JP2013234795A - Combustion device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a combustion device capable of mixing combustion exhaust gas without increasing exhaust resistance of a mixing chamber or increasing the size of the mixing chamber.SOLUTION: A rotary member with a communication port where combustion exhaust gas passes is provided at a communication part of a combustion part and a mixing chamber. When the rotary member is rotated, the position of the communication port where the combustion exhaust gas passes is changed, so that the flow of the combustion exhaust gas changes in the mixing chamber and a complicated flow is formed. Mixing of the combustion exhaust gas in the mixing chamber can be promoted. There is no need to install a partition plate, etc. for forming a serpentine flow of the combustion exhaust gas, thereby mixing the combustion exhaust gas without increasing the exhaust resistance of the mixing chamber or enlarging the mixing chamber.

Description

  The present invention relates to a combustion apparatus equipped with a sensor for detecting a predetermined gas component in combustion exhaust gas of a burner.

  As an example of a combustion apparatus provided with a burner inside, a water heater is known. In the water heater, fuel gas is burned by a burner, and high-temperature combustion exhaust gas is sent to the heat exchanger to heat the water supplied to the water pipe of the heat exchanger. The combustion exhaust gas that has passed through the heat exchanger is discharged to the outside through an exhaust pipe or the like.

  In such a combustion apparatus, when the combustion state in the burner deteriorates, the concentration of carbon monoxide (hereinafter referred to as CO) in the combustion exhaust gas increases. In view of this, there is known a combustion apparatus that can detect the combustion state by installing a sensor (CO sensor) for detecting the CO concentration and monitoring the CO concentration in the combustion exhaust gas. Even if a CO sensor is provided, if the CO concentration in the combustion exhaust gas is biased, the combustion state cannot be detected accurately. Therefore, a technique for mixing combustion exhaust gas upstream of the CO sensor has been proposed. Yes. For example, in the combustion apparatus disclosed in Patent Document 1, a partition plate for partitioning the inside of a mixing chamber for mixing combustion exhaust gas in multiple stages is provided, and the flow of combustion exhaust gas is meandered.

JP 2006-258386 A

  However, the structure disclosed in Patent Document 1 has a problem that exhaust resistance increases due to combustion exhaust colliding with a partition plate or an exhaust passage length becoming longer. In addition, there is a problem that the mixing chamber is enlarged because the partition plate is installed.

  The present invention has been made in response to the above-mentioned problems of the prior art, and enables sufficient mixing of combustion exhaust gas without increasing the exhaust resistance of the mixing chamber or increasing the size of the mixing chamber. The purpose is to provide technology.

In order to solve the above-described problems, the combustion apparatus of the present invention employs the following configuration. That is,
Combustion unit including a burner, a mixing chamber in which combustion exhaust gas flowing from the combustion unit is mixed and discharged, and a gas sensor for detecting a predetermined gas component in the combustion exhaust gas discharged from the mixing chamber In the combustion device,
A rotating member having a communication port through which the combustion exhaust gas passes is provided at a communication location between the combustion section and the mixing chamber.

  Here, as the “predetermined gas component detected by the gas sensor”, for example, the component concentration in the combustion exhaust gas may depend on the combustion state of the burner, and examples include carbon monoxide and fuel gas. be able to.

  In such a combustion apparatus of the present invention, since the position of the communication port through which the combustion exhaust passes is switched by the rotation of the rotating member, the flow of the combustion exhaust changes in the mixing chamber to form a complicated flow. Therefore, it is possible to promote the mixing of the combustion exhaust in the mixing chamber. Further, since the position of the opening only moves, the passage of the combustion exhaust is not blocked. Further, there is no need to lengthen the exhaust passage or to provide a partition plate for partitioning the mixing chamber in multiple stages. For this reason, it becomes possible to mix combustion exhaust gas without increasing the exhaust resistance of the mixing chamber or increasing the size of the mixing chamber.

  Moreover, in the combustion apparatus of this invention mentioned above, while dividing a combustion part and a mixing chamber with a partition, you may provide the rotating plate parallel to a partition as a rotation member.

  In this way, since it is sufficient if there is an installation space corresponding to the thickness of the rotating plate in the direction in which the combustion exhaust gas passes, the mixing chamber can be made compact.

  In the combustion apparatus of the present invention described above, the rotating member may be rotated by the flow of combustion exhaust gas passing through the communication port.

  In this way, since the rotating member rotates using the wind pressure of the combustion exhaust, it is not necessary to provide a drive motor for rotating the rotating member, and the combustion exhaust can be mixed more easily.

It is explanatory drawing which showed the structure of the combustion apparatus of a present Example taking the water heater 10 as an example. It is the perspective view which showed the internal structure of the mixing chamber 50 of a present Example. It is explanatory drawing which showed the reason for which mixing of combustion exhaust is accelerated | stimulated when the rotating plate 70 of the mixing chamber 50 rotates. It is the perspective view which showed the internal structure of the mixing chamber 50 of the 1st modification. It is the perspective view which showed the internal structure of the mixing chamber 50 of the 2nd modification. It is the perspective view which showed the internal structure of the mixing chamber 50 of the 3rd modification.

  FIG. 1 is an explanatory view showing the structure of a combustion apparatus of the present embodiment, taking a water heater 10 as an example. As shown in the drawing, the water heater 10 includes a combustion unit 20 disposed at a lower position, a heat exchanger 40 provided above the combustion unit 20, and a mixing chamber 50 provided above the heat exchanger 40. And a cylindrical exhaust cylinder 54 connected to the upper surface of the mixing chamber 50. The water heater 10 is entirely covered with an outer case, but the outer case is not shown in FIG.

  In the combustion section 20, a plurality of (15 in the illustrated example) unit burners 22 elongated in the front-rear direction (a direction orthogonal to the paper surface of FIG. 1) are provided on the water heater 10. They are arranged side by side in a direction (a direction parallel to the paper surface of FIG. 1). Fuel gas is supplied to the plurality of unit burners 22 through a gas supply pipe 30 connected to the combustion unit 20.

  In the water heater 10 of the present embodiment, a plurality (15) of unit burners 22 are divided into three burner groups, and the first burner group 24 includes three unit burners 22, and the second burner group 26. Is composed of five unit burners 22, and the third burner group 28 is composed of seven unit burners 22. The hot water supply capacity can be switched depending on which burner group the fuel gas is supplied to. For example, when only the smallest hot water supply capacity is required, the fuel gas is supplied only to the first burner group 24. Moreover, when the greatest hot water supply capability is required, fuel gas is supplied to all the burner groups (24, 26, 28). When an intermediate hot water supply capability is required, one or two burner groups are appropriately selected from the three burner groups (24, 26, 28) and fuel gas is supplied.

  A blower fan 32 is attached below the combustion unit 20. When the blower fan 32 is rotated, combustion air is supplied to the unit burner 22 in the combustion unit 20, and the unit burner 22 Hot combustion exhaust gas generated by the combustion is sent to the upper heat exchanger 40.

  Inside the heat exchanger 40, a water pipe 42 is disposed, and a large number of heat absorption fins (not shown) are provided around the water pipe 42. When water is supplied to the water flow pipe 42, the water passing through the water flow pipe 42 is heated by heat exchange with the high-temperature combustion exhaust sent from the combustion unit 20 to the heat exchanger 40, and becomes hot water (hot water).

  The combustion exhaust gas that has passed through the heat exchanger 40 passes through the mixing chamber 50 and the exhaust pipe 54 and is discharged to the outside from an exhaust port 56 at the upper end of the exhaust pipe 54. As will be described in detail later, a CO sensor 58 for detecting the carbon monoxide concentration (hereinafter referred to as CO concentration) in the combustion exhaust is provided in the mixing chamber 50 into which the combustion exhaust flows from the heat exchanger 40. ing. Further, the upper part of the exhaust tube 54 is provided so as to protrude from an exterior case (not shown) that covers the water heater 10. The CO sensor of this example corresponds to the “gas sensor” of the present invention.

  FIG. 2 is a perspective view showing the internal structure of the mixing chamber 50 of this embodiment. As shown in the drawing, the bottom of the mixing chamber 50 is constituted by an exhaust guide plate 60 in which a circular inflow port 62 for communicating the heat exchanger 40 and the mixing chamber 50 is formed. The exhaust guide plate 60 is formed in a shape that rises toward the mixing chamber 50, and guides the combustion exhaust gas that has passed through the heat exchanger 40 and collects it at the inlet 62. The position of the inflow port 62 is set to a position shifted from the position facing the outflow port 52 formed on the upper surface of the mixing chamber 50. Moreover, in the water heater 10 of the present embodiment, the disk-shaped rotating plate 70 is installed so as to cover the inlet 62 from above. The rotary plate 70 is formed with a communication port 72 penetrating in the vertical direction, and a rotary shaft 74 is provided at the center. The rotary shaft 74 is connected to a drive motor (not shown) that rotates the rotary plate 70. The rotating plate 70 of the present embodiment corresponds to the “rotating member” of the present invention, and the exhaust guide plate 60 of the present embodiment corresponds to the “partition wall” of the present invention. Note that the position of the inflow port 62 is not necessarily shifted from the position facing the outflow port 52, and may be a position facing the outflow port 52. By facing the inflow port 62 and the outflow port 52, the passage direction of the combustion exhaust gas is not bent, so that the exhaust resistance of the mixing chamber 50 can be reduced.

  A CO sensor 58 is provided inside the mixing chamber 50. The CO sensor 58 includes a detection element 58a, a storage case 58b for storing the detection element 58a, a hollow sampling pipe 58c connected to the storage case 58b, and the like. In a state where the storage case 58 b is attached to the side surface of the mixing chamber 50, the sampling pipe 58 c is extended to a position below the outflow port 52 formed on the upper surface of the mixing chamber 50. The collection pipe 58c is provided with a plurality of collection holes (not shown) arranged in the extending direction of the collection pipe 58c, and combustion exhaust gas passing through the outlet 52 is taken in from the collection hole. The combustion exhaust gas thus taken into the collection pipe 58c is guided to the storage case 58b, and the CO concentration is detected by the detection element 58a. When the CO concentration exceeds a predetermined reference value, it is determined that the combustion state in the combustion unit 20 has deteriorated (combustion failure has occurred), and the supply of fuel gas to the unit burner 22 is shut off. As a result, combustion is stopped.

  Thus, in the water heater 10 that determines the combustion state in the combustion unit 20 by monitoring the CO concentration in the combustion exhaust gas, if the CO concentration in the combustion exhaust gas in the mixing chamber 50 is biased, The combustion state cannot be detected accurately. Therefore, in the water heater 10 of the present embodiment, the mixing plate 50 is provided with the rotating plate 70, and the mixing of the combustion exhaust is promoted by rotating the rotating plate 70.

  FIG. 3 is an explanatory view showing the reason why mixing of combustion exhaust is promoted by the rotation of the rotating plate 70 of the mixing chamber 50. First, as shown in FIG. 3A, the combustion exhaust gas that has passed through the heat exchanger 40 flows into the mixing chamber 50 from two communication ports 72 formed in the rotating plate 70. The band-shaped arrow in the figure schematically represents the flow of combustion exhaust as an example. In the illustrated example, the combustion exhaust flows into the mixing chamber 50 vertically upward from the communication port 72.

  FIG. 3B shows a state in which the rotating plate 70 is rotated 90 degrees from the state of FIG. When the rotating plate 70 rotates, the position of the communication port 72 moves, and the location where the combustion exhaust gas flows changes. 3 (a) and 3 (b), the inflow location of the combustion exhaust differs by 90 degrees with respect to the rotation shaft 74 of the rotating plate 70. Accordingly, the flow of the combustion exhaust in the mixing chamber 50 is also different. Change. Thus, if the rotating plate 70 is rotated, the flow of the combustion exhaust gas in the mixing chamber 50 changes every moment, and a complicated flow is formed in the mixing chamber 50. As a result, since the mixing of the combustion exhaust in the mixing chamber 50 can be promoted, the combustion state of the combustion unit 20 can be accurately detected.

  Further, in the configuration in which the rotating plate 70 is rotated as in the present embodiment, the position of the communication port 72 of the rotating plate 70 only moves, so that the heat exchanger 40 and the mixing chamber 50 are always in communication with each other through the communication port 72. ing. Therefore, combustion exhaust gas can be mixed without increasing the exhaust resistance of the mixing chamber 50.

  Furthermore, in the mixing chamber 50 of the present embodiment, it is only necessary to install the rotating plate 70 so as to cover the inflow port 62 from above, and to the outflow port 52 like the conventional mixing chamber 50 that meanders the flow of combustion exhaust gas. There is no need to increase the length of the exhaust passage or to provide a partition plate for partitioning the interior in multiple stages. For this reason, combustion exhaust gas can be mixed without enlarging the mixing chamber 50.

  The combustion apparatus (hot water heater 10) of the above-described embodiment also has the following modifications. In the following, modifications will be described focusing on differences from the above-described embodiment. In the description of the modification, the same components as those in the above-described embodiment are denoted by the same reference numerals and the description thereof is omitted.

  FIG. 4 is a perspective view showing the internal structure of the mixing chamber 50 of the first modification. As shown in the drawing, in the mixing chamber 50 of the first modified example, a rectangular inlet 62 is formed in the exhaust guide plate 60 constituting the bottom. Further, a columnar rotating body 80 is provided, and the rotating shaft 84 of the rotating body 80 is fitted into the inflow port 62 so as to be parallel to the exhaust guide plate 60. Four through holes 82 penetrating the rotary body 80 are formed on the circumferential side surface of the rotary body 80, and the four through holes 82 have different penetration directions by 45 degrees. In the illustrated example, in a state in which the left end through hole 82 faces the vertical direction, the second through hole 82 from the left is inclined 45 degrees toward the front, and the third through hole 82 from the left faces the horizontal direction. The through hole 82 at the right end is inclined 45 degrees to the back side. Furthermore, a drive motor (not shown) is connected to the rotation shaft 84 of the rotator 80, and the rotator 80 is rotated by the drive of the drive motor. The rotating body 80 of the first modification corresponds to the “rotating member” of the present invention, and the through hole 82 of the first modification corresponds to the “communication opening” of the present invention.

  In the mixing chamber 50 of the first modified example as described above, when the rotating body 80 rotates and, for example, the left end through-hole 82 facing the vertical direction faces the horizontal direction, the second through-hole 82 from the left is the back. The third through-hole 82 from the left is inclined in the vertical direction, the right-end through-hole 82 is inclined 45 degrees toward the front side, and the position where each through-hole 82 opens to the mixing chamber 50 side (That is, the location where the combustion exhaust flows) is switched. Since the inflow location of the combustion exhaust gas changes in this way, the flow of the combustion exhaust gas in the mixing chamber 50 changes as the rotating body 80 rotates. As a result, similar to the above-described embodiment, mixing of combustion exhaust can be promoted.

  FIG. 5 is a perspective view showing the internal structure of the mixing chamber 50 of the second modification. In the mixing chamber 50 of the second modified example, a so-called cross flow fan 90 having a cylindrical shape is provided instead of the rotating body 80 of the first modified example in which the through hole 82 is formed, and the rotating shaft 96 is an exhaust guide plate. The inlet 62 is fitted so as to be parallel to the inlet 60. The cross flow fan 90 is provided with a plurality of blade pieces 92 elongated in the axial direction of the rotary shaft 96 in a radial pattern with respect to the rotary shaft 96. A predetermined gap 94 is provided between the blade piece 92 and the blade piece 92, and the combustion exhaust gas flows into the mixing chamber 50 through the gap 94. When a driving motor (not shown) connected to the rotating shaft 96 is driven to rotate the cross flow fan 90, the position of the gap 94 (the location where the combustion exhaust flows in) moves, and the mixing chamber The flow of combustion exhaust in 50 changes. Therefore, mixing of combustion exhaust can be promoted. The cross flow fan 90 of the second modified example corresponds to the “rotating member” of the present invention, and the gap 94 of the second modified example corresponds to the “communication port” of the present invention.

  FIG. 6 is a perspective view showing the internal structure of the mixing chamber 50 of the third modification. In the mixing chamber 50 of the third modified example, an impeller 100 is installed so as to cover the inlet 62 from above instead of the rotating plate 70 of the above-described embodiment. In the impeller 100, a plurality of (three in the illustrated example) blades 102 are radially attached around a rotation shaft 106, and an opening 104 through which combustion exhaust passes between the blades 102 and 102. Is provided. The blades 102 are provided so as to be inclined at a predetermined angle from the horizontal direction. The impeller 100 of the third modification corresponds to the “rotating member” of the present invention, and the opening 104 of the third modification corresponds to the “communication port” of the present invention.

  In the mixing chamber 50 according to the third modified example, the impeller 100 is rotated by the wind pressure of the combustion exhaust from the heat exchanger 40. Accordingly, the position of the opening 104 of the impeller 100 (combustion exhaust inflow location) moves, so that the flow of combustion exhaust in the mixing chamber 50 changes. As a result, similar to the above-described embodiment, mixing of combustion exhaust can be promoted. Further, since the impeller 100 of the third modification rotates using the wind pressure of the combustion exhaust, it is not necessary to provide a drive motor for rotating the impeller 100, and combustion exhaust can be mixed more easily. It becomes.

  Although the combustion apparatus (water heater 10) of the present embodiment and the modification has been described above, the present invention is not limited to the above-described embodiment and modification, and can be implemented in various modes without departing from the gist thereof. Is possible.

  For example, in the above-described embodiments, the CO concentration in the combustion exhaust gas is detected. However, the gas component to be detected is not limited to carbon monoxide, and the component concentration in the combustion exhaust gas is the combustion of the combustion unit 20. Anything that depends on the state may be used. For example, fuel gas may be detected. In this case, a gas sensor for detecting the fuel gas concentration may be provided in place of the CO sensor 58.

  In the above-described embodiment, the CO sensor 58 is provided in the mixing chamber 50. However, the CO sensor 58 is not necessarily provided in the mixing chamber 50. For example, the CO sensor 58 may be installed at a position different from the mixing chamber 50, and the combustion exhaust collected at the position of the outlet 52 of the mixing chamber 50 may be guided to the CO sensor 58 through the induction passage. In this way, the mixing chamber 50 can be made compact.

10 ... Hot water heater, 20 ... Combustion section, 22 ... Unit burner,
24 ... 1st burner group, 26 ... 2nd burner group, 28 ... 3rd burner group,
30 ... Gas supply pipe, 32 ... Blower fan, 40 ... Heat exchanger,
42 ... Water pipe, 50 ... Mixing chamber, 52 ... Outlet,
54 ... exhaust pipe, 56 ... exhaust port, 58 ... CO sensor,
58a: detecting element, 58b: storage case, 58c: sampling pipe,
60 ... Exhaust guide plate, 62 ... Inlet, 64 ... Shielding wall,
70 ... Rotating plate, 72 ... Communication port, 74 ... Rotating shaft,
80 ... Rotating body, 82 ... Through hole, 84 ... Rotating shaft,
90 ... Cross flow fan, 92 ... Wings, 94 ... Gap,
96 ... Rotating shaft, 100 ... Impeller, 102 ... Blade,
104 ... opening, 106 ... rotating shaft

Claims (3)

Combustion unit including a burner, a mixing chamber in which combustion exhaust gas flowing from the combustion unit is mixed and discharged, and a gas sensor for detecting a predetermined gas component in the combustion exhaust gas discharged from the mixing chamber In the combustion device,
A combustion device, wherein a rotation member having a communication port through which the combustion exhaust gas passes is provided at a communication location between the combustion section and the mixing chamber. The combustion apparatus according to claim 1, wherein
The combustion section and the mixing chamber are separated by a partition wall,
The combustion apparatus, wherein the rotating member is a rotating plate provided in parallel with the partition wall. The combustion apparatus according to claim 1, wherein
The rotation device is rotated by the flow of the combustion exhaust gas passing through the communication port.

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