This application is directed, in general, to combustion furnaces for HVAC systems, and more specifically, to clamshell heat exchangers.
In gas furnaces used as an aspect of heating ventilating air conditioning (HVAC) systems, a number of heat exchangers are utilized. The heat exchangers may be used in a heating area of the furnace to heat an airstream that passes through the heating area of the furnace. One type of heat exchanger that is used is a “clamshell” heat exchanger. A “clamshell” heat exchanger typically includes two concave halves that are joined either by welding or folding to form a passageway or opening with an inlet and an outlet. To form such a clamshell heat exchanger, individual panel halves, typically formed by stamping mirror images of the combustion chambers into corresponding metal sheets, are coupled together to form the passageway. Clamshell heat exchangers have been used extensively, and yet still, improvements are desired.
The preceding discussion of the background is intended to facilitate an understanding of the present disclosure only. It should be appreciated that the discussion is not an acknowledgement or admission that any of the material referred to was part of the common general knowledge at the priority date of the application.
According to an illustrative embodiment, a clamshell heat exchanger for use in a direct combustion furnace of an HVAC system includes a first clamshell half and a second clamshell half. When the first clamshell half is coupled to the second clamshell half, it forms an assembled clamshell heat exchanger. The clamshell heat exchanger further includes an inlet and an outlet, and a first passageway, which is a combustion passageway, having a first end and a second end. The inlet is proximate the first end. The clamshell heat exchanger also includes a turnaround passageway having a first end and second end, wherein the second end of the first passageway is fluidly coupled to the first end of the turnaround passageway, and includes a second passageway, which is an exhaust passageway, having a first end and a second end, wherein the first end is fluidly coupled to the second end of the turnaround passageway and wherein the outlet is proximate the second end of the second passageway. The first passageway is fluidly coupled to the turnaround passageway and the second passageway is fluidly coupled to the turnaround passageway to form a flow pathway for combustion products. A lateral cross section of the first passageway has more area above a lateral centerline than below the lateral centerline. In one illustrative embodiment, the lateral cross section of the first passageway is shaped like an upside down tear drop or like an airfoil with a leading edge facing upward.
According to another illustrative embodiment, a clamshell heat exchanger for use in a combustion furnace includes a first clamshell half and a second clamshell half. When coupled, the first clamshell half and the second clamshell half form the clamshell heat exchanger. The clamshell heat exchanger further includes a first passageway coupled to an inlet for receiving combustion products from a burner assembly. The first passageway has a longitudinal length in a first direction and forms a first portion of a flow pathway. The clamshell heat exchanger also includes a turnaround passageway coupled to the first passageway and forming a second portion of a flow pathway that receives fluids going in a first direction and turns the fluids at least 120 degrees. The clamshell heat exchanger further includes a second passageway coupled to the turnround passageway and having a longitudinal length in the first direction and forming a third flow pathway that is opposite in direction to the first flow pathway and that comprises two flow streams. The first passageway has a lateral cross section resembling an airfoil with its leading edge closest to the second passageway.
According to still another illustrative embodiment, a clamshell heat exchanger for a combustion furnace includes a heat exchanger body formed with an inlet and an outlet; a first passageway, turnaround passageway, and a second passageway formed in the heat exchanger body that together define a flow pathway from the inlet through the first passageway, then the turnaround passageway, then the second passageway, and finally to the outlet. An outer wall portion and an inner wall portion of the first passageway diverge from one another. The first passageway is not symmetric about a lateral centerline. In one embodiment, a lateral cross section of the first passageway is shaped like a teardrop having a widest portion closest to the second passageway. Other embodiments and teachings are disclosed herein.
Illustrative embodiments of the present invention are described in detail below with reference to the attached drawing figures, which are incorporated by reference herein and wherein:
In the following detailed description of the preferred embodiments, reference is made to the accompanying drawings that form a part hereof, and in which is shown, by way of illustration, specific embodiments in which the invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention, and it is understood that other embodiments may be utilized and that logical structural, mechanical, electrical, and chemical changes may be made without departing from the spirit or scope of the invention. To avoid detail not necessary to enable those skilled in the art to practice the invention, the description may omit certain information known to those skilled in the art. The following detailed description is, therefore, not to be taken in a limiting sense, and the scope of the present invention is defined only by the claims.
In gas furnaces used as an aspect of heating ventilating air conditioning (HVAC) systems, a number of heat exchangers are utilized, such as a “clamshell” heat exchanger. A “clamshell” heat exchanger typically includes two concave halves that are coupled either by welding or folding to form a passageway or opening with an inlet and an outlet. To form such a clamshell heat exchanger, individual panel halves, typically formed by stamping mirror images of the combustion chambers into corresponding metal sheets, are coupled together to form the passageway. The metal sheet may be made with various materials and thickness. In one illustrative embodiment, the clamshell halves are made from 0.74 mm (29 mil) T1-40 EDDS aluminized steel. In other embodiments, the material may be 0.74 mm (29 mil) T1-25 EDDS aluminized steel or DDS aluminized steel, or 409 stainless steel.
With these types of furnaces using clamshell exchangers, air passes through the heating zone from a blower or fan and is heated. The furnaces of this type experience high operating temperatures, which can cause failure within the heating chamber. In this context, the illustrative embodiments of the clamshell heat exchangers, systems, and methods herein may lead to a reduction in thermo-mechanical stress of the clamshell heat exchangers while maintaining combustion, heat transfer, and flue and air-side pressure drops as desired. Moreover, the heat exchangers, systems, and methods may provide improved reliability compared to existing systems and, in some embodiments, allow for lower-cost materials to be used.
One type of furnace that is used in HVAC systems at times is referred to as an “80% gas furnace.” Such a furnace may be one in which approximately 80% of the energy put into the furnace is converted into heat for the purposes of heating a targeted space. Such furnaces may have high operating temperatures, e.g., >1000° Fahrenheit. Other furnaces may be used as well that involve higher efficiencies. Two commercial examples are the LENNOX ML 180 furnace and the LENNOX EL296V gas furnace. The illustrative embodiments herein may be well suited for such furnaces. Unless otherwise indicated, as used throughout this document, “or” does not require mutual exclusivity.
Referring now to the figures and initially to
The illustrative gas furnace 100 includes a housing 108 having an opening 112 that in an assembled position is covered by covering 116. A mounting shelf 120, which is formed with opening 124, is positioned within the housing 108 when assembled. A heating zone 128 is formed in a heat exchanger assembly 130, which includes the plurality of clamshell heat exchangers 104.
The clamshell heat exchangers 104 have a configuration to provide a number of potential benefits over previously known clamshell heat exchangers. The plurality of clamshell heat exchangers 104 are coupled to an inlet panel 132, or vest panel. A plurality of combustion inlets 136 on the inlet panel 132 provide combustion products into inlets of each of the plurality of clamshell heat exchangers 104 and a plurality of combustion outlets 140 on a upper portion of the inlet panel 132 receive the combustion products after they have traveled through the plurality of clamshell heat exchangers 104. While a specific number of clamshell heat exchangers 104 are shown in the figure, those skilled in the art will understand that other embodiments may include fewer or more of the clamshell heat exchangers 104. The flow pathway through each clamshell heat exchanger 104 is generally serpentine with a 180 turn as will be described herein. The inlets 136 and outlets 140 may be coplanar on the inlet panel 132, or vest panel.
The furnace 100 further includes a burner assembly 144. The burner assembly 144 may include a thermostatically-controlled solenoid valve 148 or other valve and one more gas inlets (not explicitly shown). Gas orifices (not explicitly shown) are coupled to a manifold 152. Burners within the burner assembly 144 may correspond in a one-to-one fashion with the plurality of inlets 136 although other illustrative embodiments may have more or fewer burners. When assembled, the burner assembly 144 lines up with the heat exchanger assembly 130 such that burners of the burner assembly 144 align with the plurality of inlets 136 to provide combustion products thereto.
The illustrative furnace 100 also includes a draft-inducer assembly 160. The draft-inducer assembly 160 includes a draft-inducing fan 162 fluidly coupled to a manifold 164, which fluidly couples with the outlets 140 on the inlet panel 132, and further includes a flue 169. The flue 169 is coupled to an outlet of the draft-inducing exhaust fan 162. Burned gases (i.e., products of combustion) may be delivered into flue 169 that vents the gases. In an assembled position, the draft-inducer assembly 160 is positioned relative to the heat exchanger assembly 130 such that manifold 164 at least substantially aligns with the outlets 140 and the flue 169 aligns with an opening in housing 108 to exhaust burned gases.
To move the air that is to be heated for the controlled space, a blower assembly 168 is suspended from the shelf 120. The blower assembly 168 includes a blower 172 with the blower outlet 176 that aligns with the opening 124 in the mounting shelf 120. When assembled and operating, air is pulled into sides of the blower 172 and then forced air exits the blower outlet 176 and goes through the opening 124 in the shelf 120 before going as an airstream over an exterior of the plurality of clamshell heat exchangers 104 before exiting the furnace 100 through a heated-air outlet of the housing 108.
A controller 183 is shown associated with the blower 172. The controller 183 may be operable to turn on the draft-inducing fan 162 to initiate a draft in the heat exchangers 104 in the heating zone 128 and purge potentially harmful unburned gases or gaseous combustion products. The controller 183 activates an igniter to warm up over a set period of time. Then the controller 183 opens the valve 148 to admit gas into the manifold 152 and the one or more gas orifices. The gas exits the orifice(s) and begins to mix with primary air to form a rich gas-air mixture inside the burner(s). Assuming ignition by the igniter (protocols are provided in case that is not the situation), the controller 183 then activates the blower 172, which forces the airstream upward through the opening 124 and across the heat exchangers 104. As the airstream passes over the surfaces of the heat exchangers 104, the air is warmed, whereupon it may be delivered or distributed as needed to provide heating in the space to be conditioned.
Referring now primarily to
The joining of the two clamshell halves 184, 188 forms a clamshell body 196. The claimshell body 196 is shown with contour lines 197 for illustration purposes. The clamshell heat exchanger 104 includes an inlet 200 and an outlet 204. The inlet 200 receives combustion products from a burner assembly, e.g., burner assembly 144 (
The clamshell heat exchanger 104 in the assembled position includes a first passageway 216 having a first end 220 and a second end 224. The first passageway 216 is a combustion passageway that receives combustion products from the burner assembly as introduced through the inlet 200. The second end 224 of the first passageway is fluidly coupled with another portion of the clamshell heat exchanger 104, namely, a turnaround passageway 228.
The turnaround passageway 228 has a first end 232 and a second end 236. The first end 232 is coupled to the second end 224 of the first passageway 216. The turnaround passageway 228 is configured to change the direction of fluid flow received from the first passageway 216 by at least about 120 degrees and in some embodiments by 150 degrees or 180 degrees as shown. The second end 236 of the turnaround passageway 228 is coupled to a second passageway 240.
The second passageway 240 has a first end 244 and a second end 248. The first end 244 of the second passageway 240 is coupled to the second end 236 of the turnaround passageway 228. The outlet 204 is coupled to the second passageway 240 proximate the second end 248 of the second passageway 240. The second passageway 240 may include a first dimple 252 and a second dimple 256 that create a restriction and direct the gas flow around the dimples 252, 256 to cover a broader area of the second passageway 240. The second passageway 240 creates a plurality of flow streams, e.g., flow streams 260 and 264 in portions. A half dimple 268 may be formed on an inboard edge 272 of the second passageway 240. A plurality of veins 282 in the second passageway 240 create a number of flow streams 260, 264, e.g., two or three or more. The veins 282 direct flue gas flow to maximize heat transfer and efficiency while minimizing flow restriction (ie pressure drop) through passageway 240.
The first passageway 216 is fluidly coupled to the inlet 200 on the first end 220 and to the turnaround passageway 228 at the second end 224. The first end 244 of the second passageway 240 is fluidly coupled to the second end 236 of the turnaround passageway 228 and to the outlet 204 at the second end 248. Together, the first passageway 216, turnaround passageway 228, and second passageway 240 form a flow pathway for combustion products through the clamshell heat exchanger 104. The combustion products enter the inlet 200, travel through the first passageway 216, turn at the turnaround passageway 228, go through the second passageway 240, and exit at the outlet 204 from where the flow may go to a draft inducer. Meanwhile, a blower assembly, e.g., blower assembly 168, moves an airstream 274 across an exterior of the clamshell heat exchanger 104 to transfer heat thereto. The heated airstream 274 may then be delivered to a space that is to be conditioned or controlled.
The first passageway 216 has a lateral cross section that has more area above a lateral center line 276, than below the lateral center line. This is seen clearly in
The clamshell heat exchanger 104 includes one or more seal portions or flanges 292 with one or more eyelets 296. The two clamshell halves 184, 188 are attached to each other to avoid leaks from within the passageways 216, 228, 240.
In the illustrative embodiment of
Referring now primarily to
It will be apparent that the first passageway 216 diverges in the direction of the fluid flow along the flow pathway. For example, at approximately 25% of the distance from just beyond the inlet 200 to the far end of the turnaround passageway 228, the height 400 is 2.84 inches and at approximately 50% the height 396 is 3.19 inches, which is a 12% greater in height. At approximately the 75% point, the height 384 is 3.56 inches, which is about 25% greater than the height at the 25% point. The first passageway 216 diverges along a majority of the flow pathway from the inlet 200 to the turnaround passageway 228. In one illustrative embodiment, the first passageway 216 has a first end 220 proximate the inlet 200 and a second end 224 opposite the first end 220, and the first passageway 216 diverges from proximate the first end 220 to the second end 224 by at least 35%.
With reference now primarily to
Referring again primarily to
With reference now primarily to
The final portion 432 of the second passageway 240 that is about 10% to 18% of the longitudinal length of the second passageway 240 has a steep slope back to the outlet 204; in some embodiments, the slope is in the range of −1.25 to −2.5, and in the embodiment shown is approximately −2.3. The negative sign is for the orientation shown in
In some embodiments, the first passageway 216 diverges along the flow path only. In others, both the first passageway 216 and the second passageway 240 diverge along a majority of the flow path for each. The first passageway 216 diverges along a majority of the flow pathway from the first end 220 to the second end 224 of the first passageway 216 and the second passageway 240 diverges along a portion of the flow pathway from the first end 244 to the second end 248 of the second passageway 240. In one embodiment, the two passages 216, 240 both diverge with a slope of 0.08 (orientation of
Referring now primarily to
Referring now primarily to
In some embodiments, the clamshell heat exchangers 104 shown above may include additional features. For example, a folding pattern of the lip 194 over the other clamshell half may be used. “W” shaped stamping may be the pattern between the first passageway and the second passageway to prevent short circuiting of the combustion gases and resultant loss in efficiency. Of course, perimeter profiles of the heat exchanger may be modified to fit into particular furnace applications.
Although the present invention and its advantages have been disclosed in the context of certain illustrative, non-limiting embodiments, it should be understood that various changes, substitutions, permutations, and alterations can be made without departing from the scope of the invention as defined by the claims. It will be appreciated that any feature that is described in a connection to any one embodiment may also be applicable to any other embodiment.