KR20100119211A - Heat storage tank with a continuous bended pipe and integrated heat storage tank for hot water and heater - Google Patents

Abstract

The present invention relates to a heat storage tank, characterized in that formed to form a closed space therein by bending a hollow pipe (bending). In addition, the heat storage tank and the integrated heat storage tank is integrated with the hot water storage tank.

Description

Heat storage tank with a continuous bended pipe and integrated heat storage tank for hot water and heater}

The present invention relates to a heat storage tank, and more particularly, to a heat storage tank in which a heat pipe is formed by bending a hollow pipe to form a heat storage tank while supplying a heat medium inside the hollow pipe to heat exchange the heat storage tank and a hot water heat storage tank.

Such a conventional heat storage tank is shown in FIGS. 1A to 1C.

As shown in FIG. 1A, a heat storage coil 11 is installed in a conventional heat storage tank 10.

Therefore, the heat storage tank 10 has the advantage that the water stored therein is directly heated by the heat exchange coil 11, but there is a disadvantage that a considerable amount of heat exchange coil 11 must be inserted in order to secure a sufficient heat exchange area. .

In addition, since the heat exchange coil 11 is in direct contact with the water in the heat storage tank 10, a scale is attached to the heat exchange coil 11 to reduce the heat exchange efficiency.

In particular, when the heat exchange coil 11 is corroded and damaged, the heat medium flowing inside the heat exchange coil 11 is mixed with water in the heat storage tank 10 and mixed.

The heat storage tank 10 to improve this disadvantage is installed separately by separating the heat storage tank 10 and the heat exchanger 12, as shown in Figure 1b.

As such, the heat exchanger 12 is separately installed from the heat storage tank 10, so that the disadvantages of the heat storage tank 10 of the above-mentioned example can be compensated for, and the heat exchange efficiency can be increased. However, the heat exchanger 12 is separated from the heat storage tank 10. Due to the installation, not only a large installation area is required but also an installation cost is increased and the installation work is cumbersome.

In addition, the heat medium flowing between the spaced heat exchanger 12 and the heat storage tank 10 generates heat loss as much as the distance between the heat exchanger 12 and the heat storage tank 10, so that the heat exchange efficiency is expected to be improved. There was a hard disadvantage. In addition, a separate pipe connecting the spaced heat exchanger 12 and the heat storage tank 10 to each other and a circulation pump capable of flowing the heat medium therebetween are required.

On the other hand, in order to overcome the above disadvantages, the applicant has developed a dual jacket type heat storage tank 20, such as the registered Utility Model Publication No. 20-0336272 and Registration Utility Model Publication No. 20-0435845, shown in Figure 1c.

As shown in FIG. 1C, the heat storage tank 20 is formed of an inner tube and an outer space that are spaced apart from each other, and forms a spiral flow path by installing a spiral plate between the inner tube and the outer tube.

Such a double jacketed heat storage tank 20 does not require a conventional heat exchange coil 11 or a separate heat exchanger 12 by heating the heat storage tank 20 while the heat medium flows along the spiral flow path between the inner tube and the exterior.

Therefore, not only the disadvantages of the heat storage tank 20 as described above can be compensated, but heat exchange efficiency can be maximized.

However, such a double jacketed heat storage tank 20 has to form a spiral flow path between the inner tube and the exterior, which not only complicates the work process but also lowers workability and productivity and has a high manufacturing cost.

In addition, the heat storage tank and the hot water storage tank are installed separately so far, there are disadvantages such as an increase in manufacturing cost, an increase in the installation area, and an increase in the number of piping parts. In order to solve this problem, the two-layer structure, that is, the heating heat storage tank and the hot water heat storage tank are integrally formed.

Accordingly, the present invention has been made to solve the problems of the prior art as described above, by bending the hollow pipe several times to form a heat storage tank and supply the heat medium therein, as well as high heat exchange efficiency The purpose is to provide a heat storage tank that can be expected.

In addition, another object is to provide a heat storage tank in which a heating heat storage tank and a hot water heat storage tank are integrally formed.

The above object is achieved by a heat storage tank, which is formed to bend a hollow pipe to form a closed space therein.

In addition, the hollow pipe is formed by continuous bending in a helical shape, the heat radiation fins or protrusions are formed in the hollow pipe, the welding portion is formed in the contact portion between the bent hollow pipe.

In addition, a partition wall for partitioning an inner space may be provided in the heat storage tank formed by the bent hollow pipe, and the space inside the heat storage tank may be used as an integral part of the heat storage heat storage unit and the hot water heat storage unit.

According to the heat storage tank of the present invention, the hollow pipe is bent in a spiral shape to form a heat storage tank, the heat storage tank can be easily produced, and by supplying a heat medium to the inside of the bent hollow pipe constituting the heat storage tank, the effect of high heat exchange efficiency can be expected. There is.

In addition, the present invention provides a heat storage tank in which a heating heat storage tank and a hot water heat storage tank are integrated, and has a heat storage tank having two functions in one heat storage tank in comparison with the manufacturing cost, installation area, and the number of piping parts required for a heat storage tank having two heat storage tanks. Since it is integrated, the manufacturing cost can be lowered, the installation area can be reduced by half, and the piping for connecting the two heat storage tanks is not necessary separately.

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

2 to 5 are views showing a heat storage tank according to each embodiment of the present invention.

As shown in FIGS. 2 and 3, the heat storage tank 100 of the present invention is formed by continuously bending the hollow pipe 110 in a spiral shape, and the interior of the heat storage tank 100 forms a closed space.

In this case, the bent hollow pipe 110 is bent in a flexible state by applying heat, and after bending, heat treatment is performed using cooling water or the like to obtain mechanical properties and characteristics required in the heat storage tank 100. Can be.

In addition, both ends of the bent hollow pipe 110 are protruded as the inlet pipe 111 and the outlet pipe 112, respectively, and are connected to the collector 200, and the collector 200 may be implemented in various forms. However, in order to save energy, it is preferable to use a collector that collects solar heat. Therefore, the hot heat medium heated in the collector 200 flows through the inlet pipe 111 and flows along the hollow pipe 110, and then is re-introduced into the collector 200 through the outlet pipe 112 on the opposite side. Circulated.

In addition, the hollow pipes 110 continuously bent in a spiral are stacked to form a heat storage tank 100. The upper and lower contact portions of the bent hollow pipe 110 leak water stored in the heat storage tank 100. Welded to prevent and withstand internal pressure. In addition, the welding part 113 is preferably formed in both the inner and outer surface contact portion of the heat storage tank 100, but may be formed only in the outer surface contact portion of the heat storage tank 100 as shown in FIG.

In addition, the hollow pipe 110 forming the heat storage tank 100 is formed with a heat dissipation fin 114 or a protrusion for increasing heat exchange efficiency, but the heat dissipation fin 114 is water and the hollow pipe 110 inside the heat storage tank 100. Since it is to improve the heat exchange efficiency between the heat medium flowing inside it is preferably formed only on the hollow pipe 110 side forming the inner surface of the heat storage tank (100).

Meanwhile, the hollow pipe 110 forming the heat storage tank 100 is preferably formed of a pipe having a circular cross section as shown in FIG. 3 or a pipe having a square cross section as shown in FIG. 4, but the hollow pipe 110 described above is It is not necessarily limited to pipes of circular or rectangular cross section.

In the heat storage tank 100 formed as described above, a separate inlet pipe (not shown) and an outlet pipe (not shown) for circulating water in the heat storage tank 100 are maintained in a watertight state. It is preferable to penetrate through.

The heat storage tank 100 configured as described above is capable of easily manufacturing the heat storage tank 100 by forming a heat storage tank 100 by continuously bending the hollow pipe 110 in a spiral shape and filling water in the heat storage tank 100. Even if stored, the welded portion 113 formed between the laminated hollow pipes 110 allows the water to be stored firmly without leaking. In addition, since the hollow pipe 110 serves as a strong skeleton in the structure of the heat storage tank 100, the hollow pipe 110 has a pressure resistance that can withstand the high pressure of the heat storage tank compared to the conventional heat storage tank.

Meanwhile, the high-temperature heat medium discharged from the collector 200 flows into the inlet pipe 111 of the hollow pipe 110 forming the heat storage tank 100 and flows along the bent hollow pipe 110 while the hollow pipe ( 110 is heated, and the heat medium cooled by heat exchange is introduced into the collector 200 again through the outlet pipe 112 of the hollow pipe 110 and reheated, and then again introduced into the hollow pipe 110 as described above. Circulated.

At this time, the heat medium of the high temperature to heat the heat storage tank 100 while flowing the hollow pipe 110 to increase the temperature of the water stored in the heat storage tank 100, this heat exchange action is a heat radiation fin 114 protruding in the hollow pipe (110) By making it faster, heat exchange efficiency is maximized. Since the high-temperature fluid of the heat collector 200 is first heat-exchanged in the lid portion of the heat storage tank, when the bending form of the lid portion of the heat storage tank 100 is formed in the snail-shaped flow path, higher thermal efficiency can be obtained.

On the other hand, the heat storage tank 100 formed as described above, as shown in Figure 5, may form a partition wall 120 for partitioning the interior space up and down. In this way, the inner space of the heat storage tank 100 isolated up and down by the partition wall 120 is used as the heat storage heat storage unit 130 and the hot water heat storage unit 140, respectively.

Of course, even in this case, the inlet pipe (not shown) and the outlet pipe (not shown) that can circulate the heating water and the hot water, respectively, in the heat storage heat storage unit 130 and the hot water heat storage unit 140 are respectively maintained in a watertight state. It is installed through the bent hollow pipe (110).

In another embodiment, the applicant is heating a single heat storage tank by installing a partition wall 120 in the middle as shown in Figure 6 the double-jacket heat storage tank having a spiral flow path described in Korean Utility Model Publication No. 20-0336272 The contraction heat unit 130 and the hot water heat storage unit 140 are integrated. In addition, in the double jacket type heat storage tank 20 as shown in Registration Utility Model Publication No. 20-0435845 shown in Fig. 1C, a partition wall is provided in the same manner as the method shown in Fig. 5 to provide a heat storage heat storage unit and a hot water heat storage unit. It can be installed in one heat storage tank.

Accordingly, the inner space of one heat storage tank 100 is integrally formed with the heating water heat storage unit 130 and the hot water heat storage unit 140, while the heating water and hot water stored in each heat storage unit 130 and 140 are hollow pipe 110. Since the heating is sequentially carried out by the high temperature heat medium passing through), not only the efficiency of the heat storage tank 100 is improved, but also the manufacturing process is simplified, and parts and manufacturing costs are reduced, and the installation space is very efficient.

1 is a configuration diagram showing a conventional heat storage tank, FIG. 1A is a heat storage tank in which a heat exchange coil is incorporated, FIG. 1B is a heat storage tank in which a heat exchanger is separated, and FIG. 1C is a double jacket type heat storage tank.

2 is a block diagram of a heat storage tank according to an embodiment of the present invention.

3 is a cross-sectional view of a heat storage tank according to an embodiment of the present invention.

4 is a cross-sectional configuration diagram of a heat storage tank according to another embodiment of the present invention.

5 is a cross-sectional configuration diagram of a heat storage tank according to another embodiment of the present invention.

6 is a configuration diagram in which a partition wall is provided in a double-kake type heat storage tank having a spiral flow path.

<Description of the symbols for the main parts of the drawings>

10,20: heat storage tank 11: heat exchange coil

12: heat exchanger 100: heat storage tank

110: hollow pipe 111: inlet pipe

112 outlet pipe 113 welded portion

114: heat dissipation fin 120: partition wall

130: heating heat storage unit 140: hot water storage unit

200: collector

Claims (8)

The heat storage tank, characterized in that formed to form a closed space therein by bending the hollow pipe (bending). The method of claim 1, The heat pipe is characterized in that the hollow pipe is formed by continuous bending in a spiral. The method of claim 1, The heat storage tank, characterized in that the hollow pipe is formed with a heat radiation fin or a protrusion protruding. The method of claim 1, Heat storage tank, characterized in that the welding portion is formed in the contact portion between the bent hollow pipe. The heat storage tank according to claim 1, wherein a cross section of the pipe is circular or square, or other hollow. The heat storage tank according to claim 1, wherein the flow path of the lid portion of the heat storage tank (100) is in the form of a snail. Integrating a heating heat storage tank and a hot water storage tank, characterized in that a partition wall for partitioning an internal space into a heating heat storage tank and a hot water storage tank is provided inside the heat storage tank formed by the bent hollow pipe according to any one of claims 1 to 6. Heat storage tank. A double jacket heat storage tank comprising a partition wall for partitioning an inner space into a heating heat storage tank and a hot water storage tank in a double jacket tank.

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