KR100380805B1 - Boiler having ceramic plate - Google Patents

Abstract

An environmentally friendly boiler is disclosed, which can significantly improve thermal efficiency and exhibit energy saving effects, and at the same time, can sufficiently decompose various harmful gases generated in a boiler. A boiler according to the present invention comprises: a) a boiler having a working fluid heated by combustion heat of a burner, comprising: a hollow enclosure-type case; b) a heating tube provided at an inner upper portion of the case and for heating the working fluid; c) a plurality of convection tubes provided in the inner central portion of the case to convection the working fluid exiting the heating tube; d) a heat storage plate provided adjacent to the heating tube and having an endothermic and heat storage function in the boiler; And e) a heating plate provided at an inner lower portion of the case and directly receiving a flame generated from the burner. Since the flame is sprayed horizontally to face the 'M' shaped ceramic heating plate, the heating plate can be effectively heated, and the ceramic heating plate having excellent heat resistance and endothermic ability can maintain a high temperature, thereby decomposing a considerable amount of harmful gases generated during combustion. . In addition, the boiler according to the present invention can further improve the harmful gas decomposition ability by delaying the direct flow of combustion heat to the outside through the heat storage plate inserted between the layers of the heating tube arranged in a plurality of layers.

Description

Boiler having ceramic plate

The present invention relates to an internal structure of a boiler, and more particularly, to a boiler having a structure capable of greatly improving thermal efficiency and effectively decomposing harmful gases generated during combustion to protect the environment.

Conventionally known boilers do not effectively utilize the heat of combustion generated during combustion, and also emit harmful gas generated therein to the outside without being properly decomposed, which is undesirable in terms of fuel consumption as well as environmental protection. Problems of the conventional boiler as described above inevitably occur due to its internal structure.

That is, the conventional boiler does not have a device that allows the internal combustion heat to stay in the boiler for a long time, and also has a structure that the flames emitted from the burner nozzles do not have a structure to effectively heat the heating tube through which the working fluid flows. Such energy consumption and the release of a large amount of harmful substances are inevitable.

Therefore, it is desirable to implement a boiler having a structure and a structure composed of the material that can effectively perform the role of endothermic, regenerative, and radiant heat emission at the same time to keep the combustion heat generated in the boiler for a longer time inside the boiler. It is a problem of recent boiler manufacturing technology.

1 is a cross-sectional view showing the interior of a conventional conventional boiler.

Referring to FIG. 1, a conventional boiler heats a heating tube 15 arranged in a zigzag form provided on an upper part of a burner 14 by combustion heat of a burner 14 located inside a hollow case-shaped case 11. And the lower part is provided with a blower 12 for supplying the combustion air, the upper end of the exhaust port 13 for discharging the exhaust gas is bored and plate-shaped endothermic fins for increasing the endothermic area of the heating tube 15 ( It is configured by fixing a plurality of 16 to the heating tube (15).

A ceramic coating 20 having a predetermined composition has arrived on the outer circumferential surface of the heating tube 15 and the heat absorbing fins 16 arranged inside the case 11 of the boiler 10. The boiler 10 is used for heating and hot water by heating the water passing through the heating tube 15 as the combustion heat of the burner 14 installed therein.

The present invention has been made in view of the above-described problems of the conventional boiler, one object of the present invention is to provide a boiler that can exhibit an energy saving effect by greatly improving the thermal efficiency.

Another object of the present invention is to provide an environmentally friendly boiler capable of sufficiently decomposing harmful gases such as carbon monoxide, sulfur dioxide, and dioxin generated in a boiler.

1 is a cross-sectional view of a conventional boiler.

2 is a perspective view of a boiler according to an embodiment of the present invention.

3 is an internal perspective view of the boiler shown in FIG. 2.

4 is a front sectional view of the boiler shown in FIG. 2.

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

100: Case 102: Outer case

104: Inside case 110: Euro part

115: heating tube 120: injection part

125: discharge part 130: communication part

135: burner nozzle opening 140: heat storage plate

145: convection pipe 150: heating plate

In order to achieve the above object of the present invention, according to an embodiment of the present invention, a) a boiler having a working fluid heated by the combustion heat of the burner, comprising: a hollow enclosure-type case; b) a heating tube provided at an inner upper portion of the case and for heating the working fluid; c) a plurality of convection tubes provided in the inner central portion of the case to convection the working fluid exiting the heating tube; d) a heat storage plate provided adjacent to the heating tube and having a heat absorption and heat storage function in a boiler; And e) a heating plate provided at an inner lower portion of the case and directly receiving a flame generated from the burner.

The case has an inner case and an outer case in a shell form at predetermined intervals, and a working fluid inside the heating tube flows into a flow path portion that is a space between the inner case and the outer case. That is, the working fluid is provided to flow over the entire outer peripheral surface of the boiler.

The case is provided with an injection part into which the working fluid is first injected, a discharge part from which the working fluid is finally discharged, and a communication part from which the combustion gas in the boiler is discharged.

In addition, the case is provided with a burner nozzle hole for accommodating the burner nozzle in the lower side of the case to accommodate the flame from the burner.

The heating tube is connected to the injection part and is provided in a zigzag form on a horizontal surface of the upper part of the case. At this time, the heating tube is further arranged in a zigzag form as described above over a plurality of horizontal layers.

The heat storage plate is horizontally provided between the plurality of layers in which the heating tubes are arranged. At this time, three sides of the edge of the heat storage plate is configured to abut the inner case, and the combustion gas of the boiler passes through the other non-contact passage. In addition, the heat storage plate is made of a ceramic having excellent heat absorbing and heat storage functions. As the ceramic heat storage plate is arranged while forming a plurality of layers inside the boiler, the time for discharging the heat of combustion inside the boiler through the communication unit may be considerably delayed, thereby significantly improving the thermal efficiency as compared with the conventional boiler.

The convection tube is preferably formed in a '-' shape, provided across the interior of the boiler, and both ends thereof pass through the flow path portions facing each other.

At this time, the convection pipe is provided in plurality in parallel on a horizontal plane at a predetermined interval.

The heating plate is located directly below the convection tube, and is provided to face the burner nozzle sphere, and is composed of a ceramic having excellent heat absorption and heat resistance. Preferably, the heating plate has a plan view of 'M' and stands on the inner bottom surface of the case in the form of a folding screen. By adopting such a structure, the flame emitted from the burner is effectively collected near the 'M' shaped heating plate, and the heating and rotation are repeated.

Hereinafter, with reference to the accompanying drawings will be described in detail the structure of a boiler according to a preferred embodiment of the present invention.

Figure 2 is a perspective view of the boiler according to an embodiment of the present invention, Figure 3 is an internal perspective view of the boiler shown in Figure 2, Figure 4 is a front sectional view of the boiler according to the embodiment of the present invention.

2, 3, and 4, the case 100 is formed in a shell form with an inner case 104 and an outer case 102 at predetermined intervals. A working fluid having passed through the inside of the heating tube 115 flows into the flow path part 110, which is a space between the inner case 104 and the outer case 102. That is, the working fluid also flows in the flow path part 110, which is a space provided along the entire outer circumferential surface of the boiler.

The upper surface of the case 100 is provided with an injection part 120 through which the working fluid is first injected, a discharge part 125 through which the working fluid is finally discharged, and a communication part 130 through which combustion gas in the boiler is discharged.

In addition, the case 100 is provided with a burner nozzle hole 135 for accommodating the burner nozzle in the lower side of the side to accommodate the flame from the burner.

The heating tube 115 is connected to the injection unit 120 and is provided in a zig-zag form on a horizontal surface of the upper portion of the boiler. At this time, the heating tube 115 is further arranged in a zigzag form as described above over a plurality of horizontal layers.

The heat storage plate 140 is horizontally provided between the plurality of layers in which the heating tubes 115 are arranged. At this time, three surfaces of the edge of the heat storage plate 140 is in contact with the inner case 104, and the other non-contact passage passes through the heating tube 115 and the combustion gas of the boiler. In addition, the heat storage plate 140 is composed of a ceramic having excellent heat absorbing and heat storage functions. As the ceramic heat storage plate 140 is arranged in a plurality of layers inside the boiler, the combustion gas inside the boiler returns to the upper side in a zigzag manner in the heat storage plate 140 arranged in each layer through the communication unit 130. Since the discharge time can be delayed as much as possible, it is possible to significantly improve the thermal efficiency compared to the conventional boiler. While the combustion gas discharge temperature of the conventional boiler is about 270 to 320 degrees Celsius, the combustion gas discharge temperature of the boiler according to the present invention can achieve a significant thermal efficiency improvement of about 70 to 80 degrees Celsius.

Convection pipe 145 is preferably formed in a 'b' shape, is provided in a plurality across the inside of the boiler and both ends thereof are passed through the flow path portion 110 facing each other. At this time, the shape of the convection pipe 145 may be formed in various shapes, as well as other 'b' shape.

At this time, the convection pipe 145 is provided in parallel on the horizontal plane at a predetermined interval. Of the working fluid exiting the heating pipe 115 and entering the flow path part 110, the working fluid abutting the one end of the convex pipe 145 which is bent in a '-' shape is convection whose central portion is intensively heated. The convection action of the working fluid in the tube 145 causes the convection tube 145 to flow to the other end. After such a process, the working fluid in the flow path part 110 exits to the outside of the boiler through the discharge part 125.

The heating plate 150 is located directly under the convection pipe 145 and is provided to face the burner nozzle hole 135 and is made of ceramic having excellent heat absorption and heat resistance. The heating plate 150 is manufactured in a shape that can be heated while receiving a direct flame effectively. That is, the heating plate 150 is formed in such a way that the central portion thereof is formed close to the burner nozzle hole 135, and the heating plate 150 is symmetrical with respect to the center vertical line thereof as a reference line. Preferably, the heating plate 150 has a plan view of 'M' and stands on the inner bottom surface of the boiler in the form of a folding screen. By taking such a structure, the flame emitted from the burner is effectively collected near the 'M'-shaped heating plate 150, and the heating and rotation are repeated.

Hereinafter, the heating process of the boiler according to the present invention is summarized as follows.

The working fluid injected through the injection portion provided on one side of the outer case enters the heating tubes arranged in a zigzag manner. Since the heating tube is provided with a plurality of layers in a zigzag form on the horizontal plane, the working fluid flowing into the heating tube is heated with sufficient endothermic time. In addition, the ceramic heat storage plate is disposed horizontally in close proximity to the heating tube between each layer of the heating tube composed of the plurality of layers, so that the heating tube receives continuous radiant heat from the ceramic heat storage plate. At this time, the plurality of ceramic plates provided horizontally prevents the combustion heat in the boiler from being easily discharged.

As described above, the working fluid heated through the heating tube exits to the flow path part, which is a space provided between the outer case and the inner case. In this way, the working fluid flowing into the flow path part is heated again while passing through the 'A' shaped convection pipe provided across the heating plate of the 'M' structure, in which the flame inside the boiler is mainly formed. . In this way, the working fluid coming out of the heating tube and entering the flow path portion, the working fluid abutting the one end of the convex convex tube having a '-' shape, is the convection action of the working fluid in the convection tube whose central portion is heated intensively. This causes the flow to the other end of the convection pipe. After such a process, the working fluid in the flow path is discharged to the outside of the boiler through the discharge.

As described above, according to the present invention, by spraying the flame horizontally on the 'M' shaped ceramic heating plate, the sprayed flame is not dispersed and effectively gathers near the heating plate, swirls and continuously heats the heating plate. Therefore, since the ceramic heating plate excellent in heat resistance and endothermic property can maintain a considerable high temperature, it is possible to decompose harmful gas generated by combustion.

In addition, through the ceramic heat storage plate inserted between the layers of the heating tube arranged in a plurality of layers in a zigzag manner, the combustion heat inside the boiler is delayed to the outside as much as possible, thereby improving the combustion gas decomposition ability, Can significantly increase the heat transfer. At the same time, it significantly lowers the exhaust gas temperature, preventing global warming and protecting the atmosphere.

In addition, the fluid exiting the heating tube by the '-' convection tube is heated again, so that it is possible to further improve the thermal efficiency of the boiler.

In the above, the boiler according to a preferred embodiment of the present invention has been described and illustrated, but the present invention is not limited to the above-described embodiment and is not limited by the above-described claims without departing from the scope of the present invention as claimed in the following claims. Anyone with ordinary knowledge can understand that various changes are made.

Claims (13)

A boiler having a working fluid heated by combustion heat of a burner, said boiler comprising: a) hollow enclosure case; b) a heating tube provided at an inner upper portion of the case and for heating the working fluid; c) a plurality of convection tubes provided in the inner central portion of the case to convection the working fluid exiting the heating tube; d) a heat storage plate provided adjacent to the heating tube and having a heat absorption and heat storage function in a boiler; And e) a heating plate provided in the inner lower portion of the case and directly receiving the flame generated from the burner; Boiler comprising a. The method of claim 1, The case is composed of an inner case and an outer case having a predetermined interval, the boiler characterized in that the working fluid flows to the flow path portion which is a space between the inner case and the outer case. The method of claim 1, The case is characterized in that the boiler is characterized in that the injection portion is provided with a working fluid is injected into one side, a discharge portion for discharging the working fluid and a communication portion for discharging the combustion gas. The method of claim 1, The case is characterized in that the boiler is provided with a burner nozzle opening that can accommodate the burner nozzle in the lower side. The method according to claim 1 or 3, One side of the heating tube is connected to the injection unit, and is provided in a zig-zag form on a horizontal plane at an upper position inside the boiler, and the other end of the heating tube is disposed between the inner case and the outer case. Boiler characterized by leading to the space. The method of claim 5, The heating tube is characterized in that the boiler is provided in a plurality of layers. The method of claim 5, The heat storage plate is a boiler characterized in that it is provided horizontally between each layer arranged the heating tube. The method of claim 1, The heat storage plate is a boiler, characterized in that the surface is composed of a ceramic. The method of claim 2, The convection pipe is provided across the interior of the boiler, characterized in that the both ends are connected to the flow path portion. The method of claim 9, The convection pipe is a boiler, characterized in that a plurality is provided in parallel with a predetermined interval on a horizontal plane. The method of claim 4, wherein The heating plate is located directly below the convection pipe, characterized in that provided to face the burner nozzle port. The method of claim 11, The heating plate is a boiler characterized in that the central portion is formed in close proximity to the burner nozzle opening, symmetrical with respect to the central vertical line of the center line and the heating plate is retracted on both sides. The method of claim 1, Boiler, characterized in that the surface of the heating plate is composed of a ceramic.