JP2013071114A - Neutralization device and combustion apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To develop a neutralization device which can fix the position of a water supply pipe relative to the neutralization device to stabilize the pipe.SOLUTION: The neutralization device 11 includes a body 40 and a lid 41. A top face 45 has a water supply unit 50, a drain introduction port 51, four electrode insertion holes 52 to 55, and pipe positioning means 61 and 62. The pipe positioning means 61 and 62 each have a pipe fixing portion 63 at their tops. A water supply pipe 30 is fixed to the pipe fixing portion 63. The heights of the pipe positioning means 61 and 62 and the water supply unit 50 are determined such that the pipe positioning means 61 is the highest, the pipe positioning means 62 is the second highest, and the water supply unit 50 is the lowest. This gives the water supply pipe 30 a proper flow gradient.

Description

  The present invention relates to a neutralizer for neutralizing drain generated when recovering latent heat of combustion gas. Moreover, it is related with the combustion apparatus provided with the neutralization apparatus.

  In recent years, in order to improve the heat exchange efficiency of heat generated when a burner is burned, a latent heat recovery type combustion apparatus that recovers even the latent heat of combustion gas has become widespread in the market. Since this latent heat recovery type combustion apparatus mainly recovers heat generated when water vapor in the combustion gas is liquefied, a heat exchanger (secondary heat exchanger) for recovering latent heat has a large amount of heat. Drain is generated. And it is known that this drain will show the acidity, the nitrogen oxide produced | generated at the time of combustion melt | dissolves.

  For this reason, this type of combustion apparatus has a drain discharge system that guides drain to the outside, and a neutralization device that neutralizes acidic drain is provided in the middle of the flow path. In other words, the acidic drain generated in the secondary heat exchanger is not discharged outside while maintaining its acidity, and is neutralized by the neutralizer and then discharged outside, which has a negative impact on the environment. There is no fear of effects.

  However, since the drain discharge system and the exhaust flow path of the combustion gas are in communication with each other, the combustion gas that should be discharged to the outside through the exhaust pipe of the combustion device is originally discharged to the outside through the drain discharge system. There was a concern of being discharged. In particular, in an indoor installation type combustion apparatus, when combustion gas is discharged from the drain discharge system, combustion gas is discharged indoors in the living space, so from the viewpoint of the safety of residents, Such a defect was one of the items to be avoided.

  Therefore, as a countermeasure, a part of the neutralization device where the combustion gas can pass is filled with drain to form a water-sealed structure and forcibly block the distribution of the combustion gas through the drain discharge system. Is generally adopted.

  However, since this water-sealed structure with drain is limited to a case where a predetermined amount or more of drain is stored in the container, it may not function effectively when sufficient drain is not stored in the container. is there. For example, when a new neutralizer is installed or when the drain in the neutralizer container is artificially removed to prevent or freeze the drain, there is no drain in the container. Therefore, a water seal structure is not formed. Further, even when drain is present in the container of the neutralizer, the water level may decrease due to some cause, and the water seal structure may not be formed. As described above, the water-sealed structure that relies only on the drain generated by combustion may secure a flow path through which the combustion gas can pass in the drain discharge system, effectively preventing the circulation of the combustion gas. I couldn't.

  Therefore, Patent Document 1 discloses a technology of a combustion apparatus provided with a neutralization device forcibly supplying water according to the water level of the drain in the container for the purpose of forming a reliable water seal structure. . That is, the combustion apparatus of Patent Document 1 monitors whether or not the inside of the container of the neutralization apparatus is equal to or higher than the reference water level by the electrode, and if the water level falls below the reference water level, water is forcibly supplied into the container. It is the structure which adjusts the water level in a container more than a reference | standard water level. In Patent Document 1, since a water-sealed structure is reliably formed in the container of the neutralizer, it is not possible for combustion gas to be discharged outside through the drain discharge system.

JP 2009-150576 A

  In the combustion apparatus having the function of forcibly supplying water as described above, a water supply pipe for supplying water to the container is required.

By the way, in recent years, a combustion apparatus that can be installed in a narrow place has been desired from the market, and a combustion apparatus reduced in size has been developed to meet such a demand. In such a combustion apparatus, since the internal space of the combustion apparatus is substantially narrowed, a large space cannot be secured around the installation position of the neutralization apparatus. Then, when attaching a neutralization apparatus inside a combustion apparatus, the space for an operator to work cannot be secured.
Therefore, in the downsized combustion device, it is difficult to design the layout of the water supply pipe with respect to the neutralization device.
For this reason, in the prior art, the water supply piping for the neutralizing device is constituted by tubes and hoses, and these tubes and hoses are pushed into the gaps inside the combustion device.
Moreover, the present condition is using solid piping, such as a copper pipe, and storing the said piping in a combustion apparatus inside in the state of hanging, or installing along other piping etc. with a binding tool.
As described above, the conventional combustion apparatus has a problem that the water supply pipe is not stable.

Therefore, when installing a neutralization apparatus when assembling a combustion apparatus in a factory, or when connecting the above-mentioned water supply piping to this, piping may be bent.
Similarly, when the neutralizer is removed for the purpose of maintenance or when the neutralizer is mounted again, the pipe may be bent.
Further, when a member in the vicinity of the neutralizing device is moved for maintenance, the moved member or the like hits the water supply pipe, and the pipe may be bent or the pipe may be removed.

  Therefore, the present invention pays attention to the above-mentioned problems of the prior art, and it is an object to develop a neutralizing device and a combustion device that can determine the position of the water supply pipe with respect to the neutralizing device and can stabilize the piping. Is.

  The invention described in claim 1 for solving the above problem is provided in a combustion apparatus that heats water or a heat medium, and mainly neutralizes and discharges the drain that is generated when the latent heat of the combustion gas is recovered. It is a neutralization device, a storage part for storing drain, a drain introduction port for introducing drain into the storage part, a drain discharge port for discharging drain from the storage part, and a water supply part for introducing water into the storage part The neutralization device has a top surface portion, the top surface portion includes the water supply portion, and a pipe positioning means is integrally formed on the top surface portion.

The neutralizing device of the present invention has a top surface portion, and pipe positioning means is integrally formed on the top surface portion. Therefore, the water supply pipe can be positioned by the positioning means, and the pipe can be stabilized.
Moreover, since the piping positioning means is provided on the top surface portion, the piping can be arranged at a position along the top surface portion or in the vicinity of the top surface portion. Therefore, the water supply pipe is less likely to interfere with other pipes.

  According to a second aspect of the present invention, the position and height of the pipe positioning means are such that when the water supply pipe is positioned by the pipe positioning means and the tip of the water supply pipe is connected to the water supply section, the water supply pipe is supplied with water. The neutralization device according to claim 1, wherein the neutralization device has a position and a height that are inclined toward the portion.

An object of the present invention is to prevent water from staying in a water supply pipe.
That is, in cold districts, if water stays in the water supply pipe, the water in the water supply pipe may freeze.
That is, in a cold region, water in the neutralizing device may be drained artificially for the purpose of preventing drainage in the neutralizing device. When water in the neutralizer is drained artificially, water remains in the water supply pipe, and when the water in the water supply pipe freezes, the water supply pipe is clogged with ice when the combustion device is started. As a result, water cannot be poured into the neutralizing device, and the combustion device cannot be used.
Since water flow through the water supply pipe is often performed in a cold region, it should be avoided that water stays in the water supply pipe.
According to the second aspect of the present invention, when the water supply pipe is positioned by the pipe positioning means and the tip of the water supply pipe is connected to the water supply part, the water supply pipe is inclined toward the water supply part. It becomes posture to do. Therefore, the water supply pipe has a flow gradient toward the water supply section, and water does not stagnate in the pipe.

  The invention according to claim 3 is the neutralization apparatus according to claim 1 or 2, wherein the pipe positioning means includes a pipe fixing portion for fixing the pipe.

  In the neutralization apparatus of the present invention, the pipe positioning means itself includes a pipe fixing portion that fixes the pipe. For this reason, the water supply pipe is fixed to the neutralizer and stabilized.

  It is recommended that the tube fixing portion has a ring-shaped portion with a part cut off (claim 4).

  The pipe fixing part has a pipe arrangement part equal to or larger than the outer diameter of the pipe to be supported, and a pipe introduction port for introducing the pipe into the pipe arrangement part. It is desirable that it is narrower than the outer diameter of the above (claim 5)

  According to the present invention, the pipe can be forcibly fixed to the pipe fixing portion. Further, since the pipe introduction port is narrower than the outer diameter of the pipe, the attached pipe is difficult to come off.

  The invention according to claim 6 is a combustion section for burning fuel, a primary heat exchanger for mainly recovering sensible heat of the combustion gas generated in the combustion section, and a second for recovering mainly latent heat of the combustion gas. A secondary heat exchanger and a drain discharge system for discharging drain generated in the secondary heat exchanger to the outside, and forming a part of the drain discharge system. A water supply system for supplying water to the neutralization device, the water supply system having a water supply valve and a water supply pipe, the water supply pipe having a water supply valve and a water supply unit of the neutralization device The combustion apparatus is characterized in that it is connected, and a midway portion of the water supply pipe is positioned by the pipe positioning means.

  In the combustion apparatus of the present invention, the water supply pipe for the neutralization apparatus is stable, and assembly and maintenance are easy. Moreover, the combustion apparatus of this invention has few failures regarding water supply piping.

  The neutralization device and the combustion device of the present invention can determine the position of the water supply pipe relative to the neutralization device, and can stabilize the pipe. Therefore, assembly and maintenance are easy. Moreover, the combustion apparatus of this invention has few failures regarding water supply piping.

It is a block diagram which shows the housing | casing inside of the combustion apparatus which concerns on embodiment of this invention. It is a perspective view which shows the neutralization apparatus which concerns on embodiment of this invention. It is a disassembled perspective view of the neutralization apparatus of FIG. It is the perspective view which observed the cover part of the neutralization apparatus of FIG. 1 from the back surface side. It is the perspective view which looked at the neutralization apparatus of FIG. 1 from another angle. It is a top view which shows the main-body part of the neutralization apparatus of FIG. It is a cross-sectional perspective view of the storage part of the neutralization apparatus of FIG. It is a perspective view which shows the whole water supply system. It is a top view of the neutralization apparatus in the state which equipped with water supply piping. It is a front view of the upper surface part of the neutralization apparatus in the state where the water supply piping was installed. It is a perspective view of a piping positioning means. (A) (b) (c) is explanatory drawing which shows the behavior at the time of mounting | wearing a piping positioning means with a water supply pipe over time. It is a perspective view which shows the modification of a piping positioning means. It is a perspective view which shows the state which attached water supply piping to the piping positioning means of FIG.

Below, the combustion apparatus 1 which concerns on embodiment of this invention, and the neutralization apparatus 11 are demonstrated.
The neutralization device 11 of this embodiment is built in the combustion device 1. The combustion apparatus 1 includes a so-called reverse combustion type combustion unit 2 that sprays or vaporizes liquid fuel such as kerosene and burns it downward, and can recover even the latent heat of the combustion gas generated in the combustion unit 2. This is a latent heat recovery type combustion apparatus 1, and the neutralization apparatus 11 of the present embodiment is suitable for this type of combustion apparatus 1.

First, the combustion apparatus 1 will be described.
As shown in FIG. 1, the combustion device 1 has a combustion case 5 disposed substantially at the center of the housing 3, and the combustion case 2, the primary heat exchanger 20, and the secondary heat exchanger 25 are disposed in the combustion case 5. Is built-in. Specifically, in the combustion case 5, a burner side case 4, a vertically long case 6 having a substantially rectangular parallelepiped shape that is long in the height direction (vertical direction), and a horizontally long case 7 that is long in the width direction (left and right direction) communicate with each other. The combustion part is arranged in the burner side case 4, the primary heat exchanger 20 is arranged in the vertically long case 6, and the secondary heat exchanger 25 is arranged in the horizontally long case 7. Yes.
Further, an exhaust cylinder 10 for exhausting combustion gas to the outside is disposed on the left side of the casing 3 of the combustion apparatus 1. Specifically, the exhaust cylinder 10 is disposed so as to extend inside and outside the casing 3 of the combustion apparatus 1 and is connected to the upper left side of the horizontally long case 7.

That is, when combustion gas is generated in the combustion unit 2, the combustion gas first proceeds downward, passes through the primary heat exchanger 20, and flows into the secondary heat exchanger 25. The combustion gas flowing into the secondary heat exchanger 25 changes the flow direction of the combustion gas from the lower direction to the upper direction, passes through the exhaust pipe 10 and is exhausted to the outside.
In addition, the combustion apparatus 1 of this embodiment has an air blower which is not shown in figure, the air required for combustion is supplied with the air blower, and also the combustion gas produced | generated by the combustion part 2 is flowed downward.

  Moreover, the primary heat exchanger 20 and the secondary heat exchanger 25 each have a heat receiving pipe (not shown) through which clean water that exchanges heat with the combustion gas flows, and these heat receiving pipes, a water inlet side pipe and a hot water outlet side pipe (not shown). Forms a series of flow paths in the housing 3 of the combustion apparatus 1. Specifically, the inlet side piping, the secondary heat exchanger 25, the primary heat exchanger 20, and the hot water side piping are connected in series in this order from the upstream side in the flowing water direction. That is, in the combustion apparatus 1, the clean water that has passed through the water inlet side pipe flows through the secondary heat exchanger 25 and then flows through the primary heat exchanger 20, so that heat is sequentially exchanged. It is supplied toward the hot water supply destination.

Also, in the combustion case 5, a horizontally long case 7 is provided with a recovery unit (not shown) that recovers drain generated when the latent heat of the secondary heat exchanger 25 is recovered, and from the recovery unit to the combustion device 1. A drain discharge system 12 is connected to flow drain toward the lower side. That is, this drain discharge system 12 is located on the lower side of the housing 3 with respect to the horizontally long case 7, a neutralization device 11, a drain introduction side pipe 13 that connects the horizontally long case 7 and the neutralization device 11, It is comprised by the drain external discharge piping 14 which guides the drain neutralized with the neutralization apparatus 11 outside.
In addition, the neutralization device 11 of the present embodiment has a water seal structure in the device,
A water supply pipe 30 through which clean water supplied from a water supply source passes is connected.

That is, the combustion apparatus 1 of the present embodiment has a water supply system 31 that pours clean water into the neutralization apparatus 11.
As shown in FIGS. 1 and 8, the water supply system 31 is connected to an external water supply source (not shown), and a water retention pipe 35 distributed through a distribution valve 33 from a main pipe portion 32 that draws clean water into the housing 3. And a solenoid valve (open / close valve) 36 and a water supply pipe 30.
The water retaining pipe 35 and the water supply pipe 30 are connected via an electromagnetic valve 36.
Therefore, when the electromagnetic valve 36 is opened, water is supplied to the water supply pipe 30 and clean water is injected into the neutralizing device 11.
In the present embodiment, as shown in FIG. 1, the solenoid valve 36 is disposed on the side opposite to the exhaust tube 10 and on the side surface portion of the secondary heat exchanger 25.

Next, the neutralizing device 11 having a characteristic configuration will be described in detail.
In the following description, the vertical and horizontal positional relationships will be described based on the normal installation state shown in FIG. 1 unless otherwise specified.
As described above, the neutralization device 11 of the present embodiment is connected to the water supply pipe 30 in order to ensure the water-sealed structure in the device, and from a water supply source (not shown) when a predetermined condition is satisfied. The supplied clean water is introduced through the water supply pipe 30.
Specifically, as shown in FIG. 2, the neutralizing device 11 is a container having an approximately “L” -shaped appearance, and includes a main body portion 40 and a lid portion 41.
Here, the main body 40 is a container having a storage part 15 in which the drain that has passed through the drain introduction side pipe 13 is temporarily stored, and a bottomed space 16 through which the clean water that has flowed through the water supply pipe 30 passes. The lid portion 41 is detachably provided on the upper portion of the main body portion 40 and constitutes the top surface portion 45 of the entire neutralizing device 11.

The lid portion 41 is made of resin, and each member is integrally formed by injection molding.
As shown in FIG. 3, the lid portion 41 surrounds the top surface portion 45 having a substantially “L” shape in plan view and the edge of the top surface portion 45 and faces vertically downward with respect to the top surface portion 45. It is the structure which has the side wall 46 standingly arranged, and the fitting groove 47 (FIG. 4) in which the upper part of the main-body part 40 fits.

The top surface portion 45 is provided with a water supply portion 50, a drain introduction port 51, and four electrode insertion holes 52 to 55.
The water supply part 50 is a pipe joint part that penetrates in the thickness direction of the top surface part 45 in order to introduce the clean water that has passed through the water supply pipe 30 into the bottomed space 16 of the main body part 40. Specifically, the water supply unit 50 is in the region 57 on the side where the “L” overhang length of the top surface portion 45 is short. The water supply part 50 is connected to the water supply port 58 (FIG. 4) on the back side.
It can be said that the position of the water supply unit 50 is one corner of the top surface 45.
In the present embodiment, an auxiliary joint 60 extending in the horizontal direction (the direction along the top surface portion 45) is attached to the water supply unit 50. The auxiliary joint 60 has an inner diameter set to be approximately the same as the outer diameter of the water supply pipe 30. That is, the water supply pipe 30 is inserted and connected along the inner diameter side of the auxiliary joint 60.

Further, pipe positioning means 61 and 62 are integrally formed on the top surface portion 45 at the time of injection molding. Although the pipe positioning means 61 and 62 are different in direction and height, the external appearance is the same. As shown in FIG. 11, the pipe positioning means 61 and 62 have a plate wall portion 86 and project vertically from the top surface portion 45. A reinforcing rib 87 is provided between the top surface portion 45 and the plate wall portion 86.
Further, a pipe fixing portion 63 is provided at the distal end portion of the pipe positioning means 61 and 62.
The pipe fixing part 63 is a ring having a missing part 64 in part, and has a circular pipe arrangement part 69. The diameter of the pipe arrangement portion 69 is slightly larger than the outer diameter of the water supply pipe 30.
The missing part 64 functions as a piping inlet. The clearance gap (width of the pipe introduction port) of the missing portion 64 that is the pipe introduction port is narrower than the outer diameter of the water supply pipe 30. Further, the vicinity of the missing portion 64 of the plate wall portion 86 has a shape in which one surface side is cut off, and the protruding end portion 88 of the plate wall portion 86 is an inclined surface.
The center height H of the pipe fixing portion 63 differs between the pipe positioning means 61 and the pipe positioning means 62 as will be described later, but is generally about 1 to 3 times the diameter of the water supply pipe 30 and is low.

The position and orientation of one pipe positioning means 61 are as shown in FIGS. That is, the position of the pipe positioning means 61 in the longitudinal direction of the lid is a position close to the electromagnetic valve 36 side as shown in FIGS.
That is, the position of the pipe positioning means 61 in the short side direction of the lid is close to the side away from the water supply unit 50 as shown in FIGS.
It can be said that the position of the pipe positioning means 61 is one corner of the top surface 45. That is, it can be said that the pipe positioning means 61 is at a diagonal angle with respect to the water supply unit 50.
The direction of the pipe positioning means 61 is such that the central axis (virtual line) of the pipe fixing portion 63 is parallel to the longitudinal direction of the lid.

The position and orientation of another pipe positioning means 62 are as shown in FIGS. That is, the position of the pipe positioning means 62 in the longitudinal direction of the lid is between the pipe positioning means 61 and the water supply part 50 as shown in FIGS. More specifically, the position of the tube fixing portion 63 in the longitudinal direction of the lid portion is near the center of the lid portion 41.
The position of the pipe positioning means 62 in the longitudinal direction of the lid is between the pipe positioning means 61 and the water supply unit 50 as shown in the figure. More specifically, the position of the pipe positioning means 62 in the longitudinal direction of the lid is near the center of the lid 41.
The orientation of the pipe positioning means 62 is such that the central axis of the pipe fixing portion 63 is inclined with respect to the longitudinal direction of the lid portion.

Next, the height relationship between the pipe positioning means 61 and 62 and the water supply unit 50 will be described. The above three are higher in the order of the pipe positioning means 61, the pipe positioning means 62, and the water supply unit 50 as shown in FIG. That is, the piping positioning means 61 is the highest, the piping positioning means 62 is the next highest, and the water supply unit 50 is the lowest.
More precisely, the center of the pipe fixing part 63 of the pipe positioning means 61, the center of the pipe fixing part 63 of the pipe positioning means 62, and the opening center of the water supply part 50 are higher in this order. In other words, assuming that the water supply pipe 30 is connected to these members, the position of the pipe positioning means 61 is the highest, the position of the pipe positioning means 62 is the next highest, and the position of the water supply section 50 is the lowest. .

  The drain introduction port 51 is located at one corner of the top surface portion 45. That is, the drain introduction port 51 is in a position that forms a triangle due to the relationship between the water supply unit 50 and the pipe positioning means 61. The drain introduction port 51 is a pipe joint part that penetrates in the thickness direction of the top surface part 45 in order to introduce the drain that has passed through the drain introduction side pipe 13 into the storage part 15 of the main body part 40. The drain introduction side pipe 13 is connected so as to be fitted along the outer diameter side of the drain introduction port 51.

  As shown in FIG. 3, the four electrode insertion holes 52 to 55 are located at positions adjacent to the drain introduction port 51, and are holes that penetrate in the thickness direction of the top surface portion 45, so that electrodes 65 to 68 described later can be inserted. Is set to the size of

Here, the four electrodes 65 to 68 inserted through the electrode insertion holes 52 to 55 will be described. The electrodes 65 to 68 of the present embodiment are known water level detection means for detecting the water level in the reservoir 15. Specifically, the electrode 65 is a ground electrode, and the other electrodes 66 to 68 are an overflow electrode, a water supply control electrode, and an abnormal combustion detection electrode, respectively. In other words, this water level detection means can be used between the ground electrode 65 and the other electrodes if the ground electrode 65 and any of the other electrodes 66 to 68 are immersed in the drain. It becomes an energized state and it can be judged what the water level in the storage part 15 is.
The overflow electrode 66 detects an abnormal rise in the water level of the drain in the reservoir 15, and the water supply control electrode 67 can maintain a water level that can prevent the combustion gas from flowing in the drain discharge system 12. The abnormal combustion detection electrode 68 detects that the water level in the storage unit 15 is abnormally large and the water level cannot prevent the flow of the combustion gas in the drain discharge system 12. It is.
The above is the description of the electrodes 65 to 68 employed in this embodiment.

  The fitting groove 47 is provided on the lower surface side of the top surface portion 45, that is, on the side where the side wall 46 stands. In the present embodiment, the lid portion 41 is configured to fit a packing (not shown) in the fitting groove 47 and attach it to the main body portion 40 in this state.

  On the other hand, as shown in FIG. 3, the main body 40 is an approximately “L” -shaped container whose upper side is opened, and has an outer wall 70 that covers the bottom surface and side surfaces. And the storage part 15 and the bottomed space 16 are provided in the inside of the container of the main-body part 40. FIG. Further, a drain discharge port 80 for discharging drain from the storage unit 15 is provided at the end of the main body 40.

  The storage part 15 of the main body part 40 is a storage space having a labyrinth structure that temporarily stores and neutralizes the drain, as shown in FIGS. 6 and 7, and includes a main partition wall 71 and an auxiliary partition wall 72, It is divided into a plurality of rooms by 73 and 74. That is, the storage unit 15 is divided into a drain introduction chamber 75, a first neutralization chamber 76, and a second neutralization chamber 77 by the main partition wall 71 and the auxiliary partition walls 72, 73, 74. The second neutralization chamber 77 is further divided into three small chambers 77a, 77b and 77c.

  The drain introduction chamber 75 is a room located immediately below the drain introduction port 51 and the electrode insertion holes 52 to 55 in a state where the lid portion 41 is attached to the main body portion 40, and the drain introduced into the storage portion 15 is the first. It is a space to enter. Specifically, as shown in FIG. 6, the drain introduction chamber 75 is a room having a substantially rectangular shape in plan view surrounded by a main partition wall 71 having a plan view “L” shape and the inside of the outer wall 70. It is. A main partition wall 71 that partitions the drain introduction chamber 75 is in contact with the lid portion 41.

  The first neutralization chamber 76 is a chamber in which the drain that has passed through the drain introduction chamber 75 is introduced and neutralized, and is a space adjacent to the drain introduction chamber 75 with one side of the main partition wall 71 therebetween. The first neutralization chamber 76 is filled with a predetermined amount of neutralizing agent, and in this embodiment, calcium carbonate having a minimum particle size of 6 mm is employed as the neutralizing agent.

  As shown in FIG. 7, the first neutralization chamber 76 and the drain introduction chamber 75 are provided on the lower side in the height direction of the main partition wall 71 for flowing the drain downstream (hereinafter referred to as drain). 78a and 78b). That is, the drain introduced into the drain introduction chamber 75 flows into the first neutralization chamber 76 from the two drain upstream openings 78 a and 78 b provided on the lower side of the main partition wall 71.

The second neutralization chamber 77 is a chamber that further neutralizes the drain neutralized in the first neutralization chamber 76 and discharges it from the drain discharge port 80 on the downstream side. Is filled with a predetermined amount.
The second neutralization chamber 77 is adjacent to the first neutralization chamber 76 and the first auxiliary partition wall 72, and the drain introduction chamber 75 is a space adjacent to a part of the main partition wall 71.

  The second neutralization chamber 77 and the first neutralization chamber 76 communicate with each other on the upper side in the height direction of the first auxiliary partition wall 72. That is, since the first auxiliary partition wall 72 is provided with the notch portion 81, the first auxiliary partition wall 72 communicates with the notch portion 81. Therefore, the drain introduced into the first neutralization chamber 76 mainly flows into the second neutralization chamber 77 beyond the notch 81 provided on the upper side of the first auxiliary partition wall 72. In other words, the drain introduction chamber 75 and the first neutralization chamber 76 are always filled with drain up to the height of the notch 81, and the drain introduction chamber 75 and the first neutralization chamber 76 open to drain water. Since it communicates only with the upstream side openings 78a and 78b, a water-sealed structure is formed at that portion. That is, the main partition wall 71 that partitions the drain introduction chamber 75 is in contact with the lid portion 41, and airtightness is maintained between the drain introduction chamber 75 and the first neutralization chamber 76 on the upper side. The lower communication portions (drain upstream openings 78a and 78b) are always filled with drain. Therefore, the passage of gas is not allowed between the drain introduction chamber 75 and the first neutralization chamber 76.

  Further, the inside of the second neutralization chamber 77 is further divided into three small chambers 77a, 77b, 77c by auxiliary partition walls 73, 74, and has a flow path structure in which drains meander and flow downstream. The end of the second neutralization chamber 77 is connected to the drain discharge port 80.

  The bottomed space 16 is a room through which clean water supplied from a water supply source passes, and is a space arranged so as to protrude from the storage unit 15 as shown in FIGS. Specifically, the bottomed space 16 is located at a position adjacent to the first neutralization chamber 76 of the storage unit 15, and is disposed at a position facing the drain introduction chamber 75 across the first neutralization chamber 76. Yes. In the bottomed space 16, a partition wall 83 having an arc shape in plan view is provided in the vicinity of the boundary with the storage unit 15, and the boundary between the bottomed space 16 and the storage unit 15 is determined. That is, the bottomed space 16 is a substantially circular space surrounded by the partition walls 83.

  Further, the partition wall 83 is provided with a hot water discharge slit portion (hereinafter, referred to as a hot water slit) 85 cut out downward from the top portion, and the fresh water is stored through the hot water slit portion 85. It is the structure discharged to the part 15 side.

Next, the positional relationship in each part in the neutralizer 11 will be described.
The neutralization device 11 has a lid portion 41 mounted on the upper portion of the main body portion 40. That is, the open end of the main body 40 (the protruding end of the outer wall 70) is fitted into the fitting groove 47 of the cover 41, and the open side surface of the main body 40 is closed by the cover 41.

In this state, the drain introduction port 51 and the electrode insertion holes 52 to 55 provided in the lid part 41 are located immediately above the drain introduction chamber 75, and the water supply part 50 in the lid part 41 is located directly above the bottomed space 16. Located in. In particular, the water supply unit 50 is located substantially in the middle of the bottomed space bottom wall 17 on the inner side of the bottomed space 16, with respect to the side wall 18, the bottom wall 17, and the partition wall 83 that form the bottomed space 16. They are arranged at a predetermined distance (25 mm in this embodiment) or more.
The electrodes 65 to 68 are inserted into the electrode insertion holes 52 to 55.

Next, the external piping of the neutralizer 11 will be described. In the present embodiment, the drain introduction side pipe 13 and the water supply pipe 30 are connected to the neutralization device 11.
That is, the lowermost part of the horizontally long case 7 and the drain introduction port 51 of the neutralizing device 11 are connected by the drain introduction side pipe 13.

Further, a water supply pipe 30 connects between the electromagnetic valve 36 disposed on the side surface portion of the secondary heat exchanger 25 and the water supply unit 50 of the neutralizing device 11.
Here, the water supply pipe 30 is made by bending a copper pipe, and is divided into a falling portion 37 that falls from the electromagnetic valve 36 and an inclined portion 38. The falling portion 37 is a pipe that has fallen at a steep angle, and the inclined portion 38 is a pipe that is inclined at a gentler angle than the falling portion 37.
A part of the inclined portion 38 is fixed to the pipe positioning means 61 and 62 described above. That is, the pipe positioning means 61 and 62 are on the top surface part 45, and both have the pipe fixing part 63. The water supply pipe 30 is fixed to the pipe fixing portion 63.

That is, the tube fixing portion 63 is a ring having a missing portion 64 in part. Then, as shown in FIG. 12A, when the water supply pipe 30 is pressed against the missing part 64, the missing part 64 is opened by the elasticity of the resin, and the water supply pipe 30 is fitted into the pipe fixing part 63.
Further, since the missing part 64 is narrower than the outer diameter of the water supply pipe 30, the water supply pipe 30 does not easily fall off the pipe fixing part 63.

The pipe positioning means 61 and 62 are provided at the corner and the center of the top surface 45, and the pipe positioning means 62 provided at the center is directed in an oblique direction. It is fixed to the pipe positioning means 61 in the vicinity of one of the corners, is supported in an oblique direction by the pipe positioning means 62 at the center, and is guided to the water supply section 50 provided at the other corner.
Further, as described above, the pipe positioning means 61 and 62 are the highest in the pipe positioning means 61, next in the pipe positioning means 62, and lowest in the water supply section 50, so that the water supply pipe 30 has a proper flow gradient. .

Next, operation | movement of the combustion apparatus 1 of this embodiment is demonstrated.
The combustion apparatus 1 of the present embodiment is provided with a neutralizer water supply function for supplying water to the neutralizer 11 in order to maintain the water seal structure formed in the neutralizer 11. That is, the water level of the reservoir 15 is monitored by the arranged electrodes 65 to 68. And if it is not confirmed by those electrodes 65-68 (especially water supply control electrode 67) that the water level in the storage part 15 is more than a predetermined value, a neutralizer water supply function will work and it will be forced to the storage part 15 Water is supplied to

  Water supply to the storage unit 15 by the neutralizer water supply function opens the electromagnetic valve 36 based on the signals of the electrodes 65 to 68, and water is supplied from the water supply source via the water supply pipe 30 and the water supply unit 50. It is introduced into the bottomed space 16. Here, the water supply pipe 30 is divided into a falling part 37 and an inclined part 38, and the inclined part 38 has a flow gradient secured by the pipe positioning means 61 and 62 as described above. Therefore, during the period from the solenoid valve 36 to the water supply unit 50, the slope is always downward and there is no upward slope. Therefore, when the solenoid valve 36 is closed, water does not stagnate in the water supply pipe 30.

Next, a procedure for mounting the neutralizing device 11 in the housing 3 will be described.
A recommended procedure is to attach the water supply pipe 30 to the lid 41 of the neutralizing device 11 in advance outside the housing 3 and insert it into the housing 3 in this state.
That is, outside the housing 3, the tip of the water supply pipe 30 is connected to the water supply part 50 of the lid part 41, and the inclined part 38 of the water supply pipe 30 is fixed to the pipe positioning means 61 and 62. In this state, the neutralizing device 11 is put into the housing 3 and fixed at a predetermined position. After that, the other end of the water supply pipe 30 is connected to the electromagnetic valve 36.

In the present embodiment, the water supply pipe 30 is fixed to the neutralizing device 11 at three locations of the water supply unit 50, the pipe positioning means 62, and the pipe positioning means 61. Therefore, even if an external force is applied, the water supply pipe 30 is not easily detached. There is no deformation.
Particularly in the present embodiment, the pipe positioning means 61 is at a diagonal position with respect to the water supply unit 50. Therefore, the water supply pipe 30 is fixed to the neutralization device 11 in a long region, and is not easily detached even when an external force is applied, and is not easily deformed.

  Moreover, since the water supply pipe 30 is held at a position close to the top surface portion 45, there is little interference with other members.

In the embodiment described above, two pipe positioning means 61 and 62 are provided on the top surface portion 45 of the neutralizing device 11, but the number of pipe positioning means is arbitrary. Of course, only one pipe positioning means 61 may be provided.
However, since it is desirable that the water supply pipe 30 be along the upper surface of the neutralization device 11 in as long a region as possible, one of the pipe positioning means is opposite to the water supply section 50 or opposite to the water supply section 50. It is desirable to provide in the vicinity of the end on the side.
In addition, it is recommended that each pipe positioning means is designed to have an appropriate height change so that a gradient toward the water supply unit 50 is formed in the water supply pipe 30 regardless of the number.
It is recommended that the slope be 1/100 or higher, and a more desirable slope is 1/20 or higher.

In the embodiment described above, the pipe fixing part 63 of the pipe positioning means 61, 62 has an opening (the missing part 64) on the upper side and the water supply pipe 30 is mounted from above. It is not limited to this structure, For example, the thing of a structure as shown in FIG.
That is, the pipe positioning means 89 shown in FIGS. 13 and 14 has a column part 90, and a pipe fixing part 91 is provided on the side surface thereof. The tube fixing portion 91 is a short tube having a “C” cross section made of an elastic material, and has an opening 92 on the side surface side.
Therefore, the water supply pipe 30 is held beside the column part 90 as shown in FIG.

DESCRIPTION OF SYMBOLS 1 Combustion device 3 Case 11 Neutralization device 12 Drain discharge system 15 Storage part 30 Water supply pipe 31 Water supply system 35 Water retention pipe 36 Electromagnetic valve 40 Main part 41 Cover part 45 Top surface part 50 Water supply part 60 Auxiliary joint 61, 62 Pipe positioning means 63 Pipe fixing part 64 Missing part 69 Pipe arrangement part 89 Pipe positioning means 90 Column 91 Pipe fixing part 92 Opening

Claims (6)

A neutralization device that is provided in a combustion device that heats water or a heat medium, and neutralizes and discharges drain that is generated mainly when recovering the latent heat of combustion gas, and a reservoir in which drain is stored; In the neutralization apparatus having a drain introduction port for introducing drain into the storage unit, a drain discharge port for discharging drain from the storage unit, and a water supply unit for introducing water into the storage unit,
A neutralizing device having a top surface portion, the top surface portion having the water supply portion, and a pipe positioning means being integrally formed on the top surface portion.   The position and height of the pipe positioning means is such that when the water supply pipe is positioned by the pipe positioning means and the tip of the water supply pipe is connected to the water supply part, the water supply pipe is inclined toward the water supply part. The neutralizing device according to claim 1, wherein the neutralizing device has a position and a height.   The neutralization apparatus according to claim 1 or 2, wherein the pipe positioning means includes a pipe fixing portion for fixing the pipe.   The neutralization apparatus according to claim 3, wherein the tube fixing portion has a ring-shaped portion with a part cut.   The pipe fixing part has a pipe arrangement part that is equal to or larger than the outer diameter of the pipe to be supported, and a pipe introduction port for introducing the pipe into the pipe arrangement part. The neutralization apparatus according to claim 3 or 4, wherein the neutralization apparatus is narrower than an outer diameter.   A combustion section that burns fuel, a primary heat exchanger that mainly recovers sensible heat of the combustion gas generated in the combustion section, a secondary heat exchanger that mainly recovers latent heat of the combustion gas, and the secondary A neutralization device according to any one of claims 1 to 5, wherein the neutralization device has a drain discharge system for discharging drain generated in a heat exchanger to the outside, and forms part of the drain discharge system. The water supply system has a water supply valve and a water supply pipe, and the water supply pipe connects the water supply valve and the water supply unit of the neutralizer, and the water supply pipe A combustion apparatus characterized in that a midway portion is positioned by the pipe positioning means.

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