HEAT EXCHANGER
A condensing heat exchanger of the kind having a primary heat exchanger and a secondary heat exchanger connected downstream of and in series with the primary heat exchanger. The secondary heat exchanger is arranged to at least partially condense combustion gases discharged from the primary heat exchanger. The primary heat exchanger comprising a drum having a longitudinal axis and the secondary heat exchanger comprising a plurality of small diameter tubes arranged by the side of the drum and extending parallel with the longitudinal axis of the drum.
Latest JOHNSON & STARLEY LIMITED Patents:
This disclosure relates to a heat exchanger, more particularly a condensing type heat exchanger. The disclosure also relates to a method of assembling a heat exchanger, more particularly a condensing type heat exchanger.
A known fuel-fired forced air heat exchanger is set forth in U.S. Pat. No. 4,960,102. The heat exchanger includes a primary heat exchanger and a secondary heat exchanger connected downstream of and in series with the primary heat exchanger. Advantageously, the secondary heat exchanger is arranged to condense the combustion gases discharged from the primary heat exchanger, and so capture latent heat from the available combustion gas. Such heat exchangers are commonly referred to as “condensing” heat exchangers.
The increasing cost of fuel and materials means that there is a need to improve the heating efficiency and assembly of such heat exchangers.
According to one aspect of the invention, there is provided a condensing heat exchanger of the kind having a primary heat exchanger and a secondary heat exchanger connected downstream of and in series with the primary heat exchanger, in which the secondary heat exchanger is arranged to at least partially condense combustion gases discharged from the primary heat exchanger, wherein the primary heat exchanger comprises a drum having a longitudinal axis and the secondary heat exchanger comprises a plurality of tubes extending parallel with the longitudinal axis of the drum.
In exemplary embodiments, the tubes are provided in an array adjacent, e.g. to the side of, the drum.
In exemplary embodiments, a spiral formation is formed in the outer surface of each tube, for promoting flow of combustion gases through the tube.
In exemplary embodiments, the spiral formation begins at a predetermined distance from one end of the tube and stops at a predetermined distance from the opposite end of the tube, so that the ends of the tube are plain.
In exemplary embodiments, the tubes have a small diameter relative to the diameter of the drum.
In exemplary embodiments, the tubes have a diameter in the range 4 mm to 8 mm. In another embodiment the tubes have a diameter in the range 5 mm to 7 mm. In a further embodiment the tubes have a diameter of 6 mm.
In exemplary embodiments, the tubes are arranged in staggered rows.
In exemplary embodiments, the tubes are provided between inlet and outlet plates, as a subassembly.
In exemplary embodiments, the inlet and/or outlet plates are preformed with tube apertures for receiving the ends of the tubes in a pre-defined array.
In exemplary embodiments, the tube apertures have a peripheral flange projecting from the associated plate to provide a sleeve for a section of the tubes.
In exemplary embodiments, the primary heat exchanger consists of a subassembly including a cylindrical drum sealingly attached to an outlet plate; wherein the secondary heat exchanger consists of a subassembly including said plurality of tubes sealing attached to an inlet plate; and wherein the two subassemblies are united with one another by attachment between the outlet plate and inlet plate.
In exemplary embodiments, a closure is attached to the united subassemblies and defines a passageway for combustion gases from the primary heat exchanger to the secondary heat exchanger.
In exemplary embodiments, an array of concentric circles pressed into a surface of the closure to reduce noise during flexure of the closure under thermal expansion.
In exemplary embodiments, the closure is of box-type configuration having four side walls and a base wall, wherein the base wall is pressed outwards, to extend beyond the side walls, and defines four generally triangular sloping surfaces.
According to another aspect of the invention, there is provided a method of assembling a condensing heat exchanger of the kind having a primary heat exchanger and a secondary heat exchanger connected downstream of and in series with the primary heat exchanger, and in which the secondary heat exchanger is arranged to at least partially condense combustion gases discharged from the primary heat exchanger, comprising the steps of:
-
- providing the primary heat exchanger in the form of a drum having a longitudinal axis, and providing the secondary heat exchanger in the form of a plurality of tubes extending parallel with the longitudinal axis of the drum.
In exemplary embodiments, the method includes the step of providing an inlet plate and an outlet plate for the tubes, the inlet and outlet plates being pre-formed with tube apertures for receiving the ends of the tubes in a pre-defined array, arranging the plates in a spaced array with said tubes arranged between the plates with the tubes in alignment with the tube apertures, and driving the plates together in the direction of one another to force the ends of the tubes into the respective tube apertures.
In exemplary embodiments, each tube aperture is provided with a peripheral flange projecting from the associated plate to provide a sleeve for a section of a respective tube.
In exemplary embodiments, the peripheral flange is swaged to fixedly couple the flange to the tubes.
In exemplary embodiments, a spiral thread is formed in the outer surface of each tube prior to incorporation in the assembly.
In exemplary embodiments, each tube is drawn and then the spiral thread is formed on the drawn tube, prior to a second drawing operation, to remove any significant deformations generated when the thread is formed.
In exemplary embodiments, the primary heat exchanger is formed as a subassembly including a cylindrical drum sealingly attached to an outlet plate; the secondary heat exchanger is formed as a separate subassembly including said plurality of tubes sealing attached to an inlet plate; and the two subassemblies are united with one another by attachment between the outlet plate and inlet plate.
In exemplary embodiments, a closure is attached to the united subassemblies to define a passageway for combustion gases from the primary heat exchanger to the secondary heat exchanger.
In exemplary embodiments, an array of concentric circles pressed into a surface of the closure to reduce noise during flexure of the closure under thermal expansion.
In exemplary embodiments, the closure is of pre-formed box-type configuration having four side walls and a base wall, wherein the base wall is pressed outwards, to extend beyond the side walls, and defines four generally triangular sloping surfaces.
In a further aspect of the invention, there is provided a condensing heat exchanger of the kind having a primary heat exchanger and a secondary heat exchanger connected downstream of and in series with the primary heat exchanger, in which the secondary heat exchanger is arranged to at least partially condense combustion gases discharged from the primary heat exchanger, wherein the primary heat exchanger comprises a drum having a longitudinal axis and the secondary heat exchanger comprises a plurality of tubes extending parallel with the longitudinal axis of the drum, wherein a spiral formation is formed in the outer surface of each tube, for promoting flow of combustion gases through the tube.
Other aspects and features of the invention will be apparent from the attached claims and the following description of preferred embodiments, made by way of example only, with reference to the accompanying drawings, in which:
Referring firstly to
The plate 10 further includes an array of tube apertures 20 arranged centrally on the plate 10 in a plurality of rows extending in a direction parallel with line the longest sides 16 of the plate 10. Adjacent rows in the array of tube apertures 20 are staggered relative to one another, e.g. so that the apertures do not align in a transverse direction relative to the longest sides of the plate. The tube apertures 20 are formed by a punching operation and so define a peripheral flange 22 which projects upwardly from the upper surface 24 of the plate 10, as viewed in
Plate 10 is preformed to the configuration shown in
Referring now to
Plate 30 also includes an array of tube apertures 36 arranged centrally on the plate 30 in a plurality of rows extending parallel with the longest sides 34 of the plate 10. Again, adjacent rows in the array of tube apertures 36 are staggered relative to one another. The tube apertures 36 are formed by a punching operation and so define a peripheral flange 38 which projects downwardly from the lower surface 40 of the plate 30, as viewed in
Plate 30 is pre-formed to the configuration shown in
Unlike the plate 10 in
According to an exemplary method of assembly, the two plates 10 and 30 are arranged in a spaced array with a plurality of stainless steel heat exchanger tubes 50 arranged therebetween, e.g. as shown in
An example of a heat exchanger tube 50 for use in the secondary heat exchanger assembly and method of assembly described above is shown in
Test results have shown a 6 mm diameter bore to provide beneficial performance characteristics. In exemplary embodiments, the diameter of the tubes is within the range 4 mm to 8 mm.
A spiral thread 52 is provided as a recessed formation in the outer surface of the tube 50. The configuration of the thread 52 (in terms of pitch and depth relative to the length of the tube) is configured to promote the flow of combustion gases though the tube 50, in use.
Test results show that a pitch of the spiral formation in the region of 6-12 mm (e.g.12 mm), at a depth of 0.69-0.7 mm, with a wall thickness of 0.5±0.03 mm provides optimum strength and heat transfer characteristics for exemplary embodiments.
In exemplary embodiments, the tube 50 is drawn and then the spiral thread 52 is formed on the drawn tube 50. A second drawing operation is then carried out to remove any significant deformations generated when the thread is formed, so as to maintain the accuracy of the tube diameter axial alignment, to promote optimum performance and avoid condensate being trapped within the tube.
The spiral thread 52 does not extend to the ends 54 of the tube 50; the thread 52 begins at a predetermined distance from one end 54 of the tube 50 and stops at a predetermined distance before the opposite end 54 of the tube 50, so that the ends 54 of the tube are plain, to ensure a tight fit with the tube apertures 20, 36 on the plates 10, 30.
A primary heat exchanger assembly 60 according to an exemplary embodiment of the invention will now be described with reference to
The primary heat exchanger assembly 60 has a cylindrical drum 62 of pre-selected diameter. An outlet plate 64 having a central outlet aperture 66 is fitted to the lower end of the drum 62, as viewed in
An inlet assembly 70 is fitted to the upper end of the drum 62, with a thermal insulation plate 72 fixed in place beneath the inlet assembly 70. The inlet assembly 70 affixed to the drum (e.g. by seam welding to a peripheral flange 68) to form an airtight seal with the drum 62.
X-type strengthening formations 74 are formed adjacent each of the corners 76 of the outlet plate 64. These serve as strengthening braces and also allow the material to move during the expansion and contraction cycles. Allowing the material to move eliminates noise issues which would otherwise result, such as ‘bonging’ and ‘ticking’, due to the different expansion rates of the mating materials.
Referring now to
As can be seen from
Once assembled, the finished assembly is ready for incorporation in a condensing heat exchanger, e.g. with a fuel burner (not shown) in communication with the inlet assembly 70 of the primary heat exchanger 60, so that combustion gasses pass through the drum 62, into the box closure 80 and out through the tubes 50 of the secondary heat exchanger 40.
The provision of an array of small diameter tubes as the secondary heat exchanger has been found to be particularly effective, especially when incorporating a spiral thread and/or when arranged in staggered rows. The arrangement of the tubes between the pre-formed inlet and outlet plates provides a convenient and efficient sub-assembly, which can be readily incorporated with the primary heat exchanger sub-assembly described herein.
Claims
1. A condensing heat exchanger of the kind having a primary heat exchanger and a secondary heat exchanger connected downstream of and in series with the primary heat exchanger, in which the secondary heat exchanger is arranged to at least partially condense combustion gases discharged from the primary heat exchanger,
- wherein the primary heat exchanger comprises a drum having a longitudinal axis and the secondary heat exchanger comprises a plurality of tubes,
- wherein each tube has a longitudinal axis and an outer surface which includes a spiral formation concentric with the longitudinal axis of the tube, and
- wherein the tubes are arranged to extend parallel with the longitudinal axis of the drum.
2. (canceled)
3. A condensing heat exchanger according to claim 1 wherein the spiral formation begins at a predetermined distance from one end of the tube and stops at a predetermined distance from the opposite end of the tube, so that the ends of the tube are plain.
4. A condensing heat exchanger according to claim 1 wherein the tubes have a diameter in the range of approximately 4 mm to 8 mm.
5. (canceled)
6. A condensing heat exchanger according to claim 1 wherein the tubes are provided between inlet and outlet plates, as a subassembly of the heat exchanger.
7. A condensing heat exchanger according to claim 6 wherein the inlet plate and outlet plate are preformed with tube apertures for receiving the ends of the tubes in a pre-defined array.
8. A condensing heat exchanger according to claim 7 wherein each tube aperture has a peripheral flange to provide a sleeve for receiving part of the length of a respective tube.
9. A condensing heat exchanger according to claim 1 wherein the primary heat exchanger comprises a subassembly including a cylindrical drum sealingly attached to an outlet plate; wherein the secondary heat exchanger comprises a subassembly including said plurality of tubes sealing attached to an inlet plate; and wherein the two subassemblies are united with one another by attachment between the outlet plate and inlet plate.
10. A condensing heat exchanger according to claim 9, further including a closure for connecting the two subassemblies and defining a passageway for combustion gases to be channelled from the primary heat exchanger to the secondary heat exchanger.
11. A condensing heat exchanger according to claim 10 wherein the closure has a box-type configuration with four side walls and a base wall, wherein the base wall has a pressed configuration in which an outer surface of the base wall extends outwardly.
12. A condensing heat exchanger according to claim 10, further including an array of concentric circles press-formed into a major surface of the closure.
13. A method of assembling a condensing heat exchanger of the kind having a primary heat exchanger and a secondary heat exchanger connected downstream of and in series with the primary heat exchanger, and in which the secondary heat exchanger is arranged to at least partially condense combustion gases discharged from the primary heat exchanger, comprising the steps of:
- providing the primary heat exchanger in the form of a drum having a longitudinal axis,
- providing the secondary heat exchanger in the form of a plurality of tubes, and
- providing an inlet plate and an outlet plate for the tubes, the inlet and outlet plates being preformed with tube apertures for receiving the ends of the tubes in a pre-defined array,
- wherein the method further includes the steps of arranging the plates in a spaced array with said tubes arranged between the plates with the tubes in alignment with the tube apertures, and forcing the ends of the tubes into the respective tube apertures by driving the plates in the direction of one another, and then arranging the tubes to extend parallel with the longitudinal axis of the drum.
14. (canceled)
15. A method according to claim 14 wherein each tube aperture is provided with a peripheral flange projecting from the associated plate to provide a sleeve for part of the length of a respective tube.
16. A method according to claim 15 wherein the peripheral flange is swaged to fixedly couple the flange to the tubes.
17. A method according to claim 13 wherein a spiral thread is formed in the outer surface of each tube prior to incorporation in the assembly.
18. A method according to claim 17 wherein each tube is drawn and then the spiral thread is formed on the drawn tube, prior to a second drawing operation, to remove any significant deformations generated when the thread is formed.
19. A method according to claim 13 wherein: the primary heat exchanger is formed as a subassembly including a cylindrical drum sealingly attached to an outlet plate; the secondary heat exchanger is formed as a separate subassembly including said plurality of tubes sealing attached to an inlet plate; and the two subassemblies are united with one another by attachment between the outlet plate and inlet plate.
20. A method according to claim 19 wherein a closure is attached to the united subassemblies to define a passageway for combustion gases to be channelled from the primary heat exchanger to the secondary heat exchanger.
21. A method according to claim 20 wherein an array of concentric circles is pressed into a surface of the closure to reduce noise during flexure of the closure under thermal expansion.
22. A method according to claim 20 wherein the closure is of pre-formed box-type configuration having four side walls and a base wall, wherein the base wall is pressed outwards, to reduce noise during flexure of the closure under thermal expansion.
Type: Application
Filed: Oct 4, 2011
Publication Date: Sep 5, 2013
Applicant: JOHNSON & STARLEY LIMITED (Northampton)
Inventors: Ian Williams (Northampton), Glenn Page (Northampton), Tim Cooper (Northampton), Ken Worthing (Northampton), Tom Dee (Northampton)
Application Number: 13/877,533
International Classification: F24H 8/00 (20060101); F28F 1/10 (20060101); B21D 53/02 (20060101); F28D 1/053 (20060101);