The present invention relates to an exhaust duct disposed on a combustion apparatus, the combustion apparatus comprising: a burner which ejects air-fuel mixture downward for combustion; and a combustion box which houses therein a heat exchanger heated by combustion gas and which is disposed under the burner.
As this kind of exhaust duct, there is known one comprising: a riser duct section having such an inlet port at a lower-portion thereof as is connected to an exhaust port for combustion gas, the exhaust port being opened at a lower portion of the combustion box, the riser duct section extending upward along an external surface of the combustion box (see, e.g., JP-A-2013-134010). Suppose that a direction normal to the external surface of the combustion box is defined as a front-to-back direction, and that a horizontal direction perpendicular to the front-to-back direction is defined as a lateral direction. Then the riser duct section is formed into a flat shape having a smaller dimension in the front-to-back direction than the dimension in the lateral direction.
By forming the riser duct section into a flat shape as described above, the exhaust passage can be made narrower and the exhaust noises can be reduced. In the flat shape riser duct section, however, a front-side plate part and a back-side plate part become larger in area and, consequently, easily giving rise to deflections thereof. As a result, the width between the front-side and the back-side plate parts fluctuates, and the pressure loss becomes larger in the riser duct section of smaller width.
As a solution, in order to prevent the deflections of each of the front-side and the back-side plate parts from taking place by increasing the rigidity of each of the plate parts of the riser duct section, conventionally, there is also known one in which ribs are erected on the external surface of each of the plate parts. However, by disposing this kind of ribs, the dimensions in the front-to-back direction of the riser duct section increase, thereby resulting in the enlargement of the exhaust duct, and also in bigger size of the combustion apparatus.
In view of the above points, this invention has a problem of providing an exhaust duct which is capable of restraining the fluctuations in width, between the front-side and the back-side plate parts of the riser duct section, and which is capable of avoiding an increase in size.
In order to solve the above problem, this invention is an exhaust duct disposed on a combustion apparatus. The combustion apparatus comprises: a burner which ejects air-fuel mixture downward for combustion; and a combustion box which houses therein a heat exchanger heated by combustion gas and which is disposed under the burner. The exhaust duct comprises: a riser duct section having such an inlet port at a lower-portion thereof as is connected to an exhaust port for combustion gas. The exhaust port is opened at a lower portion of the combustion box and the riser duct section extends upward along an external surface of the combustion box. Suppose: that a direction normal to the external surface of the combustion box is defined as a front-to-back direction; that such a side of the riser duct section as is closer to the external surface of the combustion box is defined as a front side; that an opposite side thereof is defined as a back side; and that a horizontal direction perpendicular to the front-to-back direction is defined as a lateral direction, then the riser duct section is formed into a flat shape having a smaller dimension in the front-to-back direction than the dimension in the lateral direction. In the above arrangement, the riser duct section comprises a rail inside the riser duct section, the rail being elongated in the vertical direction and connecting together the front-side and the back-side plate parts.
According to this invention, since both the front-side and the back-side plate parts of the riser duct section are connected together by the rail, the fluctuations in width of the exhaust passage between both the plate parts can be restrained. Furthermore, since the rail is disposed on the inside of the riser duct section, the riser duct section will not increase in dimension in the front-to-back direction thereof. The exhaust duct can thus be prevented from getting large in size.
By the way, the exhaust duct further comprises a duct coupling part disposed in a lower portion of the riser duct section and at a position above the inlet port so as to couple the riser duct section from the back side thereof to the combustion box. In this case, the position of disposing the rail shall preferably be right above the duct coupling part. According to this arrangement, the combustion gas that comes in from the inlet port to flow upward by detouring around the duct coupling part will flow smoothly upward without striking the lower end of the rail. As a result, increase in the pressure loss and noises due to the occurrence of turbulent flows can be restrained.
Further, according to this invention, among: a distance between a side edge of laterally one side of the riser duct section and an adjoining rail; a distance between a side edge of laterally opposite side of the riser duct section and an adjoining rail; and, in case a plurality of rails are disposed, a distance between the respective rails; at least one of the above distances is varied from the remaining distances. In case a plurality of rails are disposed, lateral dimension or a vertical dimension of at least one of the rails shall be varied in the lateral dimension or vertical dimension of the remaining rails. According to this arrangement, the space partitioned by the rails comes to have natural frequencies that are respectively different from one another. As a result, the resonant vibrations of the exhaust duct due to flame vibrations and consequent resonance sound can be prevented.
The burner 1 is provided with: a box-shaped burner body 11 which opens downward; and a combustion plate 12 which covers a downward opening surface of the burner body 11. The burner body 11 has, on an upper portion thereof, an inlet port 13 which opens sideways. In this arrangement, the air-fuel mixture is supplied from a fan (not illustrated) through the inlet port 13 into the burner body 11. This air-fuel mixture thus supplied is ejected downward from an air-fuel mixture ejection part 14 disposed in the combustion plate 12, thereby performing totally primary air combustion. The combustion plate 12 has a large opening in the central portion thereof. Textile fabric 14a made of heat-resistant fibers is mounted into this opening, and a distribution plate 14b having formed therein a multiplicity of distribution holes is overlapped on top of the textile fabric 14a. The textile fabric 14a and the distribution plate 14b thus constitute an air-fuel mixture ejection part 14.
The combustion box 2 is constituted by: an upper box 21 which is left open on both upper and lower surfaces and which is fastened, at an upper end portion thereof, to a periphery of the lower surface of the burner body 11; a flat and dish-like intermediate box 22 which is fastened to the lower end of the upper box 21; and a lower box 23 which is blocked at both the upper and lower surfaces and which has an upper plate part 23a to be fastened to a bottom plate part 22a of the intermediate box 22. A front portion of the bottom plate part 22a of the intermediate box 22 and the front portion of the upper plate part 23a of the lower box 23 are provided with a vent hole 24 in order to bring into communication with each other the internal space of the intermediate box 22 and the internal space of the lower box 23. Further, at a lower portion of the combustion box 2, i.e., in the lower box 23, the back surface thereof is provided with an exhaust port 25 for the combustion gas. It is thus so arranged that the combustion gas flows from inside the upper box 21 through the inside of the intermediate box 22, the vent hole 24, the inside of the lower box 23 and the exhaust port 25 into the exhaust duct 4.
The heat exchanger 3 is constituted by: a main heat exchanger 31 of fin-and-tube type which is disposed inside the upper box 21 and which is made up of a multiplicity of heat-absorbing fins 31a, and a plurality of heat-absorbing pipes 31b which penetrate through the heat-absorbing fins 31a; and a subsidiary heat exchanger 32 of latent-heat recovery type which is disposed inside the lower box 23 and which is made up of a plurality of upper and lower heat-absorbing pipes 32a elongated in the front-to-back direction in a snaking manner. On an external surface of the side plate portion 21a on laterally one side and on laterally the other side of the upper box 21, there are provided a plurality of connection lids 31c which define, between the respective side-plate 21a, connection passages of the adjoining two heat-absorbing pipes 31b, 31b. All the heat-absorbing pipes 31b are thus arranged to be connected in series. Further, a connection port 31d is provided in a connection lid 31c which defines, between the side plate 21a on laterally one side, a connection passage connected to the heat-absorbing pipes 31b on the upstream end.
Further, a side plate portion 23b on laterally one side of the lower box 23 is provided with: an inlet-side header lid 32b which defines, between the side plate portion 23b, a connection passage connecting together front end portions of a plurality of upper and lower heat-absorbing pipes 32a of the subsidiary heat exchanger 32; and an outlet-side header lid 32c which defines, between the side-plate portion 23b, a connection passage connecting together the back end portions of a plurality of upper and lower heat-absorbing pipes 32a. The inlet-side header lid 32b is provided with a water inlet port 32d for connecting thereto a water supply passage, and the outlet-side header lid 32c is provided with a connection port 32e to which is connected the above-mentioned connection port 31d through a piping (not illustrated). It is thus so arranged that the water from the water supply passage flows, via the subsidiary heat exchanger 32, to the main heat exchanger 31. Further, in that portion of the upper box 21 which is above the main heat exchanger 31, there is provided a water jacket 33 which is constituted by a plurality of upper and lower water pipes in which flows the water passing through the main heat exchanger 31, to prevent the said portion from being overheated. To a downstream end of the water jacket 33, there is connected the hot water supply passage.
With reference also to
By the way, the riser duct section 42 is formed into a flat shape having a smaller dimension in the front-to-back direction than the dimension in the lateral direction. By thus forming the riser duct section 42 into a flat shape, the exhaust passage can be made narrower, thereby reducing the exhaust noises.
However, a flat riser duct section 42 has a larger area in each of the front-side and the back-side plate parts 42a, 42b of the riser duct section 42, thereby giving rise to the possibility of deflections. As a result, the width of the exhaust passage between the front-side and the back-side plate parts 42a, 42b fluctuates, and the pressure loss in the narrow-width parts becomes larger. In this case, in order to prevent the deflection from taking place to each of the front-side and the back-side plate parts 42a, 42b by increasing the rigidity of each of the front-side and the back-side plate parts of the riser duct section 42, it is conceivable to provide the external surface of each of the plate parts 42a, 42b with a rib. However, if such a rib is provided, the front-to-back dimension of the riser duct section 42 will increase, thereby bringing about the enlargement of the exhaust duct 4 and consequent enlargement of the combustion apparatus.
As a solution, in this embodiment, inside the riser duct section 42, a plurality of (e.g., two) rails 421 which are elongated in the vertical direction, are disposed in a manner to connect the front-side and the back-side plate parts 42a, 42b together. Each of the rails 421 is constituted by fitting an H-shaped back rail part 421b which is disposed on the back-side plate part 42b to protrude forward, into an H-shaped front rail part 421a which is disposed on the front-side plate part 42a to protrude forward.
By disposing the rails 421 in this manner, both the front-side and the back-side plate parts 42a, 42b are coupled together by the rails 421, and the fluctuations in the width of the exhaust passage between both the front-side and the back-side plate parts 42a, 42b can be restrained. Further, since the rails 421 are disposed on the inside of the riser duct section 42, the dimension in the front-to-back direction will not increase, thereby preventing the exhaust duct 4 from getting larger in size.
Further, at the bottom of the riser duct section 42, a plurality of (e.g., two) bottomed duct coupling parts 422, which are recessed from the back-side plate parts 42b forward, are disposed in a lower portion of the riser duct section and at a position above the inlet port so as to couple the riser duct section 42 from the back side thereof to the combustion box 2 with screws 422a. In addition, in this embodiment the position of disposing the rails 421 is right above the duct coupling parts 422. According to this arrangement, the combustion gas that comes in from the inlet port 41 to flow upward by detouring around the duct coupling parts 422 will flow smoothly upward without hitting the lower ends of the rails 42. As a result, the increase in the pressure loss and the noises due to the occurrence of turbulent flows can be restrained.
By the way, the front-side and the back-side plate parts 42a, 42b of the riser duct section 42 are integrated by plastic moulding in a state in which flange part 424 formed in the side end part on both lateral sides of the back-side plate part 42b is inserted into a groove formed in the lateral both side-end parts of the front-side plate part 42a.
By the way, in the above-mentioned first embodiment, the distance A1 between a side edge of laterally one side of the riser duct section 42 and the adjoining rail 421, and the distance A2 between a side edge of laterally opposite side of the riser duct section 42 and the adjoining rail 421, and the distance B between the rails 421, 421 are equal to one another. Alternatively, at least one distance of these distances A1, A2, B may be made different from the remaining distances. According to this arrangement, the space partitioned by each of the rails 421 comes to have different natural frequencies. Therefore, the resonant vibrations of the exhaust duct 4 due to flame vibrations and consequent resonance sound caused thereby can be prevented. This kind of second embodiment is shown in
Further, among a plurality of rails 421 that are disposed, also in case the lateral dimension or the vertical dimension of at least one rail 421 is made different from the lateral dimension or the vertical dimension of the other rails 421, similar effect can be obtained. This kind of embodiments are shown in
Descriptions have so far been made of embodiments of this invention with reference to figures. This invention shall, however, be not limited to the above. For example, in the above embodiments the exhaust port 25 is opened on the bottom back surface of the combustion box 2. It may alternatively be so arranged that the lower portion of the riser duct section 42 is bent into L-shape so as to lie along the lower surface of the combustion box 2 and that the inlet port to be connected to the exhaust port is opened on the upper surface of the bent portion.
Number | Date | Country | Kind |
---|---|---|---|
2017-013823 | Jan 2017 | JP | national |