KR102174356B1 - A boiler using high frequency induction heating - Google Patents

Abstract

An embodiment of the present invention relates to a boiler using high frequency induction heating, which can include: a heater tank having an inner space; a high frequency induction heater provided in the inner space of the heater tank and heated through a high frequency generated from an induction coil; a hot water pipe that is placed between the heater tank and the high frequency induction heater, wherein the hot water pipe introduced from one side of the heater tank is discharged to the other side of the heater tank; and a controller for controlling the heating of the hot water pipe placed between the heater tank and the high frequency induction heater through high frequency induction heating that generates the high frequency in the induction coil of the high frequency induction heater.

Description

A boiler using high frequency induction heating

The present invention relates to a high frequency induction heating boiler using high frequency induction heating as a boiler.

A general boiler heats water to supply hot water to a radiator installed in a room with a certain space, heats the room by heat radiation from the radiator, and injects direct water into the boiler to heat exchange with the heated hot water to be used in a bath or kitchen. Supply hot water. Accordingly, conventional general boilers have two functions of heating the room by heated water and supplying hot water supply.

Such diesel or gas heating boilers are subject to noise, odor, harmful gas, and explosion risk, and electric heating boilers using electric heaters have a very large power consumption, which is costly.

Therefore, with the depletion of fossil fuels such as diesel and gas, the price of fuel is constantly rising, and the problem of causing environmental pollution by generating harmful gases during operation. Research and development is a trend.

Korean Patent Publication 10-2002-0066653

An object of the present invention is to provide an eco-friendly high frequency induction heating boiler capable of reducing environmental pollution while saving electrical energy.

An embodiment of the present invention is a heater tank having an inner space; A high frequency induction heater provided in the inner space of the heater tank and heated through a high frequency generated from the induction coil; A hot water pipe positioned between the heater tank and the high frequency induction heater and flowing into one side of the heater tank and flowing out to the other side of the heater tank; And a controller for controlling the heating of the hot water pipe located between the heater tank and the high frequency induction heater through high frequency induction heating that generates high frequency in the induction coil of the high frequency induction heater.

The hot water pipe introduced from the inlet at one side of the heater tank may be spirally wound on the high frequency induction heater and then flow out to the outlet at the other side of the heater tank.

Between the heater tank and the high frequency induction heater, a heating auxiliary member may be provided.

The heating auxiliary member may be hot water exceeding a set reference temperature.

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The hot water pipe flowing out to the other side of the heater tank is branched, and the branched branch pipe is connected to the inner space of the heater tank, and the hot water discharged from the branch pipe may be used as a heating auxiliary member.

A valve is provided at the end of the branch pipe, a water quantity detection sensor and a temperature detection sensor are provided on the inner wall of the heater tank, an outlet is provided at the bottom of the heater tank, and the controller is detected by the quantity detection sensor. The valve of the branch pipe is closed and controlled according to the amount of hot water in the inner space of the heater tank, and when the temperature of the hot water in the inner space of the heater tank falls below a set temperature, the lowered hot water is discharged through the outlet. It can be characterized by a control box.

By applying the high-frequency induction heating boiler according to the embodiment of the present invention, it is possible to construct an eco-friendly boiler while saving electric energy.

In addition, according to the embodiment of the present invention, by using a heating auxiliary member other than the heating core, it is possible to have an excellent effect of reducing the power consumption by reducing the heating time and dramatically improving the electric energy efficiency.

1 is a conceptual diagram of a high frequency induction heating boiler according to an embodiment of the present invention.
2 is a block diagram of a high frequency induction heating boiler according to an embodiment of the present invention.
3 is a diagram showing a state in which hot water is filled between a heater tank and a high frequency induction heater according to an embodiment of the present invention.
Figure 4 is a diagram showing a state in which the branch pipe is located between the heater tank and the high frequency induction heater according to an embodiment of the present invention.

Hereinafter, the advantages and features of the present invention, and a method of achieving them will become apparent with reference to the embodiments described below in detail together with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but will be implemented in various different forms, and is provided to completely inform the scope of the invention to those of ordinary skill in the art to which the present invention belongs. As such, the invention is only defined by the scope of the claims. In addition, when it is determined that related well-known technologies or the like may obscure the subject matter of the present invention in describing the present invention, detailed descriptions thereof will be omitted.

1 is a conceptual diagram of a high frequency induction heating boiler according to an embodiment of the present invention, FIG. 2 is a configuration diagram of a high frequency induction heating boiler according to an embodiment of the present invention, and FIG. 3 is a heater tank and a heater according to an embodiment of the present invention. It is a figure showing a state where hot water is filled between the high-frequency induction heaters, and FIG. 4 is a figure illustrating a state in which a branch pipe is located between a heater tank and a high-frequency induction heater according to an embodiment of the present invention.

The high frequency induction heating boiler of the present invention is a high frequency heating type boiler using an induction current as shown in FIG. 1. That is, when a high-frequency alternating current is applied to the induction coil, a high-frequency magnetic field is generated, and the surface temperature of the heating tube is rapidly increased through secondary excitation in which loss due to eddy current and Joule heat due to hysteresis loss are generated due to the high frequency magnetic field.

To this end, the high frequency induction heating boiler of the present invention includes a heater tank 100 having an internal space, as shown in FIG. 2, and a high frequency heat generated through high frequency generated by the induction coil provided in the inner space of the heater tank 100. Induction heater 200, a hot water pipe that is located between the heater tank 100 and the high frequency induction heater 200 and flows into one side of the heater tank 100 and flows out to the other side of the heater tank 100, and a high frequency induction heater A controller (not shown) for controlling the heating of the hot water pipe located between the heater tank 100 and the high frequency induction heater 200 through high frequency induction heating that generates a high frequency in the induction coil of 200 may be included. . It will be described in detail below.

The heater tank 100 is a tank having an internal space. One side of the heater tank 100 is provided with an inlet through which the hot water pipe is introduced, and an outlet through which the hot water pipe is discharged is provided at the other side of the heater tank 100. The material of the heater tank 100 may be implemented with various materials having high heat retention. In addition, the heater tank 100 may be implemented as a pillar body or the like and have an open top.

The high frequency induction heater 200 is a device provided in the inner space of the heater tank 100 and heated through a high frequency generated by an induction coil.

The high frequency induction heater 200 has a cylindrical shape and is made of a conductive material, and is a heating member that performs the same function as a kind of heater that generates heat by itself in proportion to the applied voltage. In detail, the high frequency induction heater 200 is composed of a cylindrical insulating tube 220 having an induction coil 210 formed therein, as known in the art.

For reference, looking at the heating principle of the high frequency induction heater 200, when a voltage having a predetermined frequency is applied to the induction coil, an induced electromotive force is generated in the induction coil 210, and this electromotive force is generated from the insulating tube 220 The temperature of the hot water pipe rises sharply by excitation of the hot water pipe installed at the same time. For reference, the insulating tube may be implemented as an insulator, and due to high frequency generation, bipolar molecular motion friction heat of the insulator is generated, and heat is generated in the heating tube. In addition, the high-frequency induction heater may be any heating means through high-frequency induction known in the art.

The hot water pipe is located between the heater tank 100 and the high frequency induction heater 200, and the hot water pipe flowing into one side of the heater tank 100 flows out to the other side of the heater tank 100. The hot water pipe is located on the other side of the heater tank 100 after the hot water pipe introduced from the inlet at one side of the heater tank 100 is spirally wound around the insulating pipe 220 of the high frequency induction heater 200 at regular intervals. It flows out to the outlet.

Therefore, the hot water pipe located between the heater tank 100 and the high frequency induction heater 200 is heated by the high frequency induction heater 200, and the heating medium of the heated hot water pipe is supplied as heating water or living hot water through the outlet of the heating tank. Then, the low-temperature heat medium cooled by the heating is re-introduced through the inlet of the heating tank and is reheated.

The controller (not shown) performs control to heat the hot water pipe located between the heater tank 100 and the high frequency induction heater 200 through high frequency induction heating that generates high frequency in the induction coil of the high frequency induction heater 200 . The controller (not shown) is implemented as a printed circuit board (PCB) substrate, and controls high frequency induction heating through an MCU and a memory on the PCB substrate.

On the other hand, eddy current loss and hysteresis loss generated by the high frequency induction coil are generated on the surface of the insulating tube facing the induction coil (surface effect). In other words, the rapid increase in the temperature of the insulating tube is a result of heat exchange with the entire body of heat generated on the surface of the inner circumferential surface facing the insulating tube.

Between the heater tank 100 and the high frequency induction heater 200, a hot water pipe has a structure in which the outer wall of the insulating pipe is wrapped in a spiral shape. In the space between the heater tank 100 and the high frequency induction heater 200, the space between the heater tank 100 and the high frequency induction heater 200 is empty. There is a problem in that a space is generated, thereby reducing the electrical energy efficiency and delaying the heating time.

In order to improve this problem, the present invention is provided with a heating auxiliary member between the heater tank 100 and the high frequency induction heater 200. Since a heating auxiliary member is provided between the heater tank 100 and the high frequency induction heater 200, the hot water pipe between the heater tank 100 and the high frequency induction heater 200 is formed by the heating auxiliary member. In addition to the primary heating of, heating efficiency can be increased by secondary heating of the heating auxiliary member.

Such a heating auxiliary member may be implemented with hot water exceeding the reference temperature set as shown in FIG. 3. By filling hot water between the heater tank 100 and the high frequency induction heater 200, the hot water pipe located between the heater tank 100 and the high frequency induction heater 200 is used as a heating auxiliary member for hot water in addition to the high-frequency primary heating. Secondary heating is possible. In addition to the secondary heating, such hot water can increase the thermal insulation power of the hot water pipe located between the heater tank 100 and the high frequency induction heater 200.

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When hot water is used as the heating auxiliary member, hot water must be periodically supplied into the heater tank 100. To this end, the hot water pipe through the outlet of the other side of the heater tank 100 is branched as shown in FIG. 4. The branched branch pipe is connected to the inner space of the heater tank 100 so that hot water discharged from the branch pipe can be used as a heating auxiliary member. Since the upper part of the heater tank 100 implemented as a column or the like has an open structure, the branch pipe branched from the hot water pipe coming out of the outlet is the internal space of the heater tank 100 through the upper open surface of the heater tank 100 Can be introduced into.

However, it is necessary to open and close the hot water flowing into the internal space of the heater tank 100 and discharged from the branch pipe. In addition, when the temperature of the hot water flowing into the internal space of the heater tank 100 drops, the secondary heating Because it loses its function, it is necessary to exchange hot water.

To this end, a valve (not shown) is provided at the end of the branch pipe, a water quantity detection sensor and a temperature detection sensor (not shown) are provided on the inner wall of the heater tank 100, and hot water is provided at the bottom of the heater tank 100. Make sure to have an outlet connected to the pipe.

Accordingly, the controller (not shown) can control the valve of the branch pipe according to the quantity of hot water in the inner space of the heater tank 100 detected by the quantity detection sensor. The valve of the branch pipe is opened until the internal space of the heater tank 100 is completely filled with hot water, so that hot water from the branch pipe is discharged. When the internal space of the heater tank 100 is filled with hot water, the valve of the branch pipe is opened. Shut off so that hot water from the branch pipe is no longer discharged.

In addition, the controller (not shown) performs control of discharging hot water through an outlet provided in the heater tank 100 when the temperature of the hot water in the inner space of the heater tank 100 is less than a set temperature. For example, when the temperature of hot water in the inner space of the heater tank 100 falls below a set temperature, the cooled hot water is discharged through an outlet, and then the hot water is introduced again through a branch pipe. An opening and closing means such as a solenoid valve is provided at the outlet.

The embodiments in the description of the present invention described above are presented by selecting the most preferable examples to aid the understanding of those skilled in the art from among various possible examples, and the technical idea of the present invention is not necessarily limited or limited only by this embodiment. , Various changes and modifications, and other equivalent embodiments are possible within the scope of the technical spirit of the present invention.

100: heater tank
200: high frequency induction heater

Claims (7)

A heater tank having an inner space;
A high frequency induction heater provided in the inner space of the heater tank and heated through a high frequency generated by an induction coil;
A hot water pipe positioned between the heater tank and the high frequency induction heater and flowing into one side of the heater tank and flowing out to the other side of the heater tank; And
A controller for controlling the heating of the hot water pipe located between the heater tank and the high frequency induction heater through high frequency induction heating that generates high frequency in the induction coil of the high frequency induction heater;
The hot water pipe introduced from the inlet at one side of the heater tank is spirally wound on the high frequency induction heater and then flows out to the outlet at the other side of the heater tank,
A heating auxiliary member is provided between the heater tank and the high frequency induction heater,
The heating auxiliary member is hot water exceeding a set reference temperature,
The hot water pipe flowing out to the other side of the heater tank is branched, the branched branch pipe is connected to the inner space of the heater tank, and the hot water discharged from the branch pipe is used as a heating auxiliary member,
A valve is provided at the end of the branch pipe, a water quantity detection sensor and a temperature detection sensor are provided on the inner wall of the heater tank, and an outlet is provided at the bottom of the heater tank,
The controller shields and controls the valve of the branch pipe according to the quantity of hot water in the inner space of the heater tank detected by the quantity detection sensor, and when the temperature of the hot water in the inner space of the heater tank falls below a set temperature, A high-frequency induction heating boiler, characterized in that controlling the hot water whose temperature has decreased to be discharged through the outlet. delete delete delete delete delete delete

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