JP7248276B2 - Water heater - Google Patents

Description

The present invention relates to a water heater provided with a burner unit comprising a plurality of burners and a gas distribution unit for distributing and supplying fuel gas to each burner of the burner unit.

The water heater includes a combustion device provided with a burner unit in which a plurality of burners are arranged in a lateral direction, and a heat exchanger disposed above the combustion device, and a fuel gas and combustion air. The water passing through the heat exchanger is heated and discharged by the combustion exhaust of the burner unit that ignites and burns the air-fuel mixture with.
Moreover, as disclosed in Patent Document 1, a manifold (gas distribution unit) for supplying fuel gas to each burner of the burner unit is provided on the front surface of the combustion device. This gas distribution unit consists of a main body with a nozzle projecting toward the burner, a lid plate attached to the front side of the main body, and a sealing member for sealing between the main body and the lid plate. A downstream gas passage to which fuel gas is supplied and a plurality of distribution passages communicating with the gas passage and each having a different number of nozzle regions are formed by the concave portion and the raised portion provided on the inner surface of the lid. ing.

JP 2015-143588 A

In the above-mentioned conventional water heater, a controller housing an electric circuit board is installed below the gas distribution unit, and harnesses for electronic components such as temperature sensors provided in heat exchangers and pipes are connected to the electric circuit board of the controller. be done. Therefore, it is difficult to combine a plurality of harnesses, and if separate members are used to combine the harnesses, the number of components increases, leading to an increase in cost.

Therefore, the present invention makes it possible to easily organize the harnesses of electronic components without increasing the number of parts, and to keep the harnesses away from the heater even when the heater provided in the piping of the heat exchanger is close to the main body. It is an object of the present invention to provide a water heater capable of preventing adverse effects of heat from a heater .

In order to achieve the above object, the invention according to claim 1 provides a heat exchanger, and a burner unit arranged below the heat exchanger and having a plurality of burners arranged side by side in the left-right direction. and an inner case for housing a burner unit, and a plurality of nozzles for supplying fuel gas to each burner are arranged side by side in the front surface of the inner case, and a plurality of nozzles are divided by a predetermined number. A gas distribution unit comprising a main body having a distribution section, a plurality of passages connected to the lower part of each distribution section in an inclined manner, and a lid attached to the front surface of the main body to cover the distribution section and the passage. A water heater to which
Pipes connected to the heat exchanger are arranged vertically on either the left or right outside of the inner case, and the pipes are attached with heaters positioned outside in the left and right direction of the main body when viewed from the front. while
At least at the ends of the left and right ends of the main body on the side where the heater is attached , there are projections that project forward without projecting outward in the left-right direction from the ends, and projections that protrude outward in the left-right direction. A harness holding portion is formed by alternately arranging a plurality of protruding claw portions in the vertical direction, and at least one of the plurality of claw portions adjacent to the heater is positioned above and below the convex portion. are arranged with a shift toward the central portion in the left-right direction of the main body .

According to the first aspect of the invention, the harness holding portion is formed at the end of the main body of the gas distribution unit. It is possible to summarize easily without increasing the number of points.
In particular , by arranging the claw portion toward the central portion side relative to the upper and lower convex portions, a portion of the harness can be linearly hooked on the central portion side of the convex portion. Therefore, even when the heater provided in the piping of the heat exchanger is close to the right side of the main body, the harness can be separated from the heater to prevent adverse effects of the heat of the heater.

Fig. 2 is a front view of the water heater with the front cover removed; 1 is a perspective view of a combustion device; FIG. 1 is an exploded perspective view of a combustion device and gas distribution unit; FIG. It is a front view of a main body. It is a rear view of a main body. It is explanatory drawing of a harness holding|maintenance part, (A) shows the expansion perspective view from the back lower side, (B) shows the expansion perspective view from the front lower side, respectively. FIG. 10 is an explanatory diagram of the flow dividing action of the fuel gas by the rear-side flow dividing projection; It is a front view of a lid. It is a rear view of a lid. It is a perspective view from the front of a lid. It is a perspective view from the back of a lid. FIG. 5 is an explanatory diagram of the flow dividing action of the fuel gas by the front-side flow dividing projection; Fig. 3 is a front view of the gas distribution unit; 13A is a sectional view taken along the line AA of FIG. 13, and FIG. 13B is a sectional view taken along the line BB. (A) is a sectional view taken along the line CC of FIG. 13, and (B) is a sectional view taken along the line DD. (A) is a plan view of the gas distribution unit, and (B) is a cross-sectional view taken along line EE. (A) is an enlarged view of the A portion of FIG. 14, and (B) is an enlarged view of the B portion. (A) is an enlarged view of the C section in FIG. 15, and (B) is an enlarged view of the D section. FIG. 5 is an explanatory diagram of the flow dividing action of the fuel gas by the rear side and front side flow dividing protrusions.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is an explanatory diagram showing an example of a water heater, showing a housing 2 from the front with a front cover removed. A water heater 1 comprises a rectangular box-shaped housing 2 in which a combustion device 3, a heat exchanger 4, and an exhaust hood 5 are installed in this order from below. A gas distribution unit 6 for distributing and supplying fuel gas to a burner unit 21 (described later) in the combustion device 3 is mounted on the front surface of the combustion device 3, and a supply unit 6 for supplying combustion air is mounted on the bottom surface of the combustion device 3. Air fan 7 is assembled. A controller 8 containing an electrical circuit board is installed laterally on the inner bottom surface of the housing 2 on the front side of the air supply fan 7 and below the combustion device 3 .
The heat exchanger 4 is provided with a plurality of fins (not shown) at predetermined intervals in the left-right direction inside the casing, and is provided with heat transfer tubes 9 that pass through the fins in a meandering manner. and heat exchange with water flowing in the heat transfer tube 9 is possible.
The exhaust hood 5 has a laterally oblong exhaust pipe 10 on its front surface and protrudes forward through the front cover so that combustion exhaust that has passed through the heat exchanger 4 can be discharged to the outside.

The lower surface of the housing 2 is provided with a gas inlet 11 to which an external gas pipe is connected, a water inlet 12 to which a water pipe is connected, and a hot water outlet 13 to which a pipe to a hot water tap is connected. . Among these, the gas inlet 11 is connected to the gas distribution unit 6 within the housing 2 via a gas supply section 14 having a main valve, a proportional valve, and the like. The water inlet 12 is connected to the upstream end of the heat transfer pipe 9 of the heat exchanger 4 via the water supply pipe 15, and the hot water outlet 13 is connected to the downstream end of the heat transfer pipe 9 via the hot water outlet pipe 16. .

As shown in FIGS. 2 and 3, the combustion device 3 has a plurality of flat burners 22, 22, . The burner unit 21 is housed via an L-shaped inner plate 23 when viewed from the side. Each rich/lean burner 22 has a light side introduction port (not shown) and a rich side introduction port (not shown) opening forward to introduce fuel gas and primary air. is provided with a flame hole portion 24 consisting of a thick flame hole of . On the front surface of the inner plate 23, corresponding to the light side introduction port and the rich side introduction port of each rich and thin burner 22, respectively, there are a lower light gas supply hole 25 which is an oblong burring hole and a circular shape. The upper rich gas supply hole 26, which is a burring hole, is arranged side by side in the left-right direction and exposed to an opening formed in the front lower portion of the inner case 20. As shown in FIG. A discharge electrode 27 for ignition, a frame rod 28 for detecting flame, and a viewing window 29 are provided in the upper front portion of the inner case 20 so as to protrude above the burner unit 21 through the inner case 20 .

The gas distribution unit 6 is attached to the front surface of the inner case 20 so as to close the opening in the lower front portion of the inner case 20 . The gas distribution unit 6 is flat and consists of a rear main body 30, a front lid 31, and a sealing body 32 interposed between the main body 30 and the lid 31. A gas supply unit 14 is connected.

(description of the main body)
First, the main body 30 is plate-shaped and made of die-cast aluminum, and as shown in FIG. It has an inverted L shape when viewed from the front, and through holes 35, 35, . . . again. As shown in FIG. 6, on the right edge of the upper plate portion 33, there are two convex portions 37, 37 projecting forward, and two L-shaped claw portions 38 projecting forward and then bent to the right. , 38 are alternately arranged to form a harness holding portion 36 . That is, when a harness such as a temperature sensor provided on the heat exchanger 4 side is routed to the controller 8, a harness 39 (a plurality of harnesses may be used) is attached to the convex portion 37 and the claw portion 38 as indicated by the two-dot chain line in FIG. By alternately locking, the harness 39 can be linearly held along the right edge of the upper plate portion 33 .

In particular, a notch portion 33a recessed leftward is formed in the right edge of the upper plate portion 33 where the upper claw portion 38 is provided, and the claw portion 38 is displaced leftward from the upper and lower convex portions 37, 37. It is Therefore, the harness 39 caught by the claw portion 38 between the upper and lower protrusions 37, 37 is routed in a straight line without jumping out to the right. As a result, even when the heater 18 ( FIG. 1 ) provided in the hot water discharge pipe 16 of the heat exchanger 4 is close to the right side of the upper plate portion 33 , the distance between the harness 39 and the heater 18 is ensured, and the heater 18 is It is possible to prevent the harness 39 from being adversely affected by the heat of the heat.

A gas distribution portion 40 surrounded by an endless ridge 41 is formed in the inner area surrounded by the through holes 35 on the front surface of the main body 30 . The upper side of the gas distribution section 40 has a quadrangular shape surrounding a region that overlaps in the front-rear direction with the formation region of the lean gas supply holes 25 and the rich gas supply holes 26 of the rich and lean burners 22 provided in the inner plate 23 . The lower side of the gas distribution section 40 slopes downward and to the left as it goes downward, and has a tapered shape in which the width gradually narrows. As shown in FIGS. 5 and 6, in the upper region of the gas distribution unit 40, upper and lower pairs are provided corresponding to the light gas supply holes 25 and the rich gas supply holes 26 of each rich and lean burner 22. A plurality of pairs of upper and lower nozzles 42, 42 protruding to the side are arranged side by side in the left-right direction according to the number of the light and dark burners 22. As shown in FIG.
However, the number of groups of nozzles 42, 42 (the number of dark and light burners 22) differs between the left and right sides of the ridge 41 (here, the number of groups of nozzles 42 on the right side is greater than the number of groups of nozzles 42 on the left side). , and the lower area is also divided into right and left sides according to the number of pairs of nozzles 42, 42 so that the width of the right side is larger than the width of the left side.

Therefore, the gas distribution section 40 includes a first distribution section 44 having more pairs of nozzles 42, 42 on the right side of the middle ridge 43, and a wide inclined first distribution section 44 extending downward from the lower left end of the first distribution section 44. A first passage portion 45, a second distributing portion 46 in which the number of nozzles 42, 42 is reduced on the left side of the middle ridge 43, and a narrow inclined second passage extending downward from the lower left end of the second distributing portion 46. A portion 47 is formed. The lower portions of the first passage portion 45 and the second passage portion 47 are formed so as to become deeper rearward as they go downward. 48 are formed. These gas inlets 48 , 48 are opened and closed by electromagnetic valves 17 , 17 provided in the gas supply section 14 .
Further, screw holes 49, 49· for screwing the cover 31 are formed at predetermined intervals in the ridge 41 and the middle ridge 43. As shown in FIG. In the uppermost horizontal part of the projection 41, short projections 50, 50, . It is Further, positioning projections 51, 51 . . .

The upper portion of the first passage portion 45 is inclined toward the right side, and is formed by the upper inclined portion 43a of the middle ridge 43 and the inclined portion 41a of the ridge 41, which are bent in the shape of a character when viewed from the front. The width of the passage is tapered to form a narrow portion 52 below the left end of the first distribution portion 44 where the width of the passage is the narrowest. The downstream side of the narrowed portion 52 forms an expanded portion 53 that expands rightward and communicates with the entire lower end of the first distribution portion 44 .
As a result, the first distribution portion 44 includes a first nozzle region E1 at the left end closest to the narrow portion 52, a second nozzle region E2 adjacent to the first nozzle region E1 via one short rib 50, and a second nozzle region E2. Adjacent to the nozzle region E2, it is divided into two third nozzle regions E3, E3 that are the furthest from the narrowed portion 52. As shown in FIG. Here, the second nozzle region E2 is located on the extension of the main stream S of the fuel gas flowing along the shape of the first passage portion 45 and heading toward the narrow portion 52 at substantially the center of the tapered portion. The area E1 is positioned to the left of the extension of the main stream S, and the third nozzle areas E3, E3 are positioned to the right of the extension of the main stream S.

A rear-side diversion projection 55 is formed on the downstream side of the narrow portion 52 in the main stream S. As shown in FIG. 7 , the rear branch projection 55 has a horizontally long rectangular shape when viewed from the front, and the front surface is formed such that the left side surface 56 is slightly lower than the middle projection 43 . However, the front surface of the rear-side flow dividing projection 55 gradually lowers from the front end of the left side surface 56 toward the right side, forming an inclined surface 58 that forms the lower surface 57 in a right-downward inclination. The rear-side flow dividing projection 55 is arranged in the left-right direction at the boundary between the first distribution portion 44 and the first passage portion 45 with the lower left corner portion 59 positioned substantially downstream of the center of the narrow portion 52 .

Therefore, a part of the main stream S of the fuel gas flowing over the narrowed portion 52 of the first passage portion 45 first comes into contact with the lower left corner portion 59 of the rear-side diversion projection 55 and splits left and right, and then splits to the left side surface 56 side. Part of the discharged fuel gas is guided upward as it is along the left side surface 56 and flows into the first nozzle region E1 as indicated by the solid line arrow a. Part of the fuel gas diverted to the lower surface 57 side climbs over the lower surface 57 due to the inertia of the main flow S, passes in front of the rear-side branch projection 55 as indicated by the solid arrow b, and flows into the second nozzle region E2. Another part of the fuel gas diverted to the lower surface 57 side is guided rightward along the lower surface 57 as indicated by the solid line arrow c and flows from the expanded portion 53 to the third nozzle regions E3, E3. In this way, part of the main stream S of the fuel gas is distributed to the first to third nozzle regions E1 to E3 by the rear-side diversion projections 55, respectively.

(Description of lid)
As shown in FIGS. 8 and 9, the lid 31 has substantially the same shape as the gas distribution portion 40 of the main body 30 when viewed from the front, and is a metal plate press-formed so as to cover the gas distribution portion 40 from the front. . As shown in FIGS. 10 and 11, a peripheral edge portion 65 covering the outer periphery of the ridges 41 of the main body 30 is formed on the outer periphery of the lid 31 by folding. and the first passage portion 45 to overlap and bulge forward, and the second distribution portion 46 and the second passage portion 47 to overlap and overlap and bulge forward. An exit portion 67 is formed. Through holes 68, 68, . . .
In the cover 31, the portion that covers the first and second nozzle regions E1 and E2 is a flat portion 69 that does not bulge forward, and the lower end of the flat portion 69 (the upper end of the first bulging portion 66) is , and a lateral rising portion 70 that rises forward and downward corresponding to the boundary portion between the first distribution portion 44 and the first passage portion 45 .

As shown in FIG. 12, a front branching projection 71, which has a substantially square shape when viewed from the front, protrudes rearward (inward) from the first bulging portion 66 on the left side of the rising portion 70. It is drawn and formed to As shown in FIGS. 13 to 16, the front-side flow dividing projection 71 overlaps the rear-side flow dividing projection 55 on the upper left side of the main body 30 in the front-rear direction near the left end of the expanded portion 53, and the lower left corner portion 72 is positioned on the rear side. It is located on the downstream side of the main stream S from the lower left corner portion 59 of the branch projection 55 . In this state, a gap is formed in the front-rear direction between the front-side flow dividing projection 71 and the rear-side flow dividing projection 55 .

Therefore, a part of the main stream S flowing in the first bulging portion 66 over the narrow portion 52 of the first passage portion 45 abuts on the lower left corner portion 72 of the front side diversion projection 71 and splits into the left and right sides. A part of the fuel gas diverted to the side is guided upward along the left side surface 73 as it is, as indicated by the dotted arrow a, crosses over the rising portion 70, and flows to the first nozzle region E1 side. Part of the fuel gas diverted to the lower surface 74 side passes behind the front-side flow dividing projection 71 and passes through the gap with the rear-side flow dividing projection 55 as indicated by the dotted line arrow b due to the inertia of the main stream S, or As indicated by c, it flows to the right side of the front-side diversion projection 71 guided by the lower surface 74 . However, in the lid 31, the entrance to the second nozzle region E2 is narrowed by the flat portion 69, and the upper end of the first swelling portion 66 is formed with a rising portion 70 in the left-right direction. As indicated by d, most of the part of the fuel gas is guided to the right by the rising portion 70 and flows to the third nozzle regions E3, E3. That is, in the first bulging portion 66, only a portion of the fuel gas that has passed through the flat portion 69 flows into the second nozzle region E2.

The seal body 32 is made of cork, rubber, or the like, and is formed along the ridges 41, middle ridges 43, and short ridges 50 of the main body 30 as shown in FIG. A through-hole 80 is provided in the rear portion thereof, and a small hole 81 is provided in a portion corresponding to the positioning projection 51 . In addition, it has a mesh shape with connecting portions 82, 82 . . .

This gas distribution unit 6 has a sealing member 32 on the front surface of a main body 30, each through hole 80 is aligned with each screw hole 49, a positioning projection 51 is inserted into a small hole 81, and a projection 41, a middle projection 43, It is set on the front surface of the short rib 50. In this state, the lid 31 is put on from the front, and the bolts 85, 85, etc. passed through the through hole 68 of the lid 31 and the through hole 80 of the seal 32 are screwed into the respective screw holes 49 from the front. Assembly of the gas distribution unit 6 is completed as shown in -16.
In this state, the front surfaces of the first distributing portion 44 and the first passage portion 45 on the main body 30 side are closed by the lid 31, and the first bulging portion 66 extends into the first distributing portion 44 and the first passage portion 45. As shown in FIGS. 16 to 18, the rising portion 70 is located in front of the boundary position between the first distribution portion 44 and the first passage portion 45, and the front side flow dividing projection 71 is on the rear side. It is positioned in front of the flow dividing projection 55 . Similarly, the front surface of the second distribution portion 46 and the second passage portion 47 on the main body 30 side is also closed by the lid 31 , and the second swelling portion 67 extends into the second distribution portion 46 and the second passage portion 47 . It straddles and covers from the front.
The main body 30 of the gas distribution unit 6 thus assembled is screwed from the front to the lower front surface of the inner case 20 with screws 86, 86 (FIG. 1), and the gas supply section 14 is screwed to the rear surface of the lower end of the main body 30. The assembly of the gas distribution unit 6 to the combustion device 3 is then completed.

In the water heater 1 configured as described above, when the hot water supply valve connected to the pipe of the hot water outlet 13 is opened to allow water to flow through the appliance, the controller 8 detects this and the gas flow path of the gas supply unit 14 is detected. is opened to supply fuel gas to the gas distribution unit 6, and the air supply fan 7 is operated to supply combustion air. Therefore, the fuel gas supplied from the nozzles 42 of the gas distribution unit 6 is supplied from the lean gas supply holes 25 and the rich gas supply holes 26 of the inner plate 23 together with the primary air through the lean side inlets and the rich side inlets. It is supplied to each rich and thin burner 22 . When the discharge electrode 27 is continuously discharged by the controller 8, the air-fuel mixture ejected from the burner port 24 of each rich/lean burner 22 is combusted. Combustion exhaust gas from the burner unit 21 is heat-exchanged with water passing through the heat transfer tube 9 of the heat exchanger 4 from the water supply pipe 15 , and turned into hot water at a set temperature and discharged from the hot water discharge pipe 16 . The controller 8 operates the solenoid valves 17 of the gas supply unit 14 in accordance with the required combustion amount to control the opening and closing of the gas inlets 48, 48, thereby increasing the number of combustion of the rich/lean burner 22 in the burner unit 21 to three. Step-by-step control.

Here, when the fuel gas is supplied from the first distribution portion 44 and the first passage portion 45 of the gas distribution unit 6, in the first distribution portion 44 and the first swelling portion 66, as described above, the first passage portion 45 A portion of the main stream S of the fuel gas that has passed through the narrow portion 52 from the main body 30 contacts the rear-side flow dividing projection 55 and is divided as indicated by solid line arrows a to c in FIGS. 7 and 19 . Further, another part of the main stream S contacts the front-side diversion projection 71 of the lid 31 and the rising portion 70 located at the lower end of the flat portion 69, so that the main stream S is moved as indicated by the dotted arrows a to d in FIGS. 12 and 19 . is diverted to Therefore, the fuel gas is distributed evenly to the first nozzle region E1 and the third nozzle region E3 without concentrating on the second nozzle region E2, which is an extension of the main stream S.
When the fuel gas is supplied from the second distribution portion 46 and the second passage 47, the main stream of the fuel gas flowing through the second passage 47 flows substantially in the center of the second distribution portion 46. Fuel gas is evenly distributed to each nozzle 42 .

(Effects of invention of rear-side flow diversion projection of main body)
Thus, according to the water heater 1 of the above-described configuration, the gas inlets 48 are formed at the lower ends of the passages 45 and 47, respectively, while the first distributing portion 44 of the main body 30 has the first distributing portion A second nozzle region E2 (extended upper nozzle region) located on the extension of the main stream S of the combustion gas of the first passage portion 45 connected to the first passage portion 45 connected to the 44, and a second nozzle region E2 (extended upper nozzle region) located on the extension of the main stream S of the first passage portion 45 connected to 1. Third nozzle regions E1 and E3 (non-extending upper nozzle regions) are arranged side by side in the left-right direction, and between the first passage portion 45 and the second nozzle region E2 in the main body 30, the first passage portion 45 Since the rear-side diversion projection 55 is provided to distribute part of the fuel gas flowing from the nozzle region E1, E3 to the first and third nozzle regions E1 and E3, the main flow S of the fuel gas flowing toward the second nozzle region E2 is diverted to the first nozzle region E2. The fuel gas can be divided into the nozzle region E1 and the third nozzle region E3, and the fuel gas can be supplied to the first and third nozzle regions E1 and E3 where it is difficult for the fuel gas to flow. Therefore, the fuel gas can be uniformly distributed and supplied to the nozzle regions E1 to E3 without forming a gas passage for reducing the force of the fuel gas so as to extend in the left-right direction. , the weight can be reduced.

Particularly, here, since the rear-side flow dividing projection 55 is formed in a horizontally long rectangular shape extending in the left-right direction when viewed from the front, it is possible to reliably divide the fuel gas into the first nozzle region E1 and the third nozzle region E3. can.
In addition, since the rear-side flow diversion projection 55 is formed so as to gradually become lower as it goes from the end closer to the first passage portion 45 to the end on the farther side, the second nozzle region E2 side has the same height. Excessive increase in pressure loss in the vicinity of the second nozzle region E2 can be prevented in comparison with the case of blockage with a small flow diversion projection. Therefore, an appropriate amount of fuel gas can be caused to climb over the rear-side diversion projection 55 and be guided to the second nozzle region E2. Further, by increasing the height of the side close to the narrow portion 52, the fuel gas diverted to the first nozzle region E1 can be prevented from overcoming the rear-side diversion protrusion 55 and flowing out to the second nozzle region E2. It becomes possible to secure the outflow amount to the region E1.
A portion of the fuel gas from the first passage portion 45 is diverted to a position overlapping the rear-side diversion projection 55 in the front-rear direction between the first passage portion 45 and the second nozzle region E2 in the lid body 31. Since the front-side flow dividing projection 71 is provided to distribute the fuel gas to the first and third nozzle regions E1 and E3, the fuel gas can be more reliably divided in cooperation with the rear-side flow dividing projection 55. FIG.

The shape of the rear-side flow diversion projection is not limited to the above. It can be changed as appropriate, such as forming an inclination so as to be lower. A plurality of rear flow diversion projections may be provided, or a separate rear flow diversion projection may be attached to the front surface of the main body.
Further, in the invention relating to the rear-side flow dividing projection, it is also possible to eliminate the front-side flow dividing projection and distribute the fuel gas only by the rear-side flow dividing projection. The flat portion of the lid can also be omitted.
Furthermore, depending on the configuration of the second distributing portion and the second passage portion, the rear side flow dividing projection can be provided between the second distributing portion and the second passage portion. The same applies to the case where three or more pairs of distribution portions and passage portions are provided.

(Effect of Invention of Front-side Diverting Projection of Lid)
Thus, according to the water heater 1 of the above-described configuration, the gas inlets 48 are formed at the lower ends of the passages 45 and 47, respectively, while the first distributing portion 44 of the main body 30 has the first distributing portion A second nozzle region E2 located on the extension of the main stream S of the combustion gas of the first passage portion 45 connected to the first passage portion 44, and first and third nozzle regions not located on the extension of the main stream S of the first passage portion 45. E1 and E3 are arranged side by side in the left-right direction. Since the front-side flow dividing protrusion 71 is provided for dividing the three nozzle regions E1 and E3, the main stream S of the fuel gas flowing toward the second nozzle region E2 is divided into the first nozzle region E1 and the third nozzle region E3. Therefore, the fuel gas can be supplied to the first and third nozzle regions E1 and E3 into which the fuel gas is difficult to flow. Therefore, the fuel gas can be uniformly distributed and supplied to the nozzle regions E1 to E3 without forming a gas passage for reducing the energy of the fuel gas so as to extend in the left-right direction. Weight can be reduced.

In particular, here, the first passage portion 45 provided with the front-side flow dividing projection 71 is formed with a narrow portion 52 having the narrowest passage width, and the front-side flow dividing projection 71 is arranged downstream of the narrow portion 52. Therefore, the main stream S of the fuel gas can be diverted more effectively.
In addition, the first passage portion 45 is connected to the left end portion of the first distribution portion 44, and the downstream side of the narrow portion 52 is formed as an expanded portion 53 that is expanded to the right end portion side and connected to the front side branch flow. Since the protrusion 71 is arranged near the left end of the widened portion 53, even if the first passage portion 45 is widened rightward from the narrowed portion 52, the front side diversion protrusion 71 distributes the fuel gas uniformly. can be supplied to
Furthermore, since the cover 31 is made of a press-formed metal plate and the front-side diversion projection 71 is made of a metal plate by drawing, the manufacturing cost can be kept low.

The shape of the front-side flow diversion projection is not limited to the above-described form. I don't mind. It is also possible to make the depth gradually shallower from the left end to the right side like the rear branch projection. It is also possible to attach the front-side flow diversion projection as a separate member to the inner surface of the lid.
Further, in the invention relating to the front-side flow dividing projection, it is also possible to dispense with the rear-side flow dividing projection and distribute the fuel gas only with the front-side flow dividing projection. The flat portion of the lid can also be omitted.

(Effect of Invention of Flat Portion of Lid)
Thus, according to the water heater 1 of the above-described configuration, the gas inlets 48 are formed at the lower ends of the passages 45 and 47, respectively, while the first distributing portion 44 of the main body 30 has the first distributing portion A second nozzle region E2 located on the extension of the main stream S of the combustion gas of the first passage portion 45 connected to the first passage portion 44, and first and third nozzle regions not located on the extension of the main stream S of the first passage portion 45. E1 and E3 are arranged side by side in the left-right direction, and a first bulging portion 66 that bulges forward is provided at a portion of the lid 31 that covers the first passage portion 45 and the first and third nozzle regions E1 and E3. is formed, the portion covering the second nozzle region E2 is formed with a flat portion 69 (non-bulging portion) that does not bulge forward, so the fuel gas is excessively supplied to the second nozzle region E2. Therefore, the fuel gas can be evenly supplied to the first and third nozzle regions E1 and E3.

In particular, here, the boundary portion (rising portion 70) between the first bulging portion 66 and the flat portion 69 corresponding to the space between the first passage portion 45 and the second nozzle region E2 is positioned at the lower end of the second nozzle region E2. Since it is formed in the left-right direction along the line, the flow of the fuel gas can be guided in the left-right direction. Therefore, it is possible to prompt the supply of the fuel gas to the third nozzle region E3, which is away from the narrow portion 52 and to which the fuel gas is difficult to be supplied, and to uniformly supply the fuel gas to the third nozzle region E3. .

In addition, in the above embodiment, the front side of the first nozzle region in the lid is also a flat portion, but only the front side of the second nozzle region may be a flat portion. The lower end of the flat portion is not limited to the boundary portion between the first distribution portion and the first passage portion, and may be set above or below the boundary portion. The shape of the rising portion and the length in the left-right direction can also be changed as appropriate. The non-bulging portion is not limited to a flat portion, and may be a concave portion recessed backward.
Further, in the invention relating to the flat portion of the lid, the fuel gas can be distributed only by the flat portion without the rear-side flow dividing projection and the front-side flow dividing projection.

(Effect of Invention of Harness Holding Portion of Main Body)
As described above, according to the water heater 1 of the above-described configuration, on the front surface of the right end portion of the main body 30, the convex portion 37 projecting forward and the claw portion 38 projecting right outward are arranged vertically. Since the harness holders 36 are alternately arranged in the direction, the main body 30 of the gas distribution unit 6 can be used to easily organize the harnesses 39 for electronic parts such as temperature sensors without increasing the number of parts. It becomes possible.
In particular, one of the claws 38 is displaced toward the central portion of the main body 30 in the left-right direction from the projections 37, 37 positioned above and below. can also be hooked in a straight line on the central side. Therefore, even when the heater 18 provided in the hot water discharge pipe 16 of the heat exchanger 4 is close to the right side of the upper plate portion 33, the harness 39 can be separated from the heater 18 to prevent adverse effects of the heat of the heater 18. .

Note that the number of protrusions and claws is not limited to the above embodiment, and can be increased or decreased as appropriate. Also, the harness holding portion may be provided at the left end or at both ends. The shapes of the convex portion and the claw portion can also be changed as appropriate.

In common with each invention, the structure of the water heater itself is not limited to the above-described form, but may be a latent heat recovery type equipped with a sub-heat exchanger, or equipped with an exhaust pipe in which an exhaust hood protrudes upward from the housing. Alternatively, each of the above inventions can be applied even if each burner in the burner unit is not a rich/lean burner and is provided with one introduction port and one supply hole.

DESCRIPTION OF SYMBOLS 1... Water heater, 2.. Case, 3.. Combustion device, 4.. Heat exchanger, 6.. Gas supply unit, 7.. Air supply fan, 8.. Controller, 14.. Gas supply part , 18... heater, 20... inner case, 21... burner unit, 22... concentration burner, 24... flame port, 30... body, 31... cover, 32... seal, 36... Harness holding portion 37 Convex portion 38 Claw portion 39 Harness 40 Gas distribution portion 41 Projection 41a Inclined portion 42 Nozzle 43 Middle Ridge 43a Upper inclined portion 44 First distributing portion 45 First passage portion 46 Second distributing portion 47 Second passage portion 48 Gas inlet 52 Narrow portion 53 Expanded portion 55 Rear branch projection 56, 73 Left side surface 57, 74 Lower surface 58 Inclined surface 59, 72 Lower left corner portion 66 First bulging portion 67 Second bulging portion 69 Flat portion 70 Rising portion 71 Front branch projection E1 First nozzle region E2 Second nozzle area, E3: third nozzle area, S: main stream.

Claims (1)

in the housing,
a heat exchanger;
a burner unit arranged below the heat exchanger and having a plurality of burners arranged side by side;
and an inner case that houses the burner unit,
On the front surface of the inner case, a plurality of nozzles for supplying fuel gas to each of the burners are arranged side by side in the left-right direction, and a plurality of distribution sections in which a predetermined number of the nozzles are divided, and a plurality of distribution sections below each distribution section. A water heater to which a gas distribution unit is attached, comprising a main body having a plurality of passages connected in an inclined manner, and a cover attached to the front surface of the main body to cover the distribution portion and the passages. hand,
A pipe connected to the heat exchanger is arranged vertically on either the left or right outside of the inner case. is attached, while
At least at the ends of the right and left ends of the main body on the mounting side of the heater , there are convex portions that protrude forward without projecting outward in the lateral direction from the end portions , and projections that protrude outward in the lateral direction. A harness holding portion is formed by alternately arranging a plurality of claw portions projecting toward the heater in a vertical direction, and at least one of the plurality of claw portions adjacent to the heater is positioned vertically. A water heater , wherein the protrusion is shifted toward the central portion in the left-right direction of the main body from the convex portion .

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