KR20140122445A - Instantaneous hot water boiler having hot water mixing structure - Google Patents

Abstract

The present invention relates to an instantaneous hot water boiler with a hot water mixing structure and, in particular, to an instantaneous hot water boiler with a hot water mixing structure which is mounted in the instantaneous hot water boiler using a burner, thereby preventing sudden variation in the temperature of hot water.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a hot water boiler having a hot water mixing structure,

The present invention relates to a hot water boiler having a hot water mixing structure, and more particularly, to a hot water mixing boiler using a burner, a hot water mixing structure for preventing hot water from being rapidly changed The present invention relates to a hot water boiler having a plurality of hot water boilers.

Generally, hot water boilers are also called hot water boilers and they are used where hot water is needed rapidly.

This type of hot water boiler boils fuel in a burner or uses an electric heater to rapidly heat the direct water, and supplies the heated hot water to the user, usually a hot water storage tank is used.

Korean Patent No. 10-721459 and No. 10-993832 disclose a device for use as a net water heater simultaneously with heating, or a single water heater for a single use.

However, in the conventional art, there is a problem that the hot water temperature is rapidly lowered or the hot water temperature is overshooted due to a sudden change in the flow rate when hot water is used.

For example, there is a problem that the user feels cold because the hot water temperature is too low at the initial stage of heating the hot water, and the hot water temperature is too high after a predetermined time to feel a hot or severe burn.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems and it is an object of the present invention to provide a hot water boiler having a hot water mixing structure capable of preventing a sudden change in hot water temperature by mounting a hot water mixing structure in a hot water boiler using a burner .

To this end, a hot water boiler having a hot water mixing structure according to the present invention includes a burner for supplying fuel and igniting it; A heat exchanger for exchanging heat between a heat source generated when the fuel is ignited in the burner and the supplied water; A first hot water mixing chamber having a width at a side where water having been heat-exchanged and a width at a side where water is discharged are narrowed in the heat exchanger; And a water circulation pipe connected to the low temperature water to be supplied to the first hot water mixing chamber after completion of heat exchange in the heat exchanger.

At this time, the second hot water mixing chamber is connected to the water discharge side of the first hot water mixing chamber, the second hot water mixing chamber having a shape having a narrow width on the water inlet side and a wider side toward the water discharge side, 2 The hot water mixing chamber preferably has an hourglass shape.

Further, the heat exchanger is preferably composed of a sensible heat exchanger and a latent heat exchanger.

The water circulation pipe may include a direct water supply pipe for supplying direct water to the latent heat heat exchanger;

A first connection pipe for supplying lukewarm water from the latent heat heat exchanger to the sensible heat exchanger; A second connection pipe for supplying the hot water from the sensible heat exchanger to the first hot water mixing chamber; And a hot water supply pipe for discharging the hot water out of the second hot water mixing chamber.

The apparatus may further include a bypass pipe branched from the first connection pipe and connected to supply the lukewarm water to the first hot water mixing chamber, wherein the bypass pipe is provided with an on-off valve.

Way valve, the water passing through the latent heat heat exchanger is supplied to the first hot water mixing chamber, is supplied to the sensible heat exchanger, or is supplied to the first hot water heat exchanger by adjusting the three-way valve. Or both the first hot water mixing chamber and the sensible heat exchanger.

The present invention as described above is temporarily filled and mixed in an hourglass shaped hot water mixing chamber before providing hot water. Therefore, the hot water temperature is prevented from being changed suddenly primarily.

Further, according to the present invention, when the hot water temperature can not be maintained in an appropriate state only by the mixing effect of the hot water mixing chamber, hot water having a relatively low temperature is mixed through the bypass pipe. Accordingly, the hot water temperature is prevented from being changed suddenly secondarily.

In addition, the present invention includes a latent heat exchanger and a sensible heat exchanger to increase the thermal efficiency and mix the hot water, which has undergone the heat exchange in the latent heat exchanger, through the bypass pipe, thereby preventing the hot water temperature from being drastically changed.

FIG. 1 is a first operational state diagram of a hot water boiler having a hot water mixing structure according to the present invention.
FIG. 2 is a second operating state diagram of a hot water boiler having a hot water mixing structure according to the present invention.

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

1, the present invention includes a burner 110 for burning fuel, a heat exchanger 120 for exchanging heat between a heat source and water, a hot water mixing chamber 130 for mixing hot water, And a water circulation pipe 140 for circulating water along the hot water mixing chamber 130 and the hot water mixing chamber 130.

A bypass pipe 145 branching from the water circulation pipe 140 and bypassing water to the hot water mixing chamber 130 and a water supply control assembly 140 installed at the inlet side of the water circulation pipe 140 150).

According to this configuration, the flame and the combustion gas (hereinafter referred to as "heat source") are provided in the burner 110, and the water circulation pipe 140 circulates water to the heat exchanger 120. In the heat exchanger (120), heat exchange is performed between the heat source and water to generate hot water.

Particularly, in the present invention, heated water (that is, hot water) passing through the heat exchanger 120 is mixed in the process of passing through the hot water mixing chamber 130 and then supplied to the user. Therefore, the hot water temperature is prevented from being changed suddenly primarily.

2, when the hot water temperature can not be maintained in an appropriate state only by the mixing effect of the hot water mixing chamber 130, the hot water having relatively low temperature is passed through the bypass pipe 145 to the hot water mixing chamber 130 Pass. Accordingly, the hot water temperature is prevented from being changed suddenly secondarily.

The heat exchanger 120 is constructed of the latent heat exchanger 122 and the sensible heat exchanger 121 to increase the heat efficiency and to transfer the lukewarm water having undergone heat exchange in the latent heat exchanger 122 to the bypass pipe 145. [ So that the temperature of the hot water can be prevented from changing abruptly.

More specifically, the burner 110 supplies and ignites fuel such as oil or gas. The high temperature flames and combustion gases generated upon ignition of the fuel are blown toward the heat exchanger 120 to heat the water.

2 and 3 illustrate a top-down burner 110 having a burner 110 directed downward so as to discharge a flame downward. However, if a heat source can be supplied to the heat exchanger 120, Various types of burners 110 may also be used.

The heat exchanger 120 ignites the fuel in the burner 110 to cause heat exchange between the generated heat source and the supplied water. A water circulation pipe 140 is connected to the heat exchanger 120 and a heat source generated in the burner 110 is discharged through the heat exchanger 120. Thus, the water flowing along the water circulation pipe 140 is heated by the heat source.

The heat exchanger 120 may be a condensing heat exchanger 120 including a sensible heat exchanger 121 and a latent heat exchanger 122. The sensible heat exchanger 121 is installed close to the burner 110, and the latent heat exchanger 122 is installed thereunder.

The sensible heat exchanger 121 mainly exchanges heat with the flame, and the latent heat exchanger 122 mainly exchanges heat with the combustion gas of the burner 110 to recover latent heat. Conventionally, only a heat exchanger or a single heat exchanger is used, but the sensible heat exchanger 121 and the latent heat exchanger 122 are adopted for the hot water boiler of the instantaneous type, thereby increasing the heat efficiency.

The hot water mixing chamber 130 mixes the heat-exchanged water (i.e. hot water) in the heat exchanger 120. This is to prevent the hot water temperature from becoming under or overshoot due to a sudden change in flow rate when hot water is used so that it is not excessively cold or hot.

When both the sensible heat exchanger 121 and the latent heat exchanger 122 are used as the heat exchanger 120, the lukewarm water heated by the latent heat exchanger 122 is supplied to the sensible heat exchanger 121 And the hot water, which is secondarily heated by the sensible heat exchanger 121, is supplied to the hot water mixing chamber 130.

Meanwhile, the hot water mixing chamber 130 includes a first hot water mixing chamber 131. The first hot water mixing chamber 131 has a shape in which the width of the side where the heat-exchanged water flows in the heat exchanger 120 is wide and the width thereof becomes narrower toward the side where the water is discharged.

That is, the first hot water mixing chamber 131 of the present invention forces a bottleneck phenomenon. Thus, the previously filled water and the back supplied water are mixed with each other. For example, if the previously filled water temperature is low and the temperature of the water supplied later is high, they are mixed with each other to maintain an appropriate temperature.

As described above, the present invention has a hot water mixing effect even if only the first hot water mixing chamber 131 is provided alone. However, it is preferable to further connect the second hot water mixing chamber 132 to the lower part of the first hot water mixing chamber 131 (i.e., the direction in which water flows out).

The second hot water mixing chamber 132 has a shape in which the width of the water inlet side is narrow and the width of the second hot water mixing chamber 132 is increased toward the water outlet side. Accordingly, the entire hot water mixing chamber 130 including the first hot water mixing chamber 131 and the second hot water mixing chamber 132 has an hourglass shape.

If the second hot water mixing chamber 132 is further included, the water discharged from the first hot water mixing chamber 131 may be further mixed while being discharged into the expanded space. In addition, it also has an effect of compensating for the problem caused by the bottleneck in the first hot water mixing chamber 131.

The water circulation pipe 140 is installed such that the low temperature water is supplied to the hot water mixing chamber 130 after the heat exchange in the heat exchanger 120 is completed. Water is circulated in the order of the latent heat exchanger 122, the sensible heat exchanger 121, the first hot water mixing chamber 131 and the second hot water mixing chamber 132, so that the water circulation pipe 140 also sequentially connects them .

The water circulation pipe 140 includes a direct water supply pipe 141 for supplying direct water to the latent heat exchanger 122 and a first connection for supplying the lukewarm water discharged from the latent heat exchanger 122 to the sensible heat exchanger 121. [ And a second connection pipe 143 for supplying the hot water from the sensible heat exchanger 121 to the first hot water mixing chamber 131 and a second hot water mixing chamber 132 for discharging the hot water out of the second hot water mixing chamber 132. [ And a hot water supply pipe (144).

The bypass pipe 145 bypasses the heat-exchanged lukewarm water in the latent heat exchanger 122 to the first hot water mixing chamber 131 to be mixed with the water filled in the first hot water mixing chamber 131. This prevents sudden temperature changes of water.

One end of the bypass pipe 145 is connected to the first connection pipe 142 between the latent heat heat exchanger 122 and the sensible heat exchanger 121 so that the water can be bypassed and the other end is connected to the sensible heat exchanger 121 And the first hot water mixing chamber 131. The first hot water mixing chamber 131 and the second hot water mixing chamber 131 are connected to each other.

However, since the other end of the bypass pipe 145 may be directly connected to the first hot water mixing chamber 131, in this case, a problem may arise in terms of reverse flow generation and supply of water. It is preferable to be connected.

The bypass pipe 145 is provided with an on-off valve M_V. It is preferable that the on-off valve M_V is an electronic control valve that is automatically controlled to be opened or closed by a controller (not shown). Accordingly, the water passing through the latent heat exchanger 122 is selectively supplied to the first hot water mixing chamber 131 by operating the on-off valve M_V.

In particular, the on-off valve M_V is a three-way valve and the water passing through the latent heat heat exchanger 122 is supplied only to the first hot water mixing chamber 131 by the adjustment of the three- 1 mode), or only to the sensible heat exchanger 121 (second mode) or simultaneously to the first hot water mixing chamber 131 and the sensible heat exchanger 121 (third mode).

When the first mode is operated, the lowest temperature water is supplied to the first hot water mixing chamber 131 because the hot water is not passed through the sensible heat exchanger 121. When the operation mode is the second mode, all the water passes through the sensible heat exchanger 121, so that the water of the highest temperature is supplied to the first hot water mixing chamber 131. When the first mode is operated in the third mode, the first and second modes are merged, so that the intermediate temperature water is supplied to the first hot water mixing chamber 131. Therefore, it is possible to supply the hot water having the optimum temperature according to the present situation.

The water supply regulating assembly 150 is connected to the water supply side of the water circulation pipe 140, that is, the direct water supply pipe 141. The water supply control assembly 150 includes a flow sensor and a flow control valve. Accordingly, the supply amount of low-temperature direct water supplied through the water circulation pipe 140 is controlled and the temperature change of the hot water is prevented from being drastically changed.

The control of the water supply regulating assembly 150 and the operation of the on-off valve M_V are controlled by the controller. At this time, the direct water supply pipe 141, the second connection pipe 143 and the hot water supply pipe 144 1 temperature sensor S1 to the third temperature sensor S3.

The specific embodiments of the present invention have been described above. It is to be understood, however, that the scope and spirit of the present invention is not limited to these specific embodiments, and that various modifications and changes may be made without departing from the spirit of the present invention. If you have, you will understand.

Therefore, it should be understood that the above-described embodiments are provided so that those skilled in the art can fully understand the scope of the present invention. Therefore, it should be understood that the embodiments are to be considered in all respects as illustrative and not restrictive, The invention is only defined by the scope of the claims.

110: Burner
120: heat exchanger
121: sensible heat exchanger
122: latent heat exchanger
130: hot water mixing chamber
131: first hot water mixing chamber
132: second hot water mixing chamber
140: Water circulation pipe
141: Direct supply pipe
142: first connector
143: second connector
144: Hot water supply pipe
145: Bypass pipe
150: Water supply control assembly

Claims (6)

A burner 110 for supplying fuel and igniting the fuel;
A heat exchanger 120 for exchanging heat between a heat source generated when the fuel is ignited in the burner 110 and the supplied water;
A first hot water mixing chamber 131 having a shape in which the width of the side where the heat-exchanged water flows in the heat exchanger 120 is wide and the width becomes narrower toward the side where the water is discharged; And
And a water circulation pipe (140) connected to the low temperature water to be supplied to the first hot water mixing chamber (131) after the heat exchange in the heat exchanger (120) is completed. Snack hot water boiler. The method according to claim 1,
A second hot water mixing chamber 132 having a shape in which the width of the water inlet side is narrow and the width of which is increased toward the water outlet side is connected to the water discharge side of the first hot water mixing chamber 131, Wherein the mixing chamber (131) and the second hot water mixing chamber (132) have an hourglass shape. 3. The method of claim 2,
Wherein the heat exchanger (120) comprises a sensible heat exchanger (121) and a latent heat exchanger (122). The method of claim 3,
The water circulation pipe (140)
A direct water supply pipe 141 for supplying direct water to the latent heat heat exchanger 122;
A first connection pipe 142 for supplying lukewarm water from the latent heat heat exchanger 122 to the sensible heat exchanger 121;
A second connection pipe 143 for supplying the hot water exiting from the sensible heat exchanger 121 to the first hot water mixing chamber 131; And
And a hot water supply pipe (144) for discharging the hot water discharged from the second hot water mixing chamber (132). 5. The method of claim 4,
Further comprising a bypass pipe (145) branched from the first connection pipe (142) and connected to supply the lukewarm water to the first hot water mixing chamber (131), and the bypass pipe (145) Wherein the hot water boiler has a hot water mixing structure. 6. The method of claim 5,
The on-off valve M_V is a three-way valve, and the water passing through the latent heat exchanger 122 is supplied to the first hot water mixing chamber 131 by the adjustment of the three-way valve Is supplied to the sensible heat exchanger (121), or is supplied to the first hot water mixing chamber (131) and the sensible heat exchanger (121).

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