Patent Application
20080164007
1. Field of the Invention
The present invention relates to a condenser tube for use in a heat exchanger.
2. Description of the Prior Art
Heat exchangers normally include a pair of tanks or headers and a plurality of condenser tubes. The headers include header walls which are spaced from and face one another. The condenser tubes extend between the headers and convey cooling fluid through the header walls and into the closed headers. A plurality of fins extend between adjacent condenser tubes for transferring heat from the tubes to air passing through the heat exchanger to ultimately cool the fluid in the tubes. Such condenser tubes are frequently separated into a plurality of channels.
A method of forming a flat strip into such a condenser tube having two ends separated by a pre-determined tube length and two channels extending between the ends is disclosed in the U.S. Pat. No. 6,615,488 to Anders et al. The flat strip is progressively formed via a series of roller stations until the edges are folded into a pair of central abutting flanges engaging the inner surface of the strip along the center. The result is a continuous enclosed B-shaped tube with two channels extending the length of the tube and with the central abutting flanges forming channel sides which separate the channels from one another. The B-shaped tube is then severed to separate it into successive condenser tubes each of the pre-determined tube length.
It is also well known to produce such a condenser tube but having additional channels extending between the ends. The method includes moving the strip through a plurality of forming operations to form a continuous enclosed tube separated into channels by the longitudinally parallel channel sides and severing the enclosed tube to separate the enclosed tube into successive condenser tubes of the pre-determined tube length. Typical severing operations include sawing and die cutting.
In sawing, cutting residue contaminants, such as metal shavings or particles or cutting lubricants, penetrate the openings and either plug or otherwise contaminate the severed sides of the channels. Because of the small size of the individual channels, it is difficult to remove these contaminants.
In a die cutting operation, the blade of the die is moved across and through the entire enclosed tube to sever the exterior of the tube as well as the channel sides. Even with a new die and a sharp blade, some distortion of the channel sides occurs. As the blade dulls, the degree of the distortion increases and the severed edges of the individual condenser tubes become severely distorted.
Whichever severing technique is utilized, undesirable distortion and/or contamination occurs.
Accordingly, the invention provides such a heat exchanger utilizing the multi-channel condenser tube of the aforementioned type and a method of fabricating same by forming at least one aperture in the flat strip at the pre-determined tube length and positioning the aperture in the channel side separating the channels during the forming of the enclosed tube. The severing operation is further defined as severing the enclosed tube across the aperture without engaging the channel side for separating the enclosed tube into successive condenser tubes of the pre-determined tube length between tube ends with the aperture being divided into a notch in adjacent ends of successive condenser tubes.
By severing the enclosed tube across the aperture, the deformation and/or contamination of the ends of the condenser tube is eliminated because there is no severing contact with the channel side. When the condenser tube is installed in the heat exchanger, the notches are disposed within the header walls where they have no effect on the operation of the heat exchanger.
Other advantages of the present invention will be readily appreciated, as the same becomes better understood by reference to the following detailed description when considered in connection with the accompanying drawings wherein:
Referring to the Figures, wherein like numerals indicate corresponding parts throughout the several views, the invention provides a method of fabricating a condenser tube 20 having two ends separated by or defining a pre-determined tube length L and multiple channels 22 each of which having channel sides 24 and channel bottoms 25 extending the length of the condenser tube 20. The method comprises the steps of forming at least one aperture 26 in a flat strip 28 of metal at the pre-determined tube length L (shown in
Although the preferred embodiment includes multiple channels 22 defining multiple channel sides 24, the invention requires only one longitudinally extending channel side 24 separating the channels 22. It is in this longitudinally extending channel side 24 that the apertures 26, and subsequently the notches 31, are positioned.
The flat strip 28 of metal has a center line C that bisects the strip along its length, two outer edges 36 opposing one another on opposite sides of the center line C, and a middle portion. The flat strip 28 is preferably metal but could be of any material suitable for a condenser tube 20.
A plurality of pairs of apertures 26 are formed in the flat strip 28. Each of the pairs is spaced from the next pair by a distance equal to the pre-determined tube length L. Each of the pairs straddles the center line C. In other words, there is one aperture 26 on each side of the center line C as the respective pair is aligned transversely of the center line C. Both apertures 26 are equidistant from the center line C. The apertures 26 will be formed into the channel sides 24 and channel bottoms 25 as the channels 22 are formed via the forming operations. Alternatively, any number of apertures 26 could be formed and the size, shape, and number of the apertures 26 would depend on the design of the enclosed tube 30.
A hole 38 is formed in the flat strip 28 between the apertures 26 of each pair of apertures 26. The hole 38 will be utilized to error-proof the subsequent severing operation. The hole 38 is aligned transversely of the center line C. The position of the hole 38 between the apertures 26 of a particular pair on the flat strip 28 is such that the hole 38 will align under one of the apertures 26 in the channel sides 24 and channel bottoms 25 once the forming operations are completed. The severing operation employs a severing device. The severing device should cut and sever the enclosed tube 30 across the hole 38 and the apertures 26. If the severing device is not properly aligned, its cut will not pass through the apertures 26, and will consequently damage the channel sides 24.
The severed condenser tube 20 is installed between two headers 73 to define a heat exchanger, which is then charged with cooling fluid as is known in the art. Each header 73 includes a header wall 74 and the condenser tube 20 extends through each header wall 74 of the respective header 73. As the heat exchanger is operated, it is checked for leakage of cooling fluid through the hole 38. If the severing device was aligned properly and the condenser tube 20 was cut across the apertures 26, the hole 38 and the notches 31 will be disposed within the respective header wall 74, where a leak would have no effect on the operation of the heat exchanger. However, if the severing device was not properly aligned and the condenser tube 20 was not cut across the apertures 26, the hole 38 and the notches 31 will be disposed outside of the header wall 74, where the cooling fluid will leak through the notches 31 and the hole 38. As such, the leak would be easily detected.
For this error-proofing mechanism to function properly, the hole 38 must align under one of the apertures 26. Without being under one of the apertures 26, the cooling fluid cannot leak through the otherwise enclosed channel 22 and through the hole 38.
The first forming operation (after the forming of the apertures 26, shown in
The next forming operation, shown in
Each of the first and second V shaped grooves 40, 44 are then formed into first and second U shaped grooves 48, 50, respectively, as shown in
Next, an upward bow 52 is formed in the middle portion of the flat strip 28 between the first and second U shaped grooves 48, 50 on each side of the center line C as shown in
The next forming operation, shown in
The next forming operation, shown in
The next forming operation, shown in
The next forming operation, shown in
The next forming operation, shown in
The continuous enclosed tube 30 is then severed, as by the blade 72, transversely across its width and across the apertures 26 to separate the continuous enclosed tube 30 into one condenser tube 20 of the pre-determined tube length L, as shown in
The severing is accomplished by moving the severing device across the enclosed tube 30. The recommended severing device is a blade 72. Once the cut is made, the blade 72 returns to its original position, where it remains until the next pair of apertures 26 is aligned into position. Successive severing operations yield successive condenser tubes 20. Because each pair of apertures 26 is spaced from the next pair by the pre-determined tube length L, each severing operation produces a condenser tube 20 of the pre-determined tube length L.
The apertures 26 in the channel sides 24 eliminate the need for the channel sides 24 to be severed, particularly from a broadside. As such, these portions of the channel sides 24 do not come in contact with the blade 72. Because no contact is made, there is no opportunity for the channel sides 24 to become contaminated, distorted, or otherwise damaged. The portion of the flat strip 28 that encloses the channels 22 still must be severed, however.
In addition to the method of the invention, the invention includes a heat exchanger assembly, shown in
The condenser tube 20 has a center line C and two ends separated by the pre-determined tube length L. The center line C of the condenser tube 20 and the center line C of the flat strip 28 are the same center line C. The condenser tube 20 has a flat cross section with a pair of parallel and spaced tube walls 76 extending between rounded edges 78. The condenser tube 20 includes the plurality of U shaped channels 22 formed during the forming operations of the method. These channels 22 extend between the ends with each of the channels 22 having two parallel channel sides 24 and a channel bottom 25 perpendicular to and connecting said two channel sides 24 to form the U shape. Three U shaped channels 22 are disposed on each side of the center line C with one downwardly facing U shaped channel 22 sharing channel sides 24 with two upwardly facing U shaped channels 22. As mentioned above, these channels 22, including the respective channel sides 24 and channel bottoms 25, are formed and positioned during the forming operations of the method of the invention. The condenser tube 20 extends through a bend outwardly of each of said flanges 46. This bend defines the rounded edges 78 on each side of the condenser tube 20 and the bend defines two edge channels 22 extending along the length of the condenser tube 20.
Each of the upwardly facing U shaped channels 22 disposed next adjacent to the center line C has channel sides 24 abutting one another along the center line C. In other words, the two innermost U shaped channels 22 face upwardly and abut one another as they extend along the center line C. Immediately outward of each of these two upwardly facing U shaped channels 22 is one downwardly facing U shaped channel 22. One additional upwardly facing U shaped channel 22 is disposed immediately outwardly of each of the downwardly facing U shaped channels 22 and one edge channel 22 is disposed immediately outwardly of each of the outermost upwardly facing U shaped channels 22.
Alternatively, the number, shape, and disposition of the channels 22 could vary as is known in the art. However, the invention requires that there be at least one channel side 24 separating two channels 22.
A flange 46 extends generally horizontally from each of the upwardly facing U shaped channels 22 disposed most outwardly on each side of the center line C.
Each of the U shaped channels 22 includes the open notch 31 in the channel sides 24. The notch 31 extends transversely of the center line C from each of the flanges 46 to the respective abutting channel sides 24. The notch 31 is disposed adjacent each of the condenser tube 20 ends. As mentioned above, the notches 31 are a result of the enclosed tube 30 being severed across the apertures 26. It is the utilization of these apertures 26 in the severing step that prevents damage to the channel 22 walls that would be otherwise done by the blade 72 used to sever the condenser tube 20 to the pre-determined tube length L.
The tube also defines a hole 38 disposed transversely of the center line C. The hole 38 is aligned on each of the condenser tube 20 ends and under one of the apertures 26. The hole 38 is used to verify that the notches 31 are disposed within the header walls 74. When the hole 38 is disposed within the header walls 74, a leak therethrough has no effect on the operation of the heat exchanger. However, if the hole 38 were to be disposed outside of the header walls 74, cooling fluid would leak through the aperture 26 and the hole 38 and would be easily detected. As mentioned above, this leak would signify that the condenser tube 20 was not severed across the respective apertures 26.
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.
