JP4687272B2 - Water heater - Google Patents

Description

The present invention relates to a configured hot water equipment to generate hot water by recovering heat from combustion gas generated by the combustor.

  Some hot water supply apparatuses include a so-called latent heat recovery type heat exchanger. In this type of water heater, in addition to the sensible heat of the combustion gas generated by the combustor being recovered by the heat exchanger, the latent heat of the combustion gas (more precisely, the latent heat of water vapor in the combustion gas) is also generated. To be recovered. Therefore, the heat exchange efficiency can be increased as compared with a case where latent heat recovery is not performed. When the above-described latent heat recovery is performed, water vapor in the combustion gas is condensed and a large amount of condensed water is generated. Generally, this condensed water absorbs sulfur oxides, nitrogen oxides, etc. in the combustion gas. It becomes strong acidity of about PH3. If the condensed water is drained into a general pipe with strong acidity, the pipe will be corroded and the environment will deteriorate due to water pollution.

  Therefore, conventionally, a means for neutralizing condensed water generated with latent heat recovery is used by using a neutralizer in which a neutralizing agent such as calcium carbonate is contained in a container (for example, (See Patent Document 1). According to such means, it is possible to prevent the condensed water from being discarded while remaining strongly acidic.

  However, conventionally, the following problems have occurred.

  That is, the condensed water neutralized using the neutralizer needs to be led from the neutralizer to an appropriate drainage path outside the hot water supply apparatus. As a means for this, for example, in a housing complex, a means is adopted in which a pump is connected to the condensate discharge port of the neutralizer, and the condensed water after the neutralization treatment is led to a drain trap in the bathroom by the pump. However, when such a means is adopted, there is a case where the condensed water stays in the middle of the drainage path of the condensed water downstream from the neutralizer, so that a so-called “clogged” state may occur. In particular, when the bathroom drain trap is located higher than the neutralizer, such as when a hot water supply device is installed on the first floor of the house and a bathroom is provided on the second floor of the house, The drainage path is likely to be clogged. Conventionally, when such a clogged drainage path occurs, the air present in the neutralizer container does not escape to the outside, and the condensed water enters the container from the condensed water inlet of the neutralizer. It becomes difficult to flow in smoothly.

In contrast to the specific example described above, when the neutralizer is located higher than the bathroom drain trap, when the condensed water of the neutralizer is fed into the bathroom drain trap using a pump, There is a risk of causing a siphon phenomenon. When this siphon phenomenon occurs, the condensed water in the neutralizer flows into the drainage path even after the pump is stopped. On the other hand, the neutralizer is connected to a heat exchanger so as to receive condensed water from the heat exchanger of the hot water supply apparatus, and combustion gas may enter the neutralizer through this pipe. Therefore, when the siphon phenomenon occurs, the combustion gas may flow into the drainage path downstream of the neutralizer together with the condensed water, and may enter the bathroom through the bathroom drainage port.

The present applicant has previously proposed the one described in Patent Document 2 as an example of a neutralizer. The neutralizer described in this document has a configuration in which a vent hole is provided in a container containing a neutralizing agent. According to such a configuration, even if the drainage path downstream of the neutralizer is clogged, the air in the neutralizer container can be released to the outside from the vent hole. It is possible to flow in smoothly. Moreover, since the airtight state in the container of the neutralizer is eliminated, the occurrence of the siphon phenomenon as described above is prevented, and the problem that the combustion gas enters the bathroom is appropriately avoided.

However, the vent hole of the neutralizer described in Patent Document 2 is merely formed as a simple through hole formed in the upper wall of the container. For this reason, for example, when a situation occurs in which the condensate accumulates in the container due to clogging in the drainage path downstream of the neutralizer or in the neutralizer, the water level becomes the height of the top wall of the container. After reaching, the condensed water easily overflows from the vent hole to the outside of the container. In this case, various devices and devices arranged below the neutralizer are contaminated by condensed water that has not been neutralized. Therefore, it is desirable to appropriately prevent or suppress such a situation.

JP 2001-336826 A Japanese Patent Laid-Open No. 2003-320381

The present invention has been conceived under the circumstances described above, and is intended to smooth the flow of condensed water into the neutralizer and to prevent the occurrence of siphon phenomenon when the condensed water is discharged from the neutralizer to the outside. Hot water supply that prevents condensate from overflowing easily outside the neutralizer when the condensate drainage path is clogged, and appropriately suppresses contamination by condensate to provide the equipment is set to the task.

  In order to solve the above problems, the present invention takes the following technical means.

Hot water supply device provided by the present invention, a combustor, a heat exchanger for performing heat recovered from the generated combustion gas by the combustor, in for neutralizing condensed water generated due to the heat recovery A heat exchanger that includes a casing in which an intake port and an exhaust port for combustion gas are formed, a water pipe for heat exchange disposed in the casing, and the water pipe from the water pipe. a pipe section for feeding condensed water dropped onto the bottom of the casing to the neutralizer, and wherein the neutralizer comprises a container containing a neutralizing agent therein, this container, A hot water supply apparatus provided with an inlet for the condensed water, an outlet for discharging the condensed water neutralized by the neutralizing agent to the outside, and a ventilation means for communicating the inside of the container to the outside of the container The vent means has a series of air flow paths formed therein. And a base end portion is connected to the container of the neutralizer and includes a vent pipe body portion having an opening at a tip end portion, and at least a part of the vent pipe body portion stands upward. Thus, the air flow path is characterized in that it extends to a position higher than the lowest part of the edges of the air supply port and the exhaust port of the casing of the heat exchanger .

According to such a configuration, since the inside of the neutralizer vessel communicates with the outside of the vessel via the air flow path of the vent pipe body portion, when the condensed water flows into the vessel, The air is discharged to the outside through the air flow path, so that the condensed water flows smoothly into the container of the neutralizer. In addition, the siphon phenomenon is prevented from occurring when the condensed water in the container is drained to the outside. On the other hand, since at least a part of the vent tube body portion stands upward and the air flow path of the vent tube body portion extends upward from the base end portion, for example, a neutralizer Even if the water level of the condensed water in the container rises abnormally to the height of the base end of the vent pipe body part due to clogging in the container, the condensed water immediately flows into the vent pipe body part. There is no overflow from the tip opening to the outside of the container. Unless the water level of the condensed water rises above the highest part of the air flow path, the condensed water does not overflow from the tip opening to the outside of the container. Therefore, according to the present invention, when clogging occurs in the neutralizer container or the like, the condensate easily overflows to the outside of the neutralizer, and each part of the hot water supply device is appropriately suppressed. Is done.
Further, the following effects can be obtained.
For example, the following situation can be assumed when the hot water supply device is operated while the neutralizer is clogged in spite of clogging. That is, after the water level of the condensed water in the container rises and the container becomes full, the condensed water accumulates in the pipe connecting the heat exchanger and the neutralizer, and further, the heat exchanger Condensed water also accumulates in the casing. When the hot water supply device is installed outdoors, rainwater may enter the casing of the heat exchanger from the exhaust port of the heat exchanger. Originally, this rainwater, like condensed water, should be discharged to the outside through the neutralizer, and if it is clogged in the neutralizer vessel, it may accumulate in the heat exchanger casing. . In this way, when condensed water or rainwater accumulates in the casing of the heat exchanger, if the water level in the casing exceeds, for example, the lowest part of the inlet or outlet of the casing, The water flows out from the part to the outside of the casing, but unless otherwise, it is possible to keep the condensed water properly in the casing so that each part of the hot water supply device is not contaminated by condensed water or rain water. . On the other hand, according to the above configuration, while the outflow of condensed water or the like to the outside of the casing is being prevented, the condensed water or the like overflows from the front end opening of the vent pipe body to the outside of the neutralizer. There is nothing. Therefore, it is possible to more appropriately prevent the hot water supply apparatus from being contaminated.

  In a preferred embodiment of the present invention, the neutralizer includes an abnormal water level detection means for detecting when the water level in the container has abnormally increased above a predetermined height, and the air flow The path extends to a position higher than the predetermined height.

  According to such a configuration, when a situation occurs in which the water level in the container abnormally rises due to clogging in the container of the neutralizer, the water level in the container before the water level reaches the predetermined height. The condensed water does not overflow from the front end opening of the vent pipe body to the outside of the container. Therefore, there is no situation in which the region below the neutralizer is contaminated by the condensed water overflowing from the neutralizer before the abnormal water level is detected by the abnormal water level detection means. By taking appropriate measures immediately when an abnormal water level is detected, it is possible to appropriately avoid contamination of each part of the hot water supply device with condensed water. In addition, unlike the case of this configuration, if the water level of the condensed water overflows to the outside of the container before reaching the predetermined height, for example, even if the condensed water is flowing into the container, There is a possibility that the water level of the condensed water in the container does not rise properly, and that the abnormality is not properly detected. On the other hand, according to the said structure, such a fear is also eliminated appropriately.

  In a preferred embodiment of the present invention, a portion near the tip of the vent tube body is bent, and an opening at the tip of the vent tube body is downward from the horizontal direction.

  According to such a structure, it becomes difficult for dust etc. to enter into the opening part of the front-end | tip part of a vent pipe body part. When dust or the like enters the opening, clogging easily occurs in the container, but according to the configuration, such a situation is appropriately prevented by a simple configuration.

  Other features and advantages of the present invention will become more apparent from the following description of embodiments of the present invention with reference to the accompanying drawings.

  Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings.

1-3 has shown one Embodiment of the neutralizer with which the hot-water supply apparatus which concerns on this invention is equipped . As clearly shown in FIG. 1, the neutralizer A of the present embodiment includes a container 2 containing a neutralizing agent 1 and a vent pipe body portion 3. The neutralizing agent 1 is, for example, granular calcium carbonate.

  The container 2 is a blow molded product made of polypropylene or other synthetic resin. The container 2 includes an inlet 21 for condensed water, a header portion H having an abnormal water level detector 5, a neutralizing agent storage chamber 22, and an auxiliary chamber 23 in which a discharge port 24 is formed. The neutralizing agent storage chamber 22 includes an upper step portion 22a and a lower step portion 22b that is connected to the upper step portion 22a and positioned below the upper step portion 22a.

  The header part H is provided in the upper part of the one end area | region of the width direction (left-right direction of FIG. 1) of the upper step part 22a, and the cylindrical part 21a is standingly formed in the upper wall part 40. As shown in FIG. The opening of the cylindrical portion 21a is an inlet 21 for condensed water. The cylindrical portion 21a is used to fit and connect a pipe 76 that supplies condensed water. When the condensed water flows into the container 2 from the introduction port 21a, the condensed water flows through a certain path described later while passing through the gap between the neutralizing agents 1. The condensed water is neutralized in the process, and then discharged from the outlet 24 to the outside of the container 2. As will be described later, a pipe 75 having a pump P1 and a check valve 79 is connected to the discharge port 24.

  The abnormal water level detection unit 5 is a part for detecting when the liquid level of the condensed water in the container 2 rises abnormally, and has a pair of electrodes 50. These electrodes 50 are configured such that, for example, an acid-resistant stainless steel screw body is screwed into the upper wall portion 40 of the header portion H, and the lower end tips of these electrodes 50 are located below the upper wall portion 40. Protruding. Although not shown in the drawing, a pair of wiring cords to which a voltage is applied are connected to the upper part of the pair of electrodes 50. The pair of electrodes 50 is not immersed in the condensed water at normal time when the container 2 is not clogged, and is not electrically connected between them. On the other hand, when clogging occurs in the container 2 and the liquid level of the condensed water rises abnormally, the tip portions of the pair of electrodes 50 are both immersed in the condensed water and are electrically connected. As a result, a predetermined signal is output, and it is possible to determine the abnormality.

  In the header portion H, a portion where the electrode 50 below the upper wall portion 40 protrudes and a peripheral portion thereof are formed as a space portion 41 in which entry of the neutralizing agent 1 is restricted. As shown in FIG. 2B, the opposing side portions 25a ′ of the side wall portions 25a on the upper side of the container 2 are close to each other, and a slit portion 42 narrowed to a narrow width L1 is formed. ing. The slit portion 42 has a width L1 that is substantially the same as, for example, an opening width s1 of a slit 28A described later, and allows condensed water to pass between the space portion 41 and the neutralizing agent storage chamber 22, but accommodates the neutralizing agent. The passage of the neutralizing agent 1 from the chamber 22 to the space 41 is prevented. Since the neutralizing agent 1 is present in the space portion 41, the electrode 50 and the neutralizing agent 1 are brought into contact with each other, and there is an abnormality though the water level of the condensed water is not the original abnormal water level. Although there is a possibility that the water level is erroneously detected, according to the present embodiment, such a fear is avoided. In addition, the effect of protecting the electrode 50 by avoiding the collision of the neutralizing agent 1 with the electrode 50 can be expected. Note that, as clearly shown in FIG. 2, in the present embodiment, the lower step portion 22b and the auxiliary chamber 23 are offset in the thickness direction of the container 2 by an appropriate dimension L2 with respect to the upper step portion 22b. According to such a structure, it becomes possible to install this neutralizer A appropriately using the bent space in the hot water supply apparatus. The offset dimension L2 can be appropriately selected so as to correspond to the bent shape of the actual space. Of course, the offset dimension L2 may be zero.

  As shown in FIG. 1, a charging port 43 for the neutralizing agent 1 is provided on the upper portion 22 a of the neutralizing agent storage chamber 22. The insertion port 43 is normally closed by a lid 43a. The upper step portion 22a has a bottom wall portion 45a, an upper wall portion 45b, and a plurality of side wall portions connected to these, and can accommodate and hold the neutralizing agent 1 therein. However, in the terminal region 220 in the condensed water flow direction in the upper step portion 22a, the bottom wall portion 45a is not provided, and the bottom portion is open and connected to the lower step portion 22b.

  A partition portion 44a and a standing wall 44b are provided in the upper step portion 22a. The condensed water introduced into the upper stage portion 22a from the introduction port 21 first proceeds below the header portion H and then passes through the gap below the partition portion 44a, as indicated by arrows N1 to N4, and then stands upright. After passing over the upper part of 44b, it progresses to the termination | terminus area | region 220 of the upper stage part 22a, and it progresses below the lower stage part 22b after that. In addition, condensed water will be stored by the upstream side (left side of FIG. 1) of the standing wall 44b with the water level of the same height as the upper end of this standing wall 44b.

  The lower step portion 22b extends obliquely downward from the bottom of the termination region 220 of the upper step portion 22a, and the neutralizing agent 1 is also accommodated in this portion. The lower step portion 22b is not provided in the entire lower region of the upper step portion 22a, and is provided in a limited manner, for example, below the termination region 220 and in the vicinity thereof. As a result, the auxiliary chamber 23 is formed in a space-efficient manner below the upper stage portion 22a.

  The auxiliary chamber 23 is a part for temporarily storing an appropriate amount of condensed water that has passed through the lower stage 22b. The auxiliary chamber 23 is formed to be connected to the end wall 26 of the lower step portion 22b, and the first space portion 23a near the end wall 26 is formed by an upright wall portion 46 standing from the bottom portion 27a to the upper wall portion 230. It is partitioned off from the second space 23b on the opposite side. The end wall 26 and the standing wall portion 46 are provided with slits 28A and 28B for allowing condensed water to pass therethrough. Condensed water that has traveled to the lower portion of the lower step portion 22b passes through the slits 28A and 28B, and then flows into the second space portion 23b sequentially from the first space portion 23a.

  The slits 28 </ b> A and 28 </ b> B are configured to suppress the passage of the neutralizing agent 1. Explaining this configuration in more detail, as shown in FIGS. 3A and 3B, the end wall 26 in which the slit 28 </ b> A is formed is a pair of side wall portions facing the thickness direction of the lower portion of the container 2. Each part 25 b ′ of 25 b is formed by approaching inward in the thickness direction of the container 2. As shown in FIG. 5A, the slit 28A is formed by the above-described portions 25b ′ not contacting each other and having a gap. In the end wall 26, except the portion where the slit 28A is formed, the portions 25b ′ are in contact with each other and joined as shown in FIG. The opening width s1 of the slit 28A is, for example, 4 mm, and is a constant width in the entire length region in the vertical direction of the slit 28A. The neutralizing agent 1 has a size larger than the opening width s1 (for example, a size that does not pass through the through hole when a sorting operation is performed using a mesh member having a 4 mm square through hole (screen)). Is used.

  The formation method of the slit 28B and the upright wall portion 46 is the same as that of the slit 28A and the end wall 26 described above, and the upright wall portion 46 includes a portion 25b ″ of each of the pair of side wall portions 25b of the container 2 of the container 2. The slits 28B are formed by approaching inward in the thickness direction, and the portions that are close to each other but are not joined to each other through a gap are the slits 28B. s2 is, for example, 3 mm, and is smaller than the opening width s1 of the slit 28 A. The neutralizing agent 1 is cracked or chipped due to impacts when it is put into the container 2 or when the container 2 is transported. In some cases, some of the neutralizing agent may pass through the slit 28A so as to be thinned by contact with acidic condensed water, but the opening width s2 of the slit 28A is further reduced. As a result, such a neutralizing agent is appropriately suppressed from flowing further downstream through the slit 28A.

  As clearly shown in FIG. 1, the lower end of the slit 28B is provided to be higher than the upper end of the slit 28A by an appropriate dimension L3. For this reason, the condensed water proceeds as indicated by arrows N5 and N6, and the condensed water flows into the second space portion 23b only when the water level becomes higher than the lower end of the slit 28B. Such a flow of condensed water also helps to make it difficult for the neutralizing agent 1 to pass through the slit 28B. Further, since the standing wall portion 46 plays a role of blocking condensate, the lower step portion 22b and the first space portion 23a have the same height as that of the lower end of the slit 28B (in a virtual line La in a normal state). It is stored at the liquid level of the height shown. When the condensed water is stored in this way, even if the combustion gas flows into the container 2 from the inlet 21, the condensed water storage unit prevents the combustion gas from flowing into the auxiliary chamber 23. It will be. In addition, auxiliary discharge ports 49a and 49b are provided at a lower portion of the standing wall portion 46 and a bottom portion of the lower step portion 22b. These are for removing condensed water accumulated in the first space 23 a and the neutralizing agent storage chamber 22 for the purpose of preventing the condensed water from freezing, for example. Therefore, at the normal time, the tip ends of pipes (not shown) connected thereto are closed so that the condensed water is not discharged from these auxiliary discharge ports 49a and 49b.

  The vent pipe body portion 3 is a portion for communicating the inside of the auxiliary chamber 23 with the outside of the container 2, and a cylindrical portion 30 that is integrally projected on the upper wall portion of the auxiliary chamber 23 or a wall portion in the vicinity thereof. In addition, a pipe 31 that is separate from the container 2 is fitted and connected. The pipe 31 is made of a metal such as copper, for example. A series of air flow paths 32 are formed in the inside of the vent tube body portion 3, and the base end portion communicates with the auxiliary chamber 23. The vent pipe body portion 3 stands upward, and the height h1 of the highest portion of the air flow path 32 (more precisely, the condensed water is prevented from overflowing from the tip opening 31a). Is made higher than the water level detection height h2 of the abnormal water level detection unit 5. Further, the height h1 is set higher than a predetermined portion of the secondary heat exchanger 8 of the hot water supply apparatus B described later. The portion near the tip of the pipe 31 is bent in a substantially U shape, and the tip opening 31a faces downward. Such a configuration is useful for preventing dust and the like from entering the tip opening 31a.

  The condensed water discharge port 24 is formed in the wall portion 231 that stands up from the bottom of the second space portion 23b. If the discharge port 24 is provided in such a configuration, the discharge port 24 opens sideways at a position higher than the upper surface of the bottom, and it is difficult for clogs to be clogged with this portion.

  The auxiliary chamber 23 is provided with a liquid level detector 6 for driving and controlling the pump P1. The liquid level detector 6 includes two electrodes 61a and 61b having substantially the same length, an electrode 61c shorter than these electrodes, and a base member 62 that supports the upper ends of these electrodes. The electrodes 61a to 61c are inserted downward from the opening hole in the upper part of the second space 23b. In this liquid level detector 6, for example, the electrode 61b is connected to the ground, and the liquid level of the condensed water rises to a predetermined high water level LH shown in FIG. 1, whereby the two electrodes 61b and 61c are both condensed. When immersed in water, it is possible to detect the fact by conducting between them. By this detection, the pump P1 starts driving, and the condensed water flows out to the pipe 75. At this time, the electrode 61a is also immersed in the condensed water, and the electrodes 61a and 61b are electrically connected. Thereafter, when the level of the condensed water falls below the predetermined low water level LL and the electrodes 61a and 61b are in a non-conductive state, this is detected and the driving of the pump P1 is stopped.

  FIG. 4 schematically shows an example of a hot water supply apparatus provided with the neutralizer A described above.

  The hot water supply apparatus B shown in the figure includes a hot water supply apparatus main body C and an exterior case 99. The exterior case 99 surrounds the hot water supply device main body C, the neutralizer A, and various pipes described later, and protects them. The hot water supply apparatus main body C has a configuration in which two hot water supply units 90A and 90B are rationally combined. More specifically, the hot water supply unit 90A is a part for generating hot water for general hot water supply, for example, a kitchen, a washroom, and the hot water supply part 90B is a part for generating hot water for floor heating, for example. It is. These hot water supply portions 90A and 90B burn the fuel such as city gas or kerosene into the two space portions 91a and 91b in the can 91 using the combustion air supplied from the blower fans 92a and 92b. It has a configuration in which two combustors 93a and 93b and two primary heat exchangers 94a and 94b for recovering sensible heat from the combustion gas generated thereby are provided.

  A secondary heat exchanger 8 that recovers latent heat from the combustion gas that has passed through the primary heat exchangers 94a and 94b is provided on the upper portion of the can body 91. The secondary heat exchanger 8 corresponds to an example of the heat exchanger referred to in the present invention, and has a configuration in which a plurality of water tubes 80 are arranged in a casing 81. As clearly shown in FIG. 6, a partition plate 82 is provided in the casing 81, and the plurality of water pipes 80 are partitioned into upper and lower groups G 1 and G 2 by the partition plate 82. The rear wall 81a and the front wall 81b of the casing 81 are provided with two upper and lower air supply ports 82a and 82b and one exhaust port 83. The combustion gas that has passed through the primary heat exchanger 94a flows into the upper region in the casing 81 from the upper air supply port 82a as indicated by an arrow N10. Subsequently, the combustion gas is recovered from the latent heat by the water pipe 80 of the group G1, and then flows out from the exhaust port 83. On the other hand, the combustion gas that has passed through the primary heat exchanger 94b flows into the lower region in the casing 81 from the lower air supply port 82b, as indicated by an arrow N11. Next, the combustion gas flows out from the exhaust port 83 after latent heat is recovered by the water pipe 80 of the group G2. An exhaust port 990 for discharging the combustion gas flowing out from the exhaust port 83 to the outside of the outer case 99 is provided on the front wall of the outer case 99.

  As shown in FIG. 4, the secondary heat exchanger 8 is provided with a plurality of header portions 84 a to 84 f for allowing water to flow through the plurality of water pipes 80 efficiently and appropriately. In the hot water supply section 90A, when water such as tap water enters the water inlet 70a at an appropriate water pressure, the water passes through the pipe 72a and then the header sections 84a to 84c of the secondary heat exchanger 8 and the group G1. It flows through the water pipe 80 and then flows to the primary heat exchanger 94a via the pipe 72b. The hot water heated in such a water flow process then reaches the hot water outlet 71a via the pipe 72c and is supplied to a predetermined hot water supply destination such as a kitchen. On the other hand, in the hot water supply section 90B, when hot water is supplied from the main body region of the floor heating device to the water inlet 70b, the hot water passes through the pipe 72d and then the header sections 84d to 84f of the secondary heat exchanger 8 and Heated through the water pipe 80 of the group G2. Next, this hot water flows into the storage tank 73 via the pipe 72e, and is then pumped up by the pump P2, sent to the primary heat exchanger 94b and heated, and then reaches the outlet 71b through the pipe 72f. Then, it is returned to the main body area of the floor heating device. The storage tank 73 and the pump P2 are one means for circulating hot water for floor heating. The storage tank 73 is connected to a pipe 70c for entering water, and is provided with a liquid level sensor (not shown), so that a constant amount or more of hot water is always present in the storage tank 73. Thus, idling of the pump P2 is prevented. The storage tank 73 is connected with a pipe 74 for preventing a negative pressure or the like from being generated in the storage tank 73. One end 74a of the pipe 74 is directly or indirectly connected to the outside of the outer case 99 and is open to the atmosphere.

  The casing 81 of the secondary heat exchanger 8 is provided with a discharge port 86 for discharging condensed water generated along with latent heat recovery. The discharge port 86 and the introduction port 21 of the neutralizer A are connected to each other. They are connected by a pipe 76. The bottom part 81c of the casing 81 plays a role of receiving condensed water dripping from the plurality of water pipes 80 and guiding it to the discharge port 86, and the discharge port 86 can efficiently discharge such condensed water. It is provided in the vicinity. Preferably, the whole or a part of the bottom portion 81c is inclined so that the condensed water can easily flow toward the discharge port 86. The condensed water discharge pipe 75 connected to the neutralizer A is connected to the discharge port 99 a of the outer case 99. A pipe 75A for guiding condensed water to, for example, a bathroom drain trap is connected to the discharge port 99a. The check valve 79 prevents the condensed water from flowing backward from the pipe 75A side toward the neutralizer A when the pipe 75A is arranged at a high position.

  In FIG. 4, although the neutralizer A is shown in the structure arrange | positioned to the one side of the hot water supply apparatus main-body part C, this hot water supply apparatus B is actually neutralized as shown in FIG. The water heater A is arranged on the front or back of the hot water supply apparatus main body C. Such an arrangement is suitable for reducing the overall width of the hot water supply apparatus B and reducing the overall size. Further, the above-described height h1 of the air flow path 32 of the vent tube body portion 3 is set higher than the minimum height h3 of the peripheral edge portion of the exhaust port 83 and the lower air supply port 82b. In the present embodiment, as shown in FIG. 6, the heights h3 of the lowest portions n1 and n2 of the peripheral portions of the exhaust port 83 and the air supply port 82b are the same. It is aligned. As will be described later, in the unlikely event that water such as condensed water or rainwater accumulates on the bottom 81c of the casing 81 due to clogging in the drainage path of the condensed water, the water level is the portion described above. If the height of n1 and n2 is exceeded, the water will overflow from the exhaust port 83 and the intake port 83 to the outside of the casing 81. If water flows into the can 91 from the air supply port 83, it causes a problem that the combustor is contaminated. Therefore, it is preferable to prevent this. For this purpose, the portion n2 of the air supply port 82b is connected to the exhaust port. What is necessary is just to make it higher than 83 part n1. In the present invention, such a configuration may be used, or a configuration having a height relationship opposite to this may be used.

  Next, the operation of the neutralizer A and the hot water supply device B will be described.

  First, the acidic condensate generated with the latent heat recovery of the secondary heat exchanger 8 is received by the bottom 81c of the casing 81, and then sent to the neutralizer A via the pipe 76, and the inlet 21 thereof. Into the container 2. This condensed water flows through a portion filled with the neutralizing agent 1 in the container 2 along a path indicated by arrows N1 to N4 in FIG. 1, and is neutralized in the process. The neutralized condensed water passes through the two narrow slits 28A and 28B and flows into the second space 23b of the auxiliary chamber 23 as shown by arrows N5 and N6. Along with the inflow of water, the air present in the second space 23 b is discharged to the outside of the container 2 through the vent tube 3. Therefore, the inflow of condensed water into the second space 23b, and consequently the inflow of condensed water into the container 2 becomes smooth.

  Next, when the amount of condensed water stored in the second space portion 23b increases and the water level rises to a predetermined high water level LH, this is detected by the liquid level detector 6. Then, the pump P1 starts driving, and the condensed water in the auxiliary chamber 23 is sent out to the pipes 75 and 75A. Thereafter, when the liquid level of the condensed water falls below the low water level LL, this is detected by the liquid level detector 6 and the driving of the pump P1 is stopped. When such condensed water is discharged, external air enters the second space portion 23b from the vent tube body portion 3, so that a siphon phenomenon is appropriately avoided as the pump P1 is driven. . When the siphon phenomenon occurs, the water seal structure of the condensed water stored in the lower step portion 22b and the first space portion 23b is destroyed and flows into the container 2 from the casing 81 of the secondary heat exchanger 8. Although there is a possibility that the combustion gas flowing out will flow out to the pipes 75 and 75A, in this embodiment, such a fear is also prevented appropriately. The pump P1 is intermittently operated every time the water level of the condensed water rises to a predetermined high water level LH. When the pump P1 is intermittently operated in this way, compared to the case where the pump P1 is continuously operated for a long time, The lifetime can be extended.

  When the neutralizer A is used, due to various circumstances, for example, the condensate discharge port 24 and the pipe 75 may be clogged. When such clogging occurs, condensed water accumulates in the container 2 and the water level rises abnormally. When the water level reaches a predetermined height h2, this is detected by the abnormal water level detection unit 5 shown in FIG. 1, and is notified by a notifying means (not shown) separately provided in the hot water supply apparatus A. This allows the user to detect that the condensate drainage path is clogged and take appropriate countermeasures. On the other hand, the rise in the water level of the condensed water as described above also occurs in the air flow path 31 of the vent pipe body portion 3, but as described above, the height h1 of the upper portion of the air flow path 31 is the above-described height. Higher than h2. Therefore, before the abnormal water level detection unit 5 detects an abnormal rise in the water level, the condensed water does not overflow outside from the tip opening 31a of the vent tube body unit 3, and the lower region of the neutralizer A Can be prevented from being contaminated by condensed water. Further, if the condensed water overflows from the vent tube body part 3 at an early stage, the water level in the container 2 does not rise or the rising speed becomes slow, so the abnormal water level detection part 5 clogs the container 2. However, according to the present embodiment, such a situation can be appropriately avoided.

  In spite of the detection of the abnormal rise in the water level as described above, for example, when the user leaves the state without taking appropriate countermeasures, the water level of the condensed water is set to the pipe 76. It is assumed that the condensed water starts to rise in the casing 81 of the secondary heat exchanger 8. In addition, when the hot water supply device B is installed outdoors, it is assumed that rainwater enters the casing 81 from the exterior case 99 and the exhaust ports 990, 83 of the casing 81, and the rise in the water level in the casing 81 is further promoted. Can do. Even if such an abnormal situation occurs, as long as the water level in the casing 81 does not become higher than the portions n1 and n2 where the height of the edge of the exhaust port 83 or the air supply port 82b is the lowest, Such condensed water is prevented from flowing out of the casing 81. On the other hand, since the height h1 of the air flow path 31 is higher than the parts n1 and n2, as long as the water level in the casing 81 is lower than the parts n1 and n2, the ventilation tube part 3 Condensed water or the like does not overflow to the outside of the neutralizer A from the front end opening 31a, and each part of the hot water supply apparatus B can be prevented from being contaminated.

  As shown in FIG. 1, the neutralizer A of the present embodiment meanders in the vertical direction when condensed water travels through the upper stage 22 a of the container 2. Therefore, it becomes suitable for lengthening the flow path length of condensed water and raising the contact frequency of condensed water and the neutralizing agent 1. FIG. Moreover, the condensed water which passed the upper stage part 22a flows into the lower stage part 22b after that, and the neutralization process is accelerated | stimulated also in this part. In this way, if the inside of the container 2 is divided into two upper and lower stages and the condensed water flows from the upper stage to the lower stage, the horizontal width of the container 2 (the width in the left-right direction in FIG. 1) and the direction orthogonal thereto. Even when the thickness of the container 2 is reduced, the volume in the container 2 can be increased to increase the filling amount of the neutralizing agent 1 and the length of the condensed water flow path in the container 2 can be increased. Therefore, while reducing the overall width and thickness of the container 2, the amount of condensed water to be treated is large, and the container 2 is optimal for applications requiring excellent neutralization performance for a large amount of condensed water. The container 2 is a blow molded product, and the upper step portion 22a and the lower step portion 22b of the neutralizing agent storage chamber 22, the auxiliary chamber 23, and the like can be appropriately formed when the container 2 is blow molded. For this reason, the container 2 can also be manufactured easily and inexpensively.

7 and 8 show another embodiment of a hot water supply device. In these drawings, elements that are the same as or similar to those in the above embodiment are given the same reference numerals as in the above embodiment.

  In the hot water supply apparatus shown in FIG. 7, a vent hole 34 is formed in the auxiliary chamber 23 of the container 2 of the neutralizer A, and the vent hole 34 is connected to a part of the pipe 74 via a pipe 77. . The pipe 74 has one end 74a connected to the outside of the exterior case 99 and is open to the atmosphere, as in the above embodiment.

  In the present embodiment, the inside of the auxiliary chamber 23 of the container 2 is communicated with the outside of the container 2 through piping 77 and 74. Therefore, when the condensed water flows into the container 2 and when the condensed water accumulated in the auxiliary chamber 23 flows out to the pipe 75 by driving the pump P1, the outflow of air from the auxiliary chamber 23 to the outside of the container, or Air flows into the auxiliary chamber 23 from the outside of the container. As a result, it is possible to obtain an effect of allowing the condensed water to smoothly flow into the container 2 and preventing an unreasonable siphon phenomenon from occurring when the pump P1 is driven. On the other hand, for example, when the condensate discharge port 24 and the pipe 75 are clogged and the water level of the condensate in the container 2 rises above the height of the vent hole 34, the condensation that has entered the pipe 77 from the vent hole 34. Water can be discharged to the outside of the outer case 99 using the pipes 77 and 74. Therefore, each part of the hot water supply apparatus B provided in the exterior case 99 is also appropriately prevented from being contaminated by condensed water.

  In the hot water supply apparatus shown in FIG. 8, a part of the pipe 77 rises upward. Accordingly, the height h4 of the uppermost portion 77a of the pipe 77 is set higher than the water level detection height h2 of the abnormal water level detection unit 5.

  In the present embodiment, when the water level of the condensed water in the container 2 rises abnormally, the condensed water does not flow from the pipe 77 to the pipe 74 as long as the water level is not higher than the height h4. Therefore, before the water level of the condensed water is detected by the abnormal water level detector 5, the condensed water in the container 2 is not discharged to the outside via the pipes 77 and 74, and the condensed water discharge port 24 and the pipe When clogging occurs in 75 or the like, the water level in the container 2 is reliably increased, and this can be accurately detected.

The present invention is not limited to the contents of the above-described embodiment. Specific configuration of a hot water supply equipment of each portion according to the present invention may be modified in various ways.

The vent tube body referred to in the present invention does not necessarily have to be configured using a pipe separate from the container. For example, the entire vent tube body may be resin-molded integrally with the container. The higher the height of the vent tube body portion, the condensed water it is possible to hardly overflows from the opening at the distal end of the vent tube body portion, not preferred.

  The whole of the vent pipe body portion does not have to stand upward, and at least a part of the vent tube body portion only needs to stand up. The standing direction may be a direction inclined with respect to the vertical direction. Further, from the viewpoint of preventing the entry of dust into the vent tube body, it is preferable that the front end opening of the vent tube body is downward. You can do it. In this invention, it can also be set as the structure which discharges | emits condensed water naturally as a means to discharge | emit the condensed water neutralized with the neutralizer outside a neutralizer, without using a pump. In such a case, the neutralizer can be configured not to include an auxiliary chamber for storing condensed water. It can be provided so that the portion filled with the summing agent communicates with the outside of the container. In the above-described embodiment, the neutralizer container has a structure in which the neutralizing agent is accommodated in two upper and lower stages. However, the present invention is not limited to this and may have a so-called one-stage structure. As the neutralizing agent, a substance other than calcium carbonate can be used.

  Unlike the above-described embodiment, the hot water supply apparatus according to the present invention may not have a configuration in which two hot water supply units are combined. The hot water supply apparatus according to the present invention can be configured as various hot water supply apparatuses such as an instantaneous hot water supply apparatus for general hot water supply, a bath hot water supply apparatus, a hot water supply apparatus for floor heating, or a hot water supply apparatus for melting snow. Of course, instead of the so-called normal combustion method in which the combustion gas is advanced above the combustor, for example, a so-called reverse combustion method in which heat exchange is performed while the combustion gas is progressing downward may be employed.

It is principal part sectional drawing which shows an example of the neutralizer with which the hot-water supply apparatus which concerns on this invention is equipped . (A) is the left view of FIG. 1, (b) is the partial cross section side view. (A) is IIIa-IIIa sectional drawing of FIG. 1, (b) is IIIb-IIIb sectional drawing of FIG. It is explanatory drawing which shows typically an example of the hot water supply apparatus which concerns on this invention. It is a schematic front sectional drawing of the hot water supply apparatus shown in FIG. It is VI-VI sectional drawing of FIG. It is a schematic front sectional drawing which shows the other example of a hot-water supply apparatus . It is a schematic front sectional drawing which shows the other example of a hot-water supply apparatus .

Explanation of symbols

A Neutralizer B Hot-water supply device 1 Neutralizing agent 2 Container 3 Vent tube body part 5 Abnormal water level detection part 8 Secondary heat exchanger (heat exchanger)
21 Inlet 24 Outlet 31 Air flow path 74, 77 Piping 80 Water pipe 81 Casing 82a, 82b Air inlet 83 Air outlet 93a, 93b Combustor 99 Outer case

Claims (2)

A combustor, a heat exchanger for recovering heat from the combustion gas generated by the combustor, and a neutralizer for neutralizing condensed water generated in association with the heat recovery,
The heat exchanger includes a casing in which an intake port and an exhaust port for combustion gas are formed, a water pipe for heat exchange disposed in the casing, and condensed water dripped from the water pipe onto the bottom of the casing. And a piping part for sending to the neutralizer,
The neutralizer includes a container containing a neutralizing agent therein ,
The container is provided with an inlet for the condensed water, an outlet for discharging the condensed water neutralized by the neutralizing agent to the outside, and a ventilation means for communicating the inside of the container to the outside of the container. A water heater,
The ventilation means is configured to include a ventilation pipe body portion having a series of air flow paths therein and a base end portion connected to the container of the neutralizer, and having an opening at a distal end portion,
Since at least a part of the vent pipe body portion stands upward, the air flow path has the lowest height among the edges of the air supply port and the exhaust port of the casing of the heat exchanger. A hot water supply device, wherein the hot water supply device extends to a position higher than the portion . The neutralizer comprises an abnormal water level detection means for detecting when the water level in the container has abnormally increased above a predetermined height,
The hot water supply apparatus according to claim 1, wherein the air flow path extends to a position higher than the predetermined height .

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