KR200167810Y1 - An installation of heating in storage electric water boiler - Google Patents

Abstract

The present invention relates to a heat storage hot water boiler, and relates to a heating device of a heat storage hot water boiler for preventing the accumulation of lime components generated by repeated heating and cooling of the heating rod mounted inside the boiler.

The present invention for this purpose is a heater case is formed so that the heater rod mounted in the storage tank is built in a predetermined space; And a circulation pump for allowing the water of the water storage tank to flow through the absorption port provided at one side of the heater case, and allowing the water to flow out into the water storage tank through the drain hole provided at the other side of the heater case. After allowing the water in the storage tank to flow through the circulation pump to one side of the, the inflow of water to the other side of the heater case can be discharged into the storage tank, so that the lime component does not accumulate in the appearance of the heater rod. Corrosion can be prevented, and as a result, the service life of the heater rod is extended, thereby achieving stability including life of the system.

Description

Heating device of regenerative hot water boiler {AN INSTALLATION OF HEATING IN STORAGE ELECTRIC WATER BOILER}

The present invention relates to a regenerative hot water boiler, and more particularly, to a heating device of a regenerative hot water boiler for preventing the accumulation of lime components generated by repeated heating and cooling of the heater rod mounted inside the boiler.

In general, regenerative boilers use hot water by using electric energy in the midnight hours (22:00-08:00). Therefore, the electricity supplied to the heater rod is supplied at a specific time, and then cut off the electricity supply to the heater for a predetermined time. Referring to the heat storage boiler according to the accompanying drawings as follows.

1 is a perspective view of a regenerative boiler. First, the boiler 100 referring to FIG. 1 is provided with a hot water supply opening 107, and a cold water inlet 105 for cold water inflow is provided at one side of the boiler 100. At one end of the boiler 100, heating of the boiler is performed at night time, and a predetermined controller 103 is installed for protection of the heater during heating. The heat storage boiler 100 having such a configuration includes a heater 201 for converting electrical energy into heat inside the heat storage tank 203 as shown in FIG. 2.

The heater 201 forms a heater rod by embedding the magnesia surrounding the nichrome wire and the magnesia in a pipe having a predetermined shape. This heater rod is for extending the heater life by preventing the nichrome wire, which is a heating element, from directly heating cold water.

Hereinafter, the operation of the heat storage boiler according to the above configuration is as follows.

First, in a state where water of a predetermined water pressure flows into the cold water inlet 105, the user sets the heat storage time and the heat storage temperature through the controller 103. This setting is to control the heat generation temperature of the heater 201 to perform the heat storage function is made by the electricity supply in the night time zone.

Therefore, when power is supplied to the heater 201, the cold water of a predetermined water pressure is continuously introduced through the cold water inlet 105, so that the water inside the boiler 100 is heated. The heated water may maintain the temperature of the water due to the heat storage tank 203, and the temperature of the water determines whether the heater 203 is operated in addition to the temperature detection from the controller 103.

The continuous operation of the heater 203 raises the temperature of the water, thereby generating convection in the boiler 100, thereby heating the water, thereby heating the water of the internal capacity of the boiler 100 to a predetermined temperature during a late night time zone. It is to let. The heated water is discharged to the outside through the hot water inlet 107, and low temperature cold water flows into the cold water inlet 105 according to the amount of discharged water.

In addition, the inflow of the cold water is mixed with hot water in the boiler 100, and is heated by the heater 201 to maintain the temperature of the water in the heat storage tank 203 based on the temperature control of the controller 103. .

However, the above-described heat storage boiler heats the heater in the late-night time zone, and thus stops the operation of the heater after the late-night time, so that the temperature of the heater rod after the late-night time decreases. Therefore, when the demand for hot water is small, the inside of the boiler maintains a static water state, from which lime components accumulate around the heater. That is, the lime component in the ionized state is distributed in the water continuously heated in the midnight time zone, and the lime water is changed to a gel state when a high temperature heater rod is touched, and then the temperature of the heater rod is lowered to a predetermined value or less. The lime component turns into a solid.

The solidified lime component then increases the temperature of the rod during the heating operation of the heater rod, and the increase in temperature causes the breakage of the nichrome wire, which leads to the progressive development of the heater rod, that is, the rupture phenomenon, and shortens the life of the heater. This phenomenon not only lowers the efficiency of the system, but also causes a problem that the lifetime and reliability of the product are lowered.

The present invention was devised to solve such a problem, and an object of the present invention is to provide a heating device of a regenerative boiler that improves the efficiency of the system by extending the heater life of the regenerative boiler.

Heating device of a heat storage boiler according to an aspect of the present invention for achieving the above object, the heater case is formed so that the heater rod mounted in the storage tank is built in a predetermined space; And a circulation pump for allowing the water of the water storage tank to flow through the absorption port provided at one side of the heater case, and allowing the water to flow out into the water storage tank through the drain hole provided at the other side of the heater case. .

1 is a perspective view of a conventional heat storage hot water boiler.

2 is a cross-sectional view of FIG.

Figure 3a is a cross-sectional view showing the present invention heat storage boiler.

3B is a sectional view of the heater case of FIG. 3A.

Figure 4 is an operation diagram showing the flow of water in the reservoir according to the present invention.

<Description of the code | symbol about the principal part of drawing>

300: regenerative boiler 303: controller

305: heater case 309: circulation pump

317: connection piping 321: heater rod

323: drain port 325: absorption port

Hereinafter, the present invention will be described in detail based on the accompanying drawings.

Figure 3a is a cross-sectional view of the present heat storage boiler. 3C is a cross-sectional view illustrating the heater case of FIG. 3A. 3D is a cross-sectional view illustrating still another example of FIG. 3C. 3A, 3C, and 3D, the heat storage type boiler 300 includes a boiler casing 313, a cold water inlet 307 and a hot water inlet 301 respectively mounted at upper and lower ends of the casing 313, and the casing. (313) a storage tank 315 mounted therein to store water, a storage tank 311 provided between the storage tank 315 and the casing 313 and made of a urethane thermal insulation material for heat dissipation, and the heat storage boiler Mounted at the lower end of the 300 to the heater case 305 for heating the cold water in the water tank 315 to the predetermined space and the circulation pump 309 for circulating the water heated in the heater case 305 It is composed.

In addition, the circulation pump 309 is mounted outside the storage tank 315 and circulates the water of the storage tank 315 to the heater case 305 through a connection pipe 317. In addition, a controller 303 for normally controlling the system such as the heat storage / heat dissipation time of the heater case 305, whether the circulation pump 309 is driven, and the amount of water in the water storage tank 315 is detected at one side of the heat storage boiler 300. ) Is attached.

In addition, the heater case 305 may be made of a copper tube as an example, the heater case 305 to introduce a heater rod 321 of a predetermined length and the water circulated from the circulation pump 309 into the inside. The absorption port 325 and the drain port 323 provided on one side of the) and the heater terminal 327 is connected to the controller 303 to supply power to the heater rod 321.

Hereinafter, the operation of the present invention according to the above configuration will be described.

First, the controller 303 determines whether the amount of water in the reservoir 315 is greater than or equal to the reference value, and receives data according to heat storage time, heat dissipation time, and water temperature from the user. In addition to the data input, the controller 303 determines whether the current time is in the late night time zone, and if it is determined in the late night time, determines whether the controller 303 has entered the heat storage time zone input by the user.

When the heat storage time is reached, the electric power is supplied to the heater rod 321 embedded in the heater case 305, and the circulation pump 309 is operated. The operation of the circulation pump 309 allows the water of the reservoir 315 to flow through the connection pipe 317, and then forcibly supplies the introduced water to the heater case 305. Therefore, after the water of the water storage tank 315 flows in through the absorption port 325 of the heater case 305, it is heated by the heater rod 321 and exits to the drain port 323.

Water exiting through the drain 323 forms a convection in the water storage tank 315, so that the cold water maintained at the top of the water storage tank 315 sinks to the bottom. The cold water is supplied to the absorption port 325 of the heater case 305 again based on the circulation pump 309 through the connection pipe 317. This continuous operation will generally heat the water in the reservoir 315.

On the other hand, the diameter of the drain port 323 of the heater case 305 is advantageously provided in proportion to the pumping capacity of the circulation pump 309, to maintain the flow rate of the water flowing through the absorption port (325). That is, when the pumping capacity of the circulation pump 309 is small, the diameter of the drain port 323 is reduced to increase the flow rate in the heater case 305, and when the pumping capacity of the circulation pump 309 is large, the drain port Even if the diameter of 323 is not small, the flow rate in the heater case 305 is maintained.

The faster the flow rate in the heater case 305, the better, but considering the power consumption of the circulation pump 309, it is sufficient that the lime component does not accumulate in the appearance of the heater rod 321.

In addition, while the water is continuously heated, the controller 303 measures the temperature of the water and determines whether the measured temperature corresponds to a temperature set by the user or reaches a heat storage time set by the user. If the temperature of the water reaches the set value, the power supplied to the heater rod 321 is cut off, but the operation of the circulation pump 309 is not stopped.

Here, when the lime component ionized around the heater rod 321 is in contact with the heater rod 321 while the heater rod 321 is heated for a long time, the solid state gradually changes when the heating is stopped after changing to a gel state. As a result, the temperature in the heater rod 321 is increased during subsequent heating, which causes disconnection of the nichrome wire in the heater rod. Therefore, the continuous operation of the circulation pump is to prevent the above phenomenon, to form a flow rate in the heater case 305 to circulate the ionized lime components to melt in the water in the water tank 315 to disappear.

As a result, the operation of the circulation pump 309 is to form a flow rate around the heater rod 321 to suppress chemical and physical changes of the lime component in the heating stop state of the heater rod 321.

On the other hand, as shown in Figure 3b can be used to install the heater case 305 of the present invention as the appearance of the heat storage boiler 300, the heater case 305 is connected to the circulation pump (317) through the connection pipe (317) 309). In addition, the circulation pump 309 is connected to the lower end of the water storage tank 315 so that the circulation of water is made outside the casing 313.

That is, the water of the water storage tank 315 is to be supplied to the lower end of the heater case 305 mounted to the outside of the casing 313 through the circulation pump 309. Therefore, a constant water pressure is formed in the heater case 305, and this water pressure is supplied to the inside of the water storage tank 315 again, so that the water is circulated.

In this structure as well, the water is heated by the heater rod 321 mounted inside the heater case 305, and the accumulation of the lime component is prevented by the continuous circulation of the water at the same time as the heating.

Here, the convection change in the reservoir 315 is shown in FIG. 4, which takes the structure of FIG. 3A as an example. The operation of the circulation pump 309 is controlled by the controller 303, and the driving time of the circulation pump 309 is set so that lime components do not accumulate on the exterior of the heater rod 321 through a plurality of experiments.

For example, when electric power is supplied to the heater rod 321, and in addition to continuous driving of the circulation pump 309, when the power supply to the heater rod 321 is cut off, the circulation pump 309 has a predetermined cycle. Is to be repeated on / off.

On the other hand, when the user sets the temperature of the water through the controller 303, after the power supply of the heater rod 321 is cut off according to the set temperature, if a predetermined amount of water is used through the hot water inlet 301 Cold water is introduced from the cold water inlet 307 by the amount of reduced water. The introduced cold water lowers the temperature of the water in the water storage tank 315, and the controller 303 performs power supply to the heater rod 321 according to the lowered temperature of the water.

Therefore, the heating state of the heater rod 321 is variable according to the amount of water flowing out to the hot water supply port 301. Since the operation of the circulation pump 309 is continuously performed even in the heating variable state of the heater rod 321, the generation of the lime component by the temperature change of the heater rod 321 not only maintains the ionic state, Dispersed inside the bath 315 is a lime component does not accumulate in the heater rod 321 appearance.

The present invention as described above is that the lime component is not accumulated in the solid state by the flow rate of the water flowing into and out of the absorption port 325 and the drain port 323 provided on one side of the heater case 305 and the heater case, The snowfall of the heater case 305 can have the same function even in the vertical direction including the horizontal direction. In addition, even if the heater case 305 is not installed in the inside of the water storage tank 315, the gist of the present invention can be accommodated when the structure of the above-described principles of the present invention is applied.

The heating device of the present invention-generated regenerative hot water boiler is provided with a heater case so that the heater rod mounted on the hot water boiler can be built into a predetermined space, and the water in the reservoir is introduced into one side of the heater case through a circulation pump. Afterwards, as the water introduced to the other side of the heater case can be discharged into the storage tank, lime components do not accumulate in the appearance of the heater rod, thereby preventing corrosion by the lime component. From this, it is possible to extend the service life of the heater rod to obtain the effect of ensuring the stability including the life of the system.

Although the present invention has been illustrated and described with respect to specific preferred embodiments, the present invention is not limited to the above-described embodiments, and is not only sufficiently applied to water heaters, solar boilers, and general boilers, including a regenerative hot water boiler, but also a utility model. Various modifications may be made by those skilled in the art to which the present invention pertains without departing from the spirit of the present invention as claimed in the scope of registration.

Claims (2)

A storage tank 315 for accumulating water; And In the heat storage boiler 300 for heating the water through the heater rod 321 installed in the storage tank 315, A heater case 305 formed such that the heater rod 321 is installed in a predetermined space; And Water from the storage tank 315 is introduced through the absorption port 325 provided at one side of the heater case 305, and the water is stored through the drain 323 provided at the other side of the heater case 305. Heating device of a heat storage hot water boiler, characterized in that it comprises a circulation pump (309) for outflow to the bath (315). According to claim 1, wherein the heater case 305 in which the heater rod 321 is installed is mounted outside the storage tank 315, the water in the storage tank 315 is circulated from the circulation pump 309 Heating device of a regenerative hot water boiler, characterized in that to make.