KR102244776B1 - Siphon for condensing boiler - Google Patents

Abstract

The present invention relates to a siphon for a condensing boiler having an anti-freezing function, which conducts the heat from an exhaust gas discharged to the outside via a condensate drain to a heat conductor disposed inside the cylindrical shape thereof when a condensing boiler performs an anti-freezing combustion operation for a predetermined combustion time as the external temperature of the condensing boiler becomes below the condensate freezing temperature, thereby preventing freezing of the condensate filled in the cylindrical shape by the heat from the exhaust gas transferred through the heat conductor. According to the present invention, as it is not required to use a conventional planar heater attached to the outer surface of the siphon, power consumption for the operation of a conventional heater, and a reduction in the productivity, and an increase in the cost, of the condensing boiler due to the attachment and assembly of a conventional siphon and the conventional planar heater can be solved.

Description

Siphon for condensing boiler with freeze protection function {Siphon for condensing boiler}

The present invention relates to a siphon for a condensing boiler, and more particularly, to a siphon for a condensing boiler having a freeze protection function.

The condensing boiler is designed to facilitate condensation heat exchange by installing a burner on the top or side of the heat exchanger to make the flue gas flow downward and the temperature to be below the dew point temperature.

In particular, in a condensing boiler, water vapor contained in exhaust gas generated during combustion operation is condensed below the dew point temperature and discharged to the outside of the heat exchanger, and the condensed water discharged to the outside of the heat exchanger has high acidity. If it is located on the bottom and contains a neutralizing agent inside, it is collected in a siphon and then neutralized with an alkaline neutralizing agent (eg, CaCO ₃ ) and discharged to the outside.

For reference, FIGS. 1 to 2 are exemplary embodiments showing a siphon 100 ′ for a conventional condensing boiler 200 ′.

As shown in FIG. 1, in the conventional condensing boiler 200', water enters the bottom of the condensate drip tray 220' to communicate with the condensate drip tray 220' disposed on the bottom of the heat exchanger 210'. After the condensed water generated during the combustion operation of the condensing boiler 200 ′ is disposed and the condensed water is collected in the cylindrical siphon 100 ′ through the condensed water drip tray 220 ′. It is discharged to the outside.

In FIG. 2, exhaust gas generated during the combustion operation of the condensing boiler 200 ′ is discharged to the outside via an exhaust flue 230 ′ installed to discharge exhaust gas to the outside through the condensate water tray 220 ′. The exhaust gas movement path and the condensed water movement path collected in the cylindrical siphon 100 ′ through the condensed water drip tray 220 ′ are indicated by arrows. In addition, in Fig. 1, the exhaust gas movement path is indicated by arrows.

On the other hand, in order to solve the problem that the condensing boiler 200 ′ is frozen at a time when the temperature decreases, such as in winter, while the condensed water collected inside the cylindrical siphon 100 ′ is filled above a certain level, In a state in which the temperature is lowered below a certain temperature, such as in winter, the heating wire of the planar heater 240' attached to the outer surface of the siphon 100' operates to generate heat according to a signal from the control unit, and the outer side of the siphon 100' Heat is transmitted to the surface to prevent freezing of the siphon 100' filled with condensed water above a certain level.

As described above, the method of preventing freezing of the siphon 100 ′ by heating the plane heater 240 attached to the outer surface of the siphon 100 ′ as described above is a problem in that power is consumed for the heater operation, and the siphon ( 100') and the surface heater 240' are attached and assembled, resulting in a decrease in productivity and an increase in cost of the condensing boiler 200'.

KR 10-2006-0001583 A

The present invention is to solve the conventional problems as described above, and an object of the present invention is to pass through the condensate drip tray during the freeze-prevention combustion operation of the condensing boiler for a predetermined combustion time as the external temperature of the condensing boiler becomes below the condensate freezing temperature. Thus, the heat of the exhaust gas discharged to the outside is conducted to the heat conductor arranged inside the cylindrical shape, and the freezing prevention function prevents freezing of the condensed water filled in the cylindrical shape by the heat of the exhaust gas transmitted through the heat conductor. It is to provide a siphon for equipped condensing boiler.

In order to achieve the object of the present invention as described above, the siphon for a condensing boiler having a freezing prevention function according to the present invention has a cylindrical shape in which a condensed water inlet and a condensed water discharge are formed at the upper and lower portions, respectively, and the condensing boiler The external temperature of the condensing boiler is condensed water freezing temperature by arranging a heat conductor in the tubular shape, which is disposed on the bottom of the condensed water drip tray so as to communicate with the condensed water drip tray disposed on the bottom of the heat exchanger of When the condensing boiler is operated for freeze prevention combustion for a predetermined combustion time, the heat of the exhaust gas discharged to the outside via the condensate water tray is conducted to the heat conductor and is filled inside the cylindrical shape by the heat conducted to the heat conductor. It is characterized in that it prevents freezing of condensed water.

In the siphon for a condensing boiler having a freezing protection function according to the present invention, as the external temperature of the condensing boiler becomes less than or equal to the condensate freezing temperature, the condensing boiler passes through the condensed water drip tray during the freezing prevention combustion operation for a predetermined combustion time. It is characterized in that the heat of the exhaust gas discharged to the outside is conducted to the heat conductor.

In the siphon for a condensing boiler having a freezing protection function according to the present invention, the upper end of the condensed water inlet part communicates with the condensed water discharge part of the condensate water tray.

In the siphon for a condensing boiler having a freeze-preventing function according to the present invention, the heat conductor exposed to the upper end of the condensed water inlet part protrudes from the inner bottom part of the condensed water drip tray while passing through the condensate discharge part of the condensate water tray. It is characterized in that heat is transferred through the exhaust gas retained by the wall.

In the siphon for a condensing boiler having a freeze protection function according to the present invention, the heat conductor is one of a cylinder type, a corrugated cylinder type, a semi-cylindrical type, a plate type, a perforated plate type, a corrugated plate type, a bent plate type, and a multifaceted bending plate type. It is characterized by that.

In the siphon for a condensing boiler having a freezing prevention function according to the present invention, an upper end of the heat conductor is exposed higher than an upper end of the condensed water inlet.

In the siphon for a condensing boiler having a freeze protection function according to the present invention, the upper end of the heat conductor is exposed lower than the lower surface of the heat exchanger.

In the siphon for a condensing boiler having a freeze protection function according to the present invention, the upper end of the heat conductor is exposed so as to contact the bottom surface of the heat exchanger.

According to the present invention, since there is no need to use the conventional area heater attached to the outer surface of the siphon, the problem of power consumption for the operation of the conventional heater and the reduction in productivity and cost of the condensing boiler due to the attachment and assembly of the conventional siphon and the area heater All problems can be solved.

1 is an embodiment showing a conventional siphon for a condensing boiler.
Figure 2 is a side view of Figure 1;
Figure 3 is an embodiment showing a siphon for a condensing boiler having a freeze protection function according to the present invention.
Figure 4 is a side view of Figure 3;
5 is an embodiment showing a cylindrical heat conductor disposed in a siphon for a condensing boiler having a freeze protection function according to the present invention.
6 is an embodiment in which an extension wall portion protrudes from an inner bottom portion of a condensed water drip tray coupled to communicate with a condensed water inlet of a siphon for a condensing boiler having a freezing protection function according to the present invention.
7 is an embodiment showing a heat conductor of any one of a corrugated cylinder type and a plate type, a porous plate type, and a corrugated plate type arranged in a siphon for a condensing boiler having a freezing prevention function according to the present invention.
8 is an embodiment showing a semi-cylindrical heat conductor disposed in a siphon for a condensing boiler having a freeze protection function according to the present invention.
9 is an embodiment showing a bent plate-type heat conductor disposed in a siphon for a condensing boiler having a freeze protection function according to the present invention.
10 is an embodiment showing a multi-sided bent plate-type heat conductor disposed in a siphon for a condensing boiler having a freezing protection function according to the present invention.
11 is a flow chart illustrating an operation of anti-freeze combustion of the condensing boiler according to the present invention.

Hereinafter, embodiments of the present invention will be described in more detail with reference to the accompanying drawings.

The siphon for a condensing boiler having a freeze protection function according to the present invention described below is not limited to the following examples, and without departing from the gist of the technology claimed in the claims, those having ordinary knowledge in the relevant technical field It has the technical spirit to the extent that anyone can change it and implement it.

3 to 4 are embodiments showing a siphon 100 for a condensing boiler 200 having a freeze protection function according to the present invention.

The siphon 100 for the condensing boiler 200 having a freezing prevention function according to the present invention is manufactured in a cylindrical shape in which a condensed water inlet 110 and a condensed water discharge 120 are formed at the upper and lower portions, respectively.

The siphon 100 is disposed on the bottom of the condensate drip tray 220 so as to communicate with the condensate drip tray 220 disposed on the bottom of the heat exchanger 210 of the condensing boiler 200.

The siphon 100 prevents the condensing boiler 200 from freezing for a predetermined combustion time as the external temperature of the condensing boiler 200 becomes less than or equal to the condensate freezing temperature by placing the heat conductor 130 inside the cylindrical shape. During the combustion operation, heat of the exhaust gas discharged to the outside via the condensed water drip tray 220 is conducted to the heat conductor 130, and the condensed water filled in the cylindrical shape by the heat conducted to the heat conductor 130 Prevent freezing.

In Figure 4, the exhaust gas generated during the combustion operation of the condensing boiler 200 passes through the condensate water tray 220 and moves the exhaust gas discharged to the outside through the exhaust flue 230 installed to discharge the exhaust gas to the outside. An arrow indicates a path and a movement path of the condensed water collected in the cylindrical siphon 100 via the condensed water drip tray 220. In addition, in Fig. 3, the exhaust gas movement path is indicated by arrows.

As shown in FIG. 5, the heat conductor 130 is disposed so that the upper end is exposed above the condensed water inlet 110 of the siphon 100 and the lower end is fixed to the cylindrical bottom of the siphon 100. desirable.

5 illustrates a state in which the lower end of the heat conductor 130 is fitted and fixed to a bracket (unsigned) formed on the cylindrical bottom of the siphon 100. Figure 5 (a) is a partial cut-away perspective view of the cipher 100, Figure 5 (b) is a front view of Figure 5 (a).

5A to 5B, the upper end of the condensed water inlet 110 communicates with the condensed water discharge part 221 of the condensed water drip tray 220.

As shown in (b) of Figure 5, it is preferable that the upper end (H) of the heat conductor 130 is exposed higher than the upper end (L) of the condensed water inlet 110.

As shown in (b) of Figure 5, it is preferable that the upper end (H) of the heat conductor 130 is exposed lower than the bottom surface (M) of the heat exchanger (210). In contrast, it is preferable that the upper end (H) of the heat conductor 130 is exposed to contact the bottom surface (M) of the heat exchanger 210, and when the water inside the siphon 100 exceeds the height of the condensate fresh water, the Is discharged as.

In the siphon 100, the heat conductor 130 exposed to the upper end of the condensate inlet 110 passes through the condensate discharge part 221 of the condensate drip tray 220, as shown in FIG. 6 It is preferable to receive heat through the exhaust gas retained by the extended wall portion 222 protruding from the inner bottom portion of the condensed water drip tray 220.

When the time during which the exhaust gas stays by the extension wall portion 222 increases, heat conduction of the exhaust gas to the heat conductor 130 may be increased.

3 to 6 illustrate a heat conductor 130 having a cylindrical shape.

7 to 10 illustrate a heat conductor 130 manufactured in various shapes such as a cylinder type, a corrugated cylinder type, a semi-cylindrical type, a plate type, a porous plate type, a corrugated plate type, a bent plate type, a multi-faceted bending plate type, and the like.

7A illustrates a heat conductor 130 in a corrugated cylinder shape.

7B illustrates a heat conductor 130 in a plate shape.

7C illustrates a heat conductor 130 in a porous plate shape.

7D illustrates a heat conductor 130 in a corrugated plate shape.

Figure 8 (a) illustrates a heat conductor 130 of a semi-cylindrical shape.

8B is a plan view showing the direction of exhaust gas transmitted to the heat conductor 130 having a semi-cylindrical shape.

9A illustrates a heat conductor 130 of a bent plate shape forming a triangular shape.

FIG. 9B is a plan view showing the direction of exhaust gas transmitted to the heat conductor 130 of a bent plate shape forming a triangular shape.

Figure 10 (a) illustrates the heat conductor 130 in a multi-sided bent plate shape forming a trapezoid.

FIG. 10(b) is a plan view showing the direction of exhaust gas transmitted to the heat conductor 130 of a multi-sided bent plate shape forming a trapezoid.

The siphon 100 for a condensing boiler having a freeze protection function according to the present invention configured as described above operates as follows.

The siphon 100 for the condensing boiler 200 having a freeze protection function according to the present invention prevents the condensing boiler 200 from freezing for a predetermined combustion time as the external temperature of the condensing boiler 200 becomes less than the condensate freezing temperature. During the combustion operation, heat of the exhaust gas discharged to the outside via the condensed water drip tray 220 is conducted to the heat conductor 130 to prevent freezing of the condensed water filled in the cylindrical shape.

Referring to FIG. 11, a detailed description of the freezing prevention combustion operation process (S100) of the condensing boiler 200 according to the present invention is as follows.

It is preferable to understand that the freezing prevention combustion operation process S100 of the condensing boiler 200 according to the present invention described below is performed by the MCU of the condensing boiler 200 or the boiler combustion controller.

The condensing boiler 200 according to the present invention maintains the combustion standby state until the user operates the room controller in the power-on state to operate the condensing boiler 200 in the heating mode or the hot water mode (S110).

As described above, while the condensing boiler 200 according to the present invention maintains the combustion standby state, the condensing boiler 200 uses a temperature sensor installed outside the condensing boiler 200 to detect the external temperature. The external temperature around the casing of the condensing boiler 200 is sensed, and it is determined whether the detected external temperature is less than or equal to the condensate freezing temperature (eg, 0° C.) (S120).

If the external temperature around the casing of the condensing boiler 200 is determined to be below the condensate freezing temperature (eg, 0° C.), the condensing boiler 200 starts the freeze prevention combustion operation (S130), When the combustion time (e.g., 10 minutes) elapses (S140), the freeze prevention combustion operation is stopped (S150), and the combustion waits until the user operates the room controller again to operate the condensing boiler 200 in the heating mode or the hot water mode. Maintain the state (S110).

When the condensing boiler 200 performs a freeze prevention combustion operation for a predetermined combustion time (eg, 10 minutes) as in the S130 to S150 processes, exhaust gas is generated. The exhaust gas is discharged to the outside of the casing of the condensing boiler 200 through the exhaust flue 230 installed to discharge the exhaust gas to the outside.

In particular, at this time, the heat of the exhaust gas discharged to the outside via the condensed water drip tray 220 is exposed above the condensed water inlet 110 formed on the upper end of the cylindrical siphon 100. Conducts to the upper end.

In addition, the heat of the exhaust gas first conducted to the upper end of the heat conductor 130 is conducted to the lower end of the heat conductor 130 disposed to be fixed to the bottom of the inside of the cylindrical siphon 100, as a result. Freezing of the condensed water filled in the cylindrical siphon 100 is prevented by the heat of the exhaust gas conducted to the heat conductor 130 as a whole.

As described above, whenever the external temperature around the casing of the condensing boiler 200 is determined to be below the condensate freezing temperature (eg, 0°C), the condensing boiler 200 is freeze-prevented combustion operation for a predetermined combustion time (eg, 10 minutes). By conducting the heat of the exhaust gas to the heat conductor 130 disposed inside the cylindrical siphon 100 to prevent freezing of the condensed water, in the conventional condensing boiler 200 ′ shown in FIGS. 1 to 2 Since there is no need to use the surface heater 240 ′ attached to the outer surface of the siphon 100 ′, the problem of power consumption for the operation of the conventional heater and the attachment and assembly of the conventional siphon 100 ′ and the surface heater 240 ′ It is possible to solve all of the problems of productivity decrease and cost increase of the condensing boiler 200'.

100: siphon 101: bottom
110: condensate inlet 120: condensate discharge
130: heat conductor 200: boiler
210: heat exchanger 220: condensate drip tray
221: condensate discharge part 222: extension wall part
230: exhaust year
100': siphon 200': boiler
210': heat exchanger 220': condensate drip tray
230': Exhaust year 240': Area heater

Claims (9)

It has a cylindrical shape in which a condensate inlet 110 and a condensate discharge 120 are formed at the top and bottom, respectively, and communicates with the condensate drip tray 220 disposed on the bottom of the heat exchanger 210 of the condensing boiler 200. Exhaust exhaust discharged to the outside via the condensate drip tray 220 by arranging a heat conductor 130 disposed on the bottom of the condensate drip tray 220 and the upper end of which is exposed above the condensate inlet 110 in a cylindrical shape Allows the heat of the gas to be conducted to the heat conductor 130 and prevents freezing of the condensed water filled in the cylindrical shape by the heat conducted to the heat conductor 130,
The heat conductor 130 collects exhaust gas retained by the extended wall portion 222 protruding from the inner bottom portion of the condensate water tray 220 while passing through the condensate water discharge portion 221 of the condensate water tray 220. Siphon for a condensing boiler having a freezing protection function, characterized in that heat is transferred through. According to claim 1, As the external temperature of the condensing boiler 200 becomes less than the condensate freezing temperature, the condensing boiler 200 goes to the outside via the condensate drip tray 220 when the freeze-preventing combustion is operated for a predetermined combustion time. Siphon for a condensing boiler having a freezing prevention function, characterized in that the heat of the exhaust gas is conducted to the heat conductor (130). The siphon of claim 1, wherein the lower end of the heat conductor (130) is fixed to the cylindrical bottom (101). [2] The siphon of claim 1, wherein the upper end of the condensed water inlet (110) communicates with the condensed water discharge (221) of the condensed water drip tray (220). The method of claim 1, wherein the heat conductor 130 has a freeze prevention function, characterized in that it has any one of a cylinder type, a corrugated cylinder type, a semi-cylindrical type, a plate type, a porous plate type, a corrugated plate type, a bent plate type, and a multi-faceted bending plate type. Siphon for equipped condensing boiler. The siphon of claim 1, wherein an upper end of the heat conductor (130) is exposed higher than an upper end of the condensate water inlet (110). The siphon of claim 1, wherein an upper end of the heat conductor (130) is exposed lower than a lower surface of the heat exchanger (210). The siphon of claim 1, wherein an upper end of the heat conductor (130) is exposed so as to contact a bottom surface of the heat exchanger (210). delete

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