KR100743983B1 - Apparatus for recurring hot-water forcibly without any electric power sources - Google Patents

Abstract

The present invention relates to a boiler, comprising: a boiler main body having a heating section provided at a lower side with an intermediate partition interposed therebetween, and a flow section provided at an upper side of the intermediate partition wall to allow heated water to flow in the heating section; Wow; At least one connecting pipe passing through the intermediate partition and having both ends disposed in the heating section and the flow section and causing the water heated in the heating section to float into the flow section; A discharge pipe exposed to the outside of the boiler body from the flow section to discharge hot water charged in the flow section; A heating pipe having one end communicating with the discharge pipe and embedded in a predetermined installation surface to heat the installation surface; A suction pipe which is exposed to the outside of the boiler body from the heating section and communicates with the heating pipe and sucks water in the heating pipe into the heating section; A branch member coupled to the suction pipe; One end communicates with the upper flow section side of the boiler body and the other end communicates with the suction pipe and includes a steam discharge pipe for circulating water vapor evaporated in the flow section to the heating section through the branch member and the suction pipe. Characterized in that.

As a result, hot water formed in the boiler body can be circulated to the heating pipe embedded in the installation surface without using the circulation pump, but it can be used more safely without the risk of explosion.

Description

Apparatus for recurring hot-water forcibly without any electric power sources}

1 is a perspective view of a boiler according to a first embodiment of the present invention,

Figure 2 is a sectional view of the boiler body shown in Figure 1,

3 is a sectional view of a boiler main body according to a second embodiment of the present invention;

4 is a sectional view of a boiler main body according to a third embodiment of the present invention;

5 is a perspective view of a boiler according to a fourth embodiment of the present invention;

6 is a perspective view of a boiler according to a fifth embodiment of the present invention;

7 is a schematic cross-sectional view of the boiler shown in FIG. 6;

8A to 8C are perspective views, respectively, of the boiler according to the sixth embodiment of the present invention, viewed from different angles.

* Explanation of symbols for the main parts of the drawings

10,210: Boiler body 12,12a: Intermediate bulkhead

13 heating section 14 flow section

15,15a: Connection piping 16: Exhaust piping

17: suction pipe 22,122: heating pipe

30,230: Steam exhaust pipe 32,232: Safety valve

40,240: branch member 310a, 310b: heating tank

312a, 312b: Suction pipe 314a, 314b: Heater mounting part

320: water replenishment tank 321: water replenishment

323: sensor mounting part 327a, 327b: connection piping

328a, 328b: exhaust pipe 330a, 330b: steam exhaust pipe

The present invention relates to a boiler, and more particularly, to a non-powered hot water circulating device which circulates hot water formed in a boiler body to a heating pipe embedded in an installation surface without using a circulation pump, so that it can be used more safely without an explosion risk. It is about.

In general, a boiler for heating cold water with hot water by heating the cold water with a heat source obtained from the gas or oil, a heater, etc. is widely used in various forms.

Such a boiler has a boiler body for generating hot water, and a heating pipe that is embedded in a living room or a floor and receives hot water formed in the boiler body to heat the living room or the floor with hot water.

Both ends of the heating pipe are in communication with the inside of the boiler body, one end is used as a discharge passage for discharging hot water from the boiler body, and the other end is used as a suction passage for sucking hot water cooled to the boiler body. The discharge passage is provided with a circulation pump for discharging hot water in the boiler body to the heating pipe.

Thus, when the boiler body is operated, cold water is heated by a predetermined heat source in the boiler body, and the water is changed into hot water. At this time, the circulating pump starts to operate so that hot water formed in the boiler body is discharged through the discharge passage and flows along the heating pipe. The hot water flowing through the heating pipe is turned into room temperature as the heat is lowered as the living room or the floor is heated. The water cooled in the heating pipe (nearly “room temperature”) is again introduced into the boiler body through the suction passage and reheated.

By the way, in such a conventional boiler, a circulation pump for circulating hot water in the boiler body to the heating pipe is necessary. Therefore, since the power required for the operation of the circulation pump is required, it cannot be employed in an area where there is no power or no power.

Therefore, the present applicant has solved such a problem through the last application because the need for a boiler to circulate the hot water in the boiler body to the heating pipe without a circulation pump.

However, in addition to the last filed, a boiler has been proposed to circulate hot water formed in the boiler body to a heating pipe embedded in the installation surface without using a circulation pump, but to be free from explosion risk and to be used safely.

Accordingly, an object of the present invention is to provide a non-powered hot water forced circulation device that circulates hot water formed in a boiler body to a heating pipe embedded in an installation surface without using a circulation pump, so that it can be used more safely without an explosion risk.

In addition, another object of the present invention, there is provided a non-powered hot water forced circulation device that can be used even where no power consumption is required, portable and can be installed anywhere.

The object is, according to the present invention, the boiler body having a heating section provided on the lower side with the intermediate partition interposed therebetween, and a flow section provided on the upper side of the intermediate partition wall and the heated water flows in the heating section. Wow; At least one connecting pipe passing through the intermediate partition and having both ends disposed in the heating section and the flow section and causing the water heated in the heating section to float into the flow section; A discharge pipe exposed to the outside of the boiler body from the flow section to discharge hot water charged in the flow section; A heating pipe having one end communicating with the discharge pipe and embedded in a predetermined installation surface to heat the installation surface; A suction pipe which is exposed to the outside of the boiler body from the heating section and communicates with the heating pipe and sucks water in the heating pipe into the heating section; A branch member coupled to the suction pipe; One end communicates with the upper flow section side of the boiler body and the other end communicates with the suction pipe and includes a steam discharge pipe for circulating water vapor evaporated in the flow section to the heating section through the branch member and the suction pipe. It is achieved by a boiler characterized in that.

On the other hand, the object, the boiler body is provided with at least one discharge pipe for discharging the heated water on one side and the inside is airtight; A body portion accommodated in at least a portion of the interior of the boiler body, a heater interposed in the body portion to generate heat, and one end of which is exposed to the outside of the boiler body and the other end communicates with the body portion to supply water into the body portion. At least one suction pipe to be introduced, and at least one of the one end is in communication with the body portion and the other end is disposed in the boiler body to deliver the water heated by the heater in the body portion to the boiler body without power. A heating member having a tube; A branch member coupled to the suction pipe; One end is in communication with the boiler body and the other end is in communication with the suction pipe, characterized in that it comprises a steam discharge pipe for circulating water vapor evaporated in the flow section into the heating member through the branch member and the suction pipe. It is also achieved by a boiler.

Here, it may further include a safety valve provided in any one section of the steam discharge pipe.

On the other hand, the object, the heating tank is equipped with at least one heating member therein; A water replenishment tank provided at an upper portion of the heating tank; A connection pipe connecting the heating tank and the water refill tank; A discharge pipe branched from the connection pipe to discharge hot water heated in the heating tank; It is also achieved by a boiler, comprising a suction pipe in communication with the heating tank and discharged through the discharge pipe and sucked hot water heated a predetermined installation surface.

Here, the boiler, one end in communication with the water filling tank and the other end further comprises a steam discharge pipe in communication with the suction pipe.

The heating tank may be separated into one or more than one. At this time, the connection pipe, the discharge pipe, the suction pipe and the steam discharge pipe attached to one heating tank may be disposed one or more than one.

At least one of the upper and side portions of the water replenishment tank is formed with a water refill.

The water filling tank is provided with a sensor mounting portion for mounting the low water level cutoff sensor.

Hereinafter, each embodiment of the present invention will be described in detail with reference to the accompanying drawings, and like reference numerals refer to like elements.

As shown in FIGS. 1 and 2, the boiler according to the first embodiment of the present invention is embedded in the boiler body 10 generating hot water and the predetermined installation surface 20 and installed on the installation surface by hot water ( And a heating pipe 22 for heating 20.

Boiler body 10 is formed in a rectangular cylindrical shape, it is disposed on the upper side of the installation surface (20). Therefore, if the installation surface 20 is shown in Figure 1, if the living room or floor surface boiler body 10 will be installed on the side wall (19). However, this is only one embodiment, the boiler body 10 may be manufactured in a variety of other shapes, such as cylindrical or triangular, or conical.

A power switch 11 is provided on a plate surface of the boiler body 10, and a handle portion 10a is provided on a side surface of the boiler body 10.

The boiler body 10 is provided with an intermediate partition 12 partitioning the boiler body 10 into two regions along the height direction. Due to the intermediate partition 12, the boiler body 10 is divided into a heating section 13 and a flow section 14 of the upper side.

At this time, the intermediate partition 12 may be a flat plate, as shown in Figure 2, but as shown in Figure 3, the central region of the intermediate partition 12a is easy to concentrate the boiling water to the upper center It may be bent upward so that it can be. Referring to FIG. 3, hot water heated in the heating section 13 may be concentrated in the upwardly curved lower region of the intermediate partition 12a, and then may be easily floated into the flow section 14 through the connecting pipe 15 to be described later. It provides the effect.

In the heating section 13, cold water or normal temperature water is heated to change to hot water. To this end, the heating section 13 is provided with a heating member (24). The hot water heated in the heating section 13 by the heating member 24 is directed to the flow section 14 provided on the upper side of the intermediate partition 12 by the connection pipe 15 to be described later.

At this time, as the heating member 24, as shown in Figure 2 and 3, may be a heater for heating the water while being heated by a predetermined power source, as shown in Figure 4, the heating member 24a Could be a flame.

The connection pipe 15 is disposed between the heating section 13 and the flow section 14. The connection pipe 15 penetrates the intermediate partition 12, and both ends thereof are disposed in the heating section 13 and the flow section 14, respectively, to naturally float the hot water heated in the heating section 13 to flow the section 14 To pass). It is preferable that the lower end of the connection pipe 15 is disposed to be substantially adjacent to the intermediate partition 12 in the heating section 13.

Here, the connection pipe 15 may be configured as one as shown in Figures 2 and 3, as shown in Figure 4 may be employed in two connection pipes (15, 15a). However, this is also only one embodiment, of course, may be employed in two or more.

On the outside of the boiler body 10 is provided with a discharge pipe 16 for discharging hot water in the flow section 14 and a suction pipe 17 through which cold water is sucked into the heating section 13 again.

Discharge pipe 16 is provided on the outer upper flow section 14 side of the boiler body 10, the position is lower than the top of the connecting pipe 15 can be easily discharged hot water by the water pressure and water level difference Make sure At the lower end of the outer side of the boiler main body 10 is provided with a suction pipe 17 in which cold water cooled by heating of the mounting surface 20 in the heating pipe 22 to be described later is sucked back into the heating section 13.

On the other hand, a separate branch member 40, also called a T-shaped pipe or union, is coupled to the suction pipe 17. A steam exhaust pipe 30 is provided between the branch member 40 and the boiler body 10.

As shown, the steam discharge pipe 30 has one end 30a communicating with the upper flow section 14 side of the boiler body 10 and the other end 30b is the suction pipe 17 through the branch member 40. Communicating with Thus, some of the steam generated in the flow section 14 of the boiler body 10 flows through one end (30a) of the steam discharge pipe 30 and then the inner wall or steam discharge pipe of the steam discharge pipe 30 ( 30 is reduced to water again in contact with the water filled in a predetermined height, through the other end (30b) of the steam discharge pipe 30, respectively through the branch member 40 and the suction pipe (17) again the boiler body (10) To the heating section 13).

Therefore, the boiler body 10 having a certain size or volume is to be released from the minimum risk that can be exploded by the heating pressure heated by the heating member (24).

Of course, as shown, if the safety valve 32 is provided on one side of the steam discharge pipe 30 will have an advantage that can be used more safely. The safety valve 32 operates by, for example, a pressure of 3 Kg, and serves to take out the internal pressure to the outside.

The discharge pipe 16 and the suction pipe 17 are not necessarily opposed to each other, as shown in Figs. Thus, as shown in Figure 5, it may be integrally disposed on one side of the boiler body (20).

At this time, the position of the discharge pipe 16, as shown in Figures 2 to 4, it is advantageous that the outer lower end of the boiler body 10, even if located on the upper side or the upper end of the boiler body 10. Irrelevant Alternatively, the intermediate partition 12 corresponding to the flow section 14 may be provided above the adjacent. As such, if the discharge pipe 16 is provided in the area of the adjacent upper flow section 14 of the intermediate partition 12, there is an advantage that can form a water circulation structure even if the water in the flow section 14 is not completely filled have.

The suction pipe 17 and the discharge pipe 16 communicate with the heating pipe 22. The heating pipe 22 (see FIG. 1) is embedded in the predetermined mounting surface 20 to heat the mounting surface 20 by the heat of hot water flowing therein, and both ends 22a and 22b of the suction pipe 17 are connected to each other. And are respectively coupled to the heating pipe 22. Although not shown, both ends 22a and 22b of the suction pipe 17, the discharge pipe 16, and the heating pipe 22 may be coupled and released by nipples, elbows, unions, or the like.

In this case, as shown in FIG. 1, the heating pipes 22 may be spaced apart so that their ends 22a and 22b are opposed to each other to form a zigzag shape forming a unidirectional circulation structure of water, as shown in FIG. 5. The heating pipe 122 may employ a return circulation structure of water such that both ends 122a and 122b are disposed adjacent to each other so that water is circulated throughout the installation surface 20a and then returned again. If the heating pipe 122 has the structure as shown in FIG. 5, the installation surface 20a can be warmed evenly throughout without a hot or cold area in the installation surface 20a.

At this time, the installation surface 20 on which the heating pipe 22 is installed may be a living room or a floor of a building or a house, as shown in FIG. 1. However, as shown in Fig. 5, the mounting surface 20a may be a portable mat. In this case, the boiler according to the present invention is portable and may be installed anywhere. On the other hand, as shown in Figure 5, if the mounting surface 20a becomes a portable mat, the heating pipe 122 embedded in the mounting surface 20a is not a copper tube, for example by forming a flexible material such as urethane It would be advantageous to be able to carry it into a backpack or pack by nesting it with the installation surface 20a.

The operation of the boiler having such a configuration will be described as follows.

When the heating member 24 is operated by the operation of the power switch 11 to start heating the room temperature water in the heating section 13, the hot water heated in the heating section 13 naturally floats and connects the connection pipe 15. It is directed through the upper flow section 14 of the intermediate partition 12.

At this time, the heating section 13 is heated to generate an empty space as much as the amount of hot water to the flow section 14 through the connecting pipe 15. In this space, the room temperature water in the heating pipe 22 naturally moves and is filled, and again, the room temperature in the heating section 13 is filled with the room temperature water next to it.

Through this process, the hot water in the heating pipe 22 naturally forms a circulation flow path flowing through the suction pipe 17, so that the heated hot water in the flow section 14 is naturally heated through the discharge pipe 16. You will be directed to. That is, the circulation passage of water continuously forms the waste circulation passages of the heating section 13, the connection pipe 15, the flow section 14, the discharge pipe 16, the heating pipe 22 and the suction pipe 17. Therefore, the boiler of the present invention does not require a circulation pump as in the prior art and can achieve a natural circulation of water.

During this circulation process, if a constant pressure acts on the boiler body 10, the vapor evaporated in the flow section 14 of the boiler body 10 flows through one end 30a of the steam discharge pipe 30. Through the other end (30b), respectively through the branch member 40 and the suction pipe 17 is directed to the heating section 13 of the boiler body (10).

Therefore, the boiler body 10 having a certain size or volume is to be released from the minimum risk that can be exploded by the heating pressure heated by the heating member (24).

As described above, according to the present invention, the hot water formed in the boiler body 10 is circulated to the heating pipe 22 embedded in the installation surface without using a circulation pump, but there is an effect that can be safely used without escape from the explosion risk. And, if the mounting surface 20a is made of a portable mat (see reference numeral 20a in Fig. 5), it is portable and can be installed anywhere.

6 and 7 are perspective views and cross-sectional views of the boiler according to the fifth embodiment of the present invention, respectively. The boiler (powerless forced circulation device) of FIG. 6 was also filed last time by the present applicant, and this technique can also add the spirit of the present invention.

6 and 7, briefly described, the boiler (powerless forced circulation device) according to the fifth embodiment of the present invention, the boiler body 210, and the heating member 220 is partially accommodated disposed in the boiler body 210 Consists of

The interior of the boiler body 210 is completely airtight from the outside. The lower end of the boiler body 210 is provided with a discharge pipe 212 for discharging water. The discharge pipe 212 is discharged to the hot water circulation pipe 234 of the hot water mat 330 when the inside of the boiler body 210 is filled with hot hot water by the heating member 220 to be described later in detail. Of course, the discharge of hot water is by the non-powered method by the thermal energy.

On the upper part of the boiler body 210, first, a water input part 214 for introducing water into the boiler body 210 is formed. In the case of boilers heated by hot water in general, when water is scarce, water should be continuously replenished, but the boiler of the present invention shows that the term of water replenishment is much longer than that of other boilers. There is an advantage.

A heating member 220 is disposed in the lower region of the boiler body 210 to extend in the horizontal direction and the end thereof is disposed to expose a predetermined length to the side of the boiler body 210. The heating member 220 may be employed one or more depending on the size of the boiler body 10, in the present embodiment will be applied to a single heating member 220 for convenience of description.

The heating member 220, the inner body is disposed in the lower region in the boiler body 210 in the horizontal direction, the hollow body portion 222, the heater interposed in the body portion 222 by a predetermined power supply to generate heat 224, one end is exposed to the lower end of the boiler body 210 and the other end is in communication with the body portion 222 and the suction pipe 226 for introducing water into the body portion 222, one end body portion 222 The other end is in communication with the other end is disposed in the upper region in the boiler body 210, the delivery pipe for delivering the water (hot water) heated by the heater 224 in the body portion 222 into the boiler body 210 without power ( 228).

As the end of the suction pipe 226 is enlarged separately, the suction pipe 226 and the body 222 are welded to each other in a state in which the end of the suction pipe 226 is embedded to extend a predetermined length into the body 222 of the heating member 220. It is advantageous to be (W).

The delivery pipe 228 has an extension part 228a extending upward from the heating member 220 and a bend part 228b bent in at least one direction at the upper end of the extension part 228a. If the delivery pipe 228 is formed as a straight pipe, hot water may not be discharged well through the delivery pipe 228 by hydraulic pressure. Therefore, in this embodiment, the bent portion 228b is formed at the end of the delivery pipe 228 so that the hot water heated in the heating member 220 can be easily taken out.

The suction pipe 226 is actually in communication with the other end 234b of the hot water circulation pipe 234 of the hot water mat 230. As a result, both ends 234a and 234b of the hot water circulation pipe 234 provided in the hot water mat 230 communicate with the discharge pipe 212 of the boiler body 210 and the suction pipe 226 of the heating member 220. .

On the other hand, it is irrelevant even if used as above, but the boiler body 210 having a certain size or volume as a means for escaping from the minimum risk that can be exploded by the heating pressure heated by the heating member 220 as follows: Adding more

That is, a separate branch member 240, also called a T-shaped pipe or a union, is coupled to the suction pipe 226. A steam exhaust pipe 230 is provided between the branch member 240 and the boiler body 210.

As shown, the steam discharge pipe 230, one end 230a is in communication with the upper portion of the boiler body 210 and the other end 230b is in communication with the suction pipe 226 through the branch member 240. Accordingly, the water vapor evaporated in the boiler body 210 flows through one end 230a of the steam discharge pipe 230 and then through the other end 230b, respectively, through the branch member 240 and the suction pipe 226. It is directed to the inside of the heating member 220 again.

Therefore, the boiler body 210 having a certain size or volume may be released from the minimum risk of explosion by a predetermined heating pressure.

8A to 8C are perspective views, respectively, of the boiler according to the sixth embodiment of the present invention, viewed from different angles.

As shown in these figures, the boiler according to the sixth embodiment of the present invention, the heating tank (310a, 310b), the water replenishment tank 320 provided on the heating tank (310a, 310b), and the heating tank It has a connection pipe (327a, 327b) for connecting (310a, 310b) and the water replenishment tank (320).

Heating tanks 310a and 310b have the same structure and function as the heating member 220 described above, and heater mounting portions 314a for mounting a heating member (not shown) for heating water in the heating tanks 310a and 310b. 314b). The heating tanks 310a and 310b may be formed of one tank or two tanks as shown in the drawing.

If the heating tank is formed of one tank, the boiler according to the sixth embodiment will have a hot water circulation structure of one cycle. However, two hot water cycles may be formed if the heating tanks 310a and 310b are composed of two tanks, and each of the heating tanks 310a and 310b is independently circulated separately. In this case, even one mat can be independently heated to two different temperature bands, so users who enjoy different temperatures must be more convenient to use.

A plurality of suction pipes 312a and 312b are formed outside the respective heating tanks 310a and 310b, and the plurality of discharge pipes 328a branched from the connection pipes 327a and 327b to the connection pipes 327a and 327b. 328b).

Accordingly, the water heated by the heating member in the heating tanks 310a and 310b moves upward along the connection pipes 327a and 327b. While moving, hot water is discharged through the discharge pipes 328a and 328b formed in the connection pipes 327a and 327b to heat the installation surface 20 of FIG. 1 or the installation surface 20a of the mat of FIG. 5. Then, the suction pipes are again sucked into the heating tanks 310a and 310b through the suction pipes 312a and 312b.

As a result, the discharge pipes 328a and 328b and the suction pipes 312a and 312b are formed as a single pipe, as described above to form the hot water circulation cycle. You may. However, when the exhaust pipes 328a and 328b and the suction pipes 312a and 312b are formed by a single pipe, the installation distance 20 or 20a may not be heated to a desired temperature because the heading distance for moving the hot water becomes long. have.

Thus, in the present embodiment, two discharge pipes 328a and 328b and two suction pipes 312a and 312b are formed so as to form independent hot water circulation cycles, thereby reducing the moving head distance of hot water. The sides 20 and 20a are to be heated. Therefore, if the area of the installation surface (20, 20a) is much larger, the discharge pipe (328a, 328b) and the suction pipe (312a, 312b) may be three or more respectively to form an independent hot water circulation cycle.

On the other hand, it is connected to the heating tank (310a, 310b) by the connection pipes (327a, 327b), the main function of the water replenishment tank 320 located on the upper portion of the heating tank (310a, 310b) is to replenish water. That is, since hot water circulates into the heating tanks 310a and 310b, the connection pipes 327a and 327b, the discharge pipes 328a and 328b and the suction pipes 312a and 312b, the hot water is actually supplied to the water replenishment tank 320. It does not go. However, the water replenishment tank 320 is provided as a means for replenishing water lost during circulation of hot water. Of course, when the circulation of the hot water is continuously performed, the water in the water replenishment tank 320 is naturally conducted to increase the temperature.

The water replenishment part 321 is formed at the side of the water replenishment tank 320. Water replenishment portion 321 may be formed on the top of the water replenishment tank 320, but in the embodiment of the ball replenishment to the side of the water replenishment tank 320 as a way to offset the pressure in the water replenishment tank 320 The part 321 is formed.

The lower portion of the water replenishment 321 is provided with a sensor mounting portion 323 for mounting the low water level blocking sensor. The low water level cutoff sensor mounted on the sensor mounting part 323 serves to turn off the heating member when the water level in the water refill tank 320 is low.

On the other hand, as in the above-described embodiments, the suction pipes 312a and 312b are coupled to separate branch members 340a and 340b, also called T-shaped pipes or unions. Further, steam discharge pipes 330a and 330b are provided between the branch members 340a and 340b and the water replenishment tank 320.

As illustrated, the steam discharge pipes 330a and 330b have one end communicating with the water refill tank 320 and the other end communicating with the suction pipes 312a and 312b through the branch members 340a and 340b. Therefore, as described above, the heating tanks 310a and 310b having a predetermined size or volume may be released from the minimum risk of explosion by the heating pressure heated by the heating member.

In the drawing is formed on the top of the water refill tank 320 is a safety valve installation portion 325 for the installation of a safety valve (not shown). For reference, in the sixth embodiment, the additional branch members 340a and 340b are further provided on the suction pipes 312a and 312b, and the steam discharge pipes 330a and 330b are connected to the branch members 340a and 340b. However, if there are no branching members 340a and 340b, the steam discharge pipes 330a and 330b may be directly connected to the suction pipes 312a and 312b.

Although the present invention has been described in detail with reference to the drawings, the present invention is not limited thereto.

As filed by the applicant, the number of the heating member, the suction pipe and the discharge pipe in Figures 6 and 7 may be two or more.

In addition to the above-described embodiment, a separate inner wall may be used to divide an inner space of one heating tank into two spaces, and hot water in each space may be independently circulated using an exhaust pipe and a suction pipe. As such, when one inner space of the heating tank is formed into two spaces, a heating member may be provided in each space or the heating member may be mounted only in one space. If the heating element is provided only in one space, the water in the other space is heated by indirect heat and is converted into hot water. Therefore, it is not only effective to use hot water, but also shorten the distance of hot water and reduce noise during boiler operation. There is an advantage that the efficiency is increased. Of course, two or more inner walls may be used to divide the space in one heating tank into three or more spaces.

As described above, according to the present invention, there is provided a non-powered hot water forced circulation system that circulates hot water formed in the boiler body to a heating pipe embedded in an installation surface without using a circulation pump, so that it can be used more safely without the risk of explosion.

In addition, according to the present invention, there is provided a non-powered hot water forced circulation device that can be used even where no power consumption is required, and is portable and can be installed anywhere.

Claims (9)

A heating section for generating steam by heating water at the lower end, a connecting pipe for ejecting steam generated from the heating section upwards, and steam ejected from the connecting pipe is converted into hot water and divided into a heating section to be formed at the top. Boiler body having a flow section that is; A suction pipe for supplying water for steam generation to the heating section; A steam discharge pipe formed at an outer side of the boiler body and connected to a suction pipe for supplying water to an upper end of the flow section and a heating section, and for maintaining a steam pressure in the flow section at a predetermined level; A discharge pipe discharging hot water generated by steam in the flow section for heating; A heating pipe having one end communicating with the discharge pipe and embedded in a predetermined installation surface to heat the installation surface and having one end connected to the suction pipe to circulate hot water; A branch member connected to the suction pipe and the steam discharge pipe to introduce water circulated through the heating pipe or water cooled from the steam discharge pipe into the heating section; The non-powered hot water forced circulation device, characterized in that it is connected to one side of the steam discharge pipe and includes a safety valve for discharging the steam pressure to the outside when the steam pressure generated in the flow section exceeds the processing by the steam discharge pipe. A boiler body having at least one discharge pipe for discharging heated water on one side thereof and having an airtight inside; A body portion accommodated in at least a portion of the interior of the boiler body, a heater interposed in the body portion to generate heat, and one end of which is exposed to the outside of the boiler body and the other end communicates with the body portion to supply water into the body portion. At least one suction pipe to be introduced, and at least one of the one end is in communication with the body portion and the other end is disposed in the boiler body to deliver the water heated by the heater in the body portion to the boiler body without power. A heating member having a tube; A branch member coupled to the suction pipe; A vapor discharge pipe having one end communicating with the boiler body and the other end communicating with the suction pipe and circulating water vapor evaporated in the flow section into the heating member through the branch member and the suction pipe; And a safety valve for discharging the steam pressure to the outside when the steam pressure generated in the flow section is connected to one side of the steam discharge pipe and is over processed by the steam discharge pipe. delete A heating tank having at least one heating member mounted therein; A water replenishment tank provided at an upper portion of the heating tank; A connection pipe connecting the heating tank and the water refill tank; A discharge pipe branched from the connection pipe to discharge hot water heated in the heating tank; And a suction pipe communicating with the heating tank, the suction pipe being discharged through the discharge pipe and sucking hot water heated to a predetermined installation surface. The method of claim 4, wherein One end of the non-powered hot water circulation system further comprises a steam discharge pipe in communication with the water refill tank and the other end in communication with the suction pipe. The method according to claim 4 or 5, The heating tank is a non-powered hot water circulation system, characterized in that separated into one or more. The method of claim 6, Non-powered hot water forced circulation device, characterized in that the connection pipe, the discharge pipe, the suction pipe and the steam discharge pipe attached to one heating tank is arranged in one or more than one. The method according to claim 4 or 5, At least one of the upper side and the side of the water refill tank is a non-powered hot water forced circulation device, characterized in that the water replenishment is formed. The method according to claim 4 or 5, The water refill tank is a non-powered hot water circulation system characterized in that the sensor mounting portion for mounting the low water level cutoff sensor is provided.

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