Patent Application
20170167753
1. Field of the Invention
The present disclosure relates generally to water heaters and boilers, and more particularly, but not by way of limitation, to an arrangement in construction of the fin tubes of a heat exchanger for a water heater.
2. Description of the Prior Art
One heat exchanger architecture which is found in the prior art includes an elongated radial burner concentrically received within a circular array of fin tubes. Such heat exchangers have previously been sold by the Assignee of the present invention under the Trademark POWER-FIN®. Examples of such heat exchangers are shown for example in U.S. Pat. No. 4,793,800 to Vallett et al., and U.S. Pat. No. 6,694,926 to Baese et al.
Elongated burners used in such heat exchangers may be constructed in accordance with the disclosures of Baese et al. U.S. Pat. No. 6,694,926; Bodnar et al., U.S. Pat. No. 6,619,951; and/or Smelcer et al., U.S. Pat. No. 6,428,312.
Additionally, it is known in the prior art to use an architecture similar to that described above but having two concentric rings of fin tubes surrounding the elongated burner. An example of a dual concentric ring fin tube architecture is seen in U.S. Pat. No. 9,074,792 to Ellingwood et al.
There is a continuing need in the construction of water heater apparatus to improve the operating efficiency and reduce the foot print or space occupied by the water heater.
A water heater apparatus is disclosed including an upper header having a water inlet and a water outlet, and including a lower header. An inner ring of inner fin tubes extends between the upper and lower headers and is communicated with the upper and lower headers to flow water through the inner fin tubes. Each inner fin tube includes a plurality of annual inner fin tube fins with circumferentially lateral portions of the inner fin tube fins bent to reduce a lateral cross-section dimension of the inner fin tube fins. An outer ring of outer fin tubes extends between the upper and lower headers and is located radially outward of the inner ring of inner fin tubes. The outer fin tubes are communicated with the upper and lower headers to flow water through the outer fin tubes. Each outer fin tube includes a plurality of annular outer fin tube fins with circumferentially lateral portions of the outer fin tube fins bent to reduce a lateral cross-section dimension of the outer fin tube fins. A burner tube is located radially inward of the inner ring of inner fin tubes and is configured to combust a fuel and air mixture and to radially project heated gases past the inner and outer rings of fin tubes to heat water flowing through the fin tubes.
In another embodiment, a water heater apparatus is disclosed including an elongated radial burner extending along a longitudinal center axis of the apparatus. A plurality of longitudinally extending fin tubes are provided. Each fin tube includes a plurality of fins having multiple wiped circumferentially lateral portions. The plurality of fin tubes are arranged to form a first ring concentrically disposed about the burner and a second ring concentrically disposed about the first ring. Each fin tube of a respective ring is arranged with one of the lateral portions thereof facing a corresponding lateral portion of an adjacent fin tube of the respective ring.
In any of the above embodiments the inner fin tubes may be close packed so that the bent circumferentially lateral portions of the inner fin tube fins of each inner fin tube contact the bent circumferentially lateral portions of the inner fin tube fins of each adjacent inner fin tube.
In any of the above embodiments the outer fin tubes may be close packed so that the bent circumferentially lateral portions of the outer fin tube fins of each outer fin tube contact the bent circumferentially lateral portions of the outer fin tube fins of each adjacent outer fin tube.
In any of the above embodiments at least some of the outer fin tubes made contact radially adjacent one of the inner fin tubes.
In any of the above embodiments the inner tube fin fins may each have a radially outer bent portion, at least some of the radially outer bent portions of the inner fin tube fins of at least some of the inner fin tubes contacting the outer fin tubes.
In any of the above embodiments the outer fin tube fins may each have two radially outer bent portions on either side of a radially outermost point of each outer fin tube fin, so that the outer fin tube fins of adjacent outer fin tubes define a V-shape space between their radially outermost points.
In any of the above embodiments a V-shaped baffle may be located in each of the V-shaped spaces.
In any of the above embodiments the bent circumferentially lateral portions of the fin tubes may be bent along lines extending substantially radially outwardly from a central axis of the apparatus.
A method of manufacturing a heat exchanger for a water heater is also disclosed, which method may include the steps of:
(a) providing a first plurality of fin tubes having laterally opposed wiped sides on each fin of the first plurality of fin tubes;
(b) providing a second plurality of fin tubes having laterally opposed wiped sides on each fin of the second plurality of fin tubes, the fins of the second plurality of fin tubes being wiped differently than the fins of the first plurality of fin tubes;
(c) assembling a first ring of the first plurality of fin tubes so that the laterally opposed wiped sides of adjacent fin tubes of the first plurality of fin tubes face each other; and
(d) assembling a second ring of the second plurality of fin tubes, the second ring concentrically disposed about the first ring, so that the laterally opposed wiped sides of adjacent fin tubes of the second plurality of fin tubes face each other.
The method may further include in step (b) providing two radially outer wiped portions on either side of a radially outermost point of each of the fins of the second plurality of fin tubes, so that the fins of adjacent fin tubes of the second ring define a V-shaped space between their radially outermost points.
The method may further include a step of placing a V-shaped baffle in one of the V-shaped spaces.
The method may further include in step (a) providing a radially outer wiped side on each fin of the first plurality of fin tubes, and in steps (c) and (d) assembling the first and second rings such that at least some of the fin tubes of the second plurality of fin tubes touch the radially outer wiped sides of the fins of the first plurality of fin tubes.
The method may further include in step (c) the assembling of the first ring of the first plurality of fin tube so that the laterally opposed wiped sides of adjacent fin tubes of the first ring touch each other.
The method may further include in step (d) assembling the second ring of the second plurality of fin tubes so that the laterally opposed wiped sides of adjacent fin tubes of the second ring touch each other.
Numerous objects features and advantages of the present invention will be readily apparent of those skilled in the art upon a reading of the following disclosure when taken in conjunction with the accompanying drawings.
Referring now to the drawings, and particularly to
An inner ring 22 of inner fin tubes 22A, 22B, 22C, etc., extends between the upper and lower headers 14 and 20. Inner fin tubes 22 are communicated with the upper and lower headers 14 and 20 to flow water through the inner fin tubes 22. An outer ring 24 of outer fin tubes 24A, 24B, 24C, etc., is located radially outward of the inner ring 22 and also extends between the upper and lower headers 14 and 20.
A burner tube or burner 26 is located radially inward of the inner ring 22 and is configured to combust a fuel and air mixture and radially project heated gasses as indicated by arrows 28 past the inner and outer rings 22 and 24 so as to heat water flowing through the fin tubes. The burner 26 may be constructed in any suitable manner including that disclosed in Baese et al. U.S. Pat. No. 6,694,926, or in U.S. Pat. No. 6,619,951 to Bodnar et al., or U.S. Pat. No. 6,428,312 to Smelcer et al., all of which are incorporated herein by reference. The burner 26 is of the type referred to as a pre-mix burner which burns a previously mixed mixture of combustion air and fuel gas. In the system shown in
In order to provide the variable output operation of the burner 26, a variable flow blower 38 delivers the pre-mixed combustion air and fuel gas to the burner 26 at a controlled burner flow rate within a burner flow rate range. The blower 38 may be driven by a variable frequency electric drive motor.
The gas line 34 may be connected to a conventional fuel gas supply (not shown) such as a municipal gas line, with appropriate pressure regulators and the like being utilized to control the pressure of the gas supplied to the venturi 30.
The gas control valve 36 is preferably a ratio gas valve for providing fuel gas to the venturi 30 at a variable gas rate which is proportional to the air flow rate entering the venturi 30, in order to maintain a predetermined air-to-fuel ratio over the flow rate range in which the blower 38 operates.
Combustion gases from the burner 26 exit the water heater 10 through a combustion gas outlet 40 which is connected to an exhaust gas flue 42.
The heat exchanger 12 may be contained within an internal liner 44, which may for example be made of stainless steel plate and be rectangular in cross-sectional plan. The exhaust gas flue 42 may be connected to the internal liner 44 and the combustion gas outlet 40 may be defined in the internal liner 44. The entire heat exchanger 12 and internal liner 44 may be enclosed within an outer housing 46.
As is further described below, each of the fin tubes such as inner fin tube 22 is connected to the upper header via one of the inner ring upper header tube openings 48 and to the lower header via one of the inner ring lower header tube openings 52. Similarly, each of the outer tubes 24 is connected to the upper and lower headers via openings 50 and 54.
The upper header 14 includes first, second and third upper header baffles 56, 58 and 60. Lower header 20 includes first and second lower header baffles 62 and 64.
The arrangement of header baffles provides that the heat exchanger 12 operates in 4 passes. Thus in plan view a first quadrant of the heat exchanger 12 is defined between first and second upper header baffles 56 and 58, a second quadrant is defined between second upper header baffle 58 and second lower header baffle 64, a third quadrant is defined between second lower header baffle 64 and third upper header baffle 60, and the fourth quadrant is defined between third upper header baffle 60 and the first upper header baffle 56 and/or the first lower header baffle 62.
Thus water flowing into inlet 16 of the upper header 14 first flows downward through the tubes located in the first quadrant, then upward through the tubes located in the second quadrant, then downward through the tubes located in the third quadrant, then back upward through the tubes located in the fourth quadrant and out the water outlet 18 of upper header 14.
Each of the inner fin tubes 22 and outer fin tubes 24 are manufactured from a fin tube blank such as the fin tube blank 66 shown if
As best seen in
The inner fin tubes 22 and outer fin tubes 24 are each made from blanks like the fin tubes blank 66 shown in
Similarly, the outer fin tubes 24 may be formed by pulling a fin tube blank 66 through a die 82 having a shape generally as shown in
It is noted that
Regarding inner fin tubes 22, as shown in
As is best illustrated with reference to
In the embodiment shown in
Referring now to the die 80 which is used to form the bent fins 23 of inner fin tubes 22, the die 80 has internal surfaces 94′ corresponding to bent surface 94, 84′ corresponding to bent surface 84, 86′ corresponding to bent surface 86, and 88′ corresponding to unbent outer diameter.
It will be understood that due to the resilience of the fins 74 of the fin tube blank 66, the internal dimensions of surfaces 94′, 84′, 86′ and 88′ of the die 80 will be slightly smaller than the desired final dimensions of the corresponding surfaces of the fin 23 so that after the fins pass through the die and spring back slightly toward their initial shapes, the final dimensions of the fin 23 will be as needed for the final assembly of the heat exchanger 12.
Referring now to
Each of the outer fin tube fins 25 may also have two radially outer bent portions 108 and 110 on either side of a radially outermost point 112 of each outer fin tube fin 25, so that the outer fin tube fins 25 of adjacent outer fin tubes 24 define a V-shaped space 114 there between as is best seen in
As seen in
The V-shaped baffles 116 as shown in plan view in
As is best appreciated in viewing
As is also apparent from
The methods of manufacturing and assembling the heat exchanger 12 can best be appreciated with reference to
As previously described, a plurality of the inner fin tubes 24 are constructed as described with regard to
Then as seen in
Similarly, the outer or second ring of fin tubes 24 is assembled so that laterally outer wiped sides 102 and 104 face each other, and preferably touch each other.
It will be appreciated that the positions of each of the inner fin tubes 22 and outer fin tubes 24 relative to each other is defined by the construction of the upper header 14 shown in
It will be appreciated that the central tube body 68 of each of the fin tubes 22 or 24 is received in the openings in the upper and lower headers. In the construction illustrated, the central tube bodies 68 are received in the openings 48, 50, 52, 54 as appropriate, and then are swaged or otherwise formed so as to hold the central tube bodies 68 firmly in place within the headers 14 and 16. This is a form of construction sometimes referred to as a gasketless header. It is noted that with this construction the heat exchanger 12 does not include tube sheets to hold the array of tubes in place.
As best seen in
As seen in
The wiping of tubes so that they may be arranged in a close packed manner as illustrated results in both a smaller footprint for the assembled water heater, and a higher efficiency of the water heater due to the improved flow pattern of gases through the fins.
Thus the wiping of the tube fins generally causes the gas flow to closely adhere to the central tube bodies 68 thus enhancing heat transfer from the hot combustion gases 28 to the water flowing through the central tube bodies 68.
With reference to
The central axes of the central tube bodies of the inner fin tubes 22 may be placed upon a diameter 200 of approximately 14.25 inches, and the axes of the outer fin tubes 24 may be placed on a diameter 202 of approximately 17.5 inches about the central axis 99 of heat exchanger 12. With this arrangement each of the inner fin tubes 22 subtend an angle of approximately 12.9 degrees about the central axis 99, and each of the outer fin tubes 24 subtend an angle of approximately 10.6 degrees about the central axis 99.
Such an arrangement may provide a water heater apparatus 10 having a nominal output of 3.5 MBtu per hour. With this arrangement operating efficiencies as high as 87% may be achieved. Other arrangements may be used to provide nominal outputs ranging for example from 2.5 MBtu per hour to 5.0 MBtu per hour.
Thus it is seen that the apparatus and methods of the present invention readily achieve the ends and advantages mentioned, as well as those inherent therein. While certain preferred embodiments of the invention have been described for purposes of the present disclosure, numerous changes in the arrangement and construction of parts and steps may be made by those skilled in the art, which changes are encompassed within the scope and spirit of the present invention as defined by the appended claims.
