KR100917811B1 - Boiler machine using time-varying magnetic field - Google Patents

Abstract

Disclosed is a boiler apparatus using a variable magnetic field generator. Boiler device of the present invention comprises a chamber for storing water; A variable magnetic field generator installed outside the chamber to boil water in the chamber; An inlet pipe connected to the chamber for introducing water into the chamber; A circulation pipe connected to the chamber for circulating water in the chamber to the outside of the chamber; It characterized in that it comprises a control unit for controlling the variable magnetic field generator, the inlet pipe and the circulation pipe.

According to the present invention, by using the variable magnetic field heat, the thermal efficiency is high, and there is a power saving effect.

Variable magnetic field, scaler, boiler

Description

Boiler machine using variable magnetic field generator {Boiler machine using time-varying magnetic field}

The present invention relates to a boiler apparatus, and more particularly, to a boiler apparatus using a variable magnetic field generator having high thermal efficiency, no residue such as scalers in a chamber, and no risk of burns.

The boiler apparatus according to the prior art, as shown in Figure 1 (a), comprises a chamber 1 and a heater coil (2) installed in the chamber (1). The boiling device of FIG. 1 (a) is a device for directly boiling water in the chamber 1 by using heat generated in the heater coil 2. When power is applied to the heater coil 2, the heater coil 2 generates heat, and the liquid around the heater coil 2 becomes hot due to the heat generated from the heater coil 2.

On the other hand, the boiler apparatus according to the prior art, as shown in Figure 1 (b), the flame device is provided in the chamber 1 and the outer lower end of the chamber (1). The boiler apparatus of FIG. 1 (b) heats the chamber 1 using the heat of the flame apparatus 3. The chamber 1 heated by the flame apparatus 3 transfers the heat to the liquid inside to boil water.

In the boiler apparatus according to the prior art, in particular, in the boiler apparatus of FIG. 1 (a), since the heater coil 2 is installed in the chamber 1, the ionic substances are agglomerated on the surface of the heater coil 2, thereby heating the heater coil 2. Stick to the surface to form a scaler. The scaler attached to the heater coil 2 surface forms debris in the liquid. Such a scaler aggregates on the surface of the heater coil 2 to hinder the operation of the heater coil 2, lowers the efficiency of the heater coil 2, and causes mechanical failure.

Moreover, since the boiler apparatus of FIG. 2 (b) heats the chamber 1 by the high heat of the flame apparatus 3, there is a risk of burns to the user due to the high heat of the flame apparatus 3. Therefore, there is a need for improvement.

The present invention has been created by the necessity as described above, and its purpose is to eliminate the risk of the occurrence of foreign matter such as power saving effect and scaler in the chamber due to high thermal efficiency, contamination of the liquid inside the chamber, and burns.

Boiler apparatus using a variable magnetic field generator according to an embodiment of the present invention, the chamber for storing water; A variable magnetic field generator installed outside the chamber to generate a variable magnetic field; An inlet pipe connected to the chamber for introducing water into the chamber; A circulation pipe connected to the chamber for circulating water in the chamber to the outside of the chamber; And a control unit for controlling the variable magnetic field generator, the inlet pipe, and the circulation pipe.

On the other hand, the variable magnetic field generator comprises a copper wire coil and electrical application means for applying alternating current to the coil, characterized in that the chamber material is made of stainless steel or iron.

The apparatus may further include a temperature sensor installed in the chamber to sense water temperature in the chamber, wherein the controller controls the operation of the variable magnetic field generator using the information received from the temperature sensor.

On the other hand, and installed in the chamber further comprises a water level sensor for detecting the water level of the quantity in the chamber, the control unit controls the flow rate in the chamber using the information received from the water level sensor.

On the other hand, the circulation pipe is provided with a circulation pump.

In addition, the hot water dispenser is installed in the circulation pipe.

In addition, the water circulation valve is further installed in the circulation pipe.

The air outlet may further include air exiting the chamber while the water in the chamber is heated.

The apparatus may further include a ceramic disposed between the variable magnetic field generator and the chamber.

In addition, the variable magnetic field generator generates a frequency in the range of 18 ~ 26KHz.

The boiler apparatus using the variable magnetic field generator according to the present invention has a high thermal efficiency and uses a variable magnetic field generator installed outside the chamber, so that foreign matters such as a scaler in the chamber do not occur, thereby contaminating liquid in the chamber. No risk of burns due to the use of variable magnetic fields.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of a boiler apparatus using a variable magnetic field generator according to the present invention. In this process, the thickness of the lines or the size of the components shown in the drawings may be exaggerated for clarity and convenience of description. In addition, terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to the intention or convention of a user or an operator. Therefore, definitions of these terms should be made based on the contents throughout the specification.

2 is a perspective view showing a boiler apparatus using a variable magnetic field generator according to an embodiment of the present invention.

2, the chamber 10 stores water therein.

The variable magnetic field generator 20 is installed at an outer lower end of the chamber 10. In the present exemplary embodiment, the variable magnetic field generator 20 is illustrated as being installed at the lower end of the chamber 10, but the variable magnetic field generator 20 may be installed on the outer circumferential surface of the chamber 10, and the liquid in the chamber 10 may be provided. It may be installed in any position as long as it can be heated. The variable magnetic field generator 20 may be formed of a coil made of a copper wire wound in an elliptical shape. When alternating current is applied to the coil, the coil forms a variable magnetic field around the coil, and the variable magnetic field induces a current in the chamber 10. The material in chamber 10 generates heat while resisting the induced current, and the heat is transferred to the water in chamber 10. The outer surface of the chamber 10 is preferably formed by coating a thermal insulator. When the heat insulator is coated and formed on the outer surface of the chamber 10, the heat lost to the outside of the chamber 10 is minimized, and even if touched by hand, it is cold enough that there is no risk of burn. Current is shaken in both chamber 10 and the coil. However, the inner side of the chamber 10 must generate heat, and the coil is preferably kept cold. For this reason, it is preferable that the coil uses copper having high electrical conductivity, and the chamber 10 preferably has a metal having low electrical conductivity, although the chamber 10 has electrical conductivity so that heat is sufficiently generated as a resistance to an induced current. Stainless steel or iron is preferably used as the material of the chamber.

Variable magnetic field generator 20 preferably generates a frequency in the range of 18 ~ 26KHz, it may vary depending on the copper diameter of the coil.

One side of the chamber 10 is provided with an inlet pipe 30 for introducing water into the chamber 10. The inlet pipe 30 may have a circular cross section, but may have another cross section as necessary. The inlet pipe 30 is provided with an inlet control valve 35 to adjust the amount of water introduced into the chamber 10.

In addition, a circulating pipe 40 for circulating water to the outside of the chamber is connected to one side of the chamber 10. Both ends of the circulation pipe 40 are connected to the chamber 10, the hot water in the chamber 10 is introduced from one end of the circulation pipe 40 to circulate through the circulation pipe 40, and the circulation pipe ( At the other end of 40, it is introduced back into the chamber 10. That is, the hot water in the chamber 10 increases the ambient temperature of the circulation pipe 40 while circulating the circulation pipe 40, and the water that loses heat while circulating is introduced into the chamber 10 again.

The circulation pipe 40 is provided with a circulation pump 42 to facilitate the circulation of water. In addition, the hot water dispenser 44 is provided at one side of the circulation pipe 40 to directly extract the hot water of the circulation pipe 40. On the other hand, the circulation pipe 40 is provided with a water amount control valve 46 to adjust the amount of water in the circulation pipe (40). When a predetermined amount of hot water flows out of the circulation pipe 40 from the hot water dispenser 44, the water quantity control valve 46 is opened to increase the quantity of the circulation pipe 40.

At the upper end of the chamber, a water level sensor 60, a temperature sensor 62, and an air outlet 64 are provided. The water level sensor 60 detects the water level in the chamber 10 because its end is submerged in the water in the chamber 10. The temperature sensor 62 measures the temperature of the water in the chamber 10. Air outlet 64 is the water is heated and the air of the portion where the volume expands to escape to the outside.

A ceramic is installed between the chamber 10 and the variable magnetic field generator 20. The ceramic installed between the chamber 10 and the variable magnetic field generator 20 prevents a lot of heat from being generated at the bottom.

Hereinafter, an operation example of the boiler apparatus using the variable magnetic field generator according to the embodiment of the present invention will be described.

First, the control unit 50 instructs the variable magnetic field generator 20 to operate the variable magnetic field generator 20. When alternating current flows through the copper wire coil, a variable magnetic field is formed around the coil. The variable magnetic field causes the chamber 10 to induce electrical resistance, which generates heat. The heat generated thus heats the water in the chamber 10. When the water in the chamber 10 is heated, the air in the chamber 10 escapes through the air outlet 64. When the water is heated and the temperature of the water in the chamber 10 reaches 100 ° C. or a temperature to be adjusted, the controller 50 stops the operation of the variable magnetic field generator 20. As such, the operation of the variable magnetic field generator 20 is controlled using the temperature data sensed by the temperature sensor 62 so that the water in the chamber 10 has a constant temperature.

The temperature of the water in the chamber 10 is kept constant by the control of the series of control units 50, and if the user wants water of a specific hot temperature, the user controls the temperature sensor to obtain hot water above a specific temperature.

On the other hand, the hot water heated in the chamber 10 is the hot water circulation control valve 46 and the circulation pump 42 operates in accordance with the temperature controlled by the external temperature sensor 47. The hot water circulates inside the circulation pipe 40. Water circulating in the circulation pipe 40 loses heat due to contact with the outside, and the lost water flows back into the chamber 40 again. Loss of heat and the water introduced into the chamber 10 is heated again in the chamber 10, the hot water is introduced into the circulation pipe 40 again to circulate the circulation pipe (40).

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary, and those skilled in the art to which the art belongs can make various modifications and other equivalent embodiments therefrom. Will understand. Therefore, the true technical protection scope of the present invention will be defined by the claims below.

1 is a perspective view showing a boiling apparatus according to the prior art,

2 is a perspective view showing a boiling apparatus using a variable magnetic field according to an embodiment of the present invention.

* Description of the symbols for the main parts of the drawings *

10 chamber 20 variable magnetic field generator

30: inlet pipe 35: inlet control valve

40: circulation pipe 42: circulation pump

44: hot water dispenser 46: quantity control valve

47: external temperature sensor 50: control unit

60: water level sensor 62: temperature sensor

64: air outlet

Claims (10)

A chamber for storing water; A variable magnetic field generator installed outside the chamber to generate a variable magnetic field; An inlet pipe connected to the chamber for introducing water into the chamber; A circulation pipe connected to the chamber for circulating water in the chamber to the outside of the chamber; A hot water dispenser installed in the circulation pipe; Boiler apparatus using a variable magnetic field generator characterized in that it comprises a control unit for controlling the variable magnetic field generator, the inlet pipe and the circulation pipe The method of claim 1, The variable magnetic field generator includes a copper wire coil and electric applying means for applying alternating current to the coil, The chamber material is a boiler device using a variable magnetic field generator, characterized in that consisting of stainless steel or iron The method according to claim 1 or 2, Installed in the chamber further comprises a temperature sensor for sensing the water temperature in the chamber, The control unit uses a variable magnetic field generator, characterized in that for controlling the operation of the variable magnetic field generator using the information received from the temperature sensor. The method of claim 3, Installed in the chamber further comprises a water level sensor for detecting the level of water in the chamber, The control unit uses a variable magnetic field generator, characterized in that for controlling the flow rate in the chamber using the information received from the water level sensor The method of claim 3, The circulation pipe is a boiler device using a variable magnetic field generator, characterized in that the circulation pump is installed delete The method of claim 1, The circulation pipe is a boiler device using a variable magnetic field generator, characterized in that the water quantity control valve is further installed. The method of claim 1, Boiler apparatus using a magnetic field generator, characterized in that it comprises an air outlet for the air generated in the chamber is heated to escape the air generated outside the chamber The method of claim 1, Boiler apparatus using a variable magnetic field generator, characterized in that further comprising a ceramic installed between the variable magnetic field generator and the chamber The method of claim 1, The variable magnetic field generator is a boiler device using a variable magnetic field generator, characterized in that for generating a frequency in the range of 18 ~ 26KHz

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