KR0154377B1 - Heat exchange apparatus for boiler - Google Patents

Abstract

The present invention relates to an assembled hot water supply heat exchanger of a boiler, which has an adequate amount of hot water tapping capacity even in a low water pressure area, and is improved by a series and parallel pipeline structure so that heat exchange capacity and circulation capacity are excellent. A plurality of formed protrusions (2, 2 ') are symmetrically distributed and two heating passages (3, 3') and hot water supply passages (4, 4 ') of the corresponding position are formed at 90 degrees apart The heat exchange plate (1) is provided, the plurality of stainless heat exchange plate (1) of the assembled hot water supply heat exchanger of the boiler, characterized in that laminated in a parallel parallel pipeline structure.

Description

Assembly hot water supply heat exchanger of boiler

1 is a perspective view showing a heat exchange plate of a hot water heat exchanger according to an embodiment of the present invention.

FIG. 2 is an assembly diagram of a hot water supply heat exchanger in which the heat exchange plates shown in FIG. 1 are sequentially arranged. FIG.

3 is a flow chart illustrating the hot water supply heat exchanger of the present invention.

* Explanation of symbols for main parts of the drawings

1: Heat exchanger plate 2,2 ': Protrusion shape

3,3 ': Heating passage 4,4': Hot water passage

5: upper heat exchanger plate 6: lower heat exchanger plate

7-14: Heat Exchanger Plate

The present invention relates to an assembled hot water supply heat exchanger of a boiler, which has an appropriate amount of hot water tapping capacity even in a low water pressure area, and is improved in a series and parallel pipeline structure so that heat exchange capacity and circulation capacity are excellent. The present invention relates to a hot water supply heat exchanger capable of reducing pipe resistance in proportion to longevity by stacking two stainless steel heat exchanger plates having two hot water flow passages and heating passages in a parallel parallel pipeline structure.

As the times evolve and society becomes more complex, the attention of residential environment is also multiplying to satisfy human needs. In areas where the four seasons are evident in the residential life, it is used to install a boiler using oil or gas in an appropriate place to keep the inner space comfortable and warm in winter and the hot water when the indoor and outdoor temperature drops.

For example, corresponding boilers installed in single-family houses and apartments are classified into briquettes, oil, gas, and electric boilers according to the fuel used, and are developed and used in various forms to suit installation purposes and water level.

Gas boilers of various types of boilers developed in this way are designed to ignite gas supplied through gas supply pipe through main burner and pilot burner by ignition transformer. A water tank or hot water circulation pump is installed.

The conventional plate-type heat exchanger has a series of pipe structures in which heat exchange plates are stacked and variously determine the capacity according to the stacked quantity, while the hot water supply and heating water are supplied to each other to exchange heat. The performance can be achieved regardless of the installation type.

In the heat exchanger as described above, the flow path is formed in a series pipe in proportion to the number of heat exchange plates, and thus the pipe resistance is severely increased, so that the heat transfer efficiency is very low. Therefore, in the conventional hot water supply heat exchanger, since the hot water supply passage and the heating passage of the heat exchange plate are stacked in series, the amount of circulation water is inevitably reduced at the same head, resulting in a problem that the pipe resistance increases in direct proportion to the longevity of the heat exchange plate. It became.

Accordingly, the present invention has been invented to solve the above-mentioned drawbacks. In the conventional series pipeline structure, a series of parallel pipeline structures, that is, a plurality of stainless heat exchangers having a plurality of symmetrical protrusions, two hot water passages, and heating passages, are formed. By stacking the plates in a parallel parallel pipe structure, the pipe resistance can be reduced in proportion to the longevity of the heat exchanger plate. It is an object of the present invention to provide an assembly hot water supply heat exchanger of a boiler.

The assembled hot water supply heat exchange apparatus of the present invention for achieving the above object is a plurality of protrusions (2,2 ') formed as stainless steel are distributed evenly symmetrically and two heating passages (3,3') of the corresponding position And the hot water supply passages 4 and 4 'are provided as heat exchange plates 1 formed at 90 ° apart, respectively, and the plurality of stainless heat exchange plates 1 are stacked in a parallel parallel pipe structure. .

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

1 is a perspective view showing a heat exchange plate of a hot water supply heat exchanger according to an embodiment of the present invention, wherein the assembled hot water supply heat exchanger of the boiler of the present invention includes two hot water supply passages 4 and 4 'and a heating passage 3, By stacking a plurality of stainless steel heat exchanger plate 1 having a 3 ') in a series-parallel pipeline structure, it is possible to reduce the pipeline resistance in proportion to the longevity of the heat exchanger plate 1.

The heat exchange plate 1 has a plurality of protruding shapes (2, 2 ') formed as stainless steel symmetrically distributed and two heating passages (3, 3') and a hot water supply passage (4, 4 ') at corresponding positions. Are formed at different angles, respectively. The protruding shapes 2, 2 'are symmetrical through the central protruding shape 2 as the folds and the contacting portions, which are intersecting parts, so that the protruding shapes 2' are evenly distributed to have an assembly point as a whole.

FIG. 2 is an assembly diagram of a hot water supply heat exchanger in which the heat exchanger plates shown in FIG. 1 are arranged in sequence. FIG. 2A illustrates an upper heat exchanger plate using the heat exchanger plate 1 shown in FIG. 5) and the hot water heat exchanger of the present invention in which a plurality of heat exchanger plates 7-14 are stacked in a series-parallel pipeline structure between the lower heat exchanger plate 6 and two heating passages 3, 3 ') and hot water supply passages (4,4') are changed by 90 ° so that the hot water and the hot water, which are the hot water and the hot water, cross between the diaphragms, resulting in excellent heat exchange and circulation capability.

The corrugations formed on the heat exchange plates 5, 7-14, and 6 and the protruding shapes 2, 2 ', which are patterns of the contact portions, are to be exchanged with each other when stacked up and down, and between the upper and lower heat exchange plates 5 and 6, respectively. It can not only withstand the high pressure as a whole, but also semi-permanent durability of the projecting shape (2, 2 ') of the heat exchanger plate (7-14) is evenly distributed and evenly stacked in a parallel parallel pipe structure.

The heating passages 3, 3 'and the hot water supply passages 4, 4' of the heat exchange plates 5, 7-14, 6 are moved by 90 °, and the heat exchange plate 7- It is possible to maximize the heat transfer and reduce the pipe resistance by forming turbulence by the pattern of 14), so it can have the proper amount of hot water tapping capacity even in the low water pressure area.

Positions for the heating passages 3, 3 'and the hot water supply passages 4, 4' of the upper heat exchanger plate 5, and the heating passages 3, 3 'and the hot water supply passages 4, 4 of the lower heat exchanger plate 6; ') Is positioned 90 degrees apart, and the other heat exchanger plates 7-14 between the upper heat exchanger plate 5 and the lower heat exchanger plate 6 are provided with the heating passages 3 and 3' and the hot water supply passage 4). 4 ') are shifted to the right by 90 ° and laminated. The heat exchange plates 5, 7-14, and 6 have respective heating passages 3, 3 'and hot water supply passages 4, 4' 0 °, 90 °, 180 °, 270 °, 360 °, 0 °. The positions are moved in the order of 90 °, 180 °, 270 ° and 360 °.

In the hot water supply heat exchange apparatus of the present invention shown in FIG. 3, the cold water side and the boiler heating water alternately flow between the inner plates of the heat exchange plates 5, 7-14, and 6, and as shown in FIG. The heating water and the hot water flow smoothly through the heating passages (3,3 ') and the hot water supply passages (4,4') that are changed by 90 °.

Accordingly, the hot water supply heat exchanger of the present invention has a lower heat exchanger plate 6 in the heating passage 3 shown in FIG. 2 (b) through the heating inlet as a parallel parallel pipe structure as shown in FIG. The heat exchange plate 7-14 and the upper heat exchange plate 5 and the corresponding heat passages 3 and 3 'and the hot water supply passages 4 and 4', respectively. Corresponding heating passages (3,3 ') and hot water supply passages (4,4') of the other heat exchange plates (7-14) and the lower heat exchange plates (6) stacked with the upper heat exchange plate (5) in the hot water supply passage (4) through Flow through the hot water outlet to form turbulence by the uniformly distributed pattern of the protruding shape (2,2 ') to reduce the pipe resistance in proportion to the longevity of the heat exchange plates (5,7-14,6). have.

As described above, according to the present invention, in a conventional series pipeline structure, a series parallel pipeline structure, that is, a plurality of stainless heat exchanger plates having a plurality of symmetrical protruding shapes, two hot water supply passages, and heating passages, are connected in series and parallel lines. By stacking as a structure, the pipe resistance can be reduced in proportion to the longevity of the heat exchanger plate, so that the hot water tapping capacity can be adequately supplied even in a low water pressure region, and the hot water assembly and hot water circulation capacity of the boiler is excellent. A heat exchanger can be provided.

Claims (3)

A plurality of protruding shapes (2,2 ') formed as stainless are distributed symmetrically and the two heating passages (3,3') and the hot water supply passage (4,4 ') at the corresponding positions are separated by 90 degrees, respectively. It is provided with a heat exchange plate (1) to be formed, assembly hot water supply heat exchanger of the boiler, characterized in that the plurality of stainless heat exchange plate (1) laminated in a series parallel pipeline structure. The other heat exchanger plates 7-14 between the upper heat exchanger plate 5 and the lower heat exchanger plate 6 move the heating passages 3 and 3 'and the hot water supply passages 4 and 4' to the right by 90 degrees. The heat exchange plates (5,7-14,6) are laminated and assembled, and the heating passages (3,3 ') and the hot water passages (4,4') are respectively 0 °, 90 °, 180 °, 270 °, and 360 °. Assembly hot water supply heat exchanger of the boiler, characterized in that the position moves in the order, 0 °, 90 °, 180 °, 270 °, 360 °. 3. The heating passage (3) of the upper heat exchange plate (5) and the other heat exchange plate (7-14) laminated with the lower heat exchange plate (6) in the heating passage (3) through the heating inlet. 3 ') and hot water supply passages (4,4') are discharged to the heating return port, and the hot water is supplied to the heat exchange passage (4) through the hot water inlet to the other heat exchanger plate (7-14) laminated with the upper heat exchange plate (5-14) And hot water outlets through the corresponding heating passages (3,3 ') and hot water supply passages (4,4') of the lower heat exchange plate (6).