KR200150944Y1 - Outlet pipe of gas boiler - Google Patents

Abstract

The present invention relates to a supply and exhaust communication used in the gas boiler, and more particularly to a gas boiler supply and exhaust communication having a structure that can prevent the exhaust gas from flowing back to the burner.

In the gas boiler supply / exhaust communication of the present invention, the exhaust flue is in the center, the exhaust flue is formed in the center, the exhaust flue communication in the gas boiler consisting of the supply flue formed with a plurality of inlets at the end, the exhaust flue, the exhaust flue A portion of the end of the incision is cut, both ends of the cut both ends are connected to the inner surface of the supply flue, and a shielding plate is formed on an inner portion of the exhaust flue so that the exhaust gas and the intake air is not mixed with each other It is done.

Description

Gas boiler supply and exhaust communication

1 is a configuration diagram of a conventionally used gas boiler.

2 is an external perspective view of a gas boiler in which supply and exhaust communication is installed.

3 is a cross-sectional view showing the structure of the supply and exhaust communication of FIG.

Figure 4 is a cross-sectional view showing the structure of the supply and exhaust communication according to the present invention.

Figure 5 is an exploded perspective view of the end of the supply and exhaust communication according to the present invention.

6 is a side view of the supply and exhaust communication according to the present invention.

* Explanation of symbols for main parts of the drawings

1: gas boiler 3: water tank

5: supply pipe 7: exhaust year

9 combustion chamber 11 exhaust pipe

21: supply and exhaust communication 23: suction port

23a, 25: exhaust port 27: supply year

29 exhaust year 31 shielding plate

33: extension portion 35: drain hole

a, b: bolt

The present invention relates to a supply and exhaust communication used in the gas boiler, and more particularly to a gas boiler supply and exhaust communication having a structure that can prevent the exhaust gas from flowing back to the burner.

Gas boilers are increasingly used because of the use of clean fuel gas to prevent environmental pollution, and also because of convenience and cleanliness. FIG. 1 shows a configuration of a forced exhaust / exhaust gas boiler 1 for forcibly performing air supply and exhaust using a conventional exhaust fan.

As shown, the upper side of the gas boiler (1) is provided with an air supply pipe (5) for supplying the air necessary for combustion, the exhaust pipe for discharging the combustion gas discharged through the exhaust flue (7) to the outside ( 11) is installed. Although not shown in detail, an exhaust fan is installed inside the exhaust pipe 11 to forcibly discharge the combustion gas. The gas used as fuel is combusted in a burner installed inside the combustion chamber 9, and the burner is supplied with gas through a gas valve installed at a lower portion thereof.

The air supply and exhaust communication 21 used in the gas boiler 1 has a communication tube spaced apart from each other connected to the air supply pipe 5 and the exhaust pipe 11 at the same time, referring to FIG. They extend into the supply and exhaust communication 21. As shown in FIG. 2, the air supply / exhaust communication 21 communicates with the air supply and the exhaust pipes 5 and 11 of the gas boiler 1 by a communication tube at one end thereof, and the other end extends to the outside.

At the other end extending to the outside, a plurality of inlets 23 are formed along the circumferential surface of the end to suck in air necessary for combustion, and an exhaust port 25 for discharging combustion gas is further extended than the intake port 23. It is formed in the form. Referring to FIG. 3, which is a cross-sectional view taken along the center line of the air supply and exhaust communication 21, the inlet 23 communicates with the air supply flue 27, which supplies air to the burner, and the exhaust port 25 is supplied to the air supply 25. It extends through the central portion of the exhaust communication 21 and communicates with the exhaust flue 29 for discharging the burned gas.

At this time, the supply flue 27 and the exhaust flue 29 is completely blocked to prevent the air movement between each other. The supply flue 27 is connected to the supply pipe 5 of FIG. 2 to supply air for combustion, and the exhaust flue 29 is connected to the exhaust pipe 11 to discharge the burned gas to the outside.

However, in the conventional air supply and exhaust communication 21 having the above structure, the exhaust gas flows back into the suction port 23 and flows into the burner. That is, in the normal discharge state, the exhaust gas is discharged to the exhaust port 25 and fresh air is introduced through the intake port 23, but the burned gas is introduced into the burner again due to the wind or the influence of surrounding features. . Therefore, incomplete combustion occurs in the burner and thermal efficiency is lowered.

In addition, since the structure of the supply and exhaust communication 21 is always fixed so that the exhaust gas is discharged horizontally from the exhaust port 25 and reaches a farther distance, the exhaust gas can not be prevented from entering the window in an adjacent place of the building. .

The present invention is devised to solve the above problems, an object of the present invention is to provide a gas boiler supply and exhaust communication that can prevent the exhaust gas is introduced into the air supply.

Another object of the present invention is to provide a gas boiler supply and exhaust communication that can be adjusted to the discharge direction of the exhaust gas arbitrarily to prevent the building from entering the room in a dense place.

Gas boiler supply and exhaust communication of the present invention for achieving the above object, the exhaust flue is formed in the center, the exhaust flue is formed in the form of surrounding the exhaust flue and a plurality of inlet at the end is composed of the supply and exhaust gas communication exhaust gas A part of an end of the exhaust flue is cut, and both ends of the exhaust flue are extended in both directions to be connected to the inner surface of the supply flue, and a shielding plate is formed at an inner part of the exhaust flue so that the exhaust gas and the intake air are mutually separated. Characterized in that not to be mixed.

Hereinafter, the gas boiler supply / exhaust communication of the present invention will be described in detail with reference to FIGS. 4 to 6.

4 is a cross-sectional view taken along the central portion of the supply and exhaust communication 21 according to the present invention. As shown, a portion of the upper end of the supply and exhaust flue 21, which formed the conventional supply flue 27, is dedicated to the exhaust flue 29, a plurality of exhaust ports (23a) on the surface of the supply and exhaust communication (21) It can be seen that is formed. Further, a suction port 23 similar to the conventional one is formed on the outer surface of the supply year 27 at the symmetrical position. Instead, the conventional exhaust port 25 is blocked.

5 is an external perspective view in a state where a part of the upper side of the air supply / exhaust communication 21 is separated. As shown, it can be seen that a portion of the upper side of the exhaust flue 29 is cut, and the extension 33 protrudes from both ends of the cut. The extension 33 is further extended to reach the inner surface of the supply year 27. Therefore, the supply flue 27 and the exhaust flue 29 are blocked from each other so that the exhaust gas and the fresh air are not mixed with each other.

The cutout portion of the exhaust flue 29 is a cut portion of the upper side of the exhaust flue 29 that is a cylinder. At this time, the degree of incision is preferably in consideration of the appropriate area so that the incoming fresh air and the exhaust gas can be moved smoothly.

In addition, in order to prevent the exhaust flue 29 and the supply flue 27 from communicating with each other, a shielding plate 31 is provided on the rear side of the exhaust flue 29. The shield plate 31 is to prevent the upper side of the exhaust flue 29 further extended by the present invention to communicate with the upper side of the supply flue 27, as shown.

In addition, it can be seen that a plurality of suction ports 23 are formed on the end surface of the air supply and exhaust communication 21. The inlets 23 may increase or decrease the diameter or number of the inlets 23 if necessary, that is, to adjust the ratio of the exhaust gas and the supply oxygen.

By the above configuration, it can be seen that the air required for combustion in the burner is supplied from the lower part of the supply / exhaust communication 21. In addition, referring to FIG. 6, the exhaust gas is discharged through the exhaust flue 29 (partly indicated by a dotted line) and then discharged through a plurality of exhaust ports 23a formed on the upper surface of the air supply and exhaust communication 21. . The exhaust gas is generated by combustion and therefore has a higher temperature than fresh air.

Therefore, since the weight is lighter than air, the combustion gas discharged through the exhaust port 23a naturally rises into the air. At this time, even though it is influenced by the external climate, that is, the wind, the positions are opposite to each other, so that the exhaust gas flows back through the suction port 23 is more difficult than the conventional supply and exhaust communication.

Further, a drain hole 35 is further formed at a position where the conventional exhaust port 25 at the outer end of the exhaust flue 29 is located. The drain hole 35 is for discharging the condensed water generated by contacting the hot exhaust gas and cold air outside. At this time, the discharge of the condensate may be naturally discharged because the supply and exhaust communication 21 itself is adjusted downward at a predetermined angle (about 3 to 5 ° C.). Although a plurality of suction ports 23 are formed at the lower side of the drain hole 35 in the drawing, the suction ports 23 on the end surface can be removed to prevent condensate from entering the supply flue 27.

The operation and effect of the supply and exhaust communication 21 of the present invention having the configuration as described above will be described. When the boiler is operated by the user, air is introduced by the exhaust fan installed therein. After the air is introduced through the suction port 23, the air is moved into the boiler along the air supply flue 27. The end of the supply flue 27 is introduced through the supply pipe 5 of the boiler as shown in FIG. The introduced air is combusted in the burner installed in the combustion chamber 9 and then passed through the exhaust flue 7 and discharged through the exhaust pipe 11.

The discharged exhaust gas passes through the exhaust flue 29 connected to the exhaust pipe 11 and moves to the end of the supply and exhaust communication 21. The moved exhaust gas moves to the upper side after moving in the direction of the arrow as shown in FIG. At this time, since the end of the exhaust flue 29 is blocked, the exhaust gas is not discharged in the horizontal direction, but only rises to the upper side. Therefore, it is discharged through the exhaust port 23a.

Since the exhaust gas is a high temperature state, the exhaust gas is discharged to the outside and condensed water is generated in contact with the cold air. The condensed water is moved along the bottom surface of the exhaust flue 29, and is usually directed downward because the supply and exhaust communication 21 is inclined downward. At this time, since the drain hole 35 is formed at the end of the supply and exhaust communication 21, the condensed water is naturally discharged to the outside through the drain hole 35.

Exhaust gas is discharged as described above, and fresh air is supplied to the burner, so even if the wind blows, it can escape from the effect. In addition, by adjusting the installation direction of the supply and exhaust communication (21), that is, the exhaust gas is discharged in the opposite direction when the window of the building is adjacent to the advantage that can be prevented from entering the exhaust gas into the room.

Although the present invention has been described in detail only with respect to the described embodiments, it will be apparent to those skilled in the art to which the present invention pertains, but it can be modified or changed within the spirit and scope of the present invention. something to do.

Claims (2)

The exhaust flue 29 is formed in the center and the exhaust flue (29) in the form of surrounding the exhaust flue 29, the exhaust flue in communication with the gas boiler formed with a flue flue (27) formed with a plurality of suction ports 23 at the end, the exhaust flue ( A part of the upper side of the end of 29 is cut off, and both ends thereof are extended to be connected to the inner surface of the supply flue 27, and a shielding plate 31 is formed on an inner part of the exhaust flue 29 to exhaust the exhaust gas. Gas boiler supply and exhaust communication, characterized in that configured to not communicate with each other and the suction air. The gas boiler gas supply and exhaust communication according to claim 1, characterized in that a drain hole (35) communicating with the exhaust flue (29) is formed on the outer end surface of the supply and exhaust communication (21).