conduits 22, 56 from a uniform section 70 disposed adjacent the corresponding outer radial abutments 28 to the corresponding conduit ends 54, 58 to define a flare 72 in the refrigerant conduits 22, 56, as shown in
The method comprises inserting each of the refrigerant conduits 22, 56 and the corresponding open end caps 26, i.e. the sub-assemblies, a predetermined distance into the corresponding headers 30, 38 so that the open end caps 26 are pressed into engagement with the interior surface 34 of the headers 30, 38, as shown in
Each of the sub-assemblies may be disposed so that the corresponding conduit body portions 62 engage the interior surfaces 34 of the corresponding headers 30, 38, as shown in
The method may comprise forming a plurality of indentations 78 spaced from one another and axially aligned in two rows in each of the headers 30, 38. The indentations 78 can extend into the corresponding cavities 36, 42 to contact the corresponding conduit body portions 62 for retaining the refrigerant conduits 22, 56 in position against the interior surfaces 34 of the corresponding headers 30, 38, as shown in
The method also typically comprises placing the first header 30 and the second header 38 in a stacker headering station fixture so that the open end cap 26 engaging the first header end 32 is disposed opposite from the open end cap 26 engaging the second header end 40. The method also typically includes creating a core structure 82 and then transferring the core structure 82 to the stacker headering station. The creation of the core structure 82 includes arranging a plurality of refrigerant tubes 76 in spaced and parallel relationship to one another. Each of the refrigerant tubes 76 extend between refrigerant tube ends 84 and include at least one fluid passage 86. The refrigerant tubes 76 typically have a rectangular cross-section and include at least one divider 88 defining a plurality of fluid passages 86, as shown in
Upon transferring the core structure 82 to the stacker headering station, the method comprises inserting the refrigerant tubes 76 into of each of the headers 30, 38, typically by pressing the refrigerant tube ends 84 into the header slots 44 so that the fluid passages 86 of the refrigerant tubes 76 are in fluid communication with the corresponding header cavities 36, 42. Each of the refrigerant tube ends 84 extend through one of the header slots 44 of the corresponding headers 30, 38, as shown in
The method typically comprises furnace brazing the headers 30, 38, end caps 26, 80, refrigerant conduits 22, 56, and core structure 82. The refrigerant conduits 22, 56 are held in close contact with the open end caps 26, as described above, which creates the conditions necessary for capillary action to form a braze joint during the furnace brazing operation. The method finally comprises leak testing the end caps 26, 80 about the header ends 32, 40 to ensure a leak-free heat exchanger assembly 20.
While the invention has been described with reference to an exemplary embodiment, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the invention without departing from the essential scope thereof. Therefore, it is intended that the invention not be limited to the particular embodiment disclosed as the best mode contemplated for carrying out this invention, but that the invention will include all embodiments falling within the scope of the appended claims.