KR20150070710A - Gas boiler having cistern tank opened to atmosphere - Google Patents

Abstract

The present invention relates to a gas boiler with an open type expansion tank. More specifically, to a gas boiler with an open type expansion tank comprising: an expansion tank which is equipped with a heating water collecting outlet/inlet and stores heating water therein; a heating water collecting outlet/inlet pipe of which the top is inserted in the expansion tank through the heating water collecting outlet/inlet, in which a barrier is formed to divide the inner space into a certain space, therefore, a space at one side provides heating water collecting outlet/inlet such that returned heating water may be flowed into the expansion tank, and a space at the other side provides returned heating water path to discharge returned heating water which is already separated; and a circulating pump which is connected to the heating water collecting outlet/inlet pipe to circulate returned heating water discharged through the heating water collecting outlet/inlet. The present invention has an effect of simplifying the assembly process by reducing the number of packing installation process to simplify the structure and seal a gap in the heating water collecting outlet/inlet pipe and the expansion tank thereby simplifying the assembly process and an effect of preventing noise which is generated by an undulating water surface or overflowing of returned heating water stored in the expansion tank soaring toward the upper side of the water surface. Additionally, the gas boiler elongates the life of the circulating pump by preventing an occurrence of cavitation in the circulating pump and prevents the generation of noise from the circulating pump.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a gas boiler having an atmospheric expansion expansion tank,

The present invention relates to a gas boiler having an atmospheric expansion type expansion tank, and more particularly, to a gas boiler having an atmospheric expansion type expansion tank, The present invention relates to a gas boiler provided with an atmospheric expansion expansion tank for preventing air from entering the atmosphere.

Generally, a gas boiler burns liquefied petroleum gas (LPG), liquefied natural gas (LNG), or city gas (CG) internally, heats the water using the combustion heat generated in the combustion process, Circulates through the circulation pump to the heating pipe in the room, and then the room is heated or supplied to the neck or the kitchen.

These gas boilers are largely divided into atmospheric-type and atmospheric-enclosed types. Atmospheric-type gas boilers (gas boilers equipped with an open-type expansion tank) are provided with a heating pipe at a lower temperature than the installation position of the boiler and the heating water is connected to the expansion tank It is a structure exposed to the atmosphere through an overflow pipe, and an atmospheric closed gas boiler (a gas boiler equipped with an airtight expansion type expansion tank) has a structure in which the heating water is shut off from the atmosphere and a separate water separator is installed.

FIG. 1 is a view showing the internal construction of an atmospheric gas boiler among the gas boilers. In the atmosphere open type gas boiler, a heating return water inlet pipe 8 and a heating water return water outlet pipe 9 are connected to the lower part, A circulation pump 2 for circulating a heat recovery water discharged through a heat return pipe 9 connected to the expansion tank 1 and a circulation pump 2 for circulating the heat recovery water discharged through the heat return pipe 9 connected to the expansion tank 1, A main heat exchanger 3 for transferring heat energy of the burner 4 to the heating water circulated by the heater 2 and a heating water supply pipe 7 at the heating time and a hot water heat exchanger 6 And a hot water heat exchanger 6 for supplying hot water by heating the hot water when hot water is used.

The heating water is heated by the burner 4 of the main heat exchanger 3 when the heating operation is performed without using hot water, and the heated water is circulated by the circulating pump 2 through the main heat exchanger 3, (3), a three-way valve (5), a heating water supply pipe (7), and a heating pipe (not shown).

However, in the conventional open-air type gas boiler as described above, the heating return water is introduced into the expansion tank 1 through the heating water return inlet pipe 8 and the heating water separated from the inside of the expansion tank 1 by the expansion tank 1 And the heat recovery water discharge pipe 9 discharged to the outside of the expansion tank 1 is separated so that the structure of the gas boiler is complicated and when the heating water return pipe 8 and the heating water discharge pipe 9 are connected to the expansion tank 1, The packing has to be installed for each tube in order to seal the gap, so that the manufacturing cost is increased and the assembling process is complicated.

When the direction of the heat transfer D1 flowing into the interior of the expansion tank 1 through the heating water return inlet pipe 8 is directed upward and the heating water return flows into the interior of the expansion tank 1, ), The water heating overflows to the upper side of the water surface, so that water overflow occurs, and there is a problem that noise occurs due to the water slipping.

Also, when the heat return water discharged through the heat return pipe 9 flows into the circulation pump 2, the flow is unstable and not only turbulence is formed but also the peripheral pressure drops below the saturation water vapor pressure due to the fast flow rate, And the circulation pump 300 is broken due to the pressure generated when the bubbles generated in the heat recovery water are destroyed or cavitation due to the noise is generated.

SUMMARY OF THE INVENTION The present invention has been conceived in order to solve the problems as described above, and it is an object of the present invention to provide an air conditioner which can simplify the structure in which the heating water is flown into and out of the expansion tank and prevent noise generation and water overflow in the expansion tank, And an object of the present invention is to provide a gas boiler having an expansion tank.

SUMMARY OF THE INVENTION The object of the present invention is to provide an expansion tank in which a heating return inlet is provided and a heating return is stored therein; The upper part is inserted into the expansion tank through the heating water inlet and the partition is partitioned into a predetermined space so that a heat exchange water is introduced into the expansion tank at one side space around the partition wall A heating return flow inlet for providing a heating return flow path and a heat return flow outlet for providing a heating return flow path for discharging heat recovery water separated from the expansion tank in the other space; And a circulation pump connected to the heating return flow inlet pipe and circulating the heating return water discharged through the heating return oil discharge channel, the gas boiler having an atmospheric expansion type expansion tank.

And a second heat transfer pipe which is located on the upper side of the heating water return inflow channel and upwardly moves through the heating water inflow inflow path to guide the direction of the heating water flow to be laterally changed by intercepting the upper side of the heating water flowing into the expansion tank And a guide plate is provided.

And a second guide plate positioned to be spaced apart from the first guide plate by a predetermined distance and guiding the movement direction of the heat recovery water moving laterally through the first guide plate to be changed in the horizontal direction.

And the length of the first guide plate toward the heat return flow path is shorter than the width of the heat return flow path.

The first guide plate is integrally formed with the expansion tank, and the first guide plate and the second guide plate are connected by a connecting portion.

An open portion is formed between the first guide plate and the second guide plate, and a part of the heat return water flowing into the expansion tank through the open portion flows into the upper side of the expansion tank.

And the second guide plate is positioned higher than the first guide plate.

In addition, a circulation pump connection part is formed in the heating return flow inlet to connect the circulation pump.

A flow rate regulating plate is formed in the circulation pump connecting portion so that the flow rate of the heat return water discharged to the circulation pump through the heating return flow discharging passage is reduced and a plurality of moving holes are formed in the flow rate regulating plate, .

And the flow rate regulating plate is located inside the heating return flow path.

And the plurality of moving holes are formed in a lattice or a honeycomb shape.

As described above, the gas boiler provided with the atmospheric-type expansion tank according to the present invention includes a heating-return inflow pipe for allowing the heating water to flow into the expansion tank and a heating-return pipe for discharging the heating water from the expansion tank to the circulating pump The heat recovery water can be flowed into the expansion tank through a single pipe (heat recovery inlet / outlet) without being installed separately in the expansion tank, thereby simplifying the structure and installing the packing to seal the gap between the heat return inlet and the expansion tank There is an effect of simplifying the assembly process by reducing the number of times of the packing installation process.

Further, the first and second guide portions may be provided in the expansion tank so that when the heat recovery water flows into the expansion tank, the direction of movement is changed from the upward direction to the upward direction through the first guide portion and the second guide portion, So that the heat recovery water stored in the expansion tank rises to the upper side of the water surface due to the fact that the heating water return flows upward and flows into the interior of the expansion tank to prevent water from overflowing or noise due to the sloshing of the water surface It is effective.

Further, the first guide portion and the second guide portion are integrally connected to each other through the connecting portion, thereby being more firmly fixed to a predetermined position.

The width of the first guide portion is formed to be shorter than the width of the heat return flow path and the opening portion is formed between the first guide portion and the second guide portion. When the heating water flows into the expansion tank, Not only in the lateral direction but also in the upward direction of the expansion tank so that the bubbles mixed in the heating water return are prevented from being discharged into the heating water discharge flow passage .

Further, by forming the openings between the first guide portion and the second guide portion, the air bubbles mixed in the heat recovery water introduced laterally flows into the upper side of the expansion tank together with the heat recovery and discharged to the outside, So that it is prevented from being discharged to the heating water discharge duct.

In addition, by forming a flow rate regulating plate at the circulation pump connection portion formed at the inlet of the heat exchange water outlet, not only the flow rate of the heat return water flowing into the circulation pump is reduced, but also the peripheral pressure is increased by stabilizing the flow, CAVITATION) is prevented from occurring, thereby prolonging the life of the circulating pump and preventing noise from occurring in the circulating pump.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a schematic diagram showing a gas boiler with a conventional atmospheric open expansion tank. Fig.
FIG. 2 is a perspective view showing a state in which a circulation pump is connected to a heating return inlet and an inlet to an expansion tank provided in a gas boiler according to the present invention. FIG.
3 is a sectional view taken along the line A-A 'in Fig.
4 is a perspective view showing the inside of an expansion tank provided in the present invention;
FIG. 5 is a perspective view showing a heat recovery inlet port provided in the present invention; FIG.
FIG. 6 is a front view showing a circulation pump connection portion formed in the heat recovery inlet and outlet provided in the present invention; FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a gas boiler having an atmospheric expansion tank according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 2 is a perspective view showing a state in which a circulation pump is connected to a heating return inlet and an expansion tank provided in a gas boiler according to the present invention, FIG. 3 is a sectional view taken along the line A-A ' 6 is a front view showing a circulating pump connection portion formed in the heat recovery inlet and outlet inlet of the present invention. FIG. 5 is a perspective view showing the interior of the expansion tank provided in the present invention, to be.

As shown in FIGS. 2 and 3, the gas boiler having the atmospheric-type expansion tank according to the present invention includes an expansion tank 100 in which the heating water is stored, a heating water- An outflow inlet 200 and a circulation pump 300 for circulating the heat recovery water.

An overflow pipe (not shown) is provided in the expansion tank 100 to store the heating water in the heating tank 100 and allow the heating water to flow to the outside when the amount of heating water stored therein is higher than a predetermined level. So that the heating water in the expansion tank 100 is subjected to odd water separation.

In addition, a plurality of water level sensors 140 for detecting whether or not the heating water return amount is within a predetermined water level range in the expansion tank 100 are provided in the upper part, and the water return water inlet / A cylindrical heat recovery inlet 130 is formed so as to introduce or discharge heat recovery water.

The heating water return inlet / outlet 200 not only introduces the heating water transferred from the heat source to the inside of the expansion tank 100, but also circulates the heating water recovered from the expansion tank 100 into the circulation pump 300, .

At this time, the heating water inlet / outlet pipe 200 is inserted into the heating water inlet / outlet inlet 130 so that the upper end thereof is interlocked with the inner space of the expansion tank 100, and the heating water inlet / outlet 130, (200), a packing (400) is provided to maintain airtightness.

In addition, the inner space of the heat recovery inlet / outlet pipe 200 is divided into two spaces by the partition 210, and one space around the partition 210 is connected to the expansion tank 100 so that the heat- And the other space is provided with a heat return flow path (230) for discharging heat recovery water from the expansion tank (100).

Therefore, the heat recovery water to which the heat is transferred to the heat source is introduced into the expansion tank 100 through the heating water return inflow channel 220, and the heat recovery water in which the water is separated from the expansion tank 100, (230) to the circulation pump (300).

The circulation pump 300 is connected to the heat recovery inlet / outlet 200 to circulate the heat recovery water discharged through the heat recovery / discharge passage 230 to the main heat exchanger (not shown).

Since the heating water return inlet pipe 8 for allowing the heating water return to the inside of the expansion tank 1 and the heating water return water outlet pipe 9 for releasing the heating water of the expansion tank 1 are separately provided in the conventional case, A packing installation process for installing a packing to seal the gap between the pipe and the expansion tank 1 must be separately performed for each pipe. However, in the case of the present invention, the heating return is performed through one pipe (heating return inlet and outlet inlet 200) Since a packing installation process for installing a packing only in one pipe is performed, the manufacturing cost is reduced and the entire assembly process is simplified .

4, in the expansion tank 100, a direction of movement of the heat recovery water flowing into the expansion tank 100 through the heat recovery inlet / outlet pipe 200 is changed, A plate 110 is provided,

The first guide plate 110 is integrally formed in the expansion tank 100 and is located on the upper side of the heating return inflow channel 220 and moves upward along the heating return inflow channel 220, The moving direction of the heat recovery water is changed so as to be deflected at a predetermined angle in the upward direction (upward inclination angle of about 45 degrees with respect to the horizontal plane) from the upper direction while blocking the upper side of the heating water flowing into the interior of the expansion tank 100.

At this time, the length of the first guide plate 110 toward the heat return flow path 230 is shorter than the width of the heat return flow path 220.

If the length of the first guide plate 110 toward the heat return flow path 230 is longer than the width of the heat return flow path 220, the heat recovery water flowing into the interior of the expansion tank 100 The bubbles mixed in the heating and returning water flow through the heating water-returning discharge passage 230 located adjacent to the heating water-returning inflow passage 220 after the first guide plate 110 hits the first guide plate 110, .

However, if the length of the first guide plate 110 toward the heat return flow path 230 is shorter than the width of the heat return flow path 220, the heating of the first guide plate 110 to the interior of the expansion tank 100 The return flow is inclined upward with respect to the horizontal plane after the first guide plate 110 hits the first guide plate 110 so that the bubbles mixed in the heating return can be prevented from being discharged through the heating return flow path 230.

Meanwhile, in the present invention, the second guide plate 120 may be further provided so that the direction of movement of the heat recovery channel is changed.

The second guide plate 120 is integrally connected to the first guide plate 110 through the connection portion 160 and is spaced apart from the first guide plate 110 by a predetermined distance, An opening 150 is formed between the first guide plate 110 and the second guide plate 120 so as to be opened in the inner space of the expansion tank 100. The position of the second guide plate 120 is determined by the position of the first guide plate 120, (110).

Therefore, the heat recovery water flowing into the expansion tank 100 while moving upward along the heating water return inflow channel 220 is changed to be inclined upward in the moving direction while bumping against the first guide plate 110, A part of the changed heating water flow is introduced in the upward direction D2 of the expansion tank 100 through the opening part 150 so that the bubbles included in the heating water return are prevented from being discharged to the heating water discharge flow path 230 And the remaining heating water is again bended by the second guide plate 120 to be bent at a predetermined angle so that the moving direction becomes a horizontal direction D3 so that the lower part of the expansion tank 100 is mixed with the heating water in the expansion tank 100 And then discharged through the heating water return discharge passage 230.

The first guide plate 110 and the second guide plate 120 can be moved in the upward direction along the heating return flow passage 220 while the heat transfer water flowing into the expansion tank 100 moves in the upward direction. And is mixed with the heating water in the expansion tank 100 while circulating the lower portion of the expansion tank 100 when the water is introduced into the expansion tank 100 so that the heating water stored in the expansion tank 100 flows into the expansion tank 100 The water is heated up to the upper side of the water surface due to the heating water return, so that water overflow occurs or the water surface is slammed to prevent the noise from being generated.

5 and 6, a circulation pump connection part 240 is formed in the heating return flow inlet / outlet 200 so that the circulation pump 300 is connected to the circulation pump connection part 240, The flow rate regulating plate 241 is formed so as to regulate the flow rate of the heat exchange water discharged through the heating return flow path 230 to the inside of the discharge flow path 230.

A plurality of moving holes 241-a are formed in the flow rate regulating plate 241 so as to move the heating water to the circulation pump 300 and the moving holes 241-a are formed in a lattice shape But the present invention is not limited thereto, and it can be formed by deforming into various shapes such as a honeycomb shape.

Therefore, the heating water returning from the heating water discharge passage 230 collides with the flow rate control plate 241 before being supplied to the circulation pump 300, so that the flow velocity is reduced and the flow is stabilized, 300 to prevent the generation of noise due to the extension of the service life of the circulation pump 300.

While the invention has been shown and described with reference to certain preferred embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. Therefore, the above description does not limit the scope of the present invention, which is defined by the limitations of the following claims.

1: expansion tank 2: circulation pump
3: main heat exchanger 4: burner
5: Three sides 6: Hot water heat exchanger
7: Heating water supply pipe 8: Heating return pipe
9: Heating return pipe 100: Expansion tank
110: first guide plate 120: second guide plate
130: Heating return inlet 140: Water level sensor
150: opening part 160: connection part
200: heating return flow inlet 210: partition wall
220: heating return flow inlet channel 230: heating return exhaust channel
240: Circulation pump connection part 241: Flow rate control plate
241-a: transfer hole 300: circulation pump

Claims (11)

An expansion tank provided with a heating water inlet and outlet and a heating water quantity stored therein;
The upper part is inserted into the expansion tank through the heating water inlet and the partition is partitioned into a predetermined space so that a heat exchange water is introduced into the expansion tank at one side space around the partition wall A heating return flow inlet for providing a heating return flow path and a heat return flow outlet for providing a heating return flow path for discharging heat recovery water separated from the expansion tank in the other space; And
A circulation pump connected to the heating return flow inlet and circulating the heating return water discharged through the heating return flow discharge channel;
Wherein the at least one air expansion tank is disposed in the atmosphere.
The method according to claim 1,
A first guide which is located on the upper side of the heating water return inflow passage and upwardly moves through the heating water inflow inflow path to guide the movement direction of the heating water passage to be laterally changed while intercepting the upper side of the heating water flowing into the expansion tank; Wherein the gas-liquid separator is provided with an air-expanding expansion tank.
3. The method of claim 2,
And a second guide plate disposed at a predetermined distance from the first guide plate and guiding the moving direction of the heating water returning in the lateral direction through the first guide plate to change in a horizontal direction, Gas boiler with tank.
3. The method of claim 2,
And the length of the first guide plate toward the heat return flow path is shorter than the width of the heat return flow path.
The method of claim 3,
Wherein the first guide plate is integrally formed with the expansion tank,
Wherein the first guide plate and the second guide plate are connected by a connecting portion.
The method of claim 3,
Wherein an opening portion is formed between the first guide plate and the second guide plate so that a part of the heating return water flowing into the expansion tank through the opening portion flows into the upper side of the expansion tank. One gas boiler.
The method of claim 3,
And the second guide plate is located higher than the first guide plate.
The method according to claim 1,
And a circulation pump connection part is formed in the heating return flow inlet to connect the circulation pump.
9. The method of claim 8,
A flow rate regulating plate is formed in the circulation pump connection portion so that the flow rate of the heat return water discharged to the circulation pump through the heating return flow path is reduced,
And a plurality of moving holes are formed in the flow rate control plate such that the heating water is moved toward the circulation pump.
10. The method of claim 9,
Wherein the flow rate regulating plate is located inside the heating return flow path.
10. The method of claim 9,
Wherein the plurality of moving holes are formed in a lattice or a honeycomb shape.

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