KR100504378B1 - Electric boiler - Google Patents

Abstract

The present invention relates to an electric boiler, and more particularly, to shorten the time required to heat the water stored in the tank to a temperature suitable for use as hot water or heating water, and to reduce the power consumed at this time, suddenly cold water when using hot water The present invention relates to an electric boiler capable of preventing a phenomenon from occurring, and includes a main heating tank and a plurality of auxiliary heating tanks each having electrodes therein; It is provided at intervals on the outside of the electrode rod of the main heating tank, the preheating means is provided to allow a portion of the water stored in the main heating tank to be heated by the electrode rod therein; The water heated by the preheating means is configured to continuously heat and circulate through a plurality of auxiliary heating tanks by the operation of a pump, thereby heating the water stored in the tank to a temperature suitable for use as hot water or heating water. Not only can significantly shorten the time, but also to reduce the power consumption, there is an advantage that can further increase the efficiency and economics of the electric boiler.

Description

Electric boiler

The present invention relates to an electric boiler, and more particularly, to shorten the time required to heat the water stored in the tank to a temperature suitable for use as hot water or heating water, and to reduce the power consumed at this time, suddenly cold water when using hot water It relates to an electric boiler so that this phenomenon can be prevented.

In general, an electric boiler heats water by electric heat so that the heated water is circulated to be heated or used as hot water.

4 is a schematic configuration diagram showing an example of a conventional electric boiler, in which a heating tank 100 is usually provided, and an electrode rod E is installed inside the heating tank 100 to be heated by the electrode rod E. Referring to FIG. The water in the tank 100 is configured to be heated, and the water in the heated heating tank 100 is circulated by the pump 200 to be used as heating water or hot water, and the heating water is again heated tank ( It is configured to return to the 100) side and circulate.

Usually, the heating tank 100 can increase the temperature of the water to about 70 ~ 80 ℃ only by heating about 30 hours, 30kw on the basis of 30kw electrode (E), the amount of power consumed is 210 ~ 250kw consumed time This takes a lot of power, a large amount of power consumption, there was a problem that causes inefficiency and economic efficiency of use.

In addition, while the temperature of the water around the electrode (E) is high, the temperature of the other water is low, there is a problem that causes the inconvenience of use by suddenly discharged cold water when using hot water.

In addition, as described above, since the capacity of the heating tank is large, it is difficult to install indoors, resulting in limitations and inconveniences of installation due to the installation outdoors.

Accordingly, the present invention has been made to solve the conventional problems as described above, the object is to reduce the time required to heat the water stored in the tank to a temperature suitable for use as hot water or heating water, the power consumed at this time It is possible to significantly reduce, and to prevent the occurrence of sudden cold water when using hot water.

In order to achieve the object of the present invention is provided with a main heating tank and a plurality of auxiliary heating tank each having an electrode therein; It is provided at intervals on the outside of the electrode rod of the main heating tank, the preheating means is provided to allow a portion of the water stored in the main heating tank to be heated by the electrode rod therein; The water heated by the preheating means is provided with an electric boiler characterized in that the continuous heating and circulation is configured to pass through a plurality of auxiliary heating tank by the operation of the pump.

In addition, the preheating means is formed of a tubular portion of a larger diameter than the electrode rod, the tubular portion is formed in the lower side is a pipe inlet communicating with the interior of the main heating tank, the upper side is characterized in that the outlet is connected to the auxiliary heating tank is formed. .

In addition, the heating tube is characterized in that installed in the vertical direction with respect to the main heating tank.

In addition, the heating tube is characterized in that the inclined to one side of the main heating tank.

In addition, the auxiliary heating tank is composed of vertical, first, second and third auxiliary heating tanks having the same shape and size, the first auxiliary heating tank has a first inlet port communicating with the outlet of the local preheating means on the lower side The first auxiliary heating tank and the second auxiliary heating tank are respectively formed with a first outlet port and a second inlet port connected to each other by a first connection pipe on the upper side, and the second auxiliary heating tank and the third auxiliary heating tank are A second outlet port and a third inlet port are respectively formed on the lower side by a second connection pipe, and a third outlet port is connected to the pump on the upper side of the third auxiliary heating tank.

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration of the present invention according to the embodiment.

1 is a schematic block diagram showing the overall configuration of an embodiment of the present invention.

As shown therein, the present invention includes a main heating tank 1 and a plurality of auxiliary heating tanks, that is, first, second and third auxiliary heating tanks 2, 3 and 4, each of which has an electrode rod ( E) is mounted, and configured to be forced circulation by the operation of the pump 200.

That is, while the conventional heating tank is composed of a single heating tank having a capacity of 800 L and an electrode of 15 kw, the present invention has a capacity of 400 L and a main heating tank 1 having an electrode E of 2 kw, and a small capacity of 1 kw. The first, second, and third auxiliary heating tank (2) (3) (4) having an electrode (E) of the separation is characterized in that, with the electrode (E) of the main heating tank (1) inside the tank It is characterized in that it is configured to heat only some water without heating to all the water contained in it.

To this end, the main heating tank 1 has a preheating means 12 including an electrode rod (E), the preheating means 12 is provided to be inclined toward one side of the main heating tank (1), the heating The first auxiliary heating tank 2 and the preheating means 12 are connected by a pipe so that the purified water can flow into the first auxiliary heating tank 2.

In addition, the first, second and third auxiliary heating tanks (2), (3) and (4) are all installed vertically with the same capacity and size, and by the operation of the pump 200 their water flow and circulation is more Piped to make it easy.

That is, the first auxiliary heating tank 2 is configured such that water introduced through the first inlet 21 at the lower side can be discharged to the outside through the first outlet 22 at the upper side, and the second auxiliary heating is performed. The tank 3 flows water supplied from the first auxiliary heating tank 2 through the first connection pipe 5 into the second auxiliary heating tank 3 through the second inlet 31 on the upper side. It is configured to be discharged to the outside through the lower side second outlet 32, the third auxiliary heating tank 4 is the water supplied from the second auxiliary heating tank 3 through the second connecting pipe (6) It is configured to be introduced into the interior of the third auxiliary heating tank (4) through the third inlet (41) of the lower side to be discharged to the outside through the upper third outlet (42).

2 is a longitudinal sectional view showing the main heating tank of FIG.

As shown therein, the preheating means 12 of the present invention is provided at intervals on the outer side of the electrode rod E inclined to one side of the main heating tank 1, and a tube having a diameter larger than that of the electrode rod E. It is formed by the body portion 12a.

In addition, the pipe part 12a has a pipe inlet 12b communicating with the inside of the main heating tank 1 at a lower side thereof, and has a suction force generated by the operation of the pump. A part is configured to be introduced into the inside of the tubular portion 12a through the pipe inlet 12b, and the auxiliary water is supplied to the upper side so that the inflowed water is heated by the electrode rod E and then sent to the auxiliary heating tank. An outlet 12c connected to the heating tank is formed.

On the other hand, the preheating means 12 is installed to be inclined to one side with respect to the main heating tank 1 is just one embodiment for ensuring the flow and circulation of water, the electrode rods in the heating tank like a conventional electric boiler The preheating means 12 may be installed vertically with respect to the main heating tank 1 as installed vertically.

Reference numeral 11 is a tank inlet port.

3 is a longitudinal cross-sectional view illustrating the first auxiliary heating tank of FIG. 1.

As shown therein, the first auxiliary heating tank 2 of the present invention forms a vertical tube with a small diameter and a long length, and the electrode rod E is vertically installed at the center of the first auxiliary heating tank 2. The space between E and the first auxiliary heating tank 2 is formed to be somewhat narrow, and the water preheated by the preheating means passes through the lower first inlet 21 of the first auxiliary heating tank 2. After being introduced into and heated by the electrode (E), it is configured to be discharged to the outside through the upper first outlet 22.

The second auxiliary heating tank 3 and the third auxiliary heating tank 4 also form the same form as the first auxiliary heating tank 2.

Next will be described in detail the operating state of the present invention configured as described above.

First, a part of the water stored in the main heating tank 1 is introduced into the pipe portion 12a through the pipe inlet 12b of the pipe portion 12a by the operation of the pump 200, and the inflow The heated water is heated by the electrode rod E mounted inside the tubular portion 12a. The heated water is again discharged from the outlet 12c of the tubular portion 12a and the first auxiliary heating tank 2. It is introduced into the first auxiliary heating tank 2 through the inlet 21 and heated by the electrode E. (See FIGS. 1 and 2.)

In addition, the water inside the first auxiliary heating tank (2) heated by the electrode (E) is again the first outlet 22 of the first auxiliary heating tank (2) and the first connecting pipe (5) and the first 2 is introduced into the second auxiliary heating tank 3 through the second inlet 31 of the auxiliary heating tank 3 and heated by the electrode E, and the heated water is again supplied to the second auxiliary heating tank 3. Through the second outlet 32 of the heating tank (3) and the second connecting pipe (5) and the third inlet (41) of the third auxiliary heating tank (4) into the third auxiliary heating tank (4) It is repeated to be heated again by the electrode rod (E).

Then, the continuously heated water is to be used as hot water or heating water by the user's choice, the water used as heating water is supplied to the main heating tank (1) again and repeated heating as described above Continuously performing the cycle is performed (see Fig. 1).

Therefore, in the present invention, the heating time is not only shortened by heating the water inside the tank by using the electrode at a time, but by dividing it continuously and repeatedly to circulate continuously, and sufficient heating is performed even with the electrode having a small rated output, thereby reducing the power consumption. There is an advantage.

That is, in the related art, the temperature of water can be increased to about 70 to 80 ° C. only by heating about 30 hours with a 30 kw electrode, whereas the amount of power consumed is 210 to 250 kw, whereas the present invention increases the temperature of water to about 70 to 80 ° C. It takes 1 hour 30 minutes to 2 hours to raise, and it is enough that the electrode used for heating also has a rated output of 5 kw, and at this time, the power consumption is only 50 to 60 kw, so that the existing electric Better than the boiler

In addition, as described above, since only water heated continuously and repeatedly by the electrode while passing through the main heating tank and the plurality of auxiliary heating tanks is used as hot water, the phenomenon in which cold water is suddenly discharged when hot water is used does not occur at all.

As described above, the present invention does not heat the water in the tank at a time by using the electrode, but by dividing it continuously and repeatedly heating to circulate the time required to heat the water stored in the tank to a temperature suitable for use as hot water or heating water. Not only can significantly shorten, but also has the effect of reducing the power consumption, there is an advantage that can further increase the efficiency and economics of the electric boiler.

In addition, since the present invention uses only water that is continuously heated repeatedly by dividing the water in the tank as hot water, the present invention also has the effect of eliminating the inconvenience of using cold water suddenly when hot water is used.

In addition, the present invention can be installed indoors by using a relatively small capacity tank has the effect of eliminating the limitations and inconvenience of the installation due to the large capacity of the existing tank to be installed outdoors.

1 is a schematic block diagram showing the configuration of an embodiment of the present invention.

Figure 2 is a longitudinal sectional view showing the main heating tank of Figure 1;

Figure 3 is a longitudinal sectional view showing the auxiliary heating tank of Figure 1;

Figure 4 is a schematic configuration diagram showing the configuration of a conventional electric boiler.

* Explanation of symbols for main parts of the drawings

1: main heating tank

  11: tank inlet 12: preheating means

  12a: pipe part 12b: pipe inlet

  12c: outlet

2: first auxiliary heating tank

  21: first inlet 22: second inlet

3: 2nd auxiliary heating tank

  31: second inlet 32: second outlet

4: 3rd auxiliary heating tank

  41: third inlet 42: third outlet

5: first connector line 6: second connector line

E: electrode

Claims (5)

A main heating tank and a plurality of auxiliary heating tanks each having electrodes therein; It is formed of a tubular portion having a larger diameter than the electrode, the tubular portion is provided with a pipe inlet for communicating with the inside of the main heating tank at the lower side, the upper side is provided with a preheating means formed with an outlet for connecting to the auxiliary heating tank;  The auxiliary heating tank is composed of vertical first, second and third auxiliary heating tanks having the same shape and size, the first auxiliary heating tank is formed with a first inlet communicating with the outlet of the preheating means on the lower side, The first auxiliary heating tank and the second auxiliary heating tank are formed at the upper side with a first outlet and a second inlet connected to each other by a first connection pipe, and the second auxiliary heating tank and the third auxiliary heating tank are located at the lower side. And a second outlet and a third inlet connected to each other by a second connection pipe line, and a third outlet connected to a pump on an upper side of the third auxiliary heating tank. delete delete delete delete