KR20000008517U - Structure of Heat Exchanger for Boiler - Google Patents

Abstract

The present invention relates to a structure of a boiler heat exchanger which extends the life of a heat exchanger by preventing the duct from being corroded by condensate and combustion sulfur contained in the combustion process. In the heat exchanger for the boiler that the heat exchange is made while passing through the portion, the corrosion preventing means 10 to withstand the strong acidity is characterized in that it is configured.

Description

Structure of Heat Exchanger for Boiler

The present invention relates to a structure of a heat exchanger for a boiler, in particular, to prevent corrosion of the duct by the condensate generated in the combustion process and sulfur components contained in the combustion gas, thereby extending the life of the heat exchanger. It's about structure.

In general, it is called air conditioning to maintain a comfortable state of temperature and humidity in a certain space, and the artificial means and apparatus used at this time is called an air conditioning apparatus.

The air conditioner includes a cooling device for lowering the temperature and a heating device for increasing the temperature.

The cooling device cools the air sucked from the room by using a thermal action generated by the expansion of the compressed refrigerant and sends the cooled air to the room, thereby cooling.

The heating device heats the fluid using heat generated as the energy source is oxidized, and circulates the heated fluid so that heat exchange is performed, thereby raising the temperature.

1 is a block diagram showing the internal structure of a general gas boiler, the gas boiler 100 is close to the cabinet 110, the combustion unit 120 is installed in the cabinet 110, and the combustion unit 120 It consists of the main heat exchanger 130 and the hot water supply unit 140, and the control unit 150.

Here, the combustion unit 120 is provided to adjust the amount of gas supplied from the gas tank not shown by the solenoid valve 122, the manifold (burner 124 is provided in the combustion chamber 121) ( 124). An ignition transformer 127 for enabling initial combustion and a flame detector 127a for preventing abnormal combustion after ignition are provided on both sides of the burner 124. A blower 129 is provided below the manifold 124 to supply air for ignition and combustion.

The main heat exchanger 130 is a heat exchange between the heat generated from the burner 124 and the water transferred to the pump 132 pressure, in the case of the non-condensing type, the pipe 126 to the outside of the combustion chamber 121 Is wound around, and a plurality of heat absorbing plates 126a are vertically provided between the pipes 126 and inserted into the combustion chamber 121. On one side of the pipe 126, an overheat prevention sensor 128 and a temperature sensor 128a are installed to maintain the desired temperature of the water temperature or to prevent abnormal temperature rise of the water temperature due to abnormalities.

In the condensing type, the flame is directed from the top to the bottom as shown in FIG. 2, and the latent heat is used. The heat exchanger 210 includes a burner 214 provided with a blower 129 and a lower part of the burner 214. It consists of a sensible heat exchanger 213 and a latent heat exchanger 212 connected to the sensible heat exchanger 213, and the condensate discharge unit 211.

Here, the gas inlet pipe 218 connected to the solenoid valve is provided in one side of the burner 214, and the burner 217 is fixed to the lower end in the horizontal direction.

The sensible heat exchanger 213 is provided with a copper pipe 216 provided with a first heat absorbing plate 216a on the inside thereof so that the heating water can flow back, and the latent heat exchanger 212 has a second heat absorbing plate 215a. The fixed stainless pipe 215 is provided and connected to the copper pipe 216.

The condensate discharge part 211 is fixed to the lower part of the latent heat exchange part 212 and has a discharge port 211b at the center thereof. The burner 214, the sensible heat exchanger 213, the latent heat exchanger 212, and the condensate discharge unit 211 are provided with flanges 214a, 213a, and 211a, and are coupled using fastening means.

The hot water supply unit 140 stores water that has undergone heat exchange while passing through the main heat exchanger 130, and uses the stored water as heating or indirect heat exchange water of hot water. The water supply storage tank 142 and the water supply line It is composed of a supplemental water valve 144 for blocking or passing the water flowing through, and a filter 146 for removing this substance contained in the water passed through the supplemental water valve 144.

Here, the water supply is supplied to the hot water heat exchanger 147 through the hot water valve 145 installed before the replenishment water valve 144, and the heating return water passing through the filter 146 is supplied.

The three-way valve 148 is provided on the delivery side of the hot water heat exchanger 147 to send the supplied water supply and heating return to the hot water and heating side. That is, the three-way valve 148 may supply hot water heated by the main heat exchanger to heating according to its operating state, or may be used as indirect heat exchange. In addition, the control of the hot water and heating is adjustable through the control 150 and the room cone 151.

In the boiler formed as described above, the solenoid valve 122 installed in the cabinet 110 is opened by the signal of the control unit 150, and the gas is injected through the burner 124 provided in the manifold 124. Ignition is performed by the ignition transformer 127. Air necessary for combustion is supplied by the blower 129.

Heat exchange is achieved by heating the water flowing in the pipe 126 during the process in which the ignition heat passes between the heat absorbing plates 126a.

At this time, the temperature of the hot water maintains the temperature set by the overheat prevention sensor 128 and the temperature control sensor 128a fixed to one side of the pipe 126. The heat exchanged hot water supply unit 140 is stored, and used as heating or hot water depending on the operation of the three-way valve 148.

However, the pipe temperature at which the heating return flows is relatively low compared to the high temperature combustion gas generated during combustion, so that condensate is generated during the heat exchange process. As a result, there is a problem in that the heat exchanger is corroded to shorten its life.

Therefore, the present invention has been devised to solve such a problem, and prevents the ducts from being corroded by the condensate generated in the combustion process and sulfur components contained in the combustion gas, thereby extending the life of the heat exchanger. To provide the structure of the group.

1 is a configuration diagram showing the internal structure of a typical gas boiler,

Figure 2 is a longitudinal sectional view showing the structure of a general heat exchanger.

Figure 3 is a longitudinal sectional view of the main portion of the heat exchanger according to the present invention.

* Description of the symbols for the main parts of the drawings *

10; corrosion prevention means

The present invention for achieving the above object is a boiler heat exchanger for heat exchange is made through the sensible heat exchanger and the latent heat exchanger, the boiler for corrosion protection to endure strong acidity in the latent heat exchanger is configured It is achieved by providing the structure of the heat exchanger.

Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings.

3 is a longitudinal sectional view of main parts of a heat exchanger according to the present invention.

Before describing this embodiment, in connection with the prior art, the boiler 100 is a cabinet 110, a main portion which is close to the combustion unit 120, and the combustion unit 120 is installed in the cabinet 110. It consists of a heat exchanger 130, hot water supply unit 140, and the control unit 150.

Here, the main heat exchange unit 130 is to heat exchange to the heating return, in the case of the non-condensing type, the pipe 126 is wound around the combustion chamber 121 outside, a plurality of endotherms between the pipe 126 The plate 126a is vertically provided and inserted into the combustion chamber 121. One side of the pipe 126 is provided with an overheat prevention sensor 128 and a temperature sensor 128a to maintain a constant water temperature.

The condensing type uses latent heat, and the heat exchanger 210 includes a burner 214 provided with a blower 129, a latent heat connected to the sensible heat exchanger 213 and the sensible heat exchanger 213 provided under the burner 214. It consists of an exchange unit 212, and the condensate discharge unit 211.

Here, the gas inlet pipe 218 connected to the solenoid valve is provided in one side of the burner 214, and the burner 217 is fixed to the lower end in the horizontal direction.

The sensible heat exchanger 213 is provided with a copper pipe 216 provided with a first heat absorbing plate 216a on the inside thereof so that the heating water can flow back, and the latent heat exchanger 212 has a second heat absorbing plate 215a. The fixed stainless pipe 215 is provided and connected to the copper pipe 216.

The condensate discharge part 211 is fixed to the lower part of the latent heat exchange part 212 and has a discharge port 211b at the center thereof. The burner 214, the sensible heat exchanger 213, the latent heat exchanger 212, and the condensate discharge unit 211 are provided with flanges 214a, 213a, and 211a, and are coupled using fastening means.

In the boiler having such a configuration, the solenoid valve 122 installed in the cabinet 110 is opened, and the gas is injected through the burner 124 provided in the manifold 124 by the ignition transformer 127. Ignition.

Heat exchange is performed by heating the water flowing in the pipe 126 during the combustion gas passing through the heat absorbing plate 126a. At this time, the temperature of the hot water maintains the temperature set by the overheat prevention sensor 128 and the temperature detection sensor 128a fixed to one side of the pipe 126. The heat exchanger is stored as a hot water supply unit 140 and used as heating or hot water according to the operation of the three-way valve 148.

As the combustion gas passes between the heat absorbing plates 126a, a large amount of condensate is generated by the temperature difference between the heating return and the combustion gas. By doing so, in the present invention to prevent corrosion of the condensate discharge portion is provided with a corrosion preventing means 10 having a predetermined thickness on the inner front of the condensate discharge portion 211.

As clearly shown in Figure 3, the preferred embodiment of the present invention is to prevent corrosion means 10 is used by coating a synthetic resin material resistant to acid and heat on the front. The coating is preferably made of Teflon or ceramic.

In this way, by using the inside of the condensate discharge portion 211 fixed to the heat exchanger coated with Teflon or ceramic, the condensate in which the sulfur component is rotten does not directly contact the surface of the discharge portion.

As discussed above, the present invention has the advantage of extending the life of the heat exchanger by preventing corrosion by applying or coating a coating material on the surface of the condensate discharge part to prevent direct contact of strongly acidic condensed water with rotting sulfur. have.

Claims (2)

In the heat exchanger for the boiler that the heat exchange is made through the sensible heat exchanger and the latent heat exchanger, The structure of a heat exchanger for a boiler, characterized in that the corrosion preventing means (10) configured to withstand the strong acidity in the latent heat exchange unit. The structure of a heat exchanger for a boiler according to claim 1, wherein the corrosion preventing means (10) is made of either teflon or ceramic which is a heat resistant synthetic resin material.