JP2021085620A - boiler - Google Patents

Abstract

To provide a boiler that heats water with heating means provided with a heat generating body inside a container, and facilitates lowering a required heatproof temperature of a device installed in a circulation path for circulating a gas from the container therethrough.SOLUTION: A boiler includes: a heat generating body; a container in which the heat generating body is installed and which can be filled with a gas whose specific heat is higher than that of air; and a circulation path including a gas path arranged in the container and on an outside of the container, as a path through which the gas circulates. The boiler heats water using the heat generated by the heat generating body. A first heat exchanger and a second heat exchanger are installed in order from the upstream side in the gas path. The boiler recovers heat collected from the gas by the first heat exchanger into the gas by the second heat exchanger.SELECTED DRAWING: Figure 1

Description

The present invention relates to a boiler that heats the supplied water.

Conventionally, boilers that heat supplied water have been widely used for various purposes including industrial and commercial use. In the boiler, a heat generating means for heating the supplied water is provided, and one form of the heat generating means includes a boiler in which a heating element is provided inside the container.

In addition, various specific forms of such a heat generating means can be mentioned, and as an example, a reactant (heating element) in which a plurality of metal nanoparticles made of a hydrogen storage metal or a hydrogen storage alloy are formed on the surface is placed inside the container. Is disclosed in Patent Document 1 as a heat generating system. According to Patent Document 1, in this heat generation system, it is described that hydrogen atoms are occluded in metal nanoparticles by supplying a hydrogen-based gas that contributes to heat generation into a container, and excessive heat is generated.

As described in Patent Document 1, an exothermic reaction occurred by heating the inside of the container while supplying deuterium gas to the inside of the container by providing a heating element made of palladium inside the container. An announcement has been made. In addition, regarding the exothermic phenomenon that generates excess heat (output enthalpy higher than input enthalpy) using hydrogen storage metal or hydrogen storage alloy, the details of the mechanism of generating excess heat are being discussed among researchers in each country. , It has been reported that a heat generation phenomenon has occurred.

Japanese Patent No. 6448074 U.S. Pat. No. 9,182,365

In a boiler that heats water by a heating means provided with a heating element inside the container, for example, a circulation path that includes the inside of the container as a part for the purpose of activating the movement of gas in the container and promoting heat transfer. It may be effective to circulate the gas in. In particular, when the above-mentioned reactant is used as the heating element, it is important to circulate the hydrogen-based gas in the container from the viewpoint of promoting the reaction that generates excess heat.

However, the gas in the container is heated by the heating element and becomes hot. Therefore, for a device (for example, a gas pump or a gas filter) provided in a circulation path in which such a high-temperature gas circulates, the required heat-resistant temperature (required heat-resistant temperature) becomes high, and for example, an increase in boiler manufacturing cost becomes a problem. Become.

In view of the above problems, the present invention heats water by a heat generating means provided with a heating element inside the container, and it is easy to lower the required heat resistant temperature of the device provided in the circulation path for circulating the gas in the container. The purpose is to provide a boiler.

The boiler according to the present invention includes a heating element, a container in which the heating element is provided and can be filled with a gas having a specific heat higher than that of air, and the container and the outside of the container as a path for circulating the gas. It is a boiler that has a circulation path including a gas path arranged in, and heats water by using the heat generated by the heating element, and is a first heat exchanger and a second heat in order from the upstream side in the gas path. A switch is provided, and the heat recovered from the gas by the first heat exchanger is returned to the gas by the second heat exchanger.

According to this configuration, water is heated by a heat generating means provided with a heating element inside the container, and it becomes easy to lower the required heat resistant temperature of the device provided in the circulation path for circulating the gas in the container. That is, the required heat resistant temperature of the device can be lowered only by arranging the device between the first heat exchanger and the second heat exchanger.

More specifically, as the above configuration, a gas pump that flows the gas from the upstream side to the downstream side of the gas path, or a gas filter that removes impurities contained in the gas is a first heat exchanger in the gas path. The configuration may be provided between the second heat exchangers. According to this configuration, it is possible to lower the required heat resistant temperature of the gas pump or gas filter.

More specifically, as the above configuration, by circulating a heat medium between the first heat exchanger and the second heat exchanger, the heat recovered from the gas in the first heat exchanger is exchanged for the second heat. It may be returned to the gas by a container and may be configured to control the circulation of the heat medium based on the temperature of the gas. According to this configuration, it is possible to efficiently circulate the heat medium.

More specifically, the gas is a hydrogen-based gas, and the heating element is provided with metal nanoparticles made of hydrogen storage metals on the surface of the heating element, and the hydrogen-based gas is placed in the container. Under the supplied situation, the structure may be a reactant in which hydrogen atoms are stored in the metal nanoparticles to generate excess heat. The hydrogen-based gas in the present application is a deuterium gas, a light hydrogen gas, or a mixed gas thereof. Further, the "hydrogen storage metal" in the present application means a hydrogen storage metal such as Pd, Ni, Pt, Ti, or a hydrogen storage alloy containing one or more of these.

More specifically, the boiler is provided with a water pipe that is heated by the heat generated by the heating element, and the water is heated by passing through the water pipe. The water pipe surrounds the heating element. It may be arranged. According to this configuration, the heat generated by the heating element can be transferred to the water to be heated very efficiently.

According to the boiler according to the present invention, water is heated by a heat generating means provided with a heating element inside the container, and it is easy to lower the required heat resistant temperature of the device provided in the circulation path for circulating the gas in the container. It becomes.

It is a schematic block diagram of the boiler 1 which concerns on 1st Embodiment. It is explanatory drawing about the path of the water passing through the water pipe of a boiler 1. It is a schematic block diagram of the boiler 2 which concerns on 2nd Embodiment. It is a schematic block diagram of the boiler 1a which flows a heat medium through a water path.

The boiler according to each embodiment of the present invention will be described below with reference to each drawing.

1. 1. First Embodiment First, the first embodiment of the present invention will be described. FIG. 1 is a schematic configuration diagram of the boiler 1 according to the first embodiment. As shown in this figure, the boiler 1 includes a container 11, a reactant 12, a heater 13, a gas path 14, a gas receiving section 15, a gas pump 16, a gas filter 17, a separator 21, a water path 22, a water receiving section 23, and a water pump. 24, a first heat exchanger 31, a second heat exchanger 32, a heat circulation path 33, and a heat circulation pump 34 are provided.

The state of the container 11 and its inside in FIG. 1 (the same applies to FIGS. 3 and 4 described later) is shown as a schematic cross-sectional view when the container 11 is cut by a plane that substantially divides the container 11, and is shown vertically and horizontally. The direction of (the vertical direction corresponds to the vertical direction) is as shown in this figure. Further, the alternate long and short dash line shown in FIG. 1 (the same applies to FIGS. 3 and 4) schematically shows the arrangement of the water pipe 22a.

The container 11 is formed in a cylindrical shape having bottoms at both upper and lower ends with the upper and lower sides as the axial direction as a whole, and is formed so as to be able to seal the gas inside. More specifically, the container 11 has a cylindrical side wall 11a formed by a water pipe 22a described later, the upper side of the side wall 11a is closed by an upper bottom portion 11b, and the lower side of the side wall 11a is a lower bottom portion. It is closed by 11c. In the present embodiment, as an example, the side wall 11a of the container 11 has a cylindrical shape, but it may be formed in another cylindrical shape. Further, the can body cover may be installed on the outer periphery of the side wall 11a, or a heat insulating material may be provided between the side wall 11a and the can body cover.

The reactant 12 is configured by providing a large number of metal nanoparticles on the surface of a carrier which is formed in a fine mesh shape as a whole. A hydrogen storage alloy (hydrogen storage metal or hydrogen storage alloy) is applied to this carrier as a material, and it is formed in a cylindrical shape having bottoms at both upper and lower ends in the vertical direction. The upper surface of the reactant 12 is connected to the gas path 14, and the gas that has flowed into the inside of the reactant 12 through the mesh-like gap can be sent out into the gas path 14. In the example of this embodiment, three reactants 12 are provided so as to be arranged in the left-right direction inside the container 11.

The heater 13 is spirally wound around the side surface of the reactant 12 formed in a bottomed cylindrical shape, and is formed so as to generate heat by using the supplied electric power. As the heater 13, for example, a ceramic heater can be adopted. The heat generated by the heater 13 heats the reactant 12, and the temperature of the reactant 12 can be raised to a predetermined reaction temperature at which a reaction for generating excess heat, which will be described later, is likely to occur. The temperature of the heater 13 can be adjusted by controlling the power supplied to the heater 13.

The gas path 14 is provided outside the container 11 and forms a gas circulation path including the inside of the container 11 as a part, and one end is connected to the upper surface of each reactant 12 and the other. The end is connected to the inside of the container 11. More specifically, the portions of the gas path 14 connected to the upper surface of each reactant 12 merge in the container 11, form a single path, penetrate the upper bottom portion 11b, and then the gas receiving portion 15, The lower bottom portion 11c is further penetrated through the first heat exchanger 31, the gas pump 16, the gas filter 17, and the second heat exchanger 32 in this order, and is connected to the inside of the container 11.

The gas receiving unit 15 receives a hydrogen-based gas (deuterium gas, a light hydrogen gas, or a mixed gas thereof) from an external supply source, and supplies the supplied hydrogen-based gas into the gas path 15. Inflow to. For example, when hydrogen-based gas is supplied from a tank in which hydrogen-based gas is stored in advance to the gas receiving unit 15, this tank serves as a supply source of hydrogen-based gas.

The rotation speed of the gas pump 16 is controlled by, for example, inverter control, and the gas in the gas path 14 flows from the upstream side to the downstream side (that is, in the direction indicated by the dotted arrow in FIG. 1) at a flow rate corresponding to the rotation speed. To do so. The amount of gas circulated in the circulation path including the gas path 14 can be adjusted by controlling the rotation speed of the gas pump 16.

The gas filter 17 removes impurities contained in the gas in the gas path 14 (particularly those that hinder the reaction that generates excess heat in the reactant 12). The separator 21 receives steam generated by heating water when passing through the water pipe 22a, and causes brackish water separation (separation of drain contained in the steam) from the steam. The steam separated by steam in the separator 21 can be supplied to the outside of the boiler 1.

The water path 22 is a water path connecting the water receiving portion 23 to the separator 21. A part of the water path 22 is a water pipe 22a forming the side wall 11a described above. Further, in the middle of the water path 22, a water pump 24 is arranged at a position closest to the downstream side of the water receiving portion 23. Of the water paths 22, the liquid water supplied from the water receiving portion 23 flows in the path upstream of the water pipe 22a, and the path downstream of the water pipe 22a (between the container 11 and the separator 21). Water (steam) heated and vaporized in the water pipe 22a will flow.

The water receiving unit 23 is adapted to appropriately receive water that is a source of steam from the outside, and causes the supplied water to flow into the water path 22. The water pump 24 causes the water in the water path 22 to flow from the upstream side to the downstream side (that is, in the direction indicated by the solid arrow in FIG. 1).

The water pipe 22a spirally extends from the lower bottom portion 11c toward the upper bottom portion 11b so as to form the tubular side wall 11a of the container 11. That is, the water pipe 22a extends spirally so as to proceed in the axial direction (vertical direction) of the tubular side wall 11a so that there is no gap between the portions of the water pipes 22a adjacent to each other on the upper and lower sides. In the example of this embodiment, the cross-sectional shape of the inner wall of the water pipe 22a is quadrangular, but it may be circular or other shape.

The first heat exchanger 31 is provided on the upstream side of the gas pump 16 in the gas path 14, and the second heat exchanger 32 is provided on the downstream side of the gas filter 17 in the gas path 14. As described above, in the gas path 14, the second heat exchanger 32 is provided on the downstream side of the first heat exchanger 31, and the gas pump 16 is located between the first heat exchanger 31 and the second heat exchanger 32. A gas filter 17 is provided.

The heat circulation path 33 is a path for circulating the heat medium X (water for the heat medium, etc.), and is arranged so as to pass through the first heat exchanger 31 and the second heat exchanger 32. Further, the heat circulation path 33 is provided with a heat circulation pump 34 that allows the heat medium X to flow in the path. The first heat exchanger 31 and the second heat exchanger 32 are formed as heat exchangers that exchange heat between the heat medium X and the gas in the gas path 14.

Next, the operation of the boiler 1 will be described. In the boiler 1, hydrogen-based gas is supplied from an external supply source to the gas receiving unit 15, and the inside of the container 11 and the gas circulation path including the gas path 14 are filled with hydrogen-based gas. The filled hydrogen gas is circulated in this circulation path in the direction indicated by the dotted arrow in FIG. 1 by the action of the gas pump 16.

At this time, inside the container 11, the hydrogen-based gas flows into the inside of the reactant 12 through the mesh-like gap, and then is sent out into the gas path 14 connected to the upper part of the reactant 12. At the same time, the reactant 12 is heated by the action of the heater 13. In this way, when the reactant 12 is heated by the heater 13 while the hydrogen-based gas is supplied to the inside of the container 11, hydrogen atoms are occluded in the metal nanoparticles provided in the reactant 12, and the reactant 12 is the heater 13. Generates excess heat above the heating temperature of. In this way, the reaction element 12 functions as a heating element by performing a reaction that generates excess heat. The principle of the reaction for generating excess heat is the same as the principle of the reaction for generating excess heat disclosed in, for example, Patent Document 1.

Impurities are removed from the hydrogen-based gas in the circulation path including the inside of the container 11 when passing through the gas filter 17. Therefore, a high-purity hydrogen-based gas from which impurities have been removed is continuously supplied to the inside of the container 11. As a result, it is possible to stably apply a high-purity hydrogen-based gas to the reactant 12 and maintain a state in which it is easy to induce an output of excess heat, thereby effectively generating heat of the reactant 12.

Further, in parallel with the operation of generating heat of the reactant 12, water is supplied from the outside to the water receiving unit 23. The supplied water is flowed in the water path 22 in the direction indicated by the solid arrow in FIG. 1 by the action of the water pump 24.

The water flowing in the water path 22 is heated by the heat generated by the reactant 12 when passing through the water pipe 22a forming the side wall 11a of the container 11. That is, the heat generated by the reactant 12 is transferred to the water pipe 22a by convection (heat transfer) and radiation by the hydrogen-based gas in the container 11, and the water flowing inside the water pipe 22a is heated by the high temperature water pipe 22a.

FIG. 2 schematically shows the path of water passing through the water pipe 22a with a solid arrow. As shown in this figure, the water that has entered the water pipe 22a from the inlet α of the water pipe 22a (the lowermost part of the water pipe 22a) proceeds along the passage in the water pipe 22a extending spirally, and the outlet β of the water pipe 22a ( It is discharged as steam from the uppermost part of the water pipe 22a toward the separator 21. At this time, the heat from the water pipe 22a (side wall 11a of the container) heated by the heat generated by the reactant 12 is transferred to the water passing through the water pipe 22a, and the temperature rises.

In this way, the water flowing through the water path 22 is heated as it passes through the water pipe 22a, the temperature rises, and finally it becomes steam. This steam is sent to the separator 21, and after the dryness is increased by the separation of air and water, it is supplied to the outside of the boiler 1.

The amount of steam supplied from the separator 21 to the outside may be adjustable according to the required amount of steam from the outside (steam load) and the like. In such an adjustment, when the amount of steam supplied to the outside is less than the appropriate amount, the calorific value of the reactant 12 is increased to increase the amount of steam generated, and when the amount is larger than the appropriate amount, the calorific value of the reactant 12 is generated. This can be achieved by reducing the amount and reducing the amount of steam generated.

The calorific value of the reactant 12 can be controlled by adjusting the temperature of the heater 13 or the gas circulation amount described above, and the calorific value of the reactant 12 increases as the temperature of the heater 13 increases or the circulation amount increases. Can be increased. Further, in the boiler 1, water is sequentially supplied to the water receiving unit 23 by the amount of steam supplied to the outside, that is, by the amount of water decreased, and steam is continuously generated and supplied to the outside. It is possible to do.

Furthermore, the heat circulation pump 34 is driven in parallel with the operation of generating heat of the reactant 12, and the heat medium X circulates in the heat circulation path 33. As a result, the heat recovered from the gas in the gas path 14 by the first heat exchanger 31 is returned to the gas by the second heat exchanger 32.

More specifically, in the first heat exchanger 31, the temperature of the gas in the gas path 14 is higher than that of the heat medium X, and the heat exchange between the two causes the gas to the heat medium X. The heat is recovered and the gas is cooled accordingly. The heat medium X whose temperature has risen due to this is sent to the second heat exchanger 32 via the heat circulation path 33, while the cooled gas is sent to the second heat exchanger 32 via the gas path 14. ..

Since the heat exchange is performed in the first heat exchanger 31, the temperature of the gas in the gas path 14 in the second heat exchanger 32 is lower than that in the heat medium X. Therefore, in the second heat exchanger 32, heat is returned from the heat medium X to the gas by heat exchange between them, and the temperature of the gas rises by that amount. The heat medium X cooled by this returns to the first heat exchanger 31 through the heat circulation path 33, and is used again for recovering heat from the gas.

As the heat exchange between the first heat exchanger 31 and the second heat exchanger 32 is continuously performed, the temperature of the gas in the gas path 14 is adjusted to the temperature of the first heat exchanger 31 and the second heat exchanger 32. It can be lowered temporarily in between. As a result, the gas whose temperature has been temporarily lowered passes through the gas pump 16 and the gas filter 17 provided between the first heat exchanger 31 and the second heat exchanger 32. It is possible to lower the heat resistant temperature (required heat resistant temperature) required for these devices. The gas cooled by the first heat exchanger 31 has returned to the temperature before cooling at the stage of flowing into the container 11 via the second heat exchanger 32. Therefore, the influence of the cooling of the gas in the first heat exchanger 31 on the heat generation of the reactant 12 and the heating of the water passing through the water pipe 22a is suppressed as much as possible.

In the present embodiment, among the devices provided in the gas path 14, both the gas pump 16 and the gas filter 17 are provided between the first heat exchanger 31 and the second heat exchanger 32, but any of them may be provided due to various circumstances. It is also possible to provide only one of them between the first heat exchanger 31 and the second heat exchanger 32. When a device other than the gas pump 16 and the gas filter 17 is provided in the gas path 14, this device is also provided between the first heat exchanger 31 and the second heat exchanger 32 to lower the required heat resistant temperature of the device. It is also possible. Further, in the portion of the heat circulation path 33 on the downstream side of the first heat exchanger 31 (on the upstream side of the second heat exchanger 32), heat exchange in the first heat exchanger 31 (heat from the hydrogen-based gas). The heat medium X, which has become hot due to recovery), flows. Therefore, from the viewpoint of lowering the required heat resistant temperature of the heat circulation pump 34, the heat circulation pump 34 should be installed on the downstream side of the second heat exchanger 32 (upstream side from the first heat exchanger 31) as shown in FIG. Is preferable.

Further, the temperature of the gas in the circulation path including the gas path 14 may be detected, and the circulation of the heat medium X may be controlled based on the temperature of the gas. For example, a sensor for detecting the temperature of gas is provided at a predetermined location (preferably the location closest to the upstream side of the first heat exchanger 31) in the gas path 14, and the higher the detection value of the sensor, the more the heat medium X. You may try to increase the circulation amount of. Further, the heat medium X should not be circulated under the condition that the detected value of the sensor does not exceed the predetermined allowable upper limit value (for example, the lower temperature of the required heat resistant temperatures of the gas pump 16 and the gas filter 17). The heat medium X may be circulated when the allowable upper limit value is exceeded. By doing so, the heat medium can be circulated more without excess or deficiency, and the heat medium can be circulated efficiently.

2. Second Embodiment Next, the second embodiment of the present invention will be described. The second embodiment is basically the same as the first embodiment except for the form of the heating element and the points related thereto. In the following description, emphasis will be placed on the explanation of matters different from those of the first embodiment, and explanations of matters common to the first embodiment may be omitted.

FIG. 3 is a schematic configuration diagram of the boiler 2 according to the second embodiment. In the boiler 1 of the first embodiment, the reactant 12 is adopted as a heating element, but in the second embodiment, a general heating element 12a is adopted instead. As an example, the heat generating element 12a here is assumed to be a halogen heater that generates heat when electric power is supplied. Further, the shape and dimensions of the heat generating element 12a are assumed to be the same as those of the reactant 12 for convenience. When the heating element 12a is applied as the heating element, it is not necessary to generate excess heat as in the first embodiment, and the heater 13 is not required, so the installation is omitted. Further, the upstream end of the gas path 14 in the second embodiment is connected to the upper bottom portion 11b instead of the heat generating element 12a, and is connected to the space inside the container 11.

In the boiler 2, the water pipe 22a is heated by the heat generated from the heat generating element 12a instead of the reactant 12, and the heat from the water pipe 22a (the side wall 11a of the container) is transferred to the water passing through the water pipe 22a to raise the temperature. Become. Further, in this embodiment, the reaction for generating excess heat described above is not required, and by directly controlling the temperature of the heat generating element 12a by electric power control, water can be appropriately heated to generate steam. it can.

Further, in the boiler 2, it is possible to control the amount of heat generated by the heating element 12a (heating element) by adjusting the power supplied to the heating element 12a. As the amount of heat generated by the heat generating element 12a is increased, the water passing through the water pipe 22a is heated more strongly, and the amount of steam generated in the boiler 2 can be increased.

3. 3. Others The boilers 1 and 2 of each of the above-described embodiments include a heating element and a container 11 provided with the heating element inside, and heat the supplied water to generate steam. Further, in each of the boilers 1 and 2, in an environment where the inside of the container 11 is filled with a gas having a specific heat higher than that of air (hydrogen-based gas in the example of the present embodiment), the water pipe 22a is heated by the heat generated by the heating element. , And the water passing through the water pipe 22a (water that is the source of steam) is heated. For example, under the condition of 1 atm at 200 ° C, the specific heat of air is about 1,026 J / Kg ° C, while the specific heat of hydrogen is about 14,528 J / Kg ° C, which is much higher than the specific heat of air. It has become. Further, as the heating element, the reaction element 12 is adopted in the boiler 1, and the heating element 12a is adopted in the boiler 2.

According to each of the boilers 1 and 2, it is possible to efficiently transfer the heat generated by the heating element to the water while heating the water by a heating means provided with a heating element inside the container 11 to generate steam. It is possible. That is, for example, when a heat medium such as a fluid other than water is circulated in a water pipe and the heat medium is exchanged with water outside the container 11, heat loss due to the presence or transfer of the heat medium may occur. In this respect, in each of the boilers 1 and 2, by arranging the water pipe itself so as to surround the heating element, a heat medium for recovering the heat generated by the heating element becomes unnecessary. As a result, the above-mentioned heat loss and the like can be suppressed, and the heat generated by the heating element can be efficiently transferred to water, which is the source of steam.

Further, since the inside of the container 11 is filled with a gas having a specific heat higher than that of air, heat transfer is improved as compared with the case where general air is filled, and the heat generated by the heating element becomes a source of steam. It can be efficiently transmitted to water. Further, since the specific heat is high, the temperature of the gas is less likely to fluctuate, and it is possible to transfer heat to the water more stably.

Further, since the water pipe 22a forms the entire circumference of the side wall 11a formed in a tubular shape, it is possible to efficiently transfer the heat generated by the heating element to the water that is the source of steam. In particular, since the water pipe 22a in the present embodiment is arranged so as to surround the heating element, it covers almost the entire circumference of the side wall 11a, and the heat generated by the heating element is used as a source of steam as little as possible. It is possible to tell to water. In each of the above embodiments, the water pipes extend spirally to surround the heating element, but the form surrounding the heating element is not limited to this. For example, a plurality of water pipes extending in the vertical direction form the heating element. A form or the like that surrounds and arranges the above may be adopted.

Further, in each of the above embodiments, the side wall 11a for sealing the gas in the container 11 is formed by the water pipe 22a, but instead, the side wall 11a is provided separately from the water pipe 22a and inside the side wall 11a. A water pipe 22a may be provided (that is, inside the container 11). Even in this case, the water pipe 22a can be heated by the heat generated by the heating element in an environment in which the inside of the container 11 is filled with a gas having a specific heat higher than that of air. Further, in this case, the water pipe 22a does not need to serve as the side wall 11a, but it is preferable that there is a gap between the vertically adjacent water pipes 22a so that the heat from the heating element can be further received.

Further, in each of the boilers 1 and 2, the gas is circulated in a circulation path including the inside of the container 11 as a part. This is expected to have the effect of activating the movement of the gas in the container 11 and more effectively transferring heat from the gas to the side wall 11a. In particular, in the boiler 1 of the first embodiment, it is important to circulate the gas in order to promote the reaction that generates excess heat in the reactant 12. Since the boiler 2 of the second embodiment does not require a reaction that generates excess heat, a gas other than the hydrogen-based gas may be used as the gas having a higher specific heat than the above-mentioned air.

Further, each of the boilers 1 and 2 is provided with a circulation path including a container 11 and a gas path 14 arranged outside the container 11 as a path for circulating the gas, and further, in the gas path 14, the first is in order from the upstream side. The first heat exchanger 31 and the second heat exchanger 32 are provided, and the heat recovered from the gas by the first heat exchanger 31 is returned to the gas by the second heat exchanger 32. Therefore, it is possible to lower the required heat resistant temperature of the gas pump 16 and the gas filter 17 provided between the heat exchangers 31 and 32.

In each of the above embodiments, water that is a source of steam flows through the water path 22 including the water pipe 22a, but instead, the heat medium Y (water for the heat medium, etc.) is passed through the water path 22. ) Is allowed to flow, and the water that is the source of steam can be heated using this heat medium Y. A schematic configuration diagram of the boiler configured in this way is illustrated in FIG.

In the boiler 1a shown in FIG. 4, a heat exchanger 50 is provided instead of the separator 21, and the heat exchanger 50 is provided with a part of the water path 22 through which the heat medium Y flows, and is a source of steam. Water is supplied. The heat medium Y circulates in the water path 22 including the water pipe 22a, as shown by the solid arrow in this figure. As a result, the heat medium Y heated by the reaction element 12 (heating element) can be sent to the heat exchanger 50, and the supplied water can be heated by the heat medium Y to generate steam and be supplied to the outside. Is. The heat exchanger 50 may be configured to generate hot water in addition to the configuration of heating water to generate steam.

As the heat exchanger 50, for example, a plate type or shell-and-tube type heat exchanger may be adopted, or various types of steam generators may be adopted. As an example of this steam generator, it has a storage space for storing the supplied water and a tubular body through which the heat medium Y arranged in the storage space is passed, and the heat of the heat medium Y passes through the tubular body. Examples include those that are transmitted to the stored water.

Although the embodiments of the present invention have been described above, the configuration of the present invention is not limited to the above embodiments, and various modifications can be made without departing from the gist of the invention. That is, the above embodiment should be considered to be exemplary in all respects and not restrictive. For example, the boiler according to the present invention can be applied to a hot water boiler, a heat medium boiler, and the like, in addition to the boiler that generates steam as in the above embodiment. The technical scope of the present invention is shown not by the description of the above embodiment but by the scope of claims, and is understood to include all modifications belonging to the meaning and scope equivalent to the scope of claims. Should be.

The present invention can be used in boilers for various purposes.

1, 1a, 2 Boiler 11 Container 11a Side wall 11b Upper bottom 11c Lower bottom 12 Reactor 12a Heat generating element 13 Heater 14 Gas path 15 Gas receiving part 16 Gas pump 17 Gas filter 21 Separator 22 Water path 22a Water pipe 23 Water receiving part 24 Water pump 31 1st heat exchanger 32 2nd heat exchanger 33 Heat circulation path 34 Heat circulation pump 50 Heat exchanger

Claims (5)

With a heating element
A container in which the heating element is provided and can be filled with a gas having a specific heat higher than that of air.
As a path for circulating the gas, the container and a circulation path including a gas path arranged outside the container are provided.
A boiler that heats water using the heat generated by the heating element.
In the gas path, a first heat exchanger and a second heat exchanger are provided in order from the upstream side.
A boiler characterized in that the heat recovered from the gas by the first heat exchanger is returned to the gas by the second heat exchanger. A gas pump for flowing the gas from the upstream side to the downstream side of the gas path, or a gas filter for removing impurities contained in the gas is provided between the first heat exchanger and the second heat exchanger in the gas path. The boiler according to claim 1, wherein the boiler is characterized in that. By circulating a heat medium between the first heat exchanger and the second heat exchanger, the heat recovered from the gas in the first heat exchanger is returned to the gas in the second heat exchanger. ,
The boiler according to claim 1 or 2, wherein the circulation of the heat medium is controlled based on the temperature of the gas. The gas is a hydrogen-based gas and
The heating element is
Metal nanoparticles made of hydrogen storage metals are provided on the surface,
Any of claims 1 to 3, wherein the hydrogen atom is a reactant that occludes hydrogen atoms in the metal nanoparticles and generates excess heat under the condition that the hydrogen gas is supplied into the container. The boiler described in Crab. The boiler according to any one of claims 1 to 4, further comprising a water pipe that is heated by the heat generated by the heating element, and the water is heated by passing through the water pipe.
A boiler characterized in that the water pipe is arranged so as to surround the heating element.

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