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JP4160576B2 - Combined heat source machine - Google Patents

Combined heat source machine Download PDF

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JP4160576B2
JP4160576B2 JP2005131271A JP2005131271A JP4160576B2 JP 4160576 B2 JP4160576 B2 JP 4160576B2 JP 2005131271 A JP2005131271 A JP 2005131271A JP 2005131271 A JP2005131271 A JP 2005131271A JP 4160576 B2 JP4160576 B2 JP 4160576B2
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exhaust
combustion
heat exchanger
burner
combustion section
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JP2006308198A (en
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猛 加藤
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Rinnai Corp
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Rinnai Corp
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  • Housings, Intake/Discharge, And Installation Of Fluid Heaters (AREA)

Description

本発明は、給湯機能と、風呂追焚きといった給湯以外の機能とを有する複合熱源機に関する。   The present invention relates to a composite heat source machine having a hot water supply function and functions other than hot water supply such as bathing.

従来、この種の熱源機として、第1バーナ及び第1バーナの上方に配置された給湯用の第1熱交換器を有する第1燃焼部と、第2バーナ及び第2バーナの上方に配置された風呂追焚き用の第2熱交換器を有する第2燃焼部とを横方向に並設して成るものは知られている。また、このような複合熱源機において、給湯能力を向上させるため、第1燃焼部の上方に位置させて、第1バーナの燃焼排気中の潜熱を回収する給湯用の副熱交換器を設けたものも知られている(例えば、特許文献1参照)。   Conventionally, as this type of heat source machine, a first combustion section having a first heat exchanger for hot water supply disposed above the first burner and the first burner, and disposed above the second burner and the second burner. It has been known that a second combustion section having a second heat exchanger for bathing is arranged side by side in parallel. Further, in such a composite heat source machine, in order to improve the hot water supply capacity, a sub-heat exchanger for hot water supply is provided that is positioned above the first combustion section and collects latent heat in the combustion exhaust of the first burner. Some are also known (see, for example, Patent Document 1).

このような副熱交換器は、熱交換部の表面温度が燃焼排気の露点温度よりも低くなるようにして、燃焼排気中の水蒸気を凝縮させ、水蒸気が持つ潜熱を回収するように構成される。ここで、凝縮水は、燃焼排気中の窒素酸化物等が溶け込むことで強酸性水になる。そのため、熱交換部はステンレス等の耐食性に優れた金属で形成することが必要になるが、このような金属は熱伝導性が悪い。従って、第1燃焼部の上方に配置される限られた大きさの副熱交換器では、潜熱の回収効率を向上させるにも限度がある。
特開平6−147629号公報(図7、図8)
Such an auxiliary heat exchanger is configured to condense the water vapor in the combustion exhaust gas and recover the latent heat of the water vapor so that the surface temperature of the heat exchange part is lower than the dew point temperature of the combustion exhaust gas. . Here, the condensed water becomes strongly acidic water when nitrogen oxides and the like in the combustion exhaust gas dissolve. Therefore, it is necessary to form the heat exchanging portion with a metal having excellent corrosion resistance such as stainless steel, but such a metal has poor heat conductivity. Therefore, there is a limit in improving the recovery efficiency of the latent heat in the limited-size auxiliary heat exchanger disposed above the first combustion section.
JP-A-6-147629 (FIGS. 7 and 8)

本発明は、以上の点に鑑み、副熱交換器での潜熱の回収効率を向上させて、給湯の高効率化を図ることができるようにした複合熱源機を提供することをその課題としている。   In view of the above points, an object of the present invention is to provide a composite heat source apparatus that can improve the recovery efficiency of latent heat in the auxiliary heat exchanger and increase the efficiency of hot water supply. .

上記課題を解決するために、本発明は、第1バーナ及び第1バーナの上方に配置された給湯用の第1熱交換器を有する第1燃焼部と、第2バーナ及び第2バーナの上方に配置された給湯以外の用途の第2熱交換器を有する第2燃焼部とを横方向に並設した複合熱源機であって、第1バーナの燃焼排気中の潜熱を回収する給湯用の副熱交換器を備えるものにおいて、第1と第2の両燃焼部の上面に、第1燃焼部の第2燃焼部とは反対側の側部から第2燃焼部の第1燃焼部とは反対側の側部に跨るようにして、燃焼排気を外部に排出する排気口を有する排気フードが配置され、副熱交換器は、排気フード内に該排気フードの横方向全幅に亘って延在するように配置され、排気フード内の両燃焼部の境界部上に位置する部分に、副熱交換器の上流側に位置する排気フード内の排気流入空間を、第1熱交換器を通過した第1バーナの燃焼排気が流れる第1燃焼部側排気流入空間と、第2熱交換器を通過した第2バーナの燃焼排気が流れる第2燃焼部側排気流入空間とに2分する仕切り部材が配置され、副熱交換器内に燃焼排気を流入させるための排気流入口を開設する副熱交換器の上流側端面の第2燃焼部側排気流入空間に面する部分が閉塞され、排気フード内に、第1燃焼部側排気流入空間から排気流入口と副熱交換器の内部空間とを介して排気フードの排気口に至る第1燃焼部用排気経路と、第2燃焼部側排気流入空間から副熱交換器の外側の空間を介して排気フードの排気口に至る第2燃焼部用排気経路とが画成されることを特徴とする。 In order to solve the above-described problems, the present invention provides a first combustion section having a first heat exchanger for hot water supply disposed above the first burner and the first burner, and above the second burner and the second burner. And a second heat exchanger having a second heat exchanger for a purpose other than hot water supply arranged side by side in the horizontal direction, for a hot water supply for recovering latent heat in the combustion exhaust of the first burner What has a sub heat exchanger WHEREIN: What is the 1st combustion part of a 2nd combustion part from the side part opposite to the 2nd combustion part of a 1st combustion part on the upper surface of both 1st and 2nd combustion parts? An exhaust hood having an exhaust port for discharging combustion exhaust to the outside is disposed so as to straddle the opposite side, and the auxiliary heat exchanger extends in the exhaust hood over the entire width in the lateral direction of the exhaust hood. On the upstream side of the auxiliary heat exchanger in the part located on the boundary of both combustion parts in the exhaust hood Combustion of the first burner side exhaust inflow space through which the combustion exhaust gas of the first burner that has passed through the first heat exchanger flows, and combustion of the second burner that has passed through the second heat exchanger, through the exhaust inflow space in the exhaust hood that is positioned A partition member that divides the exhaust gas into the second combustion section side exhaust inflow space through which the exhaust flows is arranged, and an upstream end face of the sub heat exchanger that opens an exhaust inlet for allowing the combustion exhaust to flow into the sub heat exchanger. The portion facing the second combustion section side exhaust inflow space is closed, and the exhaust hood has an exhaust port through the first combustion section side exhaust inflow space through the exhaust inlet and the internal space of the auxiliary heat exchanger. And a second combustion section exhaust path extending from the second combustion section side exhaust inflow space to the exhaust port of the exhaust hood through the space outside the auxiliary heat exchanger. characterized in that that.

本発明によれば、第1と第2の燃焼部の上面に、第1燃焼部の第2燃焼部とは反対側の側部から第2燃焼部の第1燃焼部とは反対側の側部に跨るようにして配置する排気フードの横方向全幅に亘って副熱交換器が延在する。従って、副熱交換器が第1燃焼部の第2燃焼部とは反対側の側部の上方位置から第2燃焼部の第1燃焼部とは反対側の側部の上方位置に亘って延在する大型のものになるため、副熱交換器の熱交換面積を広く確保することができる。その結果、副熱交換器での潜熱の回収効率を向上させて、給湯の高効率化を図ることができる。尚、副熱交換器が第2燃焼部の上方位置に亘って延在していても、第2熱交換器を通過した第2バーナの燃焼排気は副熱交換器を迂回して流れるため、第2燃焼部側の単独運転時に副熱交換器の過熱を生ずることはない。 According to the present invention, on the upper surfaces of the first and second combustion parts, the side of the first combustion part opposite to the second combustion part from the side opposite to the first combustion part of the second combustion part. The auxiliary heat exchanger extends across the entire width in the lateral direction of the exhaust hood arranged so as to straddle the section. Accordingly, the auxiliary heat exchanger extends from the upper position of the side portion of the first combustion section opposite to the second combustion section to the upper position of the side portion of the second combustion section opposite to the first combustion section. Since it becomes a large-sized thing which exists, the heat exchange area of a sub-heat exchanger can be ensured widely. As a result, it is possible to improve the efficiency of recovering latent heat in the auxiliary heat exchanger and increase the efficiency of hot water supply. Even if the auxiliary heat exchanger extends over the upper position of the second combustion section, the combustion exhaust of the second burner that has passed through the second heat exchanger flows around the auxiliary heat exchanger, The auxiliary heat exchanger does not overheat during the single operation on the second combustion section side.

ここで、第1燃焼部の上面に、内部に副熱交換器を配置した、第2燃焼部の上方位置に向けて横方向に広がる形状の排気ダクトを接続し、この排気ダクトで第1燃焼部用排気経路を構成すると共に、この排気ダクトを迂回するようにして第2燃焼部の上面に接続される別の排気ダクトを設けて、この排気ダクトにより第2燃焼部用排気経路を構成することも考えられるが、これでは、排気系が大型複雑化する。   Here, an exhaust duct having a shape that spreads in the lateral direction toward the upper position of the second combustion section, in which the auxiliary heat exchanger is disposed, is connected to the upper surface of the first combustion section, and the first combustion is performed in the exhaust duct. An exhaust path for the combustion chamber is configured, and another exhaust duct connected to the upper surface of the second combustion section is provided so as to bypass the exhaust duct, and the exhaust path for the second combustion section is configured by the exhaust duct. This can be considered, but this makes the exhaust system large and complex.

これに対し、本発明によれば、単一の排気フード内に第1燃焼部用排気経路と第2燃焼部用排気経路とが画成されるため、排気系を小型簡素に構成でき、有利である。 On the other hand, according to the present invention, the exhaust path for the first combustion section and the exhaust path for the second combustion section are defined in a single exhaust hood. It is.

また、このものにおいて、副熱交換器の上流側端面の第1燃焼部側排気流入空間に面する部分に開設する排気流入口が、第1と第2の両燃焼部の境界部に近付くほど排気通過抵抗が減少するように形成されていれば、第1燃焼部側排気通路から両燃焼部の境界部に近い位置で副熱交換器内に流入する第1バーナの燃焼排気の量が増加し、第2燃焼部の上方に位置する副熱交換器の部分にも十分に第1バーナの燃焼排気が流れ、潜熱の回収効率が可及的に向上する。   Moreover, in this thing, the exhaust inflow port opened in the part facing the 1st combustion part side exhaust gas inflow space of the upstream end surface of a sub heat exchanger is so close to the boundary part of both 1st and 2nd combustion parts. If the exhaust passage resistance is reduced, the amount of combustion exhaust of the first burner flowing into the auxiliary heat exchanger at a position near the boundary between the two combustion sections from the first combustion section side exhaust passage increases. In addition, the combustion exhaust of the first burner sufficiently flows also to the portion of the auxiliary heat exchanger located above the second combustion section, and the recovery efficiency of latent heat is improved as much as possible.

図1は、図示省略した外装ケース内に配置する単一の缶体1内に、給湯用の第1燃焼部2−1と風呂追焚き用の第2燃焼部2−2とを横方向に並べて設けた1缶式複合熱源機を示している。第1と第2の両燃焼部2−1,2−2は缶体1内に設けた2枚板構造の仕切り壁1aで区画されている。第1燃焼部2−2には、第1バーナ3−1とその上方の第1熱交換器4−1とが設けられ、第2燃焼部2−2には、第2バーナ3−2とその上方の第2熱交換器4−2とが設けられている。尚、缶体1は、第1と第2の両バーナ3−1,3−2を収納する下半部1bと、第1と第2の両熱交換器4−1,4−2を収納する上半部1cとで構成されている。   FIG. 1 shows a horizontal direction of a first combustion section 2-1 for hot water supply and a second combustion section 2-2 for bathing in a single can 1 arranged in an exterior case (not shown). 1 shows a single can type combined heat source machine provided side by side. Both the first and second combustion sections 2-1 and 2-2 are partitioned by a partition wall 1 a having a two-plate structure provided in the can 1. The first combustion unit 2-2 is provided with a first burner 3-1, and a first heat exchanger 4-1 thereabove, and the second combustion unit 2-2 includes a second burner 3-2 and A second heat exchanger 4-2 above it is provided. The can 1 accommodates the lower half 1b for accommodating both the first and second burners 3-1, 3-2 and the first and second heat exchangers 4-1, 4-2. And the upper half 1c.

第1と第2の各バーナ3−1,3−2は、夫々、缶体1の奥行方向(図1の紙面垂直方向)たる前後方向に長手の単位バーナ3aを横方向に複数並設して構成されている。尚、暖房よりも給湯の方が大きな加熱能力を要求されるため、各バーナ3−1,3−2を構成する単位バーナ3aの本数は第1バーナ3−1の方が多くなっている。   Each of the first and second burners 3-1 and 3-2 has a plurality of unit burners 3 a that are long in the front-rear direction in the depth direction of the can 1 (the vertical direction in FIG. 1). Configured. In addition, since hot water supply requires a larger heating capacity than heating, the number of unit burners 3a constituting each burner 3-1 and 3-2 is larger in the first burner 3-1.

各熱交換器4−1,4−2は、前後方向に隙間を存して多数積層した吸熱フィン4aと、これら吸熱フィン4aを貫通する蛇行形状の吸熱管4bとで構成される。第1熱交換器4−1の吸熱管4bの上流側には後述する副熱交換器9が接続され、吸熱管4bの下流側には出湯管(図示せず)が接続されている。そして、出湯管の下流端の出湯栓を開いて第1熱交換器4−1に通水したとき、第1バーナ4−1に点火されて、出湯栓から設定温度の湯が出湯されるようにしている。また、第2熱交換器4−2の吸熱管4bは、図示しないが、往き管と戻り管とから成る風呂回路を介して浴槽に接続されており、浴槽と第2熱交換器4−2との間に風呂回路を介して湯水を循環させて、風呂の追焚きを行う。   Each of the heat exchangers 4-1 and 4-2 includes a heat absorbing fin 4 a that is stacked in a large number with a gap in the front-rear direction, and a meandering heat absorbing tube 4 b that passes through the heat absorbing fins 4 a. A sub heat exchanger 9 to be described later is connected to the upstream side of the heat absorption pipe 4b of the first heat exchanger 4-1, and a hot water discharge pipe (not shown) is connected to the downstream side of the heat absorption pipe 4b. Then, when the hot water tap at the downstream end of the hot water pipe is opened and water is passed through the first heat exchanger 4-1, the first burner 4-1 is ignited so that hot water at a set temperature is discharged from the hot water tap. I have to. Moreover, although not shown in figure, the heat absorption pipe | tube 4b of the 2nd heat exchanger 4-2 is connected to the bathtub via the bath circuit which consists of an outward pipe and a return pipe, and a bathtub and the 2nd heat exchanger 4-2. The hot water is circulated through the bath circuit between and the bath.

缶体1の下部には、第1と第2の両燃焼部2−1,2−2に対し分布板5で仕切られた給気室6が画成されている。そして、給気室6に燃焼ファン7を接続し、燃焼ファン7からの空気が給気室6から分布板5に形成した多数の分布孔5aを介して各燃焼部2−1,2−2に供給されるようにしている。また、第1と第2の両燃焼部2−1,2−2の上面、即ち、缶体1の上面には、第1燃焼部2−1の第2燃焼部2−2とは反対側の側部から第2燃焼部2−2の第1燃焼部2−1とは反対側の側部に跨るようにして、排気フード8が配置されている。第1と第2の各バーナ3−1,3−2の燃焼排気は、第1と第2の各熱交換器4−1,4−2に導かれ、各熱交換器4−1,4−2で熱交換した後に排気フード8に流れ、排気フード8の前面に図2に示す如く形成した排気口8aから外部に排出される。 In the lower part of the can body 1, an air supply chamber 6 is defined which is partitioned by a distribution plate 5 with respect to both the first and second combustion sections 2-1 and 2-2. A combustion fan 7 is connected to the air supply chamber 6, and air from the combustion fan 7 passes through the distribution holes 5 a formed in the distribution plate 5 from the air supply chamber 6 to each of the combustion units 2-1 and 2-2. To be supplied to. Further, the upper surfaces of both the first and second combustion units 2-1 and 2-2, that is, the upper surface of the can body 1, are opposite to the second combustion unit 2-2 of the first combustion unit 2-1. The exhaust hood 8 is disposed so as to straddle the side portion of the second combustion portion 2-2 opposite to the first combustion portion 2-1 from the side portion of the second combustion portion 2-2 . The combustion exhaust from the first and second burners 3-1 and 3-2 is led to the first and second heat exchangers 4-1 and 4-2, and the heat exchangers 4-1 and 4 are connected. After the heat exchange at -2, it flows to the exhaust hood 8 and is discharged to the outside through an exhaust port 8a formed on the front surface of the exhaust hood 8 as shown in FIG.

排気フード8内には、第1バーナ3−1の燃焼排気中の水蒸気を凝縮させて潜熱を回収する給湯用の副熱交換器9が配置されており、水道管(図示せず)からの水が副熱交換器9を介して第1熱交換器4−1に供給される。副熱交換器9は、排気フード8の横方向全幅に亘って延在しており、従って、第1燃焼部2−1の第2燃焼部2−2とは反対側の側部の上方位置から第2燃焼部2−2の第1燃焼部2−1とは反対側の側部の上方位置に亘って副熱交換器9が横方向に延在することになる。副熱交換器9は、水を流す吸熱管9aと、吸熱管9aの配置部の上下に配置した上板9bと下板9cとを備えており、上板9bと下板9cとの間の副熱交換器9の内部空間に副熱交換器9の上流側端面である後面から副熱交換器9の前側の開放面に向けて燃焼排気が流れるようにしている。上板9b及び下板9cは前下がりに傾斜しており、吸熱管9aの表面で燃焼排気中の水蒸気が凝縮して発生するドレン(凝縮水)は、ドレン受けに兼用される下板9cに落下し、下板9cを介して排気フード8の前面下部の排水部8bに導かれる。 In the exhaust hood 8, a sub-heat exchanger 9 for hot water supply for condensing water vapor in the combustion exhaust of the first burner 3-1 and recovering latent heat is disposed, and is supplied from a water pipe (not shown). Water is supplied to the first heat exchanger 4-1 through the auxiliary heat exchanger 9. The auxiliary heat exchanger 9 extends over the entire width of the exhaust hood 8, and therefore, the upper position of the side portion of the first combustion portion 2-1 opposite to the second combustion portion 2-2. Thus, the auxiliary heat exchanger 9 extends in the lateral direction over the upper position of the side portion of the second combustion portion 2-2 opposite to the first combustion portion 2-1 . The auxiliary heat exchanger 9 includes an endothermic tube 9a through which water flows, and an upper plate 9b and a lower plate 9c disposed above and below the arrangement portion of the endothermic tube 9a, and is provided between the upper plate 9b and the lower plate 9c. Combustion exhaust gas flows from the rear surface, which is the upstream end surface of the auxiliary heat exchanger 9, toward the front open surface of the auxiliary heat exchanger 9 in the internal space of the auxiliary heat exchanger 9. The upper plate 9b and the lower plate 9c are inclined forward and downward, and the drain (condensed water) generated by condensing water vapor in the combustion exhaust gas on the surface of the heat absorption pipe 9a is applied to the lower plate 9c also used as a drain receiver. It falls and is led to the drainage part 8b at the lower front of the exhaust hood 8 through the lower plate 9c.

吸熱管9aは、図3に示す如く、排気フード8の横方向全幅に亘って横方向に蛇行しつつ前側から後側にのびる形状に形成されており、このような蛇行形状の吸熱管9aが複数本(図示例では5本)並設されている。そして、排気フード8の横方向一側の側板部の外面に、これら複数本の吸熱管9aの前側の端部を纏めて接続する給水ヘッダ91と、これら複数本の吸熱管9aの後側の端部を纏めて接続する出湯ヘッダ92とを配置し、給水ヘッダ91からこれら吸熱管9aに水道水を供給し、潜熱の回収で加熱された温水をこれら吸熱管9aから出湯ヘッダ92を介して第1熱交換器4−1に供給するようにしている。尚、各吸熱管9aは、強酸性の凝縮水による腐食を防止するためステンレス等の耐食性金属で形成される。また、表面積を増すため、各吸熱管9aにコルゲート状の凹凸を付けている。   As shown in FIG. 3, the endothermic tube 9a is formed in a shape extending from the front side to the rear side while meandering in the lateral direction over the entire width of the exhaust hood 8, and the meandering endothermic tube 9a is formed in such a manner. A plurality (5 in the illustrated example) are arranged in parallel. And the water supply header 91 which connects the front end part of these heat absorption pipe | tubes 9a collectively to the outer surface of the side plate part of the horizontal direction one side of the exhaust hood 8, and the rear side of these heat absorption pipe | tubes 9a. A hot water header 92 that connects the ends together is arranged, tap water is supplied from the water supply header 91 to these heat absorption pipes 9a, and hot water heated by collecting latent heat is supplied from these heat absorption pipes 9a via the hot water header 92. The first heat exchanger 4-1 is supplied. Each endothermic tube 9a is formed of a corrosion-resistant metal such as stainless steel in order to prevent corrosion due to strongly acidic condensed water. Further, in order to increase the surface area, each endothermic tube 9a is provided with corrugated irregularities.

排気フード8内の両燃焼部2−1,2−2の境界部上に位置する部分には、図1、図3及び図4に示す如く、副熱交換器9の上流側に位置する排気フード8内の排気流入空間、即ち、副熱交換器9の下側から副熱交換器9の後側に至る空間を、第1熱交換器4−1を通過した第1バーナ3−1の燃焼排気が流れる第1燃焼部側排気流入空間10−1と、第2熱交換器4−2を通過した第2バーナ3−2の燃焼排気が流れる第2燃焼部側排気流入空間10−2とに2分する仕切り部材11が配置されている。ここで、副熱交換器9の下板9cは副熱交換器9の後方に張り出しており、この張出し部9c´に、各排気流入空間10−1,10−2の副熱交換器9の下側部分と後側部分とを連通する各連通口10a−1,10a―2を開設している。そして、仕切り部材11を、副熱交換器9の下側に配置した下仕切り板11aと、副熱交換器9の後側に配置した後仕切り板11bとで構成している。尚、図4では、図面の簡略化のため吸熱管9aを省略している。   As shown in FIGS. 1, 3, and 4, the exhaust gas located on the upstream side of the auxiliary heat exchanger 9 is located in the exhaust gas hood 8 on the boundary between the combustion parts 2-1 and 2-2. The exhaust inflow space in the hood 8, that is, the space from the lower side of the auxiliary heat exchanger 9 to the rear side of the auxiliary heat exchanger 9, the first burner 3-1 that has passed through the first heat exchanger 4-1. The first combustion section side exhaust inflow space 10-2 through which the combustion exhaust flows and the second combustion section side exhaust inflow space 10-2 through which the combustion exhaust of the second burner 3-2 that has passed through the second heat exchanger 4-2 flows. A partition member 11 is divided into two parts. Here, the lower plate 9c of the auxiliary heat exchanger 9 protrudes rearward of the auxiliary heat exchanger 9, and the protruding portion 9c 'has the auxiliary heat exchanger 9 in the exhaust inflow spaces 10-1 and 10-2. The respective communication ports 10a-1 and 10a-2 that establish communication between the lower portion and the rear portion are opened. The partition member 11 includes a lower partition plate 11 a disposed on the lower side of the sub heat exchanger 9 and a rear partition plate 11 b disposed on the rear side of the sub heat exchanger 9. In FIG. 4, the heat absorption tube 9a is omitted for simplification of the drawing.

副熱交換器9の後面の第1燃焼部側排気流入空間10−1に面する部分には排気流入口9dが開設されるが、副熱交換器9の後面の第2燃焼部側排気流入空間10−2に面する部分は、後仕切り板11bに連続する蓋板9eで閉塞されている。かくして、排気フード8内に、第1バーナ3−1の燃焼排気を第1燃焼部側排気流入空間10−1から排気流入口9dと副熱交換器9の内部空間とを介して排気フード8の排気口8aに流す第1燃焼部用排気経路と、第2バーナ3−2の燃焼排気を第2燃焼部側排気流入空間10−2から副熱交換器9の上側の空間を介して排気フード8の排気口8aに流す第2燃焼部用排気経路とが画成される。尚、副熱交換器9の上板9bには、第1燃焼部側排気流入空間10−1を上方から覆う後方への張出し部9b´が形成されており、第2バーナ3−2の燃焼排気が副熱交換器9の上側の空間から第1燃焼部側排気流入空間10−1を介して副熱交換器9内に流入することが防止される。   An exhaust inflow port 9d is opened in a portion facing the first combustion section side exhaust inflow space 10-1 on the rear surface of the auxiliary heat exchanger 9, but the second combustion section side exhaust inflow on the rear surface of the auxiliary heat exchanger 9 is provided. The part facing the space 10-2 is closed by a cover plate 9e continuous to the rear partition plate 11b. Thus, the combustion hood of the first burner 3-1 is introduced into the exhaust hood 8 from the first combustion section side exhaust inflow space 10-1 through the exhaust inlet 9d and the internal space of the auxiliary heat exchanger 9. The exhaust path for the first combustion section flowing through the exhaust port 8a and the exhaust gas of the second burner 3-2 is exhausted from the second combustion section side exhaust inflow space 10-2 through the space above the auxiliary heat exchanger 9. A second combustion part exhaust path that flows to the exhaust port 8a of the hood 8 is defined. The upper plate 9b of the auxiliary heat exchanger 9 is formed with a rearward projecting portion 9b 'that covers the first combustion portion side exhaust inflow space 10-1 from above, and the combustion of the second burner 3-2. Exhaust gas is prevented from flowing into the auxiliary heat exchanger 9 from the space above the auxiliary heat exchanger 9 via the first combustion section side exhaust inflow space 10-1.

副熱交換器9の後面の第1燃焼部側排気流入空間10−1に面する部分に開設した排気流入口9dは、第1と第2の両燃焼部2−1,2−2の境界部に近付くほど排気通過抵抗が減少するように形成される。本実施形態では、排気流入口9dを横方向に複数開設し、両燃焼部2−1,2−2の境界部に近い排気流入口9dほど開口面積を大きくして、排気通過抵抗が減少されるようにしているが、排気流入口となる多数の小孔を両燃焼部2−1,2−2の境界部に近付くほど密度が高くなるように形成して、排気通過抵抗を減少させることも可能である。何れにしても、両燃焼部2−1,2−2の境界部に近付くほど排気通過抵抗が減少するように排気流入口9aを形成することにより、第1燃焼部側排気通路10−1から両燃焼部2−1,2−2の境界部に近い位置で副熱交換器9内に流入する第1バーナ3−1の燃焼排気の量が増加し、第2燃焼部3−2の上方に位置する副熱交換器9の部分にも十分に第1バーナ3−1の燃焼排気が流れる。   The exhaust inlet 9d opened at the portion facing the first combustion section side exhaust inflow space 10-1 on the rear surface of the auxiliary heat exchanger 9 is a boundary between the first and second combustion sections 2-1, 2-2. The exhaust passage resistance is reduced as it approaches the portion. In the present embodiment, a plurality of exhaust inlets 9d are provided in the lateral direction, and the opening area is increased toward the exhaust inlet 9d closer to the boundary between the combustion sections 2-1, 2-2, and the exhaust passage resistance is reduced. However, the exhaust passage resistance is reduced by forming a large number of small holes as exhaust exhaust ports so that the density increases as they approach the boundary between the combustion sections 2-1, 2-2. Is also possible. In any case, by forming the exhaust inflow port 9a so that the exhaust passage resistance decreases as it approaches the boundary between the combustion sections 2-1, 2-2, the first combustion section side exhaust passage 10-1 The amount of combustion exhaust of the first burner 3-1 flowing into the auxiliary heat exchanger 9 at a position close to the boundary between the combustion sections 2-1 and 2-2 increases, and the upper side of the second combustion section 3-2. The combustion exhaust of the first burner 3-1 also flows sufficiently to the portion of the auxiliary heat exchanger 9 located at the position.

上記した本実施形態によれば、副熱交換器9が第1燃焼部2−1の上方位置から第2燃焼部2−2の上方位置に亘って延在する大型のものになるため、副熱交換器9の熱交換面積、即ち、吸熱管9aの全表面積を広く確保することができる。そして、第2燃焼部3−2の上方に位置する副熱交換器9の部分にも十分に第1バーナ3−1の燃焼排気が流れることと相俟って、副熱交換器9における第1バーナ3−1の燃焼排気中の潜熱の回収効率を可及的に向上させ、給湯の高効率化を図ることができる。また、副熱交換器9が第2燃焼部2−2の上方位置に亘って延在していても、第2熱交換器4−2を通過した第2バーナ3−2の燃焼排気は副熱交換器9を迂回して流れるため、第2燃焼部2−2側の単独運転時に副熱交換器9の吸熱管9a内の滞留水が過度に加熱されることを防止できる。   According to the above-described embodiment, the auxiliary heat exchanger 9 becomes a large one extending from the upper position of the first combustion section 2-1 to the upper position of the second combustion section 2-2. The heat exchange area of the heat exchanger 9, that is, the entire surface area of the heat absorption tube 9a can be secured widely. Then, in combination with the fact that the combustion exhaust gas of the first burner 3-1 sufficiently flows also to the portion of the auxiliary heat exchanger 9 located above the second combustion section 3-2, the second heat exchanger 9 in the auxiliary heat exchanger 9 The recovery efficiency of latent heat in the combustion exhaust of the 1 burner 3-1 can be improved as much as possible, and the efficiency of hot water supply can be increased. In addition, even if the auxiliary heat exchanger 9 extends over the upper position of the second combustion unit 2-2, the combustion exhaust of the second burner 3-2 that has passed through the second heat exchanger 4-2 is the auxiliary exhaust. Since it flows around the heat exchanger 9, it is possible to prevent the accumulated water in the heat absorption pipe 9a of the sub heat exchanger 9 from being excessively heated during the single operation on the second combustion unit 2-2 side.

尚、上記実施形態では、副熱交換器9の吸熱管9aを蛇行形状に形成しているが、図5に示す第2実施形態の如く、副熱交換器9に、排気ダクト8の横方向全幅に亘って真直にのびる比較的小径の直管状の吸熱管9aを多数並設することも可能である。第2実施形態では、排気ダクト8の横方向両外側に、これら吸熱管9aの一端と他端とを夫々纏めて接続する一対のヘッダ91´,92´が配置される。この場合、給水側と出湯側のヘッダとして両ヘッダ91´、92´の何れを用いても良い。   In the above embodiment, the heat absorption pipe 9a of the auxiliary heat exchanger 9 is formed in a meandering shape. However, as in the second embodiment shown in FIG. It is also possible to arrange a large number of relatively small-diameter straight endothermic tubes 9a extending straight across the entire width. In the second embodiment, a pair of headers 91 ′ and 92 ′ that collectively connect one end and the other end of the heat absorption pipe 9 a are disposed on both lateral sides of the exhaust duct 8. In this case, either of the headers 91 ′ and 92 ′ may be used as the header on the water supply side and the hot water side.

ところで、第1燃焼部2−1の上面に、内部に副熱交換器9を配置した、第2燃焼部2−2の上方位置に向けて横方向に広がる形状の排気ダクトを接続し、この排気ダクトで第1燃焼部用排気経路を構成すると共に、この排気ダクトを迂回するようにして第2燃焼部2−2の上面に接続される別の排気ダクトを設けて、この排気ダクトにより第2燃焼部用排気経路を構成することも考えられるが、これでは、排気系が大型複雑化する。これに対し、上記実施形態では、単一の排気フード8内に第1燃焼部用排気経路と第2燃焼部用排気経路とが画成されるため、排気系を小型簡素に構成でき、有利である。   By the way, an exhaust duct having a shape extending in the lateral direction toward the upper position of the second combustion unit 2-2, in which the auxiliary heat exchanger 9 is disposed, is connected to the upper surface of the first combustion unit 2-1. The exhaust duct constitutes an exhaust path for the first combustion section, and another exhaust duct connected to the upper surface of the second combustion section 2-2 is provided so as to bypass the exhaust duct. Although it is conceivable to configure the exhaust path for the two combustion sections, this makes the exhaust system large and complicated. On the other hand, in the above embodiment, the exhaust path for the first combustion section and the exhaust path for the second combustion section are defined in the single exhaust hood 8, so that the exhaust system can be configured to be small and simple. It is.

尚、上記実施形態では、排気フード8の前面に排気口8aを開設し、副熱交換器9内にその後側から前側に向けて第1バーナ3−1の燃焼排気が流れるようにしているが、これに限られるものではない。例えば、缶体1の上面に、排気口を上面に有する排気フードを配置し、この排気フード内に、吸熱管と吸熱管の配置部の前後に位置する板とを備える副熱交換器を配置し、副熱交換器内にその下側から上側に向けて第1バーナ3−1の燃焼排気が流れるようにすることも可能である。この場合、排気フード内の副熱交換器の下側空間が排気流入空間となるから、第1と第2の両燃焼部2−1,2−2の境界部上に、副熱交換器の下側空間を第1燃焼部2−1側の部分(第1燃焼部側排気流入空間)と第2燃焼部2−2側の部分(第2燃焼部側排気流入空間)とに2分する仕切り部材を配置する。また、副熱交換器の上流側端面となる副熱交換器の下面の第1燃焼部側排気流入空間に面する部分に排気流入口を開設して、第1熱交換器4−1を通過した第1バーナ3−1の燃焼排気が排気流入口と副熱交換器の内部空間とを介して排気フードの排気口に流れるようにすると共に、副熱交換器の下面の第2燃焼部側排気流入空間に面する部分を閉塞し、第2熱交換器4−2を通過した第2バーナ3−2の燃焼排気が副熱交換器の前後少なくとも一方の外側空間を介して排気フードの排気口に流れるようにする。   In the above embodiment, the exhaust port 8a is opened on the front surface of the exhaust hood 8 so that the combustion exhaust of the first burner 3-1 flows in the auxiliary heat exchanger 9 from the rear side to the front side. However, it is not limited to this. For example, an exhaust hood having an exhaust port on the upper surface is disposed on the upper surface of the can body 1, and an auxiliary heat exchanger including a heat absorption tube and a plate positioned before and after the arrangement portion of the heat absorption tube is disposed in the exhaust hood. And it is also possible to make combustion exhaust of the 1st burner 3-1 flow into the sub heat exchanger from the lower side to the upper side. In this case, since the lower space of the auxiliary heat exchanger in the exhaust hood becomes the exhaust inflow space, the auxiliary heat exchanger is placed on the boundary between the first and second combustion portions 2-1, 2-2. The lower space is divided into a first combustion part 2-1 side part (first combustion part side exhaust inflow space) and a second combustion part 2-2 side part (second combustion part side exhaust inflow space). A partition member is disposed. In addition, an exhaust inlet is opened at a portion facing the first combustion section side exhaust inflow space on the lower surface of the auxiliary heat exchanger that becomes the upstream end face of the auxiliary heat exchanger, and passes through the first heat exchanger 4-1. The combustion exhaust of the first burner 3-1 flows to the exhaust outlet of the exhaust hood via the exhaust inlet and the internal space of the auxiliary heat exchanger, and the second combustion section side of the lower surface of the auxiliary heat exchanger A portion facing the exhaust inflow space is closed, and the combustion exhaust of the second burner 3-2 that has passed through the second heat exchanger 4-2 is exhausted from the exhaust hood through at least one outer space before and after the auxiliary heat exchanger. Make it flow into the mouth.

また、上記実施形態では、第2熱交換器4−2を風呂追焚き用の熱交換器としたが、第2熱交換器4−2は暖房端末との間で熱媒体を循環させる暖房用の熱交換器であっても良い。更に、上記実施形態では、複合熱源機を1缶式のものとしたが、第1燃焼部2−1と第2燃焼部2−2とを各別の缶体内に配置する2缶式の複合熱源機にも同様に本発明を適用できる。   Moreover, in the said embodiment, although the 2nd heat exchanger 4-2 was used as the heat exchanger for bathing, the 2nd heat exchanger 4-2 is for heating which circulates a heat medium between heating terminals. The heat exchanger may be used. Furthermore, in the said embodiment, although the composite heat source machine was made into the 1 can type thing, the 2 can type composite which arrange | positions the 1st combustion part 2-1 and the 2nd combustion part 2-2 in each another can body. The present invention can be similarly applied to a heat source machine.

本発明熱源機の第1実施形態を示す切断正面図。The cutting | disconnection front view which shows 1st Embodiment of this invention heat source machine. 図1のII−II線で切断した排気フードの部分の切断側面図。FIG. 2 is a cut side view of a portion of the exhaust hood cut along line II-II in FIG. 1. 図2のIII−III線で切断した排気フードの部分の切断平面図。FIG. 3 is a cut plan view of a portion of the exhaust hood cut along line III-III in FIG. 2. 第1実施形態における副熱交換器の配置部を斜め後方から見た斜視図。The perspective view which looked at the arrangement | positioning part of the sub heat exchanger in 1st Embodiment from diagonally back. 第2実施形態の排気フードの部分の図3に対応する切断平面図。The cutting | disconnection top view corresponding to FIG. 3 of the part of the exhaust hood of 2nd Embodiment.

符号の説明Explanation of symbols

2−1…第1燃焼部、2−2…第2燃焼部、3−1…第1バーナ、3−2…第2バーナ、4−1…第1熱交換器、4−2…第2熱交換器、8…排気フード、8a…排気口、9…副熱交換器、9d…排気流入口、10−1…第1燃焼部側排気流入空間、10−2…第2燃焼部側排気流入空間、11…仕切り部材。   2-1 ... 1st combustion part, 2-2 ... 2nd combustion part, 3-1 ... 1st burner, 3-2 ... 2nd burner, 4-1 ... 1st heat exchanger, 4-2 ... 2nd Heat exchanger, 8 ... exhaust hood, 8a ... exhaust port, 9 ... sub heat exchanger, 9d ... exhaust inlet, 10-1 ... first combustion part side exhaust inflow space, 10-2 ... second combustion part side exhaust Inflow space, 11 ... partition member.

Claims (2)

第1バーナ及び第1バーナの上方に配置された給湯用の第1熱交換器を有する第1燃焼部と、第2バーナ及び第2バーナの上方に配置された給湯以外の用途の第2熱交換器を有する第2燃焼部とを横方向に並設した複合熱源機であって、第1バーナの燃焼排気中の潜熱を回収する給湯用の副熱交換器を備えるものにおいて、
第1と第2の両燃焼部の上面に、第1燃焼部の第2燃焼部とは反対側の側部から第2燃焼部の第1燃焼部とは反対側の側部に跨るようにして、燃焼排気を外部に排出する排気口を有する排気フードが配置され、
副熱交換器は、排気フード内に該排気フードの横方向全幅に亘って延在するように配置され、
排気フード内の両燃焼部の境界部上に位置する部分に、副熱交換器の上流側に位置する排気フード内の排気流入空間を、第1熱交換器を通過した第1バーナの燃焼排気が流れる第1燃焼部側排気流入空間と、第2熱交換器を通過した第2バーナの燃焼排気が流れる第2燃焼部側排気流入空間とに2分する仕切り部材が配置され、
副熱交換器内に燃焼排気を流入させるための排気流入口を開設する副熱交換器の上流側端面の第2燃焼部側排気流入空間に面する部分が閉塞され、
排気フード内に、第1燃焼部側排気流入空間から排気流入口と副熱交換器の内部空間とを介して排気フードの排気口に至る第1燃焼部用排気経路と、第2燃焼部側排気流入空間から副熱交換器の外側の空間を介して排気フードの排気口に至る第2燃焼部用排気経路とが画成されることを特徴とする複合熱源機。
The 1st combustion part which has the 1st heat exchanger for the hot water supply arrange | positioned above the 1st burner and the 1st burner, and the 2nd heat of uses other than the hot water supply arrange | positioned above the 2nd burner and the 2nd burner In a combined heat source machine in which a second combustion section having an exchanger is arranged side by side in a horizontal direction, and having a sub-heat exchanger for hot water supply for recovering latent heat in the combustion exhaust of the first burner,
On the upper surfaces of both the first and second combustion sections, the first combustion section extends from the side opposite to the second combustion section to the side of the second combustion section opposite to the first combustion section. An exhaust hood having an exhaust port for discharging combustion exhaust to the outside,
The auxiliary heat exchanger is disposed in the exhaust hood so as to extend over the entire lateral width of the exhaust hood,
The combustion exhaust of the first burner that has passed through the first heat exchanger passes through the exhaust inflow space in the exhaust hood located on the upstream side of the auxiliary heat exchanger at the portion located on the boundary between both combustion parts in the exhaust hood. A partition member that bisects the first combustion part side exhaust inflow space through which the gas flows and the second combustion part side exhaust inflow space through which the combustion exhaust of the second burner that has passed through the second heat exchanger flows,
The portion facing the second combustion part side exhaust inflow space of the upstream end face of the auxiliary heat exchanger that opens the exhaust inlet for allowing combustion exhaust to flow into the auxiliary heat exchanger is closed,
In the exhaust hood, an exhaust path for the first combustion section that extends from the first combustion section side exhaust inflow space to the exhaust port of the exhaust hood via the exhaust inlet and the internal space of the auxiliary heat exchanger, and the second combustion section side A composite heat source machine, characterized in that a second combustion section exhaust path from the exhaust inflow space to the exhaust port of the exhaust hood through a space outside the auxiliary heat exchanger is defined .
前記副熱交換器の上流側端面の前記第1燃焼部側排気流入空間に面する部分に開設する前記排気流入口は、前記両燃焼部の境界部に近付くほど排気通過抵抗が減少するように形成されることを特徴とする請求項記載の複合熱源機。 The exhaust inflow opening established at a portion facing the first combustion section side exhaust inflow space on the upstream end face of the auxiliary heat exchanger is configured such that the exhaust passage resistance decreases as the distance between the two combustion sections approaches. The composite heat source machine according to claim 1 , wherein the composite heat source machine is formed.
JP2005131271A 2005-04-28 2005-04-28 Combined heat source machine Expired - Fee Related JP4160576B2 (en)

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