JP2011206632A - Neutralization apparatus and heat source machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a neutralization apparatus that secures sufficient volume without lowering strength even if a storage container is made smaller and discharges drain water fully neutralized.SOLUTION: A heat source machine 1 is equipped with a drain water discharging system 7 comprising a primary heat exchanger 20, a secondary heat exchanger 25 and a neutralization apparatus 11. The neutralization apparatus 11 includes a storage container 12 that stores drain water. Partition walls 16 are integrally bonded to the storage container 12. As a result, high robustness of the storage container 12 can be secured. At least one of the partition walls 16 is provided with communication holes 28, 66 that allow adjacent spaces to communicate with each other. The communication holes 28, 66 are configured such that the lower end of the opening is arranged in a position separated by a specific distance from the bottom face of the storage container 12 and that the drain water passes through the communicating holes 28, 66 to flow into the adjacent space. Consequently, even if precipitate is accumulated on the bottom face of the storage container 12, the drain water surely passes through the communicating holes 28, 66.

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 heat-source machine provided with the neutralization apparatus.

  2. Description of the Related Art As a heat source device that uses combustion gas generated when a burner is burned, a heat source device that includes a latent heat recovery type heat exchanger that recovers even the latent heat of the combustion gas is known. That is, this type of heat source machine is equipped with a secondary heat exchanger (latent heat recovery type heat exchanger) that recovers latent heat in addition to a primary heat exchanger that mainly recovers sensible heat of combustion gas, and has a thermal efficiency. Is expensive.

That is, since a gas whose main component is methane (CH ₄ ) or propane (C ₃ H ₈ ) is used as the fuel burned by the burner, the combustion gas contains water vapor. Therefore, when the latent heat of the water vapor is recovered by the secondary heat exchanger, the water vapor in the combustion gas is liquefied to generate drain. Further, since nitrogen and oxygen in the air react with each other by combustion to generate nitrogen oxides (NOx), the drain exposed to the combustion gas becomes acidic by the nitrogen oxides.

Since this acidic drain is nitric acid that exhibits a strong acid, there is a concern that if it is drained to the outside without being treated, it will have an adverse effect on the environment. Therefore, this type of heat source apparatus is configured to neutralize the drain generated in the secondary heat exchanger and then discharge it to the outside. That is, a drain drainage system is connected to the secondary heat exchanger, and a neutralizing device filled with a neutralizing agent is provided in the middle of the flow path.
The neutralizing agent used in the neutralizer is generally weakly alkaline such as calcium carbonate. Therefore, when neutralizing the drain of the strong acid with the neutralizer, it is necessary to take a sufficient amount of time.

Therefore, normally, the neutralization device is configured to sufficiently neutralize the drain introduced into the storage container over time.
For example, the invention described in Patent Document 1 has a configuration including a storage container formed by joining a plurality of container parts formed by blow molding. Specifically, the storage container is configured in such a manner that a plurality of joined container parts are arranged in series so as to form one flow path, and adjacent container parts are integrally joined by a thin tubular joint part. It is.
Moreover, in order to form the drain flow path in the storage container, the invention described in Patent Document 2 is configured to be partitioned into a plurality of spaces by separate partition plates.
That is, the inventions described in Patent Documents 1 and 2 are both devised to extend the substantial length from the introduction of drain into the storage container until it is discharged, and to sufficiently neutralize it. Has been.

JP 2009-34588 A JP 2001-96283 A

  By the way, in recent years, the installation location of the heat source apparatus has a tendency to save space, and accordingly, a heat source apparatus having a reduced size has been developed. That is, since the internal space of the heat source machine is substantially reduced by downsizing the heat source machine, it has been desired to make the neutralizer as small as possible.

However, when the size of the neutralization apparatus is reduced using the conventional technology, the volume of the storage container is extremely reduced, and the length of the substantial flow path of the drain is shortened. Degree) There is a concern that it cannot be neutralized.
This is related to the fact that the thickness of the storage container cannot be reduced when the neutralizer is downsized. That is, when the size is reduced, the volume of the storage container is reduced. Therefore, in order to compensate for the volume, it is necessary to reduce the member thickness of the storage container or the like. Strength is reduced. This is because the storage container is formed only by members that form the casing. Therefore, if the thickness of the member such as the storage container is reduced, there is a problem that when the drain is stored, the bottom surface of the storage container is bent and the storage container is destroyed.

  Therefore, for example, in the neutralization device of Patent Document 2, it is considered that the storage container and the partition plate are integrally formed to improve the robustness of the container. Thereby, the member thickness of a storage container etc. can be thinned within the range which improved the robustness of the container. However, since Patent Document 2 is configured to form the flow path by separating the partition plate from the bottom surface of the storage container, the bottom surface of the storage container has sufficient strength even if the partition plate and the storage container are integrated. It cannot be secured. Further, in Patent Document 2, since the bottom surface of the storage container and the partition plate are separated from each other, when the neutralizing agent that has reacted with the drain and turned into a fluid is accumulated over time on the bottom surface of the storage container, Drain flow is blocked. Thereby, the malfunction which drain | drain does not fully neutralize but overflows from a neutralization apparatus generate | occur | produces.

  Therefore, in view of the problems of the prior art, the present invention provides a neutralizing device that can secure a sufficient volume without reducing the strength even if the storage container is downsized, and can drain the drain after sufficiently neutralizing. For the purpose. At the same time, an object is to provide a heat source machine equipped with the neutralization device.

  In order to solve the above-mentioned problems, the invention described in claim 1 is provided in a heat source apparatus that heats hot water or a heat medium, and drain generated mainly by a heat exchanger that recovers latent heat of combustion gas is discharged from the heat source apparatus. The neutralization device forms a part of the drain drainage system, and the neutralization device has a storage container in which the drain is stored, and the storage container has a plurality of partitions formed integrally with the storage container. The partition wall is divided into a plurality of spaces, and at least one of the spaces is provided with a neutralizing agent for neutralizing drain, and at least one of the partition walls includes The side wall and the bottom surface of the storage container are provided with communication holes that allow communication between adjacent spaces, and one side end and bottom end of the partition wall are attached to the heat source unit. While being joined to the wall, the other side end of the partition wall is Joined to the other side wall of the distillation vessel or the side of another partition wall, the communication hole is located at a position where the lower end of the opening is separated from the bottom wall of the storage vessel by a certain distance, and is introduced into the storage vessel The drain is a neutralizing device that flows through the communication hole and flows into an adjacent space.

In the neutralizing device of the present invention, the partition wall is integrally formed with the storage container in which the drain is stored. Therefore, even if the thickness of the storage container is reduced, the storage container is equal to or higher than that of the prior art. Strength can be secured. Further, the communication hole provided in the partition wall is located at a position where the lower end portion of the opening is separated from the bottom surface of the storage container by a certain distance, so that the integration between the storage container and the partition wall is not weakened by the communication hole, The robustness of the storage container can be maintained.
That is, according to the present invention, since the volume reduction when the neutralization device is downsized can be compensated by reducing the thickness of the storage container, the flow path length is such that the drain can be sufficiently neutralized. Can be maintained. Thereby, the neutralization apparatus which can be adapted to the heat source machine reduced in size can be provided.
In addition, since the opening of the communication hole is separated from the bottom surface of the storage container by a certain distance, even if the neutralizing agent becomes a fluid by reaction with drain and accumulates at the bottom of the storage container, Does not interfere with drain flow. That is, according to the present invention, there is no fear that the drain accumulates due to the neutralizing agent accumulated at the bottom of the storage container.

  It is desirable that the communication hole has an opening shape of any one of a circle, an ellipse, a curve, and a straight line. (Claim 2)

  The invention according to claim 3 is the main partition wall joined to the pair of side wall and bottom wall of the storage container in a state in which the at least one partition wall is mounted on the heat source unit with the neutralizer. One of the spaces divided by the main partition wall is an introduction part in which drain is introduced and can be temporarily retained, and an introduction side in which the neutralizing agent is disposed downstream of the introduction part in the drain flow direction. In another space provided with a neutralization section and divided by the main partition wall, a drainage section where drainage is discharged and drainage where a neutralizing agent is disposed upstream of the drainage section in the drain flow direction A side neutralization part is provided, the drainage part is surrounded by the main partition wall and another partition member, and the other partition member is provided with an inflow part leading to the drainage port on the upper end side and introduced into the storage container The drain which has been drained reaches from the drain side neutralization part to the inflow part. A neutralizing device according.

In the neutralization device of the present invention, the space is divided by the main partition wall in which the storage container is joined to the pair of side wall and bottom wall. That is, the neutralizing device of the present invention is reinforced so that the bottom wall of the storage container does not bend due to the weight of the drain because both end portions of the partition wall are joined to the side wall of the storage container. Thereby, there is no fear that the bottom wall of the storage container is bent by the weight of the drain and the bottom wall is destroyed.
Moreover, there exists a neutralization part in which the neutralizing agent is arranged in both of the space divided into two. And since the drainage part is enclosed by the main partition wall and the partition member, and the inflow part which the drain which flowed into the drainage side neutralization part can reach the drainage port is provided in the partition member, neutralizer The drain introduced into the water is neutralized at the introduction side neutralization part, and is further reliably neutralized and drained at the drain side neutralization part. Further, since the inflow portion is provided on the upper end side of the partition member, the drain that has flowed into the drain side neutralization portion from the bottom surface side is not drained until it is pushed up to the upper end side of the partition member. The time until it is drained is extended. That is, even if the storage container is reduced in size, the substantial flow path until the drain is drained can be extended.

By the way, when trying to reduce the size of the heat source device as much as possible, each device may be limited not only in size but also in shape due to the arrangement of the devices inside the heat source device. However, since heat exchangers and solenoid valves can hardly be changed in size or shape in order to exert the same ability from the viewpoint of heat capacity, thermal efficiency, or standards, it is meaningless to consider changing these shapes. It is. On the other hand, compared with them, the neutralization device is easy to change the shape and size, but the drainage can be sufficiently neutralized by making the storage container into a shape and size that fit inside the limited heat source machine It was difficult to ensure the length of the flow path.
Accordingly, in the invention described in claim 4, the storage container has a multi-stage structure in which the position of the bottom surface is different in the vertical direction in a state where the neutralization device is mounted on the heat source device. The neutralization apparatus described in any one of the above was used.

According to this structure, the storage container is comprised by the multistage structure from which depth differs. That is, even when the device (solenoid valve or the like) is placed in close contact with the neutralization device when the device is placed in a miniaturized heat source device, the device or the like in close contact with the storage container can be placed without any problem. it can. Therefore, according to the neutralization apparatus of this invention, it can adapt to the restriction | limiting inside a heat source machine.
As a specific arrangement method, for example, if a device that can be in close contact with the neutralization device is arranged on the lower side of the bottom wall at a position higher in the vertical direction than the other bottom wall in the neutralization device, the member The arrangement between them is eliminated. And, if the bottom wall is arranged as deep as possible in the vertical direction from where the device does not exist, the volume of the storage container can be increased, and the flow path length is sufficient to allow the drain to be neutralized sufficiently. It can be secured.

  In the storage device, it is desirable that the bottom wall has a two-stage structure including a shallow bottom wall and a deep bottom wall, and both the introduction portion and the drainage portion are arranged on the shallow bottom wall side. (Claim 5)

  The invention according to claim 6 is the main partition wall joined to the pair of side wall and bottom wall of the storage container in a state where the neutralization device is mounted on the heat source machine, 6. The neutralization device according to claim 1, wherein the deep bottom chamber has a space divided by a deep bottom partition wall disposed so as to intersect the main partition wall.

  According to such a configuration, the space in the deep bottom chamber is divided and arranged so that the deep bottom partition wall intersects the main partition wall, so that the drain introduced into the storage container is drained. It flows three-dimensionally. That is, the length of the flow path where the drain is sufficiently neutralized can be ensured within a limited region.

  The invention according to claim 7 is the neutralization apparatus according to claim 6, wherein the deep bottom partition wall is provided with a slit at the upper end in addition to the communication hole.

  According to such a configuration, since the deep bottom partition wall is provided with a slit on the upper end side in addition to the communication hole, even if freezing or clogging occurs on the communication hole side of the deep bottom partition wall, The drain whose water level has risen can flow from the slit on the upper end side of the deep bottom partition wall to the adjacent space. That is, even if the drain cannot flow through the communication hole of the deep bottom partition wall, the drain that can overflow from the storage container can be reliably drained through the drain drainage system.

  The storage container and the partition wall are preferably formed by injection molding. (Claim 8)

  According to a ninth aspect of the present invention, in the storage container according to any one of the first to eighth aspects, wherein the storage container is provided with water level detecting means for detecting that the drain has reached a constant water level. Japanese equipment.

  According to such a configuration, even if the drain overflows from the storage container, the drain level overflows from the storage container because the water level abnormality of the drain stored by the water level detection means is detected. The situation that will do is not left.

  The invention according to claim 10 is a combustion device for burning fuel, a primary heat exchanger for recovering mainly sensible heat of combustion gas generated by the operation of the combustion device, and mainly for latent heat of the combustion gas. A secondary heat exchanger to be recovered, and a drain drainage system having the neutralization device according to any one of claims 1 to 9 for neutralizing drain generated in the secondary heat exchanger and discharging to the outside. It is the heat source machine characterized by having.

  The heat source apparatus of the present invention includes a neutralization device in which a partition wall is integrally formed in a storage container in which drain is stored, and the neutralization device is equivalent to that of the prior art even if the member thickness is reduced. Or the intensity | strength more than the conventional thing is securable. Thus, even if the neutralizing device is downsized, a sufficient volume can be secured without reducing the strength. Therefore, if the neutralizing device is installed in a downsized heat source device, the drain can be sufficiently neutralized and drained to the outside.

  In the neutralization device of the present invention, since the partition wall is integrally formed with the storage container, the partition wall can be thinned, and a sufficient volume can be secured without reducing the strength even if the size is reduced. Moreover, by providing the neutralization device in the heat source machine, the heat source machine itself can be reduced in size.

It is a block diagram which shows the heat source apparatus which concerns on embodiment of this invention, (a) is a front view inside a housing | casing, (b) is a side view inside a housing | casing. 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 a B direction arrow directional view of FIG. 3 which shows a cover part. It is an A direction arrow directional view of Drawing 2 showing a neutralization device. FIG. 3 is a perspective view showing an internal structure by partially breaking a main body portion of the neutralizing device of FIG. 2. It is a C direction arrow directional view of FIG. 2 which shows a main-body part. It is a D direction arrow directional view of Drawing 3 which shows the internal structure by partly breaking the main part of a neutralization device. It is the E direction arrow directional view of FIG. 3 which shows the inside of the main-body part of a neutralization apparatus. It is a perspective view which shows the modification of the main-body part of a neutralization apparatus. It is a perspective view which shows the modification of the main-body part of a neutralization apparatus. It is a front view which shows the modification of a communicating hole, (a) Ellipse shape, (b) It is the shape which combined the curve and the straight line.

  Next, the heat source device 1 and the neutralizing device 11 according to the embodiment of the present invention will be described. In the following description, the vertical / horizontal positional relationship will be described based on the normal installation state unless otherwise specified.

  The heat source unit 1 is a so-called latent heat recovery type heat source unit. As shown in FIG. 1, the casing 3 has a combustion unit 2, a primary heat exchanger 20 that mainly recovers sensible heat, and mainly recovers latent heat. A part of the drain heat system 25 for discharging the drain generated in the secondary heat exchanger 25 and the secondary heat exchanger 25 to the outside is incorporated.

  The heat source device 1 has a rectangular parallelepiped combustion case 5 disposed substantially at the center of the housing 3, and the combustion case 5 includes a combustion section 2, a primary heat exchanger 20, and a secondary heat exchanger 25. ing. Specifically, the combustion unit 2 is disposed on the lower side of the combustion case 5, and the primary heat exchanger 20 and the secondary heat exchanger 25 are disposed on the upper side of the combustion case 5 in order from the bottom. That is, the combustion case 5 is a portion through which high-temperature combustion gas generated in accordance with the combustion operation in the combustion section 2 flows. Further, the secondary heat exchanger 25 is located downstream of the primary heat exchanger 20 in the flow direction of the combustion gas. Thus, the combustion gas generated in the combustion unit 2 passes through the primary heat exchanger 20 and reaches the secondary heat exchanger 25 in the combustion case 5. An exhaust port 10 is attached to the upper front side of the combustion case 5, and the combustion gas that has passed through the secondary heat exchanger 25 is exhausted through the exhaust port 10.

  The combustion unit 2 includes a burner 9 and a blower 6. The burner 9 is accommodated inside and below the combustion case 5, and the blower 6 is attached to the outside of the combustion case 5 below the burner 9. That is, the combustion unit 2 is configured to operate the blower 6 to supply air to the burner 9, further supply fuel gas from a fuel supply source (not shown) to the burner 9, and burn the burner 9. The combustion gas generated at that time flows upward of the combustion case 5.

  The primary heat exchanger 20 is a known gas / liquid heat exchanger, and is disposed downstream of the combustion unit 2 in the flow direction of the combustion gas. The primary heat exchanger 20 includes a copper heat receiving pipe (not shown) through which hot water flows and fins (not shown). That is, the combustion gas flowing through the combustion case 5 can exchange heat with the fins in addition to the heat receiving pipe, so that hot water flowing through the heat receiving pipe is efficiently heat exchanged.

The secondary heat exchanger 25 is a known gas / liquid heat exchanger, and is arranged downstream of the primary heat exchanger 20 in the flow direction of the combustion gas, as described above. The secondary heat exchanger 25 is configured by a heat receiving pipe (not shown) through which hot water flows.
Here, as described above, since the secondary heat exchanger 25 mainly recovers latent heat of the combustion gas, in the secondary heat exchanger 25, the temperature of the combustion gas decreases to a certain value or less, and combustion occurs. Water vapor contained in the gas is liquefied and drainage is generated. And when the drain is exposed to combustion gas, the nitrogen oxide produced | generated by combustion melt | dissolves and it exhibits acidity. That is, in this embodiment, stainless steel having high corrosion resistance is used for the heat receiving pipe of the secondary heat exchanger 25.

Further, the secondary heat exchanger 25 and the primary heat exchanger 20 are connected by a connecting pipe 35, and the secondary heat exchanger 25 is arranged so as to be located upstream of the primary heat exchanger 20 in the hot water flow direction. Yes.
That is, the water inlet 21 of the primary heat exchanger 20 and the water outlet 26 of the secondary heat exchanger 25 are connected by the connection pipe 35. And the water outlet 22 of the primary heat exchanger 20 is connected to piping connected to a hot water supply destination such as a currant or a bathtub.

  In addition, a water inlet pipe 34 for supplying hot water to be heated from the outside is connected to the water inlet 27 of the secondary heat exchanger 25. Therefore, when there is a hot water supply request at the hot water supply destination and hot water is supplied from the external water supply source to the water inlet pipe 34, this hot water is supplied to the water inlet 27 of the secondary heat exchanger 25. The hot water supplied to the water inlet 27 flows through the secondary heat exchanger 25 and then flows through the primary heat exchanger 20 to be sequentially heat exchange heated. Thereafter, the water outlet of the primary heat exchanger 20 22 is supplied toward the hot water supply destination.

  In addition, a recovery unit (not shown) that recovers the drain generated by the latent heat recovery in the secondary heat exchanger 25 between the primary heat exchanger 20 and the secondary heat exchanger 25 inside the combustion case 5. ) And a drain drainage system 7 is connected to the recovery unit. That is, the drain drainage system 7 includes, in order from the upstream side in the drain flow direction, a drain drain port (not shown) provided in the recovery unit, an upstream drain pipe member 37, a neutralizer 11, and a downstream drain pipe. The member 38 is used.

  The drain drainage system 7 extends downward from a drain drain port (not shown), and the drain introduced into the upstream drain piping member 37 through the drain drain port (not shown) flows into the neutralizer 11 and is neutralized. Then, the water is discharged from the downstream drain piping member 38 to the outside. In the present embodiment, the neutralizing device 11 is disposed on the lower left side (FIG. 1A) inside the housing 3. In addition, the piping member before and behind connected to the neutralization apparatus 11 is a rubber tube.

  Next, the neutralizing device 11 having a characteristic configuration will be described in detail with reference to the drawings. For easy understanding, the x, y, and z directions shown in FIGS. 2 to 9 are defined.

  As shown in FIG. 2, the neutralization device 11 includes a storage container 12 that stores drainage flowing from the secondary heat exchanger 25 side. As shown in FIG. 1 (b), the storage container 12 has a main body 13 in which the appearance viewed from the left side surface direction of the heat source device 1 is rotated “L” by 180 degrees when attached to the heat source device 1. And the cover part 15 provided in the upper part of the main-body part 13 so that attachment or detachment was possible was provided.

  The lid portion 15 is formed of a top wall 40 and a side wall 41 that is integrally joined so as to surround the edge of the top wall 40 and protrudes in the z direction. The top wall 40 has a substantially rectangular shape in plan view (z direction). Specifically, the top wall 40 is partially cut off in the xy direction at one vertex (vertex in front of the left side in FIG. 2) to form a cutout portion 15a. The cutout portion 15a is a part along which piping close to the neutralization device 11 is placed when the neutralization device 11 is installed in the heat source unit 1. Note that a cutout portion 13a is also formed at a similar position in the main body portion 13 described later.

  2 and 3, the top wall 40 protrudes in the z-direction and guides the drain from the upstream drain piping member 37 into the storage container 12, and the z-direction. The electrode arrangement portions 52 and 53 are provided in which electrode members (water level detecting means) (not shown) that can project that the water level has risen excessively in the storage container 12 are provided.

  The lid-side introduction part 45 is a tubular member that penetrates in the z direction, and has an inner diameter of about 1.0 cm. Further, on the outside of the lid-side introduction portion 45, a step portion 45a having an enlarged outer diameter in the z direction is provided. The lid-side introduction portion 45 is provided with a tapered portion 45b whose outer diameter gradually becomes narrower from the step portion 45a to the tip. In other words, the lid-side introduction portion 45 is easy to attach the upstream drain piping member 37 by the tapered portion 45b, and the upstream drain piping member 37 is not easily detached by the step portion 45a.

  The electrode placement portions 52 and 53 are cylindrical bodies having an outer diameter of about 9 mm, and through holes 52a and 53a having an inner diameter of about 2 mm penetrating in the z direction are provided at the center. That is, an electrode member (not shown) is inserted into the through holes 52a and 53a, and the abnormal water level of the drain introduced into the storage container 12 is detected.

  As shown in FIG. 4, a mounting space 42 surrounded by the side wall 41 is formed on the protruding side of the side wall 41. The mounting space 42 is a place where a part of the main body 13 described later is disposed. The top panel 40 on the side of the mounting space 42 is provided with a groove 44 extending in the x direction in which a partition wall 16 of the main body 13 described later is fitted, in the middle of the y direction. The side wall 41 is provided with an engaging claw 43 protruding inward. In other words, the engaging claw 43 protrudes toward the mounting space 42 side. The engaging claws 43 are engaged with the main body 13 and a total of 14 engaging claws 43 are provided in this embodiment.

  On the other hand, the main body 13 is a container having an open top as shown in FIG. 3, and connects the two bottom walls 48, 49 and the two bottom walls 48, 49 as shown in FIG. The side walls 50 are integrally joined so as to surround the edges of the bottom walls 48 and 49. Specifically, the bottom surface of the main body 13 has a two-stage structure in the vertical direction (z direction). That is, as shown in FIG. 1, in a state where the neutralization device 11 is mounted on the heat source device 1, the shallow bottom wall 48 is disposed on the front side, and the deep bottom wall 49 is disposed on the back side.

As shown in FIG. 3, in the main body 13, the partition wall 16 is integrally joined to the main body 13 so as to divide the inside of the container into a plurality of spaces. In the present embodiment, in order to integrally mold the main body portion 13 and the partition wall 16, production by injection molding is employed. The partition wall 16 is designed to have a height extending from the bottom walls 48 and 49 to the open side of the main body 13 where the lid 15 is disposed. That is, when the lid portion 15 is attached to the main body portion 13, the drain does not flow from the upper end of the partition wall 16.
In the present embodiment, as the partition wall 16, a main partition wall 46 parallel to a plane extending in the xz direction and a deep bottom partition wall 47 parallel to the plane extending in the yz direction are provided.

  The main partition wall 46 divides the inside of the container in two in the y direction, and has a bottom end portion joined to the shallow bottom wall 48 and a side end portion joined to the inner side surface of the side wall 50. That is, with the neutralization device 11 attached to the heat source device 1, a shallow chamber 17 is formed on the front side (FIG. 3) of the main body 13 and a deep chamber 18 is formed on the back side (FIG. 3). The main partition wall 46 is provided with a communication hole 28 for communicating the shallow chamber 17 and the deep chamber 18 (FIG. 6). The communication hole 28 is a circular opening, and is provided so that the lower end of the opening is located at a position away from the shallow bottom wall 48 by a certain distance in the z direction (upward). Specifically, the lower end of the opening of the communication hole 28 is separated from the shallow bottom wall 48 by about 1.0 cm. Further, the communication hole 28 is located on the front side (FIG. 6) from the center in the x direction of the main partition wall 46. In other words, the communication hole 28 is arranged on the side surface where the cutout portion 13a is located.

  7 and 8, since the main partition wall 46 is arranged on the shallow bottom wall 48 side from the boundary between the shallow bottom wall 48 and the deep bottom wall 49, the shallow chamber 17 includes the main partition wall. 46, a shallow bottom wall 48 and a side wall 50, and the deep chamber 18 is formed by a main partition wall 46, a shallow bottom wall 48, a deep bottom wall 49 and a side wall 50.

As shown in FIG. 3, the shallow chamber 17 includes a main body side introduction portion (introduction portion) 51, sensor placement portions 55 and 56, and an introduction side neutralization portion 23.
The main body side introduction part 51 is a space at the same position as the lid side introduction part 45 of the lid part 15 and into which the drain that has passed through the lid side introduction part 45 is introduced. As shown in FIG. 6, the main body side introduction portion 51 is formed by an arc member 70 and is integrally joined to the side wall 50 of the main body portion 13. Moreover, the main body side introduction part 51 has a slit 71 (FIG. 7) in which a part of an arc is cut. The slit 71 is a rectangular opening extending in the z direction, and the drain introduced into the main body side introduction portion 51 flows from the slit 71 to the introduction side neutralization portion 23.

  As shown in FIG. 7, a through hole 51 a that communicates with the outside is provided on the bottom surface of the main body side introduction portion 51. This through hole 51a is a hole for maintenance, and is connected to a piping member (not shown) provided with a normally closed valve. Therefore, the drain introduced into the main body side introduction portion 51 is not discharged to the outside from the through hole 51a except for the maintenance of the neutralizing device 11 and the drainage for preventing freezing.

  As shown in FIG. 3, the sensor placement portions 55 and 56 are at the same positions as the electrode placement portions 52 and 53 of the lid portion 15, and are not shown electrodes inserted through the through holes 52 a and 53 a of the electrode placement portions 52 and 53. It is a space where the sensor side of the member is located. As shown in FIGS. 6 and 7, the sensor placement portions 55 and 56 are configured by a deformable portion 72 and an arc member 73 in which the side wall 50 is deformed in a columnar shape inside, and are deformed to the bottom surface side of the main body portion 13. The arc member 73 is located and formed so that the part 72 is located and is integrally joined to the upper part thereof. That is, the sensor arrangement portions 55 and 56 are from the upper end of the deformable portion 72 to the upper end of the arc member 73.

  Further, the side end portion of the arc member 73 is separated from the side wall 50 of the main body portion 13. That is, there is a gap between the arc member 73 and the side wall 50, and it is a slit through which drain can enter. In addition, the sensor arrangement | positioning parts 55 and 56 are provided in a row by the y direction, and both space is connecting.

  The introduction side neutralization part 23 is a space in the shallow chamber 17 other than the main body side introduction part 51 and the sensor placement parts 55 and 56, and is filled with a neutralizing agent C exhibiting weak alkalinity such as calcium carbonate. The drain is neutralized. In the present embodiment, the main body side introduction part 51 and the sensor arrangement parts 55 and 56 are not filled with the neutralizing agent C.

  As shown in FIG. 3, the deep chamber 18 is further divided into two spaces. That is, the deep bottom partition wall 47 is arranged so as to divide the space of the deep bottom chamber 18 substantially equally in the x direction (FIG. 7). As shown in FIG. 7, the deep bottom partition wall 47 is joined so as to be orthogonal to the side surface of the main partition wall 46, and is located at substantially the center in the x direction of the main partition wall 46. Further, the deep bottom partition wall 47 is joined so as to be orthogonal to the side wall 50 in the deep bottom chamber 18 facing the main partition wall 46. That is, the deep bottom partition wall 47 has a side end joined to the main partition wall 46 and the side wall 50 and a bottom end joined to the shallow bottom wall 48 and the deep bottom wall 49.

  Further, as shown in FIG. 6, the deep bottom partition wall 47 is provided with a communication hole 66 that communicates the divided space and a notch 67. The communication hole 66 is an opening having substantially the same shape as the communication hole 28 of the main partition wall 46, and a lower end portion of the opening is provided at a position separated from the deep bottom portion 49 in the z direction (upward) (FIG. 8). Further, the communication hole 66 is substantially the center of the deep bottom wall 49 in the y direction, as shown in FIG. The notch 67 has a rectangular shape and is provided at the upper end of the deep partition wall 47. Further, the notch 67 is located slightly to the left of the center of the deep bottom partition wall 47 in the y direction. Normally, the drain does not pass through the notch 67, and the drain flows temporarily when the drain that has passed through the communication hole 28 of the main partition wall 46 overflows.

  The space divided by the deep bottom partition wall 47 includes a first deep bottom portion 57 that communicates with the shallow chamber 17 side through a communication hole 28 provided in the main partition wall 46, and a communication hole 66 of the deep bottom partition wall 47. And a second deep bottom portion 58 communicating with the first deep bottom portion 57 via the notch 67.

As shown in FIGS. 6 to 9, the first deep bottom portion 57 is on the shallow bottom wall 48, and a weir forming plate 74 is disposed near the boundary between the shallow bottom wall 48 and the deep bottom wall 49. Further, the positional relationship between the weir forming plate 74 and the notch 67 of the deep bottom partition wall 47 is such that the weir forming plate 74 is closer to the main partition wall 46 and they do not overlap in the y direction.
The weir forming plate 74 is joined to the side wall 50, the shallow bottom surface 48, and the side wall of the deep bottom partition wall 47 of the main body 13, and divides the space into the first drain side neutralization unit 76 and the communication space 83. is doing.
The first drain side neutralization part 76 is filled with the neutralizing agent C and has a function of further neutralizing the drain that has passed through the introduction side neutralization part 23.

The communication space 83 is a space in which drainage can be accumulated up to the height of the weir forming plate 74. The drain stored in the communication space 83 prevents the combustion gas flowing in from the main body side introduction portion 51 from passing downstream from the communication space 83. That is, the communication space 83 has a water sealing function for blocking the circulation of the combustion gas with the drain.
Therefore, the length in the z direction of the weir forming plate 74 is such that it covers the horizontal projection region of the communication hole 28 provided in the main partition wall 46. In the present embodiment, the length in the z direction of the weir forming plate 74 is set to one third or less of the length in the z direction of the main partition wall 46.
Further, the communication space 83 can secure a space on the discharge side of the communication hole 28 in the main partition wall 46. That is, the communication space 83 also has a closing prevention function for preventing the discharge side of the communication hole 28 from being closed by the neutralizing agent C.

  In addition, the side wall 50 connecting the shallow bottom wall 48 and the deep bottom wall 49 in the deep bottom chamber 18 has a steep inclined portion 75. Therefore, since the drain toward the deep bottom wall 49 flows along the slope, the drain neutralization time can be slightly extended.

  As shown in FIGS. 3, 7, and 9, the second deep bottom portion 58 is provided with a drainage partition plate (partition member) 54 at the same position as the y direction of the dam formation plate 74 of the first deep bottom portion 57. The drainage partition plate 54 has a side end joined to the side wall 50 of the main body 13 and the side of the deep bottom partition wall 47, and a bottom end joined to the shallow bottom wall 48. 77 and the drainage part 59 are divided into spaces. Further, the drainage partition plate 54 is provided with an inflow portion 60 through which drain passes at the upper end. As shown in FIG. 9, the inflow portion 60 is two slit-shaped openings.

The second drainage neutralization part 77 has a function of further neutralizing the drain filled with the neutralizing agent C and having passed through the first drainage side neutralization part 76.
The drainage part 59 is a space surrounded by the drainage partition wall 54, the side wall 50 of the main body part 13 and the main partition wall 46, and can flow only from the inflow part 60 provided in the drainage partition wall 54. Further, the drainage part 59 is provided with a drainage port 59a on the bottom surface, and is drained from the downstream drain piping member 38 through the drainage port 59a.
As shown in FIG. 5, the drain port 59 a communicates with a drain pipe portion 61 that protrudes outside the main body portion 13. The drain pipe part 61 has substantially the same shape as the lid-side introduction part 45 described above, and has a step part 61a and a taper part 61b. That is, the drain pipe part 61 is easy to attach the downstream drain piping member 38 by the taper part 61b, and the downstream drain piping member 38 is hard to come off by the step part 61a.

Next, the operation of the heat source device 1 will be described.
In the heat source unit 1, for example, when a curan (not shown) is opened and there is a request for hot water supply, hot water flows into the inlet pipe 34, and a flow rate sensor (not shown) provided in the middle of the inlet pipe 34 detects the flow rate. The combustion unit 2 starts the combustion operation. And the combustion gas generated with the combustion operation flows toward the combustion case 5 upward. Then, the combustion gas flows into a region where the primary heat exchanger 20 is disposed, and is further introduced into a region where the downstream secondary heat exchanger 25 is disposed. And the combustion gas heat-exchanged by the secondary heat exchanger 25 is exhausted outside from the exhaust port 10.

  On the other hand, hot water supplied from the outside via the water inlet pipe 34 is introduced into the secondary heat exchanger 25 via the water inlet 27 of the secondary heat exchanger 25. The hot water introduced into the secondary heat exchanger 25 mainly recovers latent heat in the combustion gas and is heated by this. As a result, water vapor contained in the combustion gas is condensed, and drainage is generated on the surface of the secondary heat exchanger 25 and the like.

  The hot water heated by the secondary heat exchanger 25 is discharged from the outlet 26 of the secondary heat exchanger 25 and is introduced into the primary heat exchanger 20 from the inlet 21 of the primary heat exchanger 20. The hot water introduced into the primary heat exchanger 20 is heated by heat exchange with the combustion gas generated in the combustion unit 2. In the primary heat exchanger 20, mainly sensible heat in the combustion gas is recovered and heated by this. In this way, the hot water heated in the primary heat exchanger 20 flows out from the water outlet 22 of the primary heat exchanger 20 and is supplied toward a hot water supply destination such as a currant or a bathtub.

  As described above, in the heat source device 1, drainage is generated along with heat exchange in the secondary heat exchanger 25. The drain generated here gathers in a drain recovery unit (not shown) between the secondary heat exchanger 25 and the primary heat exchanger 20 and is drained to the outside through the drain drainage system 7.

  If it demonstrates concretely, the drain collect | recovered by the said drain collection part will pass through the drain drain port which is not shown in figure, and will be introduce | transduced into the neutralization apparatus 11 from the upstream drain piping member 37. FIG. That is, the drain that has passed through the upstream-side drain piping member 37 flows from the lid-side introduction portion 45 of the lid portion 15 into the body-side introduction portion 51 of the main body portion 13. The main body side introduction part 51 is provided with a slit 71, and the drain flows out from the slit 71 to the introduction side neutralization part 23. This drain is neutralized by reacting with the neutralizing agent C filled in the introduction-side neutralizing section 23.

  When the water level of the drain of the introduction side neutralization portion 23 exceeds the lower end of the opening of the communication hole 28 in the main partition wall 46 (about 1.0 cm in the z direction from the shallow bottom wall 48), the introduction side neutralization The drain of the portion 23 flows from the shallow chamber 17 side to the deep chamber 18 side through the communication hole 28. In addition, the flow direction of the drain when passing through the communication hole 28 is from the back side to the front side of the heat source unit 1 in a state where the neutralizer 11 is mounted on the heat source unit 1.

  On the other hand, when drain freeze or clogging of dust occurs before and after the drain flow direction in the communication hole 28, the drain is not discharged from the introduction side neutralization portion 23, and the water level of the introduction side neutralization portion 23 is excessively high. May rise. However, in this embodiment, since the electrode placement portions 52 and 53 and the sensor placement portions 55 and 56 in which electrode members (not shown) are placed are provided in the shallow chamber 17, the drain water level in the introduction side neutralization portion 23. Even if it rises excessively, it can be detected before it overflows from the storage container 12. And based on the detection signal of the electrode member, the combustion operation of the combustion part 2 can be stopped. That is, in this embodiment, when the abnormal water level of the drain in the storage container 12 is confirmed, the operation of the combustion unit 2 is forcibly stopped, so that the drain does not overflow from the storage container 12. .

  When drain is introduced into the deep bottom chamber 18 from the introduction side neutralizing portion 23, the drain is stored in the communication space 83 of the first deep bottom portion 57. The communication space 83 is divided by the dam forming plate 74, and the water level of the drain stored in the communication space 83 exceeds the upper end of the dam forming plate 74 (one third of the height of the main partition wall 46). The drain flows over the upper end of the weir forming plate 74 and flows into the first drain side neutralization portion 76 adjacent to the communication space 83.

  The drain that has flowed into the first drain side neutralization part 76 flows along the inclined part 75 connected to the deep bottom wall 49 of the main body part 13 and the neutralizer C filled in the first drain side neutralization part 76. Reacts with and neutralizes. If the water level of the drain that has flowed to the deep bottom wall 49 exceeds the lower open end of the communication hole 66 provided in the deep bottom partition wall 47, the drain passes through the communication hole 66 to the second depth. It flows to the bottom 58 side. In addition, the flow direction of the drain when passing through the communication hole 66 is from the side surface side to the inside side of the heat source device 1 in a state where the neutralization device 11 is mounted on the heat source device 1.

  Also, when drain freeze or clogging of dust occurs before and after the drain flow direction in the communication hole 66, the drain water level in the first drain side neutralization section 76 rises excessively, or the first drain side The drain in the neutralization part 76 may flow backward from the communication hole 28 of the main partition wall 46 to the introduction side neutralization part 23, and the water level in the introduction side neutralization part 23 may rise excessively. However, in the present embodiment, the notch 67 is provided at the upper end of the deep partition wall 47, so that even if the drain water level rises excessively in the first drain side neutralization part 76, the notch 67 to the second deep bottom 58 side. Thereby, it can prevent that the water level of the drain in the storage container 12 rises excessively and stops the operation | movement of the combustion part 2 by temporary causes, such as freezing of a drain. As a result, inconveniences such as not supplying hot water do not reach the user.

  When drain is introduced from the first drainage side neutralization portion 76 to the second deep bottom portion 58, the drain is stored in the second drainage side neutralization portion 77. Then, the drain that has passed through the communication hole 66 reacts with the neutralizing agent C filled in the second drainage side neutralizing portion 77 to be neutralized. The second drainage side neutralization part 77 is partitioned by the drainage partition plate 54, and the water level of the drain introduced into the second drainage side neutralization part 77 is a slit-shaped water inlet part provided in the drainage partitioning plate 54. When the pressure exceeds the lower end of 60, the drain flows from the water inlet 60 into the drain 59. And the drain which flowed into the drainage part 59 passes the drainage port 59a of a bottom part, is introduce | transduced into the downstream drain piping member 38, and is drained outside.

The above description is the flow of the drain during the initial stage when the neutralization device 11 is installed and the storage container 12 is filled with the drain.
On the other hand, when a certain period of time elapses from the initial state, the storage container 12 is filled with drain. That is, the drain is always stored up to a certain water level. In this embodiment, even in this state, when the drain is introduced into the storage container 12, the above-described drain flow is generated and drained in order from the drain that has reached the inflow portion 60.

In the present embodiment, the drain introduced into the storage container 12 is in a normal state where there is no malfunction such as drain freezing, etc., and the introduction side neutralization part 23, the first drainage side neutralization part 76, and the second drainage side neutralization. It is neutralized by the neutralizing agent C filled in the portion 77 and drained.
In the present embodiment, the drain introduced into the storage container 12 is moved in the vertical direction in addition to the horizontal movement.
That is, the drain introduced into the storage container 12 flows in the horizontal direction toward the communication hole 28 of the main partition wall 46 in the introduction side neutralization portion 23, and the deep bottom wall 49 in the first drainage side neutralization portion 76. In the second drainage side neutralization portion 77, the water level is raised toward the inflow portion 60 on the upper end side of the deep partition wall 54, and the drainage portion from the amount that has reached the inflow portion 60. Since the water is drained from 59, the drain introduced into the storage container 12 is neutralized with sufficient time. As a result, even when the neutralization device 11 is downsized, it is possible to secure a flow path length that neutralizes the drain within a limited volume. In other words, according to this embodiment, the drainage drained from the miniaturized neutralization device 11 is sufficiently neutralized and drained.
In particular, in the second drainage side neutralization portion 77, the drain introduced from the deep bottom wall 49 side is configured to raise the water level and reach the drainage portion 59, so that the drain is flowed downward. Residence time can be extended.

  Moreover, in this embodiment, since the partition wall 16 which divides | segments the space in the storage container 12 is integrally joined with the side wall 50 and the bottom wall 48, 49 of the main-body part 13, the robustness of the storage container 12 is provided. Can be increased. In other words, even if the thickness of the storage container 12 is reduced and the strength is reduced as a result, the strength of the storage device 12 is lower than the strength of the conventional neutralization device as long as the robustness is increased. There is no. Thereby, even if it is a case where the neutralization apparatus 11 is reduced in size, the fall of the volume in the storage container 12 can be suppressed, and the flow path length which neutralizes a drain does not become short.

In the said embodiment, although the main-body part 13 showed the structure which made the 2 step | paragraph structure of the shallow bottom wall 48 and the deep bottom wall 49, this invention is not limited to this, A 1 or 3 steps | paragraph or more structure is provided for a bottom wall. It may be a storage container.
For example, as shown in FIG. 10, a main body 91 in which the bottom wall has a one-stage structure and the second drainage side neutralization portion 77 is further divided into a plurality of spaces may be employed.
Moreover, as shown in FIG. 11, you may employ | adopt the main-body part 101 which made the bottom wall a 3 steps | paragraph structure.

  In the above embodiment, the communication holes 28 and 66 provided in the partition wall 16 have a circular opening shape, but the present invention is not limited to this, and as shown in FIG. The shape may be a curve. Even in this case, it is necessary to arrange the lower end of the opening at a certain distance from the bottom surface of the container.

DESCRIPTION OF SYMBOLS 1 Heat source machine 7 Drain drainage system 11 Neutralization apparatus 12 Storage container 16 Partition wall 17 Shallow bottom chamber 18 Deep bottom chamber 20 Primary heat exchanger 23 Introduction side neutralization part 25 Secondary heat exchangers 28 and 66 Communication hole 45 Cover side Introduction part (introduction part)
46 Main partition (included in 16)
47 Deep partition wall (included in 16)
48 Shallow bottom wall 49 Deep bottom wall 50 Side wall 51 Body side introduction part (introduction part)
54 Drainage partition wall (partition member)
59 Drainage part 60 Inflow part 67 Notch part 76 First drainage side neutralization part 77 Second drainage side neutralization part C Neutralizer

Claims (10)

It is a neutralization device that is provided in a heat source device that heats hot water or a heat medium, and that forms part of a drain drainage system in which drain generated mainly in a heat exchanger that recovers the latent heat of combustion gas is discharged from the heat source device. And
The neutralizer has a storage container in which drain is stored,
The storage container has a plurality of partition walls formed integrally with the storage container, and is divided into a plurality of spaces by the partition walls, and at least any one of the spaces has a neutralizing agent that neutralizes the drain. It is arranged,
At least one of the partition walls is provided with a communication hole that allows adjacent spaces to communicate with each other, and one side end and a bottom end of the partition wall are stored in a state in which the neutralization device is mounted on the heat source unit. While being joined to one side wall and the bottom wall of the container, the other one side end of the partition wall is joined to the other one side wall of the storage container or the side surface of the other partition wall,
The communication hole is located at a position where the lower end of the opening is separated from the bottom wall of the storage container by a certain distance,
The drain introduced into the storage container passes through the communication hole and flows into an adjacent space.   The neutralization device according to claim 1, wherein the communication hole has an opening shape of any one of a circle, an ellipse, a curve, and a straight line. The at least one partition wall is a main partition wall joined to the pair of side wall and bottom wall of the storage container in a state where the neutralization device is mounted on the heat source machine,
One of the spaces divided by the main partition wall is an introduction part in which drain is introduced and can be temporarily retained, and an introduction side in which the neutralizing agent is disposed downstream of the introduction part in the drain flow direction. A neutralization section is provided,
The other space divided by the main partition wall is provided with a drainage section for draining drainage and a drainage side neutralization section for positioning the neutralizing agent located upstream of the drainage section in the drain flow direction. ,
The drainage part is surrounded by the main partition wall and other partition members, and the other partition member is provided with an inflow part leading to the drainage part on the upper end side,
The neutralizer according to claim 1 or 2, wherein the drain introduced into the storage container reaches from the drain side neutralization part to the inflow part.   The neutralization device according to any one of claims 1 to 3, wherein the storage container has a multi-stage structure in which the position of the bottom surface is different in the vertical direction in a state where the neutralization device is mounted on the heat source device. The storage device has a two-stage structure in which the bottom wall is a shallow bottom wall and a deep bottom wall,
The neutralization device according to claim 4, wherein both the introduction part and the drainage part are arranged on the shallow bottom wall side. The at least one partition wall is a main partition wall joined to the pair of side wall and bottom wall of the storage container in a state where the neutralization device is mounted on the heat source machine,
The neutralization apparatus according to any one of claims 1 to 5, wherein the deep bottom chamber is divided into spaces by a deep bottom partition wall arranged to intersect the main partition wall.   The neutralization apparatus according to claim 6, wherein the deep bottom partition wall is provided with a slit at an upper end in addition to the communication hole.   The neutralization device according to any one of claims 1 to 7, wherein the storage container and the partition wall are formed by injection molding.   The neutralization apparatus according to any one of claims 1 to 8, wherein the storage container is provided with water level detection means for detecting that the drain has reached a certain water level.   A combustion apparatus that burns fuel, a primary heat exchanger that mainly recovers sensible heat of combustion gas generated by the operation of the combustion apparatus, and a secondary heat exchanger that mainly recovers latent heat of the combustion gas; A heat source apparatus comprising a drain drainage system having the neutralization device according to any one of claims 1 to 9 for neutralizing drain generated in the secondary heat exchanger, and discharging the system to the outside.

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