KR100874748B1 - Electric boiler - Google Patents

Abstract

An electric boiler is provided to prevent the water from boiling over by placing a heater inside a heater casing and reduce a noise by discharging the heated water through a water outlet formed on the lower side of the heater casing. An electric boiler comprises a heater casing(30) which is horizontally equipped inside a hot water tank(20) through one side of the hot water tank and in which a heater(40) provided with power source and generating the heat is equipped; a circulation pipe(50) which is equipped so that the water in the heater casing flows out through the water outlet connected to one side of the hot water tank, circulates, and returns to the heater casing; and a circulation motor(60) which provides pressure to circulate the water. A water flow hole(34) is formed in the shape corresponding to the water outlet of the heater casing at the position opposite to a water outlet(52) so that the water in the heater casing flows in and out.

Description

Electric boiler

The present invention relates to an electric boiler, and more particularly, to an electric boiler with reduced noise and improved stability.

In general, a boiler is a device made to generate heat energy by using fuel or electricity such as oil or gas as an energy source, and to use heating water or hot water generated by heating water with the generated heat energy for a purpose such as heating. .

These boilers are used for home or industrial use, and are classified into oil boilers, gas boilers, and oil boilers according to the type of fuel used as an energy source.

Here, since the oil boiler fuel that uses petroleum as an energy source is burned, many parts are used for storing, supplying, burning, and exhausting fuel, which is expensive, complicated in structure, and supplies air for combustion of fuel. In order to prevent gas poisoning due to leakage of exhaust gas, a separate boiler room should be provided with good ventilation and isolation from the heating area. Therefore, the length of pipes installed between the boiler and the heating area becomes complicated and long, resulting in loss of thermal energy. It is large and there exists a problem that workability falls.

In the case of gas boilers using gas as an energy source, gas poisoning and explosion accidents caused by gas leakage cause enormous loss of human life and property, which requires cumbersome checks on burners and pipes. There are disadvantages.

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

The electric boiler is configured to directly or indirectly heat the hot water tank storing the water supplied from the water supply source and the water stored and circulated in the hot water tank by a heater that generates heat by electricity, and is heated in the hot water tank. Water is supplied to the building's heating water or hot water for circulation through circulation pipes and circulation motors.

1 is a cross-sectional view illustrating a conventional electric boiler.

As shown in FIG. 1, the conventional electric boiler is provided with a hot water tank 120 in which water is received inside the housing 100, and the hot water tank 120 includes water received in the hot water tank 120. In order to heat to a temperature of the heater 140 is provided.

In addition, the circulation pipe 150 is connected to the hot water tank 120, and the circulation motor 160 is coupled to the circulation pipe 150.

Therefore, as the circulation motor 160 operates to generate a pump pressure, the hot water received in the hot water tank 120 and heated by the heater 140 is circulated through the circulation pipe 150.

However, the above-described conventional electric boiler has the following problems.

First, there is a problem in that the noise is generated as the heater is operated and the water contained in the hot water tank is heated, and when the electric boiler is installed indoors, not only does the user experience psychological discomfort due to the noise, Since it is not installed indoors but needs to be installed outdoors, there is a hassle for the user to go outside when the electric boiler is operated.

Second, the heater provided in the hot water tank is provided to be exposed to the outside without a separate cover member, there is a problem that causes a direct fire when the water in the hot water tank is overheated due to lack of water.

In order to solve the above problems, an object of the present invention is to provide an electric boiler with reduced noise and improved stability.

In order to achieve the above object, the present invention is a hot water tank containing water; One end is formed in a sealed cylindrical shape is provided through the one side of the hot water tank in a horizontal direction inside the hot water tank, the inner side is provided with a heater for generating heat by receiving power through the other end formed open Heater casing; After the water inside the heater casing is discharged through the water outlet portion penetrated to one side of the hot water tank and circulated, the water is supplied to the heater casing through the water inlet connected to one end of the heater casing through the hot water tank. Circulating piping; And a circulation motor connected to the circulation pipe to provide pressure to circulate the water in the hot water tank through the circulation pipe, and a shape corresponding to the water outlet at the other end of the heater casing; It is formed in a position opposite to the water outlet to provide an electric boiler through which the flow hole is formed so that the water in the heater casing flows in and out.

Here, it is preferable that the air discharge hole is formed through the other end of the heater casing so that the air in the heater casing is discharged.

delete

In addition, the heater casing is preferably provided to be inclined at a predetermined angle so as to be upward toward the other end formed with the air discharge hole.

And, the diameter of the air discharge hole is preferably 3mm.

In addition, the air discharge hole is preferably formed to face the flow hole.

Referring to the effect of the electric boiler according to the present invention.

First, the heater is provided inside the heater casing to prevent boiling or splashing while the water is heated, and to allow the water to flow in and out through the both ends of the heater casing, respectively, but a flow hole through which the water flows out. Since the water formed under the heater casing is continuously discharged downward, noise may be prevented from being generated while the water is heated.

Second, an air discharge hole may be formed above the heater casing so as to face the flow hole so that natural air may be discharged. As the water is continuously discharged downward through the flow hole, the pressure near the air discharge hole decreases. It is possible to more effectively prevent the generation of noise through the air and water discharged through the air discharge hole.

Third, the noise generated when the water is heated by the operation of the heater can be effectively prevented, as well as the educational facilities requiring quietness, such as the laboratory can be installed in the interior of the house and the object room.

Fourth, the water inlet pipe formed on one side of the circulation pipe is directly connected to the heater casing and circulated through the circulation pipe so that the water deprived of heat energy can be directly heated by the heater before being mixed with the water in the hot water tank, thereby achieving more efficient heating. Can be.

Fifth, a heater casing is provided inside the hot water tank, and a heater is coupled to the inside of the heater casing so that the heater is not exposed to the outside, thereby preventing a safety accident.

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

2 is a block diagram showing the configuration of an electric boiler according to an embodiment of the present invention.

As shown in FIG. 2, the electric boiler preferably includes a hot water tank 20, a heater casing 30, a circulation pipe 50, and a circulation motor 60. Here, the heater casing 30 having one end formed in a sealed cylindrical shape and the other end opened is preferably provided through one side surface of the hot water tank 20 in which water is accommodated. In addition, the heater 40 is preferably provided inside the heater casing 30, and the water received in the hot water tank 20 is heated as the heater 40 receives power to generate heat. , The heated water is circulated along the circulation pipe 50 by the pressure provided by the circulation motor 60. At this time, a flow hole 34 is formed below the other end of the heater casing 30 so that the water inside the heater casing 30 is discharged downward, and an air discharge hole 32 is formed in the upper portion to discharge the air. By doing so, it is possible to effectively prevent the noise generated while the water is heated.

In detail, the inside of the housing 10 is provided with a hot water tank 20, the water is received inside the hot water tank 20, the amount of water accommodated in the hot water tank 20 can be appropriately adjusted. .

And, the upper portion of the hot water tank 20 is formed with a refill port 22 so that water can be replenished, the refill port 22 may be selectively opened and closed by a stopper (90).

On the other hand, the inner casing of the hot water tank 20 is preferably provided with a heater casing 30 penetrates through one side surface of the hot water tank 20.

Here, the heater casing 30 is preferably one end is closed, the other end is open and formed in the shape of a cylinder having a space inside, most of the hot water tank 20 including one end of the heater casing (30). It is preferably coupled to the hot water tank 20 so as to be located inside.

And, the lower side of the heater casing 30 is preferably formed through the flow hole 34 so that the water in the hot water tank 20 can be introduced into or out of the heater casing (30).

Through this, as the appropriate amount of water is supplied to the inside of the hot water tank 20 through the refill port 22, the supplied water is filled from the lower side of the hot water tank 20 while the flow hole 34 Through it may be introduced into the heater casing (30).

In addition, the upper side of the heater casing 30 is preferably formed through the air discharge hole 32 so that the air in the heater casing 30 is discharged.

As a result, as water flows into the heater casing 30, the air inside the heater casing 30 is discharged to the outside through the air discharge hole 32, and thus the heater casing 30. And water can be accommodated inside the hot water tank 20.

In addition, it is preferable that the heater 40 is provided in the inner space of the heater casing 30. At this time, the coupling portion of the heater 40 and the heater casing 30 is preferably hermetically sealed. Water in the hot water tank 20 can be prevented from flowing out through the heater casing 30 and the heater 40.

On the other hand, it is preferable that the circulation pipe 50 is coupled to the lower side of the hot water tank 20 so that the water contained in the hot water tank 20 can be circulated.

Here, both ends of the circulation pipe 50 is preferably connected to the hot water tank 20, one end of the circulation pipe 50 is connected to the hot water tank 20, the other end is the hot water tank ( 20 is preferably connected to the heater casing 30 through.

Through this, the water circulated through the circulation pipe 50 can be introduced directly into the heater casing (30).

In addition, the circulation pipe 50 is preferably connected to the circulation motor 60 to provide a pressure so that the water in the hot water tank 20 can be circulated through the circulation pipe (50).

Accordingly, the power switch 86 is turned on in a state where water is accommodated in the hot water tank 20, the power is supplied to the heater 40, and the heater 40 is operated to operate the inside of the heater casing 30. The water of the can be heated, in this case, the heater 40 is preferably controlled by the controller 88 to heat the water contained in the hot water tank 20 up to a preset temperature stored by the operator.

Here, the set temperature may be arbitrarily set by the operator, and is not limited to a specific temperature.

When the water in the hot water tank 20 is heated up to a set temperature, the controller 88 stops the heater 40 and operates the circulation motor 60 so that the heated water is supplied to the circulation pipe 50. It is desirable to allow circulation through).

On the other hand, the water discharge unit 52 connected to the hot water tank 20 so that water is discharged from the hot water tank 20 is preferably provided with a temperature sensor 82 connected to the control unit 88, wherein the temperature The sensor 82 measures the temperature of the water passing through the water outlet 52.

When the temperature sensor 82 detects that the temperature of the heated water is lower than or equal to the set temperature as the water is continuously circulated for a predetermined time, the controller 88 operates to control the heater 40 to set the water. When it is heated to maintain the temperature and reaches the set temperature, it is preferable to repeat the stop control of the heater 40.

In addition, one side of the hot water tank 20 is preferably provided with a water level sensor 80 connected to the control unit 88, the water level sensor 80 measures the water level in the hot water tank 20 When the water level is below the set level, it is preferable to generate an alarm sound through the alarm unit (not shown) or to light the warning light to inform the operator of the low water level.

In addition, the water extraction unit 52 is preferably provided with an overheat sensor 84 connected to the control unit 88, where the overheat sensor 84 measures the water temperature of the hot water tank 20.

At this time, when the water temperature in the hot water tank 20 is higher than a predetermined temperature due to abnormal operation of the heater 40, the control unit 88 stops the heater 40 to set the water temperature to the set temperature. It is desirable to maintain.

3 is a perspective view showing a hot water tank portion of the electric boiler according to an embodiment of the present invention, Figure 4 is a cross-sectional view showing the flow of air and hot water in the hot water tank portion of the electric boiler according to an embodiment of the present invention It is also.

As shown in Figures 3 and 4, the heater casing 30 is preferably provided in the inner lower portion of the hot water tank 20, one end is closed, the other end is open, and preferably formed in a cylindrical shape with a space formed inside. This is preferable.

In addition, the heater casing 30 is preferably coupled to the hot water tank 20 such that most of the heater casing 30, including one end of the heater casing 30, is located inside the hot water tank 20. 30 is preferably coupled in the horizontal direction.

In addition, it is preferable that the heater 40 is provided inside the heater casing 30. In this case, the heater 40 has an insertion part 42 formed at one side of the heater 40 in the heater casing 30. It is preferable to be fixed by being coupled to the coupling portion 36 formed at the other end of the).

Here, the heater may be made of a conventional heater that generates heat by receiving power.

As such, since the heater 40 is provided inside the heater casing 30, noise generated as the temperature is raised by heating the water by the heater 40 is 1 by the heater casing 30. It is possible to be cut off by car.

In addition, the insertion part 42 may be formed to correspond to the shape of the coupling part 36 to be coupled to the coupling part 36.

That is, when the coupling part 36 is formed as a screw thread, the insertion part 42 may also be screwed by being formed in a thread shape corresponding to the thread shape of the coupling part 36. At this time, it is preferable that a sealing member is further provided between the insertion part 42 and the coupling part 36 so that water inside the heater casing 30 does not leak.

Of course, the shape of the coupling portion 36 and the insertion portion 42 is not limited to a specific shape, such as the shape of the thread, it can be made in a variety of shapes.

And, if necessary, the heater casing may be provided with a plurality of heaters, in this case, it is preferable that the coupling portion is further provided with a separate cover member that can be combined with the insertion portion of each heater, the cover The member may further be provided with a separate hermetic member.

On the other hand, the circulation pipe 50 is provided so that the heated water can be circulated movement is connected to the hot water tank 20, the water extraction unit 52 and the water is discharged through the water extraction unit 52 It is preferable to include an inlet portion 54 which is obtained after being circulated.

Here, the inlet portion 54 is preferably connected to the lower side of the one end of the heater casing 30 through one side of the hot water tank 20, through which, circulating through the circulation pipe 50, the heat energy The deprived water is brought into the heater casing 30 and immediately comes into contact with the heater 40 so that it can be heated more quickly, thereby enabling a more efficient temperature rise.

In addition, a flow hole 34 penetrates under the other end of the heater casing 30 so that water inside the heater casing 30 flows out or water flows into the heater casing 30. Preferably formed.

Here, the flow hole 34 has a shape corresponding to the water outlet 52, it is preferably formed in a position opposite to the water outlet 52.

As such, the inlet portion 54 is connected to one end of the heater casing 30, and the flow hole 34 is formed at the other end of the heater casing 30, thereby inside the heater casing 30. Water from the inlet portion 54 is moved in the direction of the flow hole (34).

That is, the flow of water is formed in a predetermined direction inside the heater casing 30 can be prevented from boiling or splashing while the water is heated by the heater 40, the moved water is the flow hole ( By continuously discharged downward through 34), the noise generated while the water is heated can be effectively prevented.

In addition, an air discharge hole 32 may be formed on the other end of the heater casing 30 so that air in the heater casing 30 may be discharged.

Here, the air discharge hole 32 is preferably formed to face the flow hole (34).

In addition, the air discharge hole 32 is preferably formed to be located inside the projection surface of the flow hole 34 formed when the flow hole 34 is projected on the upper side of the heater casing (30).

And, it is preferable that one air discharge hole 32 is formed, and the air discharge hole may be formed to have a diameter of 2 to 4 mm, and is preferably formed to have a diameter of 3 mm.

As such, the air discharge hole 32 is formed above the other end of the heater casing 30 so that the air that is received through the inlet 54 and moves along with the moving water naturally flows through the air discharge hole 32. Can be discharged through).

In addition, as the water is continuously discharged downward through the flow hole 34, the pressure near the air discharge hole 32 may be reduced, and is caused by the air and water discharged through the air discharge hole 32. The generation of noise can be prevented more effectively.

As the noise is prevented in this way, the electric boiler can be installed in an educational facility, a house or an office, where a quiet is required, such as a laboratory.

On the other hand, the heater casing 30 may be provided to be inclined at a predetermined angle so as to be upward toward the other end formed with the air discharge hole 32, in this way, the air discharge hole 32 is located above By discharging the air inside the heater casing 30 can be made more easily.

As described above, the present invention is not limited to the above-described specific preferred embodiments, and various modifications by those skilled in the art to which the present invention pertains without departing from the gist of the present invention claimed in the claims. Implementations are possible and such variations are within the scope of the present invention.

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

Figure 2 is a block diagram showing the configuration of an electric boiler according to an embodiment of the present invention.

Figure 3 is a perspective view showing a hot water tank portion of the electric boiler according to an embodiment of the present invention.

Figure 4 is an exemplary cross-sectional view showing the flow of air and hot water in the hot water tank portion of the electric boiler according to an embodiment of the present invention.

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

20,120: hot water tank 30: heater casing

32: air exhaust hole 34: flow hole

40,140: heater 50,150: circulation piping

52: water outlet 54: water outlet

60,160: circulating motor

Claims (6)

A hot water tank in which water is received; One end is formed in a sealed cylindrical shape is provided through the one side of the hot water tank in a horizontal direction inside the hot water tank, the inner side is provided with a heater for generating heat by receiving power through the other end formed open Heater casing; After the water inside the heater casing is discharged through the water outlet portion penetrated to one side of the hot water tank and circulated, the water is passed through the hot water tank through the water inlet connected to one end of the heater casing and provided to the heater casing. Circulating piping; And It is connected to the circulation pipe made of a circulation motor for providing a pressure to circulate the water in the hot water tank through the circulation pipe, An electric boiler having a shape corresponding to the water outlet portion and a position corresponding to the water outlet portion under the other end of the heater casing, the flow hole penetrates the water so that water inside the heater casing flows in and out. delete The method of claim 1, And an air discharge hole is formed through the other end of the heater casing so that air in the heater casing is discharged. The method of claim 3, The heater casing is characterized in that the electric boiler characterized in that the inclined at a predetermined angle so as to be upward toward the other end formed with the air discharge hole. The method of claim 3, Electric boiler characterized in that the diameter of the air discharge hole is 3mm. The method of claim 3, The air discharge hole is characterized in that the electric boiler characterized in that it is formed to face the flow hole.

Images