KR100951079B1 - Electric boiler - Google Patents

Abstract

PURPOSE: A dual instant heating electric boiler is provided to reduce preheating time by mounting a special dual heating area in a hot water storing chamber. CONSTITUTION: A dual instant heating electric boiler comprises a separator(13), a guide plate(14), a first isolated chamber(21), a first heating chamber(22), a first heater, and a storage room(41). The separator divides a hot water storing chamber(10) into a top part and a bottom part. The guide plate is expanded from the hot water storing chamber. The lower part of the storage room is connected to the upper part of the first isolated chamber through a connection pipe(43).

Description

Double instant heating electric boiler {Electric boiler}

The present invention relates to a double instantaneous heating electric boiler in which the heating medium of the heating medium is electric, and more particularly, two independent heating chambers and two isolation chambers surrounding the outside of the heating chamber and the isolation chamber and the heating of the electric heater. A double instantaneous type electric boiler which minimizes heat loss of instantaneous supply of heating and heated heating water by having a separator to smoothly supply heated heating water by dividing the upper and lower parts of a storage room and a storage room for maximizing capacity. will be.

In general, a boiler is a device that generates heat energy using fuel or electricity such as oil or gas as an energy source and heats the medium, that is, water, to generate heating water or hot water. It is divided into boiler, gas boiler and electric boiler.

Since boilers using fuels such as oil and gas as energy sources burn fuels, many components are used for storing, supplying, burning, and exhausting fuels. In order to prevent gas poisoning accidents caused by leakage of exhaust gas and supply of air required for combustion of fuel, a separate boiler room must be provided that is well ventilated and separated from the heating zone. Since the length of the complex is long, there is a problem that the loss of thermal energy is large and the workability is reduced. In the case of gas boilers, gas poisoning and explosion accidents caused by gas leakage cause enormous loss of human life and property, and thus it is cumbersome and inconvenient to operate, requiring periodic inspection of burners and pipes.

On the other hand, since electric boilers use electricity as an energy source, installation and operation are easier and hygienic than combustion-type boilers, and the risk of accidents due to overheating is relatively small, and the number of users is increasing.

The electric boiler is configured to directly or indirectly heat a large-capacity storage tank for storing water supplied from a water supply source, and an electric heater that generates and heats the water stored and purified in the storage tank, and in the storage tank. It is used to supply heated water to the building's heating water or domestic hot water through heating pipes and heating pumps.

That is, the electric boiler heats the low temperature water stored in the water storage tank 2 through the water supply pipe 5 to a high temperature through the heat transfer heater 3 installed in the lower portion of the water storage tank 2 as shown in FIG. To be discharged. At this time, the low temperature water stored in the reservoir 2 is gradually heated by the heat transfer heater 3 and is heated as a whole while circulating the inside of the reservoir 2 by the temperature difference. That is, the water stored in the reservoir 2 is heated as a whole over time.

Here, the water supply pipe 5 and the drain pipe 4 are connected to the circulation heating pipe not shown. Therefore, the heating pipe not shown uses hot water supplied to the drain pipe 4 to heat the floor or supplies warmth to the factory or farmhouse's plastic house through a blower fan not shown.

In the non-illustrated heating pipe, both ends are connected to the drain pipe 4 and the water supply pipe 5, respectively, to form a closed loop. Therefore, the heating pipe receives and circulates high temperature hot water through the drain pipe 4, and then supplies the hot water cooled while being circulated to the water supply pipe 5 again.

That is, the heating pipe is re-supply the hot water used for heating to the water supply pipe 5 so that the hot water of the hot water changed into low temperature water while being used for heating is heated again by the electrothermal heater 3 and recycled through the drain pipe (4).

At this time, the hot water re-supplied to the water supply pipe 5 by the heating pipe is converted to low temperature by heat exchange during heating and resupplied. That is, the water supply pipe 5 is supplied again with low temperature low temperature water. Therefore, the heat transfer heater 3 heats again the low temperature water supplied to the water supply pipe 5 and supplies it to the pipe 4 of the water storage tank 2.

However, such a general electric boiler uses hot water immediately in a timely manner because hot water is discharged through the drain pipe 4 only when the low temperature water stored in the reservoir 2 is heated by the heat transfer heater 3, as shown. In addition, there is a problem that the heating time of the low temperature water is very excessive.

In particular, when the boiler is manufactured in a large capacity, the low temperature water of the Honghong reservoir 2 needs to be heated for about 1 hour so that the low temperature water is heated to a temperature suitable for heating. Therefore, a large-capacity general electric boiler not only can not use hot water immediately but also cannot continue to use it in a timely manner, and it can be heated only when the heating time of about 1 hour is required.

In addition, a general electric boiler manufactured in a large capacity has an upper drain pipe 4 of the reservoir 2 while heating the low temperature water supplied to the lower side supply pipe 5 of the reservoir 2 after heating. Since hot water is discharged into the reservoir 2), there is also a problem that the electric heater 3 must be continuously operated without stopping.

On the other hand, even if the low temperature water of the reservoir (2) is heated by the heat transfer heater (3) to become hot water, when the external temperature of the reservoir (2) is low, the hot water of the reservoir (2) generates heat loss and heats the heat energy according to the heat loss. Since the heater 3 needs to be replenished, the heating efficiency is lowered.

The present invention has been made to solve the above problems, the object of the present invention is to provide a separate dual heating section in the storage room to heat the medium after rapid heating to apply to heating after the initial operation The present invention provides a double instantaneous heating electric boiler according to the present invention in which the heat loss of the instantaneous heating water is reduced by shortening the time of the heating and aggregating the heated heating to the upper part of the storage room and supplying the heating water directly through the discharge pipe. .

The present invention as described above

In the double instantaneous heating electric boiler which heats and supplies a heater in a storage room provided with an inlet pipe and an outlet pipe through which the medium is flowed in and out of the inside of the heating medium.

A through hole is formed and provided on the inner upper side of the storage chamber to separate the upper and lower portions of the storage chamber;

A guide plate extending from the inside of the storage chamber above the inflow pipe to the interior of the storage chamber;

A first isolation chamber provided inside the water storage chamber at a predetermined distance from the guide plate and having an inlet hole at a lower side to guide the medium introduced from the inlet tube into the inside;

A first heating chamber installed in the first isolation chamber at intervals from an inner side of the first isolation chamber and having through holes formed in upper and lower portions thereof;

A heater that penetrates one side of the storage chamber, the first isolation chamber, and the first heating chamber, respectively, one side of which is provided inside the first heating chamber and the other side of which is installed outside the storage chamber;

It is provided on the upper side of the first isolating chamber, the lower portion is connected to the upper portion of the first isolation chamber in a single communication tube, the upper portion is characterized in that it comprises a storage chamber for connecting to the separator plate with a 2,3 communication tube.

According to the dual instantaneous heating electric boiler according to the present invention, by providing a separate dual heating section in the storage room and rapidly heating the medium and using it for heating, it is possible to shorten the time from application to heating after the initial operation. In addition, by heating the heated heating to the upper portion of the water storage chamber and supplying the heating water directly through the discharge pipe, the heat loss of the instantaneous heating water is reduced.

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

The present invention relates to a boiler in which the heating medium of the heating medium is electric, but the medium may be water or heat medium oil, and the present invention relates to a water storage room 10 and a separator 13, a guide plate 14 and a first containment chamber. 21, a first heating chamber 22, a heater 51, and a storage chamber 41 are included.

The storage room 10 is provided with an inlet pipe 11 and a discharge pipe 12 through which the medium flows in and out on one side of the upper and lower portions as shown in FIG. 2, and the upper and lower portions of the storage room 10 are provided on the upper side. And a separator plate 13 having a through hole 13a formed therein, and a lower side of the guide plate 14 extending from the inside of the water storage chamber 10 above the inflow pipe 11 to the inside of the water storage chamber 10. ) Is provided.

The first isolation chamber 21 is provided in the storage chamber 10 at a position spaced apart from the guide plate 14 by a predetermined distance, preferably as shown in FIG. The lower left side of the first isolation chamber 21 maintains a predetermined interval so that the medium flowing into the inlet pipe 11 passes through the guide plate 14 and the first isolation chamber 21 to the upper side of the interior of the water storage chamber 10. Configure it to flow into. In addition, the first isolation chamber 21 has a plurality of inlet holes 21a at the lower side of the first isolation chamber 21 so that the medium flowing through the inlet pipe 11 flows into the first isolation chamber 21. Form to form.

The first heating chamber 22 is installed at a predetermined distance from the first isolation chamber 21 in the first isolation chamber 21 and is formed by forming a plurality of through holes 22a in the upper and lower portions thereof. .

As shown in FIG. 2, the heater 51 penetrates through the storage chamber 10, the first isolation chamber 21, and one side of the first heating chamber 22, and one side of the first heating chamber 22. ) And the other side is configured to be installed to the outside of the storage room (10).

The first heater 51 is connected to the power supply is connected to the electrical outlet is protruded to the outside of the storage chamber 10 to perform the role of heating the medium introduced into the first heating chamber 22.

The storage chamber 41 is provided on the upper side of the first isolation chamber 21, and the lower portion thereof is connected to the upper portion of the first isolation chamber 21 by the first communication tube 43, and the upper and second communication tubes 61 and 62 are connected to the upper portion of the first isolation chamber 21. It is configured to connect with the separator (13).

Meanwhile, the separator 13 of the double instantaneous heating electric boiler according to the present invention has a plurality of through holes 13a arranged at equal intervals around the separator 13 as shown in FIGS. 3 and 4. It may be formed by a plurality or may be formed into the inside of the separator (13).

In addition, the separator 13 is provided with two or three communication pipes 61 and 62 as shown in FIG. 5, and cut through holes instead of the through holes 13a at equal intervals in respective yarn directions at the outer diameter. 13b may be formed, and the cut through hole 13b may be formed by cutting in a circular shape, an oval shape, or an arc shape.

Hereinafter will be described the operation relationship of the dual instantaneous heating electric boiler configured as described above.

As shown in FIG. 2, when the medium flows into the inlet pipe 11, the moving path of the medium rides on the lower side of the guide plate 14, and a part of the medium passes through the guide plate 14 and the first isolation chamber 21. It moves to the upper side of the storage room 10, and a part of the water is introduced into the first isolation chamber 21 through the inlet hole 21a of the first isolation chamber 21.

Here, the medium flowing through the inlet hole 21a of the first isolation chamber 21 flows into the first heating chamber 22 through the through hole 22a of the first heating chamber 22 and flows into the first heating chamber 22. Is heated by one heater 51. The heated medium is then transferred to the storage chamber 41 through the first communication pipe 43, where a part of the heated medium is convection in the first containment chamber 21, and this phenomenon is first heated. The heat loss of the heated medium in the chamber 22 is blocked.

On the other hand, the heated medium introduced into the storage compartment 41 is moved to the upper side of the water storage chamber 10 by the two communication tube 61 and the three communication tube 62 is discharged through the discharge pipe 12 a part of the medium. A part of the separator 13 moves to the lower side of the water storage chamber 10 through the through hole 13a to increase the temperature inside the water storage chamber 10 as a result of convection.

Thus, in the present invention, the first isolation chamber 21 is provided so that the medium heated by the first heating chamber 22 prevents heat loss, thereby improving the efficiency of the first heater 51, and thus improving the efficiency of the boiler. It is effective.

In addition, by temporarily storing the medium heated from the first heating chamber 22 in the storage chamber 41 and supplying it to the upper side of the storage chamber 10, it is possible to maintain a smooth supply of heating water even when the boiler is first operated. In addition, in order to achieve the same effect by the configuration of the separator 13 provided in the upper portion of the storage room 10 to some extent to isolate the upper side and the lower side of the storage room 10 directly to the discharge pipe 12. The supply minimizes heat loss of the rapidly heated heating water and supplies the heating water through the discharge pipe 12 within a short time.

2 and 3 communication pipes 61 and 62 of FIG. 2 further protrude upward discharge pipes 61a and 62a in succession to the 2 and 3 communication pipes 61 and 62 as shown in FIG. 61a and 62a are installed to face the direction of the discharge pipe 12, and are formed to be discharged at a higher position than the location of the discharge pipe 12 so that the heated medium is discharged and is supplied in the direction of the discharge pipe 12 to be discharged. It is to be discharged while maintaining a high temperature.

Although the present invention has been described in connection with the preferred embodiment, those of ordinary skill in the art will be able to easily make various changes and modifications without departing from the essential characteristics of the invention. Therefore, it should be understood that the disclosed embodiments are to be considered in an illustrative rather than a restrictive sense, and that the true scope of the invention is indicated by the appended claims rather than by the foregoing description, and all differences within the scope of equivalents thereof, .

1 is a cross-sectional view showing an example of a conventional electric boiler.

2 is a cross-sectional view showing an example of a double instantaneous heating electric boiler according to the present invention.

3 is a cross-sectional plan view showing an example of the separator of FIG. 2 of the present invention.

4 is a cross-sectional plan view showing another example of the separator of Figure 2 of the present invention.

Figure 5 is a cross-sectional view showing another example of the separator of the present invention Figure 2

6 is a cross-sectional view showing another embodiment of the first containment chamber of the present invention;

7 is a cross-sectional view showing another embodiment of the communication tube of the present invention.

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

10: storage room 11: inlet pipe

12: discharge pipe 13: separator

14: guide plate 21: the first isolation chamber

22: first heating chamber 41: storage compartment

43: 1 communication tube 61: 2 communication tube

62: 3 communication pipe 42: 4 communication pipe

51: 1 heater 61a, 62a: upward discharge pipe

Claims (4)

The heating medium of the heating medium is electricity, and on one side of the upper and lower parts of the heating medium to the double instantaneous type electric boiler which heats and supplies the heater in the storage room 10 provided with the inflow pipe 11 and the discharge pipe 12 through which the medium flows in and out. In A through hole (13a) is formed and is provided on the inner upper side of the water storage chamber (10) separating the upper and lower portions of the water storage chamber (10); A guide plate (14) extending from the inside of the water storage chamber (10) above the inflow pipe (11) to the inside of the water storage chamber (10); The first plate is provided in the water storage chamber 10 at a position spaced apart from the guide plate 14 and the inlet hole 21a is formed at the lower side to guide the medium introduced from the inlet pipe 11 to the inside. An isolation chamber 21; A first heating chamber 22 installed at an interval with an inner side of the first isolation chamber 21 in the first isolation chamber 21 and having a through hole 22a formed at an upper side and a lower side thereof; The storage chamber 10, the first isolation chamber 21, and the first heating chamber 22 penetrate one side, respectively, one side of which is provided inside the first heating chamber 22 and the other side of the storage chamber 10. 1 heater 51 which is installed to the outside; It is provided on the upper side of the first isolation chamber 21 and the lower portion is connected to the upper portion of the first isolation chamber 21 by a first communication tube 43, the upper portion is the separator plate 13 by the second and third communication tube 62. A storage compartment 41 to be connected with; Dual instantaneous heating electric boiler, characterized in that comprising a. The method of claim 1, The double through-hole 13a of the separator 13 is formed by arranging a plurality of the same interval around the separator 13, or a plurality of double instantaneous heating, characterized in that formed in the inside of the separator (13). Electric boiler. The method of claim 1, Separation plate 13 is a double instantaneous heating type, characterized in that the two or three communication pipes (61, 62) are provided at predetermined intervals in the center, and the incision through-holes (13b) at equal intervals are formed in the yarn direction at the outer diameter. Electric boiler. The method of claim 1, The second and third communication pipes 61 and 62 form upward discharge pipes 61a and 62a upwards, and are installed to face in the direction in which the discharge pipe 12 is formed, and are discharged at a position higher than that of the discharge pipe 12. Dual instant heated electric boiler, characterized in that forming.

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