KR102141089B1 - Portable heating boiler - Google Patents

Abstract

The present invention relates to a portable heating boiler comprising: a water storage tank storing circulation water; a heating unit heating the circulation water; a vapor pressure pump installed in the water storage tank in a state of communicating with the same to allow the circulation water to flow therethrough while pumping and supplying hot water for heating, resulted from heating of the circulation water, with vapor pressure generated by heating the circulation water according to heating of a portion by the heating unit; and a recovery unit recovering the circulation water, cooled while the hot water for heating supplied through the vapor pressure pump is circulated, to the water storage tank. The portable heating boiler according to the present invention allows the heating unit to directly heat a portion of a pipe through which the circulation water of the water storage tank flows, thereby rapidly heating the circulation water flowing therethrough as the hot water for heating.

Description

Portable heating boiler {PORTABLE HEATING BOILER}

The present invention relates to a portable heating boiler, and more particularly, to a portable heating boiler that provides hot water for heating by heating circulating water.

In general, a hot water boiler provides hot water by heating a water supply such as water or cold water, and supplies heated hot water for use of hot water or performs heating using heated hot water. These, hot water boilers usually use oil or gas as a heat source for the heating device, and are mainly used in buildings, such as houses and shopping malls.

Recently, various leisure activities such as hiking, camping, or fishing have been activated, and the need for equipment capable of heating outdoors has emerged. However, the hot water boiler as described above is not portable, and since it is difficult to move after installation, there is a need for a boiler for a heating device with portability.

As such, a "portable boiler apparatus" of Patent Publication No. 10-1191276 (2012.10.09) is disclosed as a related art related to a portable boiler. The portable boiler according to the prior art is disposed in the lower body of the main body 10, the upper portion is formed as shown in Figure 1, the burner unit 30 and the main body to generate fire through the combustion of gas It is composed of a heat exchange tube (40) for heating the heated water received and received through heat exchange with the firearm generated in the burner unit (30). The portable boiler according to the prior art maintains a high temperature state of the body at all times, so that a small amount of gas is burned while stable heating efficiency can be achieved.

However, the conventional portable boiler heats the heating water accommodated in the main body by using the firearm generated through the combustion of the gas stored in the disposable gas cylinder (G). In this case, a large amount of heating water accommodated in the main body must be heated at once. Since the heating water takes more than a certain temperature, that is, the heating time until it is heated to the heating temperature, it takes a lot of preparation time for heating, so there is a problem in that it provides inconvenience to a user who needs heating rapidly.

On the other hand, as disclosed in Patent Publication No. 10-2016-0090019, "powerless non-powered hot water boiler for heating devices", as shown in Figure 1, the check valve is provided at the end of the bottom of the reservoir water reservoir is stored, respectively ' C-shaped outlet water pipes and return water pipes are installed in a slanted state in a pair.

The water outlet heat pipe supplies the water from the water reservoir to the mat-type heating device by gravity, and the return water heat pipe receives hot water circulated through the mat-type heating device and collects it back into the water reservoir.

The outlet water heating pipe and the return water heating pipe heat the water that is returned to the water in the reservoir or the reservoir in the reservoir, which flows through the inside as it is heated by the burner. At this time, the outlet water heating pipe turns the heated circulation water into steam and closes the check valve while rising to the upper portion, and the water flowing through the lower portion is lowered by gravity and supplied to the mat-type heating device.

In addition, the return water heat pipe is recovered as part of the water through the heating of the burner part into steam, and is recovered into the water reservoir part by the steam pressure. As described above, the water outlet heat pipe forms a low pressure as the water of the return water heat pipe is recovered into the water reservoir, and the water in the reservoir water is sucked back inside by the water pressure of the water reservoir. Therefore, such a conventional hot water boiler can supply hot water to a mat-type heating device without power.

However, in the prior art, since the gravity due to the water level difference between the water outlet pipe formed in the inclined state and the low pressure formation due to the return pipe are satisfied, the water in the water tank is supplied to the mat-type heating device, so that the hot water is effectively supplied to the heating device. Can not supply

Particularly, since check valves are provided at the ends of the outlet water heat pipe and the return water heat pipe, the respective check valves are not connected to each other, so that pressure sufficient to suck or push water is not easily generated.

In addition, since the water heated in the return heat pipe continues to flow into the reservoir water tank, and the water stored in the reservoir water boils as the reservoir water is heated by the burner part, the water in the reservoir water tank is Virtually no supply. Therefore, the above-mentioned conventional technology cannot substantially supply hot water to the mat-type heating device.

"Portable boiler device" of Korean Patent Publication No. 10-1191276 (2012.10.09) Korean Patent Publication No. 10-2016-0090019 (2016.07.29), "Powerless Non-Powered Hot Water Boiler for Heating System"

The present invention is to solve the above problems, and to provide a portable heating boiler capable of rapidly heating the circulating circulating water with hot water for heating by directly heating a portion of the pipe through which the circulating water of the reservoir tank flows. There is this.

In particular, there is another object to provide a portable heating boiler that can be pumped to circulate the heating hot water with only the vapor pressure generated by heating the circulating water, unlike the conventional one.

And, it is possible to allow (control) only the circulating water or the heating hot water flowing through the valve device into the aforementioned piping, and only the circulating water or the heating hot water introduced into the aforementioned pipe through another valve device may be discharged from the pipe. Another object is to provide a portable heating boiler that is permissible (controlled). That is, another object is to provide a portable heating boiler capable of preventing backflow of heated hot water for introduction or discharge.

In addition, as the above-mentioned heating hot water directly heats a part of the other piping through which it is heated, it is possible to quickly reheat the heated hot water to be perfused, and also to increase the pumping pressure by pumping the heating hot water again through the steam pressure of the other piping. There is another purpose to provide a portable heating boiler.

In addition, another object is to provide a portable heating boiler capable of recovering cooled circulating water to the aforementioned storage tank while the heat source of the heating hot water passes out as the heating hot water circulates through the heating means.

A portable heating boiler according to an embodiment of the present invention for achieving the above object, a storage tank in which circulating water is stored; A heating unit for heating the circulating water; It is installed in communication with the water tank to flow through the circulating water, but pumps and supplies heating hot water made of the circulating water through steam pressure generated by heating of the circulating water as part of the heating part is heated. Vapor pressure pump; And a recovery unit for recovering the heating hot water made of the circulating water that is cooled while being supplied through the steam pressure pump to the storage tank.

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On the other hand, the heating means for circulating the heating hot water supplied from the steam pressure pump to provide the heat source having the heating hot water to the outside, and the heat source of the heating hot water is discharged to the outside to supply cooled circulating water to the recovery unit; It may further include.

The heating means includes a mat used for a user to lie down or sit down; And a portion penetrates the mat, and the heating hot water discharged from the steam pressure pump flows through the inlet of one side, and the heated hot water passing through the mat passes the heat source of the heating hot water to the mat. And a circulation pipe through which the circulating water from which the heat source of the heating hot water is discharged is discharged through the outlet of the other side.

According to the portable heating boiler according to the present invention, since a part of the pipe through which the circulating water of the water tank flows is directly heated by the heating unit, the circulating water flowing therethrough can be quickly heated with hot water for heating. It can be supplied quickly. That is, in order to provide heating water for heating, the large amount of circulating water stored in the water storage tank is not heated at once, and only a small amount of circulating water flowing through the pipe is quickly heated, so that the heating water for heating can be used quickly.

In addition, the heating hot water for heating the circulation water can be easily circulated through the steam pressure pump using the steam pressure generated while the circulation water is heated. That is, the heating hot water can be easily circulated by using only the vapor pressure generated while the aforementioned circulating water is heated, even if a pump or the like that separately provides pressure is not used.

Since the steam pressure pump can be configured using a pipe, a guide pipe, a secondary pipe, a sub-guide pipe, a supply pipe, and a backflow prevention valve, the structure is simple and easy to manufacture and install.

The aforementioned piping is composed of a water supply line through which circulating water is supplied, a heating line that provides heating water by heating circulating water, and a drainage line through which heated water for heating is discharged, and the structure is simple and easy to manufacture.

In addition, when the inlet valve of the backflow prevention valve is installed, since the inlet valve prevents the reverse flow of the circulating water or heating hot water flowing into the pipe, the circulating water or the heating hot water can be easily perfused in only one direction.

In addition, when the discharge valve of the backflow prevention valve is installed, since the discharge valve prevents the reverse flow of the circulating water or heating hot water discharged from the pipe, the circulating water or the heating hot water can be easily perfused in only one direction.

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In addition, since the supply pipe guides the discharged heating hot water to the outside of the storage tank, the heating hot water can be easily supplied as a separate heating means for heating.

On the other hand, when the heating hot water is reheated through the heating unit to generate steam once again, it is possible to pump the heating hot water once more, so that not only the pumping pressure can be increased, but also the temperature of the warm water for sparing can be increased more rapidly. Heating hot water can be supplied more quickly.

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On the other hand, the secondary piping consists of a water supply line through which heating hot water is supplied, a heating line through which heating water is reheated, and a drainage line through which reheated heating hot water is discharged. The structure is simple and easy to manufacture.

In addition, since the guide piping forms a communication state with the secondary piping, it is possible to easily guide the heating hot water pumped by the steam pressure pump to the secondary piping, and it is installed outside of the water tank, so that the heating steam can be steam-pumped again to enable steam pressure pumping. It can be supplied by cooling in an air-cooled manner, it is possible to prevent the water temperature of the storage tank is increased by steam.

In addition, when the inlet valve of the backflow prevention valve is installed at the inlet of the secondary pipe, the inlet valve prevents the backing of the heating hot water flowing into the secondary pipe from the guide pipe, so that the heating hot water can be easily perfused only in one direction.

In addition, when the discharge valve of the backflow prevention valve is installed at the outlet of the secondary pipe, the discharge valve prevents the backing of the heating hot water discharged from the secondary pipe, so that the heating hot water can be easily perfused in only one direction.

On the other hand, since the supply pipe and the sub-guide pipe are in communication, the reheated heating hot water discharged from the secondary pipe can be easily guided to the aforementioned supply pipe, and since the sub-guide pipe is installed outside of the water storage tank, it has the same effect as the aforementioned guide pipe. It can also be provided.

In addition, when the discharge valve of the backflow prevention valve is installed at the outlet of the subguide pipe, the discharge valve prevents the reheating of the heated hot water discharged from the subguide pipe, so that the heating water can be easily perfused in only one direction.

In addition, since the recovery unit is composed of a first recovery pipe, a discharge valve, and a second recovery pipe, the structure is simple and easy to manufacture and install.

Since the above-described first recovery pipe is configured to flow through circulating water of heating hot water cooled by circulation, the structure is simple and easy to manufacture.

In addition, when a discharge valve is installed at the outlet of the first recovery pipe, the discharge valve prevents the reverse flow of the cooled circulating water discharged from the first recovery pipe, so that the circulating water can be easily perfused only in one direction.

In addition, since the second recovery pipe is in communication with the storage tank, it is possible to easily guide the cooled circulating water discharged from the discharge valve of the first recovery pipe to the storage tank.

On the other hand, through the heating means using the heat source of the above-mentioned heating hot water, the heat source of the heating hot water can be provided to the outside for easy heating, and the circulating water cooled by the heat source of the heating hot water can be easily supplied back to the recovery pipe. Can.

Since the above-described heating means is composed of a mat and a circulation pipe passing through the mat, its structure is simple, and manufacturing and installation are easy.

On the other hand, since the supply pipe is finally provided by heating hot water for heating, it is possible to supply hot water for heating to a heating means. That is, the hot water for heating can be supplied at a higher temperature since it is heated by a heating unit in the pipe of the steam pressure pump and the secondary pipe and the supply pipe of the additional pump.

1 is a view showing the configuration of a conventional portable boiler device.
2 is a view showing a state of use of the portable heating boiler according to the present invention.
3 is a perspective view of a portable heating boiler according to an embodiment of the present invention.
4 is an operation diagram schematically showing a use state shown in FIG. 2.
5 is a perspective view of a portable heating boiler according to another embodiment of the present invention.
6 is an operation diagram schematically showing a use state of the heating boiler illustrated in FIG. 5.
7 is an operation diagram schematically showing a use state of a portable heating boiler according to another embodiment of the present invention.
FIG. 8 is a block diagram showing the configuration of the controller shown in FIG. 7.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, and all terms in this specification are understood by those skilled in the art to which the present invention pertains unless otherwise specified in the description. Is the same as the general meaning of the term, and if the term used in this specification conflicts with the general meaning of the term, the definition used in this specification is followed. In addition, the configuration or system of the apparatus to be described below is only for explaining an embodiment of the present invention and is not intended to limit the scope of the present invention, and the same reference numerals are used throughout the specification. Shows.

The portable heating boiler 100 according to the present invention includes a reservoir tank 110, a heating unit 130, a vapor pressure pump 150, and a recovery unit 180 as shown in FIGS. 2 and 3.

The storage tank 110 is a component in which circulating water is stored, and an accommodation space in which circulating water is stored is provided as shown in FIGS. 3 and 4. Accordingly, the water storage tank 110 can easily store the circulating water to the inside. For example, the circulating water may be water for drinking, tap water, or general water obtained from surrounding rivers or rivers.

The heating unit 130 is a component that is heated to generate hot water for heating by circulating water, and is installed at a lower portion of the steam pressure pump 150, which will be described later, as shown in FIGS. 3 and 4, and a part of the steam pressure pump 150 To heat. For example, the heating unit 130 may be configured with a burner that is ignited with gas or liquid fuel. As described below, the heating unit 130 directly heats a portion of the pipe 151 and the supply pipe 159 of the steam pressure pump 150, and in addition, the secondary pipe 163 may also be directly heated.

Accordingly, the heating unit 130 does not directly heat the reservoir tank 110 in which a large amount of circulating water is stored, and unlike the reservoir tank 110 as shown in FIGS. 3 and 4, a small amount of circulating water flows through. The heating means 190 because the pipe 151, the supply pipe 159, and the secondary pipe 159 of the steam pressure pump 150 are directly heated, that is, only the circulating water for flowing through the heating means 190 is directly heated. ) Can quickly supply hot water for heating

The steam pressure pump 150 heats the circulating water to generate hot water for heating, and generates steam pressure therewith. The steam pressure pump 150 pumps hot water for heating through steam pressure and supplies it to the heating means 190 to be described later. The vapor pressure pump 150 may include, for example, a pipe 151 and a supply pipe 159 as shown in FIG. 4.

The piping 151 is a component for heating the circulating water to make heating hot water and discharging the heating hot water. As shown in FIGS. 3 and 4, the pipe 151 is composed of a hollow pipe so that the circulating water is introduced through an inlet on one side. , As a part is heated by the heating unit 130, the circulating water is heated to generate hot water for heating while generating steam pressure. The pipe 151 is composed of a water supply line 151a, a heating line 151b, and a drain line 151c so that the heating hot water produced by heating is discharged to the outlet on the other side.

The water supply line 151a is provided with an inlet on one side so that the circulating water of the water storage tank 110 is supplied to the inside. The water supply line 151a forms a communication state with the water storage tank 110 as shown in FIG. 4 so that the circulating water of the water storage tank 110 flows through. It is preferable that the water supply line 151a communicates with the water storage tank 110 through the inflow valve 153 for preventing backflow, which will be described later, so that the circulating water of the water storage tank 110 is easily introduced. That is, the water supply line 151a may be provided with an inlet valve 153 for preventing backflow of circulating water. Therefore, the backflow of the water supply line 151a is prevented as described below.

The water supply line 151a may be formed with an incision groove G as shown in FIG. 4. The incision groove (G) is a component that provides a passage through which circulating water or heating hot water flows through. The incision groove G is integrally formed at the end of the water supply line 151a as the end of the water supply line 151a is cut in plural along the circumferential direction, as shown in the enlarged view A of FIG. 4.

As shown in FIG. 4, the water supply line 151a may be introduced with circulating water or heating hot water through the incision groove G even if the opening/closing ball 153c to be described later is seated at the end by gravity. Therefore, the circulating water or the heating hot water is naturally supplied to the water supply line 151a through the incision groove G while being directed downward by gravity to flow through the water supply line 151a.

The heating line 151b extends in communication with the water supply line 151a as shown. The heating line 151b is heated by the above-described heating unit 130 as shown in FIG. 4 to apply heat to the circulating water supplied through the water supply line 151a. The heating line 151b is installed in a substantially horizontal state to pass through the upper portion of the heating unit 130 as shown. The heating line 151b directly heats the circulating water flowing through the hollow while being heated by the heat source ejected from the heating unit 130. Therefore, the heating line 151b can rapidly supply the heated hot water for heating as described above.

The drain line 151c is installed in a vertical direction extending in communication with the heating line 151b as shown in FIG. 4 in a vertical direction opposite to the gravity direction, and an inlet for inflow of heating hot water is provided on one side. Discharge outlets are provided on the other side. That is, the drain line 151c discharges the heating hot water supplied through the heating line 151b to the outlet on the other side. The drainage line 151c may be provided with a discharge valve 155 for preventing backflow, which will be described later, on the other side of the discharge port as shown in FIGS. 3 and 4 so that the heating hot water is easily discharged. Therefore, the backflow of the drain line 151c is prevented as described below.

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On the other hand, the above-described inlet valve 153 is installed in one state in communication with the storage tank 110, and the other side is installed in communication with the inlet of the pipe 151, as shown in the enlarged view A or B of FIG. do. The inflow valve 153 is a component that allows (controls) only the inflow of circulating water or heating hot water, and is composed of a backflow prevention valve that prevents backflow of the circulating water or heating water flowing through the inlet of the pipe 151. Therefore, the piping 151 does not flow back through the inlet circulating water by the inlet valve 153. The inlet valve 153 includes a fixed bracket 153a, a body 153b, and an opening/closing ball 153c.

The fixed bracket 153a is a component that fixes the inlet valve 153 in communication with the reservoir tank 110, as shown enlarged in FIG. 4, and is fixedly installed inside or outside the bottom of the reservoir tank 110. The fixing bracket 153a may be fixed by various methods such as screwing, bonding or welding. Therefore, the fixing bracket 153a is easily fixed to the water storage tank 110.

The fixed bracket 153a is formed to have a larger diameter than the cylindrical body 153b, as shown in FIG. 4, and protrudes outward of the body 153b like a normal flange, and is provided with a hollow inside to provide a reservoir tank 110 ). Therefore, the fixed bracket 153a receives the circulating water stored in the reservoir tank 110 through the hollow.

The body 153b is a component that controls the flow of circulating water or heating hot water, and is provided at a lower portion of the fixing bracket 153a as shown in FIG. The body 153b is provided with a hollow through which circulating water or heating hot water flows through to form a state in communication with the hollow of the fixed bracket 153a, and a seating sheet 153d for seating of the opening and closing ball 153c to be described later is provided. Is prepared. At this time, the seating sheet 153d forms a shape of a lower light cross-section with a narrow cross-sectional shape on the upper side and a wide cross-sectional shape on the lower side, as shown in enlarged views A and B of FIG. 4. In this way, the inlet valve 153 for preventing the reverse flow of the introduced circulating water or heating hot water may be installed in other pipes as described below, and in this case, a seating sheet 153d is formed in the form of a lower light negotiation.( 6 and 7)

Body 153b is inserted into the end of the above-described water supply line 151a into the hollow as shown in enlarged in FIG. 4. That is, the inlet of the pipe 151 is fixed to the body 153b. At this time, the water supply line 151a is inserted into the body 153b and fixed in communication with the body 153b.

The opening and closing ball 153c is a component that opens and closes the hollow of the above-described body 153b, and is embedded in the hollow of the body 153b as shown in an enlarged view A of FIG. 4. The opening and closing ball 153c is naturally seated on the inlet (end) of the pipe 151 inserted into the body 153b by gravity as shown. Therefore, the opening/closing ball 153c is located at the bottom of the above-described seating sheet 153d formed by lower light negotiation.

The opening and closing ball 153c is formed to have a size seated on the seating sheet 153d as shown in the enlarged view A of FIG. 4, but is formed larger than the hollow of the water supply line 151a. The opening and closing ball 153c is seated at the inlet of the pipe 151 by gravity, that is, at the end of the water supply line 151a to shield the hollow of the water supply line 151a.

However, even though the hollow is shielded by the opening/closing ball 153c, the water supply line 151a may partially circulate circulating water or hot water for heating because it forms a partially open state by the incision groove G as described above. That is, the water supply line 151a continuously flows circulating water from the water storage tank 110 through the cutting groove G.

On the other hand, when the circulating water is heated through the above-described heating unit 130, the opening/closing ball 153c generates steam pressure in the pipe 151, and as a result, the pressure rises as shown in FIG. While seating at (153c), the hollow of the body (153b) is shielded (closed). At this time, the water supply line 151a does not flow back to the water storage tank 110, the circulating water that has been introduced from the water storage tank 110 by the inflow valve 153. Of course, the water supply line 151a also does not flow the circulating water of the reservoir tank 110.

In conclusion, the pipe 151 does not flow back through the inlet valve 153 or the inlet circulation water or heating hot water.

Meanwhile, the aforementioned discharge valve 155 is a component that controls (allows) the pipe 151 to discharge only by preventing backflow of circulating water or heating hot water discharged from the pipe 151, and is an enlarged view C of FIG. 4 or As shown in D, the outlet of the pipe 151 and the inlet of the supply pipe 159, which will be described later, are installed on one side and the other side, respectively, in communication. 3 and 4, the discharge valve 155 is formed in the same shape as the above-described inlet valve 153, and is fixed to the inlet valve 153 with a fixed bracket 153a and a body 153b. And an opening/closing ball 153c. That is, the discharge valve 155 is the same in appearance and configuration as the inlet valve 153 described above. However, the difference between the discharge valve 155 is that the inner seating sheet 153c is formed in the form of an upper and lower strait, unlike the inflow valve 153, as shown enlarged in FIG. 4. In conclusion, the seating sheets 153c of the inlet valve 153 and the outlet valve 155 are formed of lower light and lower light, respectively.

Therefore, since the discharge valve 155 has the same configuration as the above-described inlet valve 153, a detailed description thereof will be omitted, and only the differences from the inlet valve 153 will be described. In the description, reference numerals for the components of the discharge valve 155 will be described by giving the same reference numerals as the components of the inlet valve 153 described above.
The fixing bracket 153a of the discharge valve 155 is fixed to the water storage tank 110 as shown in the enlarged view C of FIG. 4, and the inside of the supply pipe 159 is hollow, that is, one end of the supply pipe 159 Additions are combined.

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Cylindrical body 153b of the discharge valve 155, as shown in the enlarged view C of Figure 4, is provided with the seating sheet 153d of the upper and lower angular arrangement in the hollow inside, opening and closing ball for opening and closing the hollow ( 153c) is embedded. And, the body 153b is coupled to the end of the above-described pipe 151, that is, the end (end of the drain line) of the pipe 151.

The opening/closing ball 153c of the discharge valve 155 is seated on the seating sheet 153d by gravity to shield the hollow of the body 153b, as shown in enlarged view C of FIG. 4.

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Accordingly, the opening/closing ball 153c blocks circulation water or heating hot water from flowing upward.
On the other hand, the supply pipe 159 is composed of a pipe having a hollow as shown in Figures 3 and 4, a portion of the heating section 130 in parallel with the above-described piping 151 so as to be heated by the heating section 130 ) Is installed on the upper part in a substantially horizontal state. Accordingly, the supply pipe 159 again heats the heating hot water supplied from the pipe 151 through the heating unit 130 and supplies it to the heating means 190 to be described later as shown in FIG. 4. Therefore, the supply pipe 159 heats and supplies hot water for heating more rapidly.

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The operation of the vapor pressure pump 150 as described above will be described with reference to FIG. 4.

First, the circulating water stored in the water storage tank 110, as shown in A of FIG. 4, the water supply line 151a of the pipe 151 through the fixing bracket 153a and the body 153b of the inlet valve 153 ). At this time, the circulating water is supplied to the water supply line (151a) through the incision groove (G) formed in the water supply line (151a) of the pipe 151 as shown enlarged.

Then, the circulating water is supplied to the heating line 151b through the water supply line 151a. At this time, the circulating water is converted to hot water for heating (steam) as the heating line 151b is directly heated by the heating unit 130, thereby generating steam pressure. That is, the circulating water is converted into heated hot water for heating.

Subsequently, the heated hot water for heating is moved from the heating line 151b to the drain line 151c by steam pressure and is supplied to the supply pipe 159 to be described later through the outlet of the drain line 151c. At this time, the heated hot water for heating may be supplied to the supply pipe 159 to be described later through the inside of the fixed bracket 153a past the body 153b of the discharge valve 155 installed in the drain line 151c.

On the other hand, when the steam pressure is generated, the above-described inlet valve 153 increases the internal opening/closing ball 153c as shown in the enlarged view B of FIG. 4 by the steam pressure of the pipe 151, and the body 153b located at the upper part. It is seated on the seating sheet (153d) of the. Therefore, the inlet valve 153 is closed by the opening/closing ball 153c so that the circulating water of the reservoir tank 110 does not flow.
Then, the above-described discharge valve 155, as shown in the enlarged view D of FIG. 4, the opening and closing ball 153c is raised by the vapor pressure of the pipe 151 to open the hollow of the body 153b. Therefore, the discharge valve 155 is opened as shown to supply hot water for heating to the inlet (end) of the supply pipe 159 connected to the fixed bracket 153a. That is, the heating hot water discharged from the drain line 151c of the pipe 151 is discharged to the outside of the discharge valve 155 and supplied to the supply pipe 159.

Here, when the opening/closing ball 153c of the discharge valve 155 is raised as described above, the inlet of the supply pipe 159 or the guide pipe 161 to be described later, that is, their ends, as shown in D of FIG. 4 It is pushed into the incision groove (G) formed in the. However, even in this case, the circulating water changed to steam or hot water for heating is naturally discharged or supplied through the incision groove G.

On the other hand, the opening and closing ball 153c of the discharge valve 155, after the steam is discharged, that is, after the heating hot water is discharged from the pipe 151, descends by its own weight as shown in the enlarged view C of FIG. The hollow of the body 153b is closed while returning to the original position. Therefore, the discharge valve 155 prevents the heating hot water discharged to the outside from flowing back into the pipe 151. In conclusion, the discharge valve 155 only allows (controls) the heating hot water to be discharged.
On the other hand, the above-mentioned piping 151 is closed when the inlet valve 153 as described above due to the rise of the opening and closing balls 153c when the steam pressure occurs, while the inside of the steam is discharged as the discharge valve 155 is opened After the valve 155 is suddenly discharged, and the steam is discharged, a vacuum pressure is formed inside as the opening/closing ball 153c of the discharge valve 155 descends to shield the outlet. Accordingly, the inlet valve 153 is opened as shown in the enlarged view A of FIG. 4 by vacuum pressure to suck water (circulating water) of the reservoir tank 110 into the pipe 151. At this time, the inlet valve 153, as shown enlarged, the opening and closing ball 153c descends to its original position and opens the hollow, so that the water in the reservoir tank 110 is sucked into the inside. At this time, water is introduced to the pipe 151 through the inlet valve 153. Therefore, the vapor pressure pump 150 repeats the pumping as described above by heating the pipe 151 to the heating unit 130 again so that the water in the pipe 151 is heated.
Here, when the above-described inlet valve 153 is opened as shown in the enlarged view A of FIG. 4, the circulating water of the water storage tank 110 is again piped through the cut groove G of the aforementioned pipe 151 (151). At this time, the heating hot water (steam), which has been reversed from the heating line 151b of the pipe 151 to the water supply line 151a by the vapor pressure, is condensed into water while exchanging heat with low temperature circulating water. At this time, the pipe 151 is prevented from backflow of heating hot water (increase) because the internal vapor pressure disappears due to constriction.

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The steam pressure pump 150 as described above is pumped, that is, the circulating water of the water storage tank 110 is heated by the heating unit 130 to the heating water for heating in the pipe 151, and the heating water is piped through the steam pressure generated during heating. Through a series of actions discharged from (151), it is possible to easily supply hot water for heating. That is, the vapor pressure pump 150 can easily supply the circulating water of the water storage tank 110 from the pipe 151 to the supply pipe 159 through heating and thereby vapor pressure.

Meanwhile, the vapor pressure pump 150 may further include an additional pump 160. The additional pump 160 is a component that reheats the heating hot water supplied through the above-described steam pressure pump 150 secondly, and additionally pumps the heating hot water through the steam pressure by reheating to supply it to the heating means 190. The additional pump 160 may include a guide pipe 161 and a secondary pipe 163 as shown in FIG. 5.

Guide pipe 161 is composed of a pipe having a hollow as shown in Figures 5 and 6, one side (161a) having an inlet and the other side (161b) having an outlet, respectively, the outlet of the above-described pipe 151 and It is connected to communicate with the drain line 163c of the secondary pipe 163 to be described later.
Guide pipe 161, as shown in Figures 5 and 6, one side (161a) having an inlet may be connected to the pipe 151 through the discharge valve 155 of the pipe 151. In addition, the guide pipe 161 is a secondary pipe 163 through the inlet valve 165 for an additional pump installed on the secondary pipe 163, the other side (161b) having an outlet as shown in the enlarged view E and F of FIG. ). The guide pipe 161 configured as described above is configured in a form in which one side 161a and the other side 161b substantially forming an inlet and an outlet are expanded, and thus the discharge valve 155 described above inside the water storage tank 110 ) And the inlet valve 165, respectively, and the rest of the pipe is installed in a state exposed to the outside of the reservoir tank 110 through the above-described discharge valve 155 and the inlet valve 165, the pipe 151 and secondary. It is integrally connected to the pipe 163. The guide pipe 161 supplies heating water for heating of the pipe 151 through the inlet of one side 161a, and supplies the heated water for heating to the secondary pipe 163 through the outlet of the other 161b. That is, the guide pipe 161 guides the heating hot water of the pipe 151 to the secondary pipe 163.

Here, since the inlet valve 165 for the additional pump installed in the secondary pipe 163 has the same configuration, structure (shape) and function as the inlet valve 153 installed in the aforementioned pipe 151, it will be described with the same reference numerals, The detailed description is omitted.

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The guide piping 161 is installed to be exposed to the outside of the water storage tank 110 as shown in FIGS. 5 and 6, thereby preventing the water temperature of the water storage tank 110 from rising due to the inflow of hot water (steam).

At this time, the guide pipe 161 cools the hot water in an air-cooled manner through the exposed portion so that condensation occurs in the introduced hot water (steam). The guide pipe 161 supplies this heating hot water to the secondary pipe 163.

On the other hand, the guide pipe 161 is provided with a cut-out groove (G) at the inlet that is inserted into the discharge valve 155 of the pipe 151 described above. Since the incision groove G has the same structure (form) and function as the incision groove G described above, a detailed description thereof will be omitted.

On the other hand, the secondary pipe 163 described above is composed of a pipe having a hollow. The secondary pipe 163 is one side having an inlet as shown in Figures 5 and 6 is connected in communication with the outlet of the above-described guide pipe 161, the other side forming the outlet is a sub-guide pipe 171 to be described later It is connected to the inlet of the communication. Therefore, the secondary pipe 163 can receive the hot water for heating from the guide pipe 161 and guide it to the sub guide pipe 171.
The secondary pipe 163 is partially heated so that the heating hot water guided to the sub-guide pipe 171, which will be described later, that is, the heating hot water of the guide pipe 161 where condensation is generated by cooling is reheated to generate steam pressure. Is heated by. To this end, the secondary pipe 163 is installed so as to be parallel to the above-described pipe 151 as shown in Figures 5 and 6, a portion of which is adjacent to the heating unit 130. Therefore, since the secondary pipe 163 may be partially heated by the heating unit 130, the heating hot water may be reheated and supplied to the subguide pipe 171.

The secondary pipe 163 is composed of a water supply line 163a of an additional pump, a heating line 163b of an additional pump, and a drain line 163c of the additional pump connected to each other as shown in FIG. 5. This configuration is substantially the same as the above-described water supply line 151a, heating line 151b, and drain line 163c of the pipe 151, so a detailed description thereof will be omitted.

The water supply line 163a of the additional pump is connected to the other side 161b of the guide pipe 161 constituting the outlet as shown in FIG. 6 in communication, and receives heating water from the guide pipe 161. At this time, the water supply line 163a is configured to be the same as the inlet valve 153 of the above-described pipe 151 as shown, to be connected to the guide pipe 161 through the inlet valve 165 for an additional pump to prevent backflow. Can. That is, the water supply line 163a may be connected to the inlet valve 165 for an additional pump. Thus, the water supply line 163a is prevented from flowing back into the heated hot water.
Here, since the above-described inlet valve 165 is the same structure (shape) and configuration as the inlet valve 153 of the above-described pipe 151 as shown in enlarged view in FIG. 6, it is the same as the reference numeral of this inlet valve 153. Explained by reference numerals, but detailed description thereof will be omitted.

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On the other hand, the water supply line (163a) of the additional pump is provided with the same cutting groove (G) as described above. Since the incision groove G is the same as the incision groove G described above, the same reference numerals are used, and detailed descriptions of structures and functions are omitted.

The heating line 163b of the additional pump is connected to the water supply line 163a of the additional pump to receive cooling hot water cooled through the water supply line 163a, that is, heating water for which condensation has occurred.

The heating line 163b of the additional pump is disposed in a substantially horizontal state on the upper portion of the heating unit 130 in the same manner as the heating line 151b of the above-described pipe 151 as shown in FIGS. 5 and 6. The heating line 163b of the additional pump generates steam pressure by reheating the internal heating hot water to the heating unit 130. Therefore, the heating line 163b supplies hot water for heating to the drain line 163c, which will be described later, through vapor pressure.

The drain line 163c of the additional pump is connected to the above-described heating line 163b and receives hot water for heating from the heating line 163b of the additional pump to discharge it to the outlet of the end.

The drain line 163c of the additional pump is installed in a vertical direction opposite to the gravity direction as shown in FIG. 6. The drain line 163c may be provided with an additional pump discharge valve 167 at the outlet of the end as shown in enlarged views G and H so that the heating hot water is easily discharged. Since the discharge valve 167 is the same component as the discharge valve 155 of the above-described pipe 151 that prevents back flow and allows only discharge (control), it will be described with the same reference numerals, and detailed description thereof will be omitted.
Here, the discharge valve 167 installed in the secondary pipe 163 described above is fixed to the drain line 163c of the secondary pipe 163 at the inlet (end) of the body 153b, as shown in FIG. 6, The inlet of the sub guide pipe 171, which will be described later, is fixed with a shovel fixed to the reservoir tank 110 by being shoveled. The inlet of the supply pipe 159 described above may be fixed to the discharge valve 167 instead of the sub-guide pipe 171 described above to the fixing bracket 153a. Therefore, the secondary pipe 163 can supply the heated hot water for reheating to the subguide pipe 171 or the supply pipe 159 through the discharge valve 167.
The additional pump as described above supplies the heating hot water (steam) of the pipe 151 to the guide pipe 161 through the vapor pressure generated when the pipe 151 is heated. The guide piping 161 heats the hot water for heating through the inlet of one side 161a, and condenses while cooling the air for heating through the exposed part of the reservoir tank 110 by air cooling, so as to condense the outlet of the other side 161b. Through the secondary piping 163 to supply hot water for heating.
The secondary pipe 163 heats the hot water for heating supplied from the additional pump 163 to the heating unit 130 to generate steam pressure again. At this time, the secondary pipe 163 heats the hot water for heating through the above-described heating line 163b and the heating unit 130 forming a part. Accordingly, the secondary pipe 163 pumps the internal heating hot water again through steam pressure to supply the heating hot water to the guide pipe 161.
The secondary pipe 163 raises the opening/closing ball 153c of the additional pump inlet valve 165 installed at the inlet as shown in an enlarged view F of FIG. 6 when pumping. At this time, the opening and closing ball (153c) is seated on the upper seating sheet (153d) to close the inlet valve (165). Therefore, the secondary pipe 163 does not flow back the heating circulation water flowing from the guide pipe 161 to the guide pipe 161, and the heating circulation water of the guide pipe 161 does not flow.
In addition, the secondary pipe 161 raises the opening/closing ball 153c of the discharge valve 167 for the additional pump installed in the outlet as shown in an enlarged view G of FIG. 6 when pumping. At this time, the opening/closing ball 153c rises from the seating sheet 153d as shown in an enlarged view to open the discharge valve 167. Therefore, the heating hot water heated in the secondary pipe 163 is supplied to the sub guide pipe 171 through the incision groove G of the secondary pipe 163.
On the other hand, the opening and closing ball 153c of the discharge valve 167 for the additional pump is discharged, that is, after the heating hot water is discharged, as shown in the enlarged view H of FIG. 6, descends by its own weight and returns to its original position. Return to close the discharge valve (167). Therefore, the discharge valve 167 prevents the discharged heating hot water from flowing backward to the secondary pipe 163.
On the other hand, the secondary pipe 163 described above is opened by the pump, the inlet valve 165 for the additional pump is closed by the pumping, the discharge valve for the additional pump 167 is opened, the steam inside is suddenly discharged, and then descends As the discharge valve 167 for the additional pump is closed again by the ball 153c, a vacuum pressure is formed inside. Accordingly, since the secondary pipe 163 re-opens the inlet valve 165 for the additional pump as shown in the enlarged view E of FIG. 6 by vacuum pressure, the heating water for heating of the guide pipe 161 is sucked again. At this time, the inlet valve 165 is opened as the opening/closing ball 153c descends and returns to its original position as shown in an enlarged view. Therefore, the additional pump 160 heats the water sucked in the secondary pipe 163 back to the heating unit 130 to repeat pumping as described above.
On the other hand, as shown in the enlarged view E of FIG. 6, when the inlet valve 165 for the additional pump is re-opened as described above, the heating hot water of the guide pipe 161 is a cutting groove of the secondary pipe 163 (G) flows back to the secondary pipe 163 again. At this time, the heating hot water (steam) that has been reversed from the heating line 163b of the secondary pipe 163 to the water supply line 163a by the vapor pressure is condensed while exchanging heat with the heating hot water flowing from the guide pipe 161. At this time, the secondary piping 163 is prevented from backflow of heating hot water (increase) because the internal vapor pressure disappears due to condensation.
The additional pump 160 as described above can further increase the temperature of the heating hot water by reheating the heating hot water through the secondary pipe 163, and further pumping the heating hot water again, thereby further heating the hot water used for heating. It can be supplied quickly.
In addition, the additional pump 160 cools and condenses the steam by air cooling through the guide pipe 161, and heats the condensed heating hot water again through the secondary pipe 163, thereby additionally pumping the hot water for heating.

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Meanwhile, the additional pump 160 may further include a subguide pipe 171 as illustrated in FIGS. 5 and 6. As shown in the subguide pipe 171, the ends of both sides are respectively connected to the secondary pipe 163 and the supply pipe 159 to communicate with each other. The sub-guide pipes 171 are connected so that the inlet of one side 171a communicates with the outlet of the secondary pipe 163, and the outlets of the other side are connected to communicate with the inlets of the supply pipe 159, thereby communicating with each other. Order. To this end, the sub-guide piping 171 is one side (171a) constituting the only sphere as shown, the discharge valve 167 of the secondary piping 163 inside the reservoir tank 110, that is, the discharge for the additional pump described above It may be configured to be connected to the valve 167 in a fitted state to communicate with the secondary pipe 163 through the discharge valve 167, and the remaining portion is installed in a state exposed to the outside of the reservoir tank 110 to form an outlet. The other side may be configured to communicate with the supply pipe 159 from the outside of the reservoir tank (110). At this time, the sub-guide pipe 171 may be configured to be in communication with the supply pipe 159 through the discharge valve 173 by being connected to the discharge valve 173 for the sub-guide pipe as shown on the other side of the outlet. have. Therefore, since the sub-guide pipe 171 is connected to the secondary pipe 163 and the supply pipe 159, it is possible to receive reheated heating hot water from the secondary pipe 163 and guide it to the supply pipe 159. That is, the sub-guide pipe 171 is heated and heated for re-heating through the inlet and outlet is introduced and discharged.
Here, the above-described discharge valve for sub-guide piping 173 is a backflow prevention valve configured to allow (control) discharge only, such as the above-described additional pump discharge valve 167, the discharge valve for sub-guide piping 173 It is configured to be the same as the inlet valve 153 of the above-described pipe 151, as shown in order to prevent back flow, that is, to prevent the heating hot water supplied to the supply pipe 159 from flowing back to the sub guide pipe 171. It is composed of a valve that operates in the same way, but the difference is that these valves are installed upside down on the subguide piping 171. Therefore, the discharge valve 173 for the subguide piping is the same as the inlet valve 153 of the piping 151. Since it is configured and installed only upside down, detailed description thereof will be omitted.

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The sub-guide pipe 171 as described above, when the additional pump 160 is pumped, the reheated heating hot water of the secondary pipe 163 flows into the inlet of one side 171a as shown by the arrow in FIG. 6. . The sub guide pipe 171 discharges the heated hot water for inflow to the outlet of the other side and supplies it to the supply pipe 159. At this time, the discharge valve 173 for the sub-guide piping permits (controls) the heating and hot water supplied to the supply pipe 159 to be discharged while being opened and closed by the illustrated opening and closing ball 153c. That is, the discharge valve 173 for the sub guide piping prevents hot water for heating from flowing back to the sub guide piping 171. Therefore, the sub-guide piping 171 easily supplies hot water for heating.
On the other hand, since the sub-guide piping 171 is exposed to the outside of the reservoir tank 110 as described above, it is reheated in the secondary piping 163 to cool the introduced heating hot water (steam) by air cooling from the outside of the reservoir tank 110. Order. That is, the sub-guide piping 171 condenses the steam of the heating hot water. Therefore, the sub guide pipe 171 supplies hot water by condensation to the supply pipe 159.
The sub-guide piping 171 is installed outside the reservoir tank 110, as shown in FIGS. 5 and 6, so that the reheated heating hot water (steam) can be cooled by air cooling as well as the reheated secondary piping ( It prevents the water temperature of the water storage tank 110 from rising by the hot water for heating of 163).

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On the other hand, the supply pipe 159 is installed in a substantially horizontal state in parallel with the aforementioned pipe 151 or the secondary pipe 163 as shown in FIGS. 5 and 6, partially heated by the heating unit 130 do. Accordingly, the supply pipe 159 heats the heating hot water supplied from the sub-guide pipe 171 again to the third time and supplies it to the heating means 190. Therefore, the supply pipe 159 heats and supplies hot water for heating more rapidly.

Meanwhile, the heating means 190 circulates by providing the heating hot water supplied through the supply pipe 159 to the outside as described above. That is, the heating means 190 provides a heat source of hot water for heating to the outside for heating. The heating means 190 may include a mat 191 and a circulation pipe 193 as shown in FIGS. 4 and 6.

The mat 191 is a component that provides a heat source of hot water for heating to the user, and is composed of a conventional rug or mat 191 used for the user to lie down or sit down as shown in FIGS. 2 and 4 and 6. . In this mat, the circulation pipe 193 to be described later is entirely piped inside the mat 191. Accordingly, the mat 191 provides a user with a heat source for heating hot water that flows through the circulation pipe 193 to the user.

The circulation piping 193, as shown in FIGS. 2 and 4 and 6, so that the heating water is supplied to the mat 191 described above, is heated through the inlet on one side and discharged through the outlet on the other side.

The circulation pipe 193 is piped in a zigzag form as shown. Accordingly, the circulation pipe 193 transfers the heated hot water for introduction to the mat 191. The circulation pipe 193 supplies the heating hot water cooled by being radiated from the mat 191 to the recovery unit 180 to be described later.

The recovery unit 180 recovers the hot water for heating circulated by the above-mentioned puncturing means, that is, the circulating water circulating through the heating means 190 to the water storage tank 110. 6, the recovery unit 180 may include a first recovery pipe 181, a discharge valve 183 (recovery portion), and a second recovery pipe 185.

The first recovery pipe 181 guides the circulating water discharged from the circulation pipe 193 of the heating means 190 to the second recovery pipe 185. 4 and 6, the inlet on one side is connected to the circulation pipe 193, and the outlet on the other side of the first recovery pipe 181 is connected to the second recovery pipe 185. Therefore, the first recovery pipe 181 guides the circulating water to the second recovery pipe 185.

The discharge valve 183 of the recovery part allows (controls) discharge of circulating water discharged from the first recovery pipe 181 only. That is, the discharge valve 183 prevents the circulating water discharged from the first recovery pipe 181 from flowing backward. 4 and 6, the discharge valve 183 is connected to the first and second recovery pipes 181 and 185 on one side and the other side.

Since the discharge valve 183 of the recovery part is configured in the same way as the discharge valve 173 of the sub-guide pipe 171 described above, detailed description thereof will be omitted.

The discharge valve 183 of the recovery part is opened and closed by the opening/closing ball 153c described above to allow (control) the supply of circulating water while preventing the backflow of the circulating water.

The second recovery pipe 185 guides the circulating water supplied through the first recovery pipe 181 to the storage tank 110. 4 and 6, the second recovery pipe 185 is connected to the first recovery pipe 181 on one side, and the other side is fixed in communication with the storage tank 110. Therefore, the second recovery pipe 185 guides the circulating water supplied from the first recovery pipe 181 to the water storage tank 110 to recover the circulating water again.

In the present invention as described above, the circulating water of the reservoir tank 110 is easily circulated while continuously circulating the steam pressure pump 150, the heating means 190 and the recovery unit 180, and the heating unit 130 is piped ( 151) and the secondary pipe 163 and the supply pipe 159 directly heated only a portion of the circulating water is rapidly heated, and the circulating water is heated several times by such heating, so that the heating hot water can be heated more quickly. Therefore, the present invention can be quickly heated by such heating hot water.

Meanwhile, the portable heating boiler according to the present invention may further include a water collecting unit 200. The water collecting unit 200 is a component for condensing the circulating water evaporated in the water storage tank 110 and collecting it again in the water storage tank 110, as shown in FIGS. 3 and 4, the lid body 210, condensation It may be configured to include a portion 230 and the vent 250.

The lid body 210 blocks the opening of the water storage tank 110. The lid body 210 has a size corresponding to the open upper inner periphery of the water storage tank 110 as shown in FIGS. 3 and 4. In detail, as shown in FIGS. 4 and 6, the lid body 210 forms an outer border while both ends are bent, and the inner lower portion is formed in an open cap shape.

This, the lid body 210 is seated on the upper inner periphery of the reservoir tank 110, as shown in Figures 4 and 6 to block the opening of the reservoir tank (110). Accordingly, the circulating water evaporated from the inside of the reservoir tank 110 may be prevented from escaping to the outside of the reservoir tank 110 because it is blocked.

The condensation unit 230 condenses the evaporated circulating water. The condensation part 230 is a plate-shaped member traversing the inside of the lid body 210 as shown in FIGS. 4 and 6. The condensation unit 230 is installed inside the outer border provided on the lid body 210 as shown, but is installed in a spaced apart state from the lid body 210 and the inner space S inside the lid body 210. Gives Accordingly, the circulating water evaporated from the inside of the reservoir tank 110 to the top is blocked by the condensation unit 230 and does not escape to the outside of the reservoir tank 110.

This, the condensation unit 230 is cooled by air flowing into the inner space (S) of the lid body 210 through the vent 250 to be described later as shown in Figures 4 and 5. Accordingly, the circulating water evaporated to the top is condensed on the surface of the condensation unit 230 and then aggregated and collected back to the reservoir tank 110 by gravity.

Meanwhile, the condensation unit 230 may further include a curvature surface 231. The curvature surface 231 is a component for vortexing the air flowing into the inner space S of the lid body 210. The curvature surface 231 is formed at the edge of the condensation unit 230 as shown in the enlarged views of FIGS. 4 and 6, and is formed in a shape that curves toward the upper portion of the lid body 210.

The curvature surface 231 changes the course of air flowing into the inner space S of the lid body 210 through the air vent 250, which will be described later, through the curvature, thereby generating a vortex in the inner space S. Accordingly, the condensation part 230 is circulated actively by the curvature surface 231, so the surface is cooled more easily.

Vent 250 is a component that provides a passage for introducing the outside air into the inner space (S) of the lid body 210, as shown in Figures 4 and 6 on the outer border of the lid body 210 It is composed of through holes. The vent 250 communicates the inside space (S) of the lid body 210 and the outside, as shown, such that a plurality of vents 250 are provided at equal intervals along the outer border of the lid body 210 desirable.

In the lid body 210, since the inner space S communicates with the outside by the vent 250, the outside air is easily introduced into the inner space S. Therefore, the condensation unit 230 forms a low temperature state, that is, a cooled state, than the internal temperature of the water storage tank 110 by the introduced air.

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As described above, the water collecting unit 200 condenses the water vapor of the circulating water that is evaporated from the inside of the water storage tank 110 so that the condensation unit 230 collects water again into the water storage tank 110 to maintain the maximum amount of the circulation water Can be. Accordingly, the user has the convenience of using without frequently replenishing the circulating water.

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In addition, since the evaporated circulating water is condensed and recovered by the condensation unit 230 cooled by air, the temperature of the circulating water stored in the storage tank 110 can be lowered.

Meanwhile, the water collecting unit 200 may further include an exhaust port 270. The exhaust port 270 is a component that exhausts a portion of the vapor pressure accumulated inside the water tank 110 to the outside, and is a hole formed through a portion of the condensation unit 230 as shown in enlarged view in FIGS. 4 and 6. Can be configured.

The exhaust port 270 discharges the vapor pressure of the water storage tank 110 into the inner space S of the lid body 210 so that the vapor pressure is exhausted through the vent 250 of the lid body 210 described above. Therefore, since the water tank 110 discharges the vapor pressure through the exhaust port 270, an accident such as an explosion due to the vapor pressure can be prevented.

On the other hand, the above-described portable heating boiler 100, as shown in Figures 7 and 8, the water level sensor 111, the flame detection sensor 130c, the temperature sensor 194, the gas control valve (130b), Ignai At least one of the controller 130d and the controller 101 may be further included.

The water level sensor 111 is installed in the water storage tank 110 as shown in FIG. 7 to detect the water level in the water storage tank 110. The water level sensor 111 is preferably installed on the lower side of the water storage tank 110 to detect the lowest level of the water storage tank 110 as shown.

The flame detection sensor 130c is installed on the top of the heating unit 130 as shown in FIG. 7. The flame detection sensor 130c detects the flame generated in the heating unit 130. The temperature sensor 194 measures the temperature of the mat 191 which is installed in the mat 191 in a buried state as shown in FIG. 7 and heated by the circulation pipe 193.

The gas control valve 130b is installed in the heating unit 130 as shown in FIG. 7 to control the flow rate of fuel (eg, gas) supplied to the heating unit 130. The gas control valve 130b may be automatically operated, for example, by installing a server motor whose operation is controlled by the above-described controller 101. That is, the gas control valve 130b may automatically control the flow rate while operating automatically by the controller 101.

Ignite (130d) is installed on one side of the upper portion of the heating unit 130, as shown in FIG. The ignite 130d is configured like a normal electronic lighter to generate sparks. Thus, the ignite (130d) generates a spark when the fuel is ejected from the heating unit 130 to automatically ignite the fuel.

The controller 101 is installed in the water tank 110 or a water tank case (not shown) as shown in FIG. 7 to control the operation of the above-described components. The controller 101 is preferably provided on the upper side of the water storage tank 110, as shown to be spaced apart from the heating unit 130. The controller 101 is preferably installed in the water storage tank 110 together with the display DP as shown.

As illustrated in FIG. 8, the controller 101 is provided with an input unit 101b, a communication unit 101c, and a control unit 101a, and an unillustrated battery is built in and operated by power of the battery. The input unit 101b may be configured with a dial or a button, and the operation information of the storage tank 110, such as a heating temperature or a heating time of the storage tank 110, is input.

The communication unit 101c receives the storage tank operation information from an external terminal (for example, a smartphone, a PC), not shown, or transmits the sensed value detected by the above-described component to the external terminal.

The control unit 101a controls the operation of the input unit 101b and the communication unit 101c described above, and stores the operation information of the reservoir tank input from the input unit 101b or the communication unit 101c. Accordingly, the controller 101 can remotely operate the heating unit 130 for a time set by an external terminal.

The portable heating boiler 100 configured as described above operates the heating unit 130 based on the above-described storage tank operation information input through the input unit 101b or the communication unit 101c. At this time, the controller 101 stores the input storage tank operation information, and then operates the servo motor according to the stored information to open the fuel pipe connected to the heating unit 130 through the gas control valve 130b. Then, the controller 101 operates the ignite 130d to ignite the fuel supplied to the heating unit 130 to heat a portion of the vapor pressure pump 150 described above through the heating unit 130.

At this time, the controller 101 confirms whether the heating unit 130 is ignited through the monitoring signal of the flame detection sensor 130c, and if it is determined that the ignition is not performed, operates the ignite 130d again or gas The fuel pipe is closed through the control valve 130b.

The controller 101 controls the heating power of the heating unit 130 by varying the amount of opening and closing of the gas control valve 130b according to the temperature of the mat 191 applied from the temperature sensor 194. In addition, the controller 101 checks the water level value of the water storage tank 110 applied from the water level sensor 111, so that the water storage tank 110 is below the set water level, that is, the level of insufficient water signal from the water level sensor 111 In this case, all components are stopped to prevent fire.

When the display DP is provided, as shown in FIGS. 7 and 8, the controller 101 displays the driving state through the display DP. That is, the controller 101 displays the temperature of the mat 191 or the ignition state of the heating unit 130.

On the other hand, the controller 101 may receive the above-described storage tank operation information through the communication unit 101c, that is, the controller 101 inputs the storage tank operation information transmitted from an external terminal through the communication unit 101c. Can receive Thus, the controller 101 can remotely operate the components.

Then, the controller 101 may transmit the content displayed on the display DP to the external terminal as described above through the communication unit 101c. Therefore, the user can easily check the operation status of the component remotely.

100: portable heating boiler 110: water storage tank
130: heating unit 150: steam pressure pump
151: piping 151a, 163a: water supply line
151b, 163b: heating line 151c, 163c: drain line
G: incision grooves 153, 165: inlet valve
153a: Fixed bracket 153b: Body
153c: opening and closing ball 153d: seating seat
155, 167, 173, 183: discharge valve
159: Supply pipe 160: Additional pump
161: Guide piping 163: Secondary piping
171: sub guide piping 180: recovery unit
181: 1st Collection Hall 185: 2nd Collection Hall
190: heating means 191: mat
193: circulation piping 200: water collecting unit
210: lid body 230: condensation
231: curvature surface 250: vent
270: exhaust

Claims (10)

A storage tank 110 in which circulating water is stored;
A heating unit 130 for heating the circulating water;
It is installed in communication with the reservoir tank 110 to flow through the circulating water, but for heating made of the circulating water through steam pressure generated by heating the circulating water as part of the heating part 130 is heated. A steam pressure pump for supplying hot water by pumping; And
It includes; a recovery unit 180 for recovering the heating hot water made of the circulating water cooled while being supplied through the steam pressure pump to the water storage tank 110;
The vapor pressure pump,
The circulating water of the reservoir tank 110 is introduced through an inlet of one side, and at least a portion is heated by the heating unit 130 to make the circulating water introduced into the inlet into the heating hot water while generating vapor pressure. , Piping 151 for pumping the heating hot water through the steam pressure to discharge to the other outlet;
The heating hot water discharged from the pipe 151 flows into the inlet of one side 161a, and guides the heating hot water introduced into the inlet so that the heating hot water is cooled to the outside of the water storage tank 110, so that the other side 161b ) Guide pipe 161 to discharge to the outlet;
The heating hot water discharged from the guide pipe 161 flows through an inlet on one side, and at least a part is heated by the heating unit 130 to generate steam pressure while heating the heating hot water, and for heating through steam pressure A secondary pipe 163 for pumping hot water and discharging it to the outlet of the other side;
The heating hot water discharged from the secondary pipe 163 flows through the inlet of one side 171a, and guides the heating hot water introduced into the inlet so that the heating hot water is cooled to the outside of the water storage tank 110 to the other side. Sub-guide pipe 171 to discharge to the outlet of the;
The heating hot water discharged from the sub-guide piping 171 is supplied through an inlet on one side, and the heating hot water flowing into the inlet on one side so that the heating hot water is circulated from the outside of the reservoir tank 110 is discharged on the other side. Supply pipe for discharging to (159); And
Includes a backflow prevention valve installed in the piping 151, the secondary piping 163, and the subguide piping 171 to prevent the backflow of the circulating water or the heating hot water.
The guide pipe 161,
The heating hot water introduced from the piping 151 is guided to the outside of the water storage tank to be cooled, so that the heating hot water is introduced and discharged while being installed on the outside of the water storage tank 110, and one side 161a having the inlet port ) To introduce the heating hot water from the inside of the water storage tank 110 to guide the outside of the water storage tank 110, and from the inside of the water storage tank 110 through the other side 161b having the outlet. It is characterized in that the heating hot water is discharged to provide the heating hot water to the secondary pipe 163,
The sub-guide piping 171,
The heating hot water flowing in and out of the secondary tank 163 is guided to the outside of the water storage tank 110 and cooled so that the heating water for heating is introduced and discharged while being installed outside the water storage tank 110. The heating hot water is introduced from the inside of the water storage tank 110 through one side 171a to be guided to the outside of the water storage tank 110, and from the outside of the water storage tank 110 through the other side having the outlet. It characterized in that for discharging the heating hot water,
The recovery unit 180,
Circulating water by the heating hot water that is supplied to the outside of the water storage tank 110 and circulated by the supply pipe 159 of the vapor pressure pump flows through the inlet of one side, and the circulating water is discharged through the outlet of the other side One recovery tube 181;
A discharge valve 183 installed at an outlet of the first recovery pipe 181 to prevent reverse flow of the circulating water; And
The circulating water discharged through the discharge valve 183 of the first recovery pipe 181 is provided in a communication state between the discharge valve 183 of the first recovery pipe 181 and the reservoir tank 110 It includes; a second recovery pipe 185 that flows through the inlet of one side, and discharges the introduced circulating water to the outlet of the other side so as to be supplied to the reservoir tank 110 again;
The piping 151 and the secondary piping 163,
A water supply line (151a, 163a) through which the circulating water or the heating hot water flows;
Heating lines 151b and 163b extending in communication with the water supply lines 151a and 163a to flow through the circulating water or the heating hot water, and heated by the heating unit 130; And
It includes; drainage lines (151c, 163c) extending in communication with the heating lines (151b, 163b) and discharging the circulating water heated through the heating lines (151b, 163b) or the heating hot water;
It further includes a collecting unit 200 for condensing the circulating water evaporated from the inside of the water storage tank 110 and recovering it to the water storage tank 110.
The water collecting unit 200,
It is mounted on the upper portion of the reservoir tank 110, the cap body 210 is formed in a cap shape having an outer border; And
It is installed on the inner side of the outer frame provided on the lid body 210, and is installed in a state spaced apart from the lid body 210 to provide an inner space (S) in the lower portion of the lid body 210, the water It includes; a condensation unit 230 in the form of a plate to block and condense the circulating water evaporated from the reservoir tank 110 from the bottom of the lid body 210 so that the circulating water evaporated from the tank 110 is recovered; ,
The condensation unit 230,
A hole-shaped exhaust port 270 is formed so that the vapor pressure of the water tank 110 is exhausted to the outside,
The lid body 210,
A hole-shaped vent 250 communicating with the inner space S is formed so that external air flows into the inner space S formed by the condensation unit 230,
The plate-shaped condensation unit 230,
A portable heating boiler, characterized in that it is cooled by external air introduced from the vent 250 so that the circulating water evaporated from the water tank 110 condenses. According to claim 1, The backflow prevention valve,
An inlet valve (153, 165) installed in the inlet of the pipe 151 and the secondary pipe 163 into which the circulating water or the heating hot water flows in, and preventing a reverse flow of the circulating water or the heating hot water flowing into the inlet; It consists of,
The inlet valve (153, 165),
A fixed bracket 153a installed in the water storage tank 110 or in communication with the guide pipe 161;
A body 153b that is integrally provided on the fixing bracket 153a, has a hollow communicating with the fixing bracket 153a, and is fitted with an inlet of the pipe 151 or the secondary pipe 163 into the hollow to be fixed. ;
A seating sheet 153d forming a part of the inner circumferential surface of the body 153b and having a cross-sectional shape in the form of lower light negotiation; And
A portable heating boiler comprising a; opening and closing ball (153c) to open and close the hollow of the body (153b) while seated on the seating sheet (153d). According to claim 1, The backflow prevention valve,
A discharge valve installed at the outlet of the pipe 151, the secondary pipe 163, and the sub guide pipe 171 through which the circulating water or the heating hot water is discharged, and preventing a backflow of the circulating water or the heating hot water discharged to the outlet (155, 167, 173); portable heating boiler, characterized in that consisting of. The method according to any one of claims 1 to 3,
The supply pipe 159,
It is characterized in that a part of the heating is heated by the heating unit 130 to heat the heating hot water flowing into the inlet of one side through a portion, and discharge the heating hot water heated by the heating unit 130 to the outlet of the other side. Portable heating boiler. delete delete delete delete delete delete

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