KR900005596Y1 - Indirect heating type hot-water heater - Google Patents

Abstract

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Description

Indirect Heating Heat Exchange Boiler

1 is a longitudinal cross-sectional view of the present invention,

2 is a side cross-sectional view of FIG.

3 is a partial plan view of FIG.

* Explanation of symbols for main parts of the drawings

1: boiler body 2: water chamber

3: first heat exchanger 4: sealed flange

5: cold water injection pipe 6: hot water outlet pipe

7: open flange 8; combustion chamber

9: 2nd heat exchanger 10,10 ': upper and lower connection

11: Shotgun Chamber

The present invention relates to an indirect heating type hot water boiler, and in particular, the heating unit is eccentrically installed on one side of the boiler body so that the primary heating water is naturally circulated inside the boiler body and heat exchanges with the secondary heating water to improve the thermal efficiency of the boiler. It relates to an indirect heating type heat exchange boiler.

Conventional heating boilers used in places such as bathhouses and lodging facilities are used to directly heat the water supplied to the boiler to make hot water supply, and then supply it directly to each place to be supplied with new cold water. In general, calcium carbonate (CaCo ₃ ), magnesium (Mg), and dissolved oxygen (O ₂ ) contained in the water supply are deposited inside the heat transfer pipe as it circulates in the boiler body and the heat transfer tube, and grows on a scale inside the tub. do. That is, since the new water supply must be continued, the components contained in the water supply are concentrated and scaled to increase the amount of attachment to the inside of the heat pipe.

Therefore, as the actual inner diameter of the heat pipe becomes narrower, not only does the circulation of the water supply not be smoothly performed, but also accelerates the corrosion of the heat pipe, which shortens the life of the boiler and also prevents the circulation of the water supply. It has several disadvantages such that its efficiency is relatively low.

In order to improve these shortcomings, various methods and apparatuses have been proposed to increase the thermal efficiency of the boiler and to prevent corrosion of the heat pipe. One of them is a boiler employing an indirect heating method.

In other words, the indirect heating boiler is always included in the boiler fuselage by the heat of the burner's flame and combustion gas, so that the heat exchanger is installed in a certain amount of primary heating water that is directly heated. The structure is made of secondary heated water.

However, in such an indirect heating boiler, the heated primary heating water is directly extracted and used, and is not continuously replenished, but the primary heating water is circulated in a constant state in the boiler body at all times, and the cold water for hot water flowing in the heat exchanger is circulated. Because it is to be heated indirectly, calcium carbonate, magnesium, etc. contained in the primary heated water are kept in a certain amount, so even if they are scaled, they become extremely small even in the scale, as in the conventional direct heating boiler. Corrosion shape and the like of the heat transfer pipe can be effectively prevented.

However, in such an indirect heating boiler, the primary heating water, which receives heat directly from the boiler body, is circulated appropriately according to the heating state inside the boiler body, and the heat is sufficiently transferred to the high temperature and the latent heat of the heated state. There is a problem in that the inside of the heat exchanger must be sufficiently delivered to the heated hot water for hot water supply, so that secondary hot water of high temperature can be obtained as a result.

Therefore, in the conventional indirect heating boiler, various means have been devised to properly circulate the primary heating water inside the boiler body. For example, the technique proposed in Utility Model Publication No. 81-60 is provided between the heat transfer part and the heat exchange part of the boiler body. In addition, the convection guide membrane was installed to allow the heated direct heating water to move along the convection guide membrane to achieve smooth convection. However, such a boiler is difficult to manufacture due to its structure and it is expensive to manufacture. In addition, when the boiler is installed, the inlet and outlet of the water supply pipe to the heat exchanger are fixed to only one side, which causes a problem of lengthening the pipe. Heat exchanger side to heat the differential heating water As the primary heated water is not completely induced and stagnated at the primary heated portion, the circulation cannot be performed, while the hot heated water in which part of the low-temperature direct heated water cooled by heat exchange in the heat exchanger is guided to the heat exchanger again. This resulted in a defect that the boiler's efficiency was lowered due to the fact that it could be kept at a low temperature around the heat exchanger and thus could not raise the temperature of the indirectly heated water to be used directly.

Therefore, the present invention was devised to solve the above-mentioned shortcomings, and the combustion chamber was installed eccentrically inside the boiler body, and the upper and lower relations were installed adjacent to the combustion chamber to one side to connect the flue to the heating part of the boiler. In the upper chamber of the combustion chamber inside the boiler fuselage, a first heat exchanger made of tubular bundles is installed in the longitudinal direction so that the heating unit and the first heat exchanger face each other radially in the boiler fuselage. An open flange is installed at one end and an open flange is installed at the other end, and an inlet and outlet pipe of cold and hot water is attached, and an arc-shaped second heat exchanger is additionally installed in the water chamber between the lower part of the first heat exchanger and the combustion chamber, so that the convective circulation of the direct heating water In addition to helping exercise, it also absorbs latent heat, The side wall of the inlet also has a structure that is formed with a shot chamber which bypasses the direct heating water inside the boiler to absorb the heat loss. Therefore, the natural convection circulation of the direct heating water is smoothly performed, and the heat transfer effect is increased, resulting in high temperature. It is an object of the present invention to provide an indirect heating type heat exchanger boiler capable of obtaining a hot water supply within a short time and making manufacturing and installation easier.

Hereinafter, the present invention will be described in detail based on the accompanying drawings.

In the present invention, a first heat exchanger (3) made of tubular bundles along the longitudinal direction of the body is installed at one upper portion of the water chamber (2) in the boiler body (1), and at one end of the first heat exchanger (3). An open flange 7 having a cold water injection pipe 5 and a hot water outlet pipe 6 is installed at the other end of the sealed flange 4, while between the first heat exchanger 3 and the combustion chamber 8. The second heat exchanger 9 of the arc shape made of a tube bundle is installed in the water chamber 2 of the tank, and the primary gas in the water chamber 2 is discharged while the exhaust gas which is combusted and exhausted from the combustion chamber 8 passes. The upper and lower pipes 10 and 10 'forming the heating part A for heating the hot water are arranged at a position opposite to the first heat exchanger 3 at a right angle, that is, at the lower corner of the water chamber 2. On the inlet side walls of the upper and lower secondary pipes 10 and 10 ', direct heating water inside the water chamber 2 is bypassed and discharged along the associated pipe 10 and 10'. It has a structure in which a cutting chamber 11 is formed so as to recover excess heat.

In the drawings, reference numeral 12 denotes a year, and 13 denotes a burner.

Next, the operation and effects of the present invention configured as described above will be described.

As shown in FIG. 1 and FIG. 2, the combustion operation of the burner 13 is started, and the flame and combustion gas which are generated flows along the combustion chamber 8, and the primary heating water filled in the water chamber 2 is filled. The first heating is followed by flowing into the lower pipe (10 ′) flowing secondly and then flowing into the upper pipe (10) and the third heating and then discharged through the flue (12). Therefore, the primary heating water, which is on the side of the heating unit A, in which the plumbing 10, 10 'of the chamber 2 is disposed, is heated to a higher temperature more quickly, and as a result, the synergistic force is obtained and the synergistic force is maintained. As a result, water heated to a high temperature on the heating part A side is naturally circulated clockwise in the water chamber 2.

Subsequently, when the high temperature direct heating water circulated in this way passes through the first heat exchanger 3 arranged in the symmetrical direction with the heating unit A, the cold water injection pipe 5 is discharged to the first heat exchanger 3. The introduced water (secondary heating water) is indirectly heated in a hot water by the circulating primary heating water and discharged through the hot water supply. In this case, the cold water injection pipe (5) and the hot water outlet pipe (6) side open flange (7) and the closed flange (4) when the boiler is installed in accordance with the conditions of the piping or the use space to be fastened to the piping work easily Not only that, but also the length of the pipe is shortened and the hot water can be pulled out in the required direction.

On the other hand, in the water chamber 2 between the first heat exchanger 3 and the combustion chamber 8, an arc-shaped second heat exchanger 9 is installed to form a heat exchange in the first heat exchanger 3 to direct down the water. It is also possible to further recover the latent heat from the second heat exchanger (9), and if the second heat exchanger (9) having an arc shape is additionally installed, the outside of the second heat exchanger (9) By directing the flow of the direct heated water along the surface there is also an effect that the circulation of the direct heated water can be promoted.

In addition, as described above, when the first heat exchanger 3 and the second heat exchanger 9 are respectively provided, two hot water supplies having different uses can be supplied, that is, a hot water supply or a hot water supply for a bath is more preferable. The heating for which the first heat exchange 3 for obtaining hot water supply and the low temperature hot water supply can be used makes it possible to use the second heat exchange 9 so that the heating and hot water for heating can be easily used.

And a certain amount of the direct heating water filled in the water chamber (2) is repeated circulating in the closed space inside the boiler and the heating and cooling action is repeated, so as to continuously supply a new water supply as in the direct heating boiler to be heated in the water Scale generation due to the concentration of the contained impurities is effectively prevented, so that problems such as corrosion and repair of the heat pipe can be significantly reduced.

Meanwhile, as illustrated in FIGS. 2 and 3, upper and lower pipes 10 and 10 ′ communicated with the combustion chamber 8 serve as a passage for discharging the combustion gas generated in the combustion chamber 8 to the flue 12. While heating the water in the water chamber (2) is installed in each of the two top and bottom in the water chamber (2) to increase the heat transfer efficiency, and the heat of combustion lost from the combustion chamber (8) toward the door (not shown) of the boiler body (1) In order to absorb the water, a cutting chamber 11 is formed at one side wall of the upper and lower pipes 10 and 10 'so as to communicate from the lower side to the upper side of the water chamber 2 so that a part of the direct heating water in the water chamber 2 is As part of the heat lost to the door of the tube 10, 10 'while passing through the cutting chamber 11 is recovered, the efficiency of the entire boiler can be increased.

In addition, since the pipes arranged in the first and second heat exchangers 3 and 9 are not curved U-shaped pipes but are straight pipes, there is an advantage in that cleaning can be easily performed during maintenance work.

As described above, according to the indirect heating type heat exchange boiler according to the present invention, the heating portion A and the first heat exchanger portion 3 are located at one corner of the upper and lower portions in the inner water chamber 2 of the boiler body 1, respectively. It is installed eccentrically to face in the radial direction, so that convective circulation of the primary heated water is performed smoothly, and thus high temperature indirect heated water can be obtained, and the hermetic flange 4 and the open flange (1) in the first heat exchanger (3). 7) are interchangeably attached to each other, so that the cold water and hot water can be changed in and out of the pipe, making the piping work easier, and the table chamber 11 is installed on the side walls of the upper and lower pipes 10 and 10 '. In addition, since the arc-shaped second heat exchanger 9 is installed to increase the heat recovery rate, heat transfer efficiency is increased, thereby preventing energy loss as much as possible.

Claims (2)

In an indirect heating type heat exchange boiler in which an internal chamber 2 of a boiler body 1 is provided with a combustion chamber 8 and an associative and heat exchanger are arranged in a water chamber 2 around the combustion chamber 8, respectively. At the bottom of the water chamber (2) where the primary heated water is heated, a heating unit (A) consisting of upper and lower pipes (10, 10 ') is arranged so as to be deflected to one side, and the heating unit (2) is located above the water chamber (2). An indirect heating type heat exchange boiler, characterized in that a first heat exchanger (3) which is heated while passing through a second heating water at a position opposite to V) is extended in the longitudinal direction of the boiler body (1). The indirect heating type heat exchange boiler according to claim 1, wherein an arc-shaped second heat exchanger (9) is arranged below the vertical portion of the first heat exchanger (3).