KR101196940B1 - Electric boiler - Google Patents

Abstract

The present invention not only can rapidly obtain hot water of high temperature required for heating and hot water use, but also relates to an electric boiler that maximizes the efficiency of power use by efficiently controlling the fluid flow. The present invention, hot water tank; An inlet pipe formed at a lower end of the hot water tank to introduce water into the inside of the hot water tank; A plurality of heaters are formed at the top, the middle, and the bottom of the hot water tank, respectively, with a stepped height difference, thereby discharging the heated hot water formed at the top of the hot water tank, the top heater part and the bottom heater part, and the top of the hot water tank to the outside. And a discharge pipe. Preferably, the hot water tank is formed in a cylindrical shape, and the inflow pipe is spirally formed at the bottom of the bottom surface of the hot water tank to induce water to rotate inside the hot water tank in a spiral shape. Inside the hot water tank, a plurality of flow guide pins may be further formed in a plate shape having a predetermined length and disposed in a circular shape toward the center thereof. The present invention further includes a proportional control output unit for selectively outputting a proportional control signal to the upper heater unit, the middle heater unit, and the lower heater unit to control each heating state.

Description

Electric Boiler {ELECTRIC BOILER}

The present invention relates to an electric boiler, and more particularly to an electric boiler that can not only rapidly obtain the high temperature hot water required for heating and hot water use, but also maximizes the efficiency of power use by efficiently controlling the fluid flow. will be.

As is well known, an electric boiler is a device that generates heating water by using electricity transmitted from a power generation facility, and in particular, refers to a boiler that generates hot water or steam by using heat generated by electric resistance.

As described above, the conventional electric boiler has a relatively large hot water tank 100, as shown in FIG. 1, and has an electric heater 101 capable of heating hot water therein, and the electric heater ( By operating the 101 to heat the water or latent heat introduced into the interior using the inlet pipe 103 to discharge the heat accumulated by the discharge pipe 102 to enable the use of hot water as well as heating.

However, such a conventional electric boiler has a problem that the heating or hot water is not supplied until the water or the latent heat of the hot water tank becomes a usable constant temperature, and the heating time is long.

In addition, since the entire heat storage tank must be heated to operate a single heater to use heating and hot water, heating takes a long time and requires a large amount of power.

The present invention has been made to solve the above problems, it is possible to rapidly obtain the hot water of the high temperature required for heating and hot water use, as well as to efficiently control the fluid flow to maximize the efficiency of power use electric boiler The purpose is to provide.

Electric boiler according to the present invention for achieving the above object, a hot water tank; An inlet pipe formed at a lower end of the hot water tank to introduce water into the inside of the hot water tank; A plurality of heaters are formed at the top, the middle, and the bottom of the hot water tank, respectively, with a stepped height difference, thereby discharging the heated hot water formed at the top of the hot water tank, the upper and lower heater parts, and the hot water tank. It characterized in that it comprises a discharge pipe to.

Preferably, the hot water tank is formed in a cylindrical shape, and the inflow pipe is spirally formed at the bottom of the bottom surface of the hot water tank to induce water to rotate inside the hot water tank in a spiral shape.

Inside the hot water tank, a plurality of flow path guide pins are formed in a plate shape of a predetermined length, and are spaced apart at regular intervals in a circular direction toward the center thereof.

The present invention further includes a proportional control output unit for selectively outputting a proportional control signal to the upper heater unit, the middle heater unit, and the lower heater unit to control each heating state.

In addition, a temperature sensor for sensing the temperature of the hot water in the hot water tank; A water level sensor for sensing the level of hot water in the hot water tank; The hot water tank further includes a main control unit controlling a heating state of the upper heater unit, the middle heater unit, and the lower heater unit by outputting a control signal to the proportional control output unit according to the sensing result of the temperature sensor and the water level sensor. When the detected water level is equal to or more than the preset reference level, and the temperature is less than the reference value, the lower heater portion is heated at the first heating, and the stop heater portion is heated after a predetermined time, and the upper heater portion is sequentially It is more preferable to induce heating, and to perform this repeatedly to more smoothly induce the circulation of hot water.

According to the electric boiler according to the present invention configured as described above, it is possible not only to obtain hot water of high temperature required for heating and hot water rapidly, but also to efficiently control the fluid flow to maximize the efficiency of electric power use.

1 is a cross-sectional view showing a conventional electric boiler.
Figure 2 is a side sectional view showing an electric boiler according to the present invention.
3 is a front cross-sectional view of FIG. 2.
Figure 4 is a plan sectional view showing the inlet pipe of Figure 2;
5 is a plan sectional view showing the flow path guide pin of FIG.
Figure 6 is a control block diagram showing an electric boiler according to the present invention.

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

It is to be understood that the words or words used in the present specification and claims are not to be construed in a conventional or dictionary sense and that the inventor can properly define the concept of a term in order to describe its invention in the best possible way And should be construed in light of the meanings and concepts consistent with the technical idea of the present invention. Therefore, the embodiments described in this specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention. Therefore, It is to be understood that equivalents and modifications are possible. Here, like reference numerals in the drawings denote like elements.

Figure 2 is a side sectional view showing an electric boiler according to the present invention, a front sectional view of Figure 2 of FIG. 4 is a plan sectional view showing the inflow pipe of FIG. 2, and FIG. 5 is a plan sectional view showing the flow guide plate of FIG.

As shown, the present invention is a hot water tank 200, the upper heater 210, stop heater 220, lower heater 230, discharge pipe 240, inlet pipe 250 and the flow guide pin ( 260).

Hot water tank 200 is a conventional tank for storing the water therein and heating the water to make hot water in the present invention is preferably formed in a cylindrical shape.

The inlet pipe 250 is formed at the bottom of the hot water tank 200 to introduce water into the inside.

At this time, the inlet pipe 250 may be formed in a spiral on the bottom surface of the bottom of the hot water tank 200 to induce water to be rotated inside the hot water tank 200 in a spiral shape.

Therefore, since the water flowing into the inflow pipe 250 rotates while rotating from the bottom of the bottom surface of the hot water tank 200 to the top, it is possible to efficiently control the fluid flow to maximize the efficiency of power usage.

The electric heater of the present invention is installed at the upper, middle and lower ends of the hot water tank 200, respectively.

Therefore, an upper heater 210 is disposed at an upper end, an interrupted heater unit 220 is disposed at a stop, and a lower heater unit 230 is installed at a lower end thereof. In addition, the heaters 210, 220 and 230 are arranged in a zigzag shape with a stepped height difference, respectively, on the upper, middle and lower ends of the hot water tank 200 to heat hot water. .

In addition, the electric heater installed in the heaters 210, 220, 230 may be adjusted to a long or short length of the temperature efficiency or installation convenience, but is not limited to the length shown in the drawings of the present invention, of course. to be.

Due to the arrangement structure of the upper heater 210, the stop heater 220 and the lower heater 230 it is possible to rapidly obtain the high temperature hot water required for heating and hot water use.

In addition, the discharge pipe 240 is formed on the top of the hot water tank 200 to discharge the heated hot water to the outside.

In addition, inside the hot water tank 200, a plurality of flow path guide pins 260 are formed in a plate shape of a predetermined length, and are spaced apart at regular intervals in a circular direction toward the center thereof.

Therefore, the hot water can be heated quickly by controlling the fluid flow more efficiently along the flow guide pin 260, and can maximize the efficiency of power usage.

6 is a control block diagram showing an electric boiler according to the present invention.

As shown, the present invention is the key input unit 300, the temperature sensor 310, the water level sensor 320, the timer 330, the main control unit 340, the display unit 350, the circulation pump 360 and A proportional control output unit 370 is included.

The key input unit 300 inputs a user's key input, that is, on / off, temperature control, and time setting.

The display unit 350 displays the key input value and the control state, and the circulation pump 360 circulates and supplies water into the hot water tank 200 through the inlet pipe 250.

The temperature sensor 310 detects a temperature of hot water in the hot water tank 200.

The water level sensor 320 detects the level of hot water in the hot water tank 200.

The main control unit 340 outputs a proportional control signal to the proportional control output unit 375 according to the detection result of the temperature sensor 310 and the water level sensor 320 to output the upper heater 210 and the stop heater. The heating state of the unit 220 and the lower heater 230 is controlled. In this case, the heating state of each heater means an exothermic state by heat energy converted from electric energy.

Specifically, when the detected water level of the hot water tank 200 is more than a predetermined reference level and the temperature is less than the reference value, the main control unit 340 heats the lower heater unit 230 at the first heating, and After the time elapses, the stop heater 220 is heated, and after a predetermined time, the upper heater 210 is sequentially heated, and the repetition is performed repeatedly to smoothly induce hot water circulation. The reason for the heating order in the order of the lower heater 230, the interrupted heater 220 and the upper heater 210 according to a predetermined time interval is that the temperature of the water in the boiler is generally lowered due to the density difference according to the temperature. Is lower than the upper part and takes into account the convection of the water in the boiler according to the temperature to heat the water in the boiler more efficiently. In this case, the reference level means a level set for the operation of the boiler. When the reference level is lower than the reference level, the electric boiler according to the present invention does not operate like a normal boiler.

Meanwhile, the proportional control output unit 375 selectively outputs a proportional control signal to the upper heater 210, the middle heater 220, and the lower heater 230 to control each heating state. In this case, the 'proportional control signal' is based on the difference between the water temperature and the set temperature detected by the temperature monitoring sensor for the amount of power supplied to control the heating state of each heater 230, 220, 210. It can be understood as a signal, and the greater the temperature difference, the greater the amount of power supplied. For example, the water temperature at the bottom of the boiler to which the coolant flows in a steady state in which water is kept in and out of the boiler is relatively lower than the temperature of the water at the top of the boiler close to the set temperature. It is not necessary to maintain the heating state of the heater unit 230, the stop heater unit 220, and the upper heater unit 210 in the same manner, and the lower heater unit 230, the stop heater unit 220, and the upper heater unit 210 may not be maintained. It is advantageous in that each heating state of is maintained in inverse proportion to the temperature of the water detected by the temperature sensor in the vicinity of the boiler in terms of efficient use of power. That is, the lower heater portion 230 is relatively low in the water temperature is higher, the interruption heater 220 is lower than the lower heater 230, the lower heater 210 can be maintained at the lowest heating state of each By selectively controlling the amount of power supplied to each heater according to the temperature of the water in accordance with the proportional control signal transmitted from the proportional control output unit 375 to maximize the efficiency of power use.

Therefore, the present invention can control the temperature more efficiently since it proportionally controls a constant temperature value rather than simply turning on or off the heater, and can prevent unnecessary consumption of heating energy.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined in the appended claims and their equivalents. Of course, such modifications are within the scope of the claims.

200: hot water tank 210: upper heater
220: interruption heater portion 230: lower heater portion
240: discharge pipe 250: inlet pipe
260: Euro guide pin 300: Key input unit
310: temperature sensor 320: water level sensor
330: timer 340: main fisherman
350: display unit 360: circulation pump
370: proportional control output unit

Claims (5)

delete delete Hot water tank 200; An inlet pipe 250 formed at a lower end of the hot water tank 200 to introduce water into the inside thereof; A plurality of heaters are formed at the top, the middle, and the bottom of the hot water tank 200, each having a stepped height difference to heat the hot water, an upper heater part 210, a stop heater part 220, and a lower heater part 230; And a discharge pipe 240 formed at the top of the hot water tank 200 to discharge the heated hot water to the outside,
The hot water tank 200, the inside thereof is formed in a cylindrical shape, the inlet pipe 250 is formed in a spiral in the bottom surface of the bottom of the hot water tank 200, the hot water tank 200 in a spiral shape of the water flowing in To rotate the interior,
In the hot water tank 200, the electric boiler, characterized in that formed in a plate shape of a predetermined length, a plurality of flow path guide pins 260 which are spaced apart at regular intervals in a circular direction toward the center.
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