KR200218061Y1 - A regenerator for boiler - Google Patents

Abstract

The present invention installs at least one of the mutually alternating diaphragm inside the heat exchange tank so that the waste heat generated during the boiler's steam (or heating water) or boiler operation can be delayed as much as possible without vortexing in the heat exchanger. The present invention relates to a heat exchanger for a boiler that can significantly improve energy efficiency and reduce energy costs by smoothly performing heat exchange with cold water in a plurality of hot water coils installed in the

In particular, the present invention is provided with an inlet port 11 through which the heating water supplied from the boiler flows in at one end, and an outlet port 12 through which the heating water flowed into the inside is provided at one end portion thereof, A cylindrical heat exchange water tank (10) provided with alternating plates (13) alternately extending the dwelling time of the heating water at the same time and preventing eddy currents; The hot water coils 22 are respectively coupled to the flanges 14 at both ends of the heat exchange water tank 10, and a plurality of through-holes 21 are installed at the center thereof to face each other. Separating plate 20 and; An inlet cap 30 and an outlet cap 40 which are bolted to the outer side of the separating plate 20 and formed with an inlet 31 and an outlet 41 disposed on one side thereof; It is characterized by consisting of.

Description

Heat exchanger for boilers {A regenerator for boiler}

The present invention relates to a heat exchanger for a boiler, and more particularly, the waste heat generated during the steam or boiler operation of the boiler is delayed to the maximum inside the heat exchanger, while at the same time absorbing the thermal energy from the delayed steam or the waste heat to maximize hot water and heating. It relates to a heat exchanger for a boiler to be supplied.

As is well known, in the central heating boiler system, a heat exchanger for heating heated water (including hot water) circulated along a separate pipe by passing heated hot water or steam from the boiler is applied. Likewise, the heating water (or steam) heated by the primary heat exchanger of the boiler is supplied to the heat exchange water tank 1 through the hot water pipe 2, and the hot water coil 1a installed in the heat exchange water tank 1 is supplied. By exchanging heat with cold water supplied to pass through, hot water or heating water is supplied where desired.

However, even if the conventional heat exchanger configured as described above has a long length of the heat exchange water tank 1, the heating water introduced into the inlet 1b of the heat exchange water tank 1 is quickly discharged to the outlet 1c of the lower portion thereof. The heat exchange with the cold water flowing through the hot water coil (1a) is not made properly, and as a result, the energy efficiency is greatly reduced.

Therefore, the present invention was devised based on the above problems, and by installing at least one mutually alternate diaphragm inside the heat exchange water tank, the steam (or heating water) of the boiler or waste heat generated during the boiler operation is Heat exchanger for boiler that can greatly improve energy efficiency and reduce energy cost by smoothly performing heat exchange with cold water in a plurality of hot water coils installed inside the heat exchange tank. The purpose is to provide a flag.

The present invention also aims to provide a boiler heat exchanger that maximizes energy efficiency as well as effectively using the installation space by miniaturizing the heat exchanger and simultaneously installing a plurality of sets in parallel.

1 is a cross-sectional view of a general heat exchanger,

2 is an exploded perspective view of a heat exchanger according to the present invention,

3 is a perspective view of a heat exchanger according to the present invention,

4 is a cross-sectional view of FIG.

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

10: heat exchange water tank 11: water inlet

12: Exit 13: Plate

20: Separator 21: Through hole

22: hot water coil 30: inlet cap

31: Inlet 40: Outflow cap

41: outlet

In order to achieve the above object, the present invention provides a water inlet for introducing heating water supplied from a boiler at one end thereof, and an outlet for discharging the heating water introduced into the other end thereof is discharged. A cylindrical heat exchange water tank provided with alternating diaphragms alternately extending the dwelling time of the heating water introduced therein and preventing eddy currents; A separator plate coupled to each of flanges of both ends of the heat exchange tank and installed with a plurality of through-holes facing each other so that hot water coils through which cold water flows are formed in the through-holes facing each other; An inlet cap and an outlet cap which are bolted to the outer side of the separator and formed with an inlet and an outlet on one side thereof; And the like.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention in detail as follows.

Figure 2 is an exploded perspective view of a heat exchanger according to the present invention, Figure 3 is a perspective view of a heat exchanger according to the present invention, Figure 4 is a cross-sectional view of FIG.

First, the cylindrical heat exchange water tank 10 is provided with an inlet port 11 through which the heating water (or steam) supplied from the boiler is introduced, and the outlet port 12 through which the heating water introduced into the other end is discharged. It is provided, and the diaphragm 13 for preventing the vortex phenomenon at the same time as possible to extend the dwell time of the heating water introduced therein is alternately installed.

At this time, waste heat, wastewater, or steam wastewater generated during the operation of the boiler may be supplied to the inlet 11 instead of the heating water.

Separating plates 20 respectively installed at both open ends of the heat exchange water tank 10 are respectively coupled to the flanges 14 at both ends of the heat exchange water tank 10, and a plurality of through holes are provided at a central portion of the separation plate 20. Hot water coils 22 through which cold water flows are formed in the through-holes 21 which face 21 and face each other.

In addition, the inlet 31 and the outlet 41 are disposed at the inlet cap 30 and the outlet cap 40 which are bolted to the outer side portions of the two separation plates 20.

On the other hand, it is preferable that the heat exchanger is connected to one set of five than to be used one by one.

Referring to the operation of the heat exchanger configured as described above are as follows.

As shown in FIG. 4, the heating water (steam) supplied by the primary heat exchanger of the boiler is introduced into the heat exchange water tank 10 through the inlet 11 of the heat exchanger, and along the diaphragm 13 installed in an alternating state. It is discharged to the outlet 12 of one side of the heat exchange water tank 10 and flows into the inlet 11 of another heat exchanger 10.

In other words, the heating water is sequentially passed through a plurality of heat exchangers, for example, so as to absorb all the heat sources required to heat the cold water to maximize the use efficiency of energy.

The cold water supplied from the tank is supplied into the inlet cap 30 through the inlet 31, and then flows along a plurality of hot water coils 22 installed in the through-hole 21 of the separation plate 20. (10) As the heat is exchanged by the heating water inside, the temperature rises and is discharged along the outlet cap 40 on one side of the heat exchange water tank 10, and the hot water discharged from the outlet cap 40 is It is supplied to the inlet 31 of another heat exchanger through the outlet 41, wherein the hot water coil 22 is formed of, for example, a copper tube having excellent thermal conductivity, thereby facilitating absorption of heat.

On the other hand, the hot water discharged through the hot water coil 22 of the last heat exchanger is used for hot water or heating in each home.

Therefore, the present invention provides at least one or more diaphragms 13 interchanged with each other in the heat exchange water tank 10 so that the waste heat generated during the operation of the steam or heating of the boiler or the boiler is maximized without vortexing in the heat exchanger. By delaying, the cold water and the heat exchange in the plurality of hot water coils 22 installed inside the heat exchange water tank 10 can be smoothly made to greatly improve the efficiency of the energy as well as reduce the cost of energy as much as possible. This is a very useful effect.

Claims (1)

In forming a heat exchanger for a boiler, An inlet 11 through which the heating water supplied from the boiler is introduced is provided at one end, and an outlet 12 through which the heating water introduced into the outlet is discharged is provided at one end of the other end, and the time of staying of the heating water introduced therein is provided. Cylindrical heat exchange water tank 10 is installed alternately in the diaphragm 13 for extending the maximum and to prevent the vortex phenomenon; The hot water coils 22 are respectively coupled to the flanges 14 at both ends of the heat exchange water tank 10, and a plurality of through-holes 21 are installed at the center thereof to face each other. Separating plate 20 and; An inlet cap 30 and an outlet cap 40 which are bolted to the outer side of the separating plate 20 and formed with an inlet 31 and an outlet 4 1 on one side thereof; Heat exchanger for boiler, characterized in that consisting of.