KR101966400B1 - Boiler using a magnetic induction heat - Google Patents

Abstract

The present invention relates to a boiler for heating a fluid, and more particularly, to a boiler for heating a fluid, in which a cold water supply water is discharged through a supply water inlet, A dispensing tank capable of discharging through volleyball; And a magnetic induction pipe connected to a water supply pipe having a water discharge port of the distribution tank and a water supply pump and connected to a hot water discharge pipe having a heating and hot water inlet and a hot water discharge pump using a magnetic induction heat, However,
It is possible to heat the fluid through a magnetic induction heating method using a transformer capable of converting electric energy into thermal energy, and simplify the structure thereof, thereby making it possible to reduce manufacturing cost and direct heating of cold water, The present invention relates to a fluid boiler using magnetic induction heat for achieving a remarkable improvement in energy efficiency and thermal efficiency.

Description

[0001] The present invention relates to a fluid boiler using a magnetic induction heat,

The present invention relates to a boiler for heating a fluid, and more particularly, to a boiler for heating a fluid through magnetic induction heating using a transformer capable of converting electric energy into heat energy, To a fluid boiler using magnetic induction heat for enabling direct heating and improving the thermal efficiency.

Generally, a heating device that heats fluids such as water, steam, or thermal oil for hot water supply or heating uses a chemical fuel or electricity to heat the fluid and to use the heated fluid directly or through a heated fluid to a constant temperature It is a device to heat indoor

Here, the heating apparatus using chemical fuel has a problem in that a large amount of pollutants are discharged during the combustion process, and thermal efficiency is lowered compared to the consumed chemical fuel.

In recent years, electric hot water heaters have been applied. Such hot water heaters are generally heat sources for electric hot water, and hot water using electricity is divided into heat, hot water, and low temperature hot water.

The charging method is a method in which a heating element such as a nichrome wire is wrapped in a copper tube with an insulator such as mica and heated in a bathtub or a simple hot water heater to heat the water. The momentary coil is insulated with a coil such as a nichrome wire, It is heated while passing through the coil. The low-temperature type is a nichrome wire enclosed in a copper tube and installed inside the low-temperature bath, and is maintained at a constant temperature by using a thermostat.

Since such electric hot water uses pure electricity, there is a problem that energy consumption and thermal efficiency are lowered because electric consumption is considerable.

Korean Patent Registration No. 10-1269729.

The present invention has been made to solve the above problems, and it is an object of the present invention to provide a magnetic induction heating method using a transformer capable of converting electric energy into thermal energy, The present invention provides a fluid boiler using magnetic induction heat for reducing the cost and direct heating of cold water, and in particular, for converting energy into heat energy without loss of electric energy, thereby remarkably improving energy efficiency and thermal efficiency. It is an object of the invention.

In order to accomplish the above object, there is a specific means for discharging hot water, which is cold water through a water inlet, through a supply storage and a water outlet, and a hot water inlet at an upper portion, Tank; And

A magnetic induction heat exchanger connected to a water supply pipe having a water discharge port of the distribution tank and a water supply pump and connected to a hot water discharge pipe having a heating and hot water inlet and a hot water discharge pump using a magnetic induction heat, And,

The magnetic induction heating,

A heater main body on a hollow housing having an operation panel formed on an upper portion thereof, a water supply pipe connection portion connected to a water supply pipe on the outer side thereof, and a discharge pipe connection portion connected to the hot water discharge pipe 140;

A transformer formed inside the heater body to generate magnetic induction heat;

A circulation heating tube holder formed at the rear of the transformer; And

And a circulation heating tube wound around the coil so as to be spaced apart from the coil of the transformer and fixed to the circulation heating tube fixing table and having one end connected to the water supply connection port and the other end connected to the discharge pipe connection port,

The circulation heating pipe can be achieved by supplying the water through the water supply pipe and discharging it to the hot water discharge pipe by the magnetic induction heat in the process of circulating the coil of the transformer.

As described above, in the fluid boiler using the magnetic induction heat of the present invention, it is possible to heat the circulation heating tube and heat the cold water by using the heat generated in the process of electromagnetic induction of the transformer, It is possible to heat the fluid through the magnetic induction heating system and to simplify the structure thereof, thereby reducing the manufacturing cost and direct heating of the cold water. In particular, it is possible to convert into heat energy without loss of electric energy, The efficiency and the thermal efficiency can be remarkably improved.

1 is an overall view of a fluid boiler using magnetic induction heat of the present invention.
2 is a magnetic induction heating perspective view of a fluid boiler using magnetic induction heat of the present invention.
3 is a perspective view of a magnetic induction heating element of a fluid boiler using magnetic induction heat of the present invention.
Figure 4 is another embodiment of a fluid boiler using magnetic induction heat of the present invention.
5 is an overall flow diagram of a fluid boiler using magnetic induction heat of the present invention.

The terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms and the inventor may appropriately define the concept of the term in order to best describe its invention It should be construed as meaning and concept consistent with the technical idea of the present invention.

Therefore, the embodiments described in the present specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention, and not all of the technical ideas of the present invention are described. Therefore, It should be understood that various equivalents and modifications may be present.

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

1 is a general view of a fluid boiler using the magnetic induction heat of the present invention, FIG. 2 is a magnetic induction heating perspective view of the fluid boiler using the magnetic induction heat of the present invention, and FIG. It is a magnetic induction thermoregulator.

As shown in FIGS. 1 to 3, the fluid boiler 1 using the magnetic induction heat of the present invention comprises a distribution tank 100 and a magnetic induction heater 200.

Here, the distribution tank 100 is configured to be capable of supplying and discharging water (cold water) from the outside, and storing and distributing heated hot water.

The distribution tank 100 is provided with a water supply inlet 111 through which a water supply pipe (not shown in the drawing) connected to the water supply inlet 111 is connected to one side of the distribution tank 100 so that water can be supplied, A water outlet 112 is formed.

In the distribution tank 100, a hot water inlet 121 is formed to allow hot water to flow into the upper portion, and at least one hot water outlet is formed in the upper portion to distribute hot water.

On the other hand, the distribution tank 100 is not limited, and it is preferable that the inside of the distribution tank 100 is partitioned into an upper portion and a lower portion so as to separate water supply and hot water.

The magnetic induction heat exchanger 200 is configured to change electric energy to heat energy to generate magnetic induction heat and heat the feed water using heat. Preferably, when a change in current occurs in the conductor, a magnetic field is generated, When a magnetic field is applied to a conductor, a current is supplied to the coil to generate a magnetic field, and the eddy current is induced by applying the magnetic field to a metal (circulating heating tube) corresponding to the coil. This eddy current is induced by the electrical resistivity and the eddy current is converted into heat by the electrical resistivity of the metal.

At this time, the induction heater 200 is constituted of a heater main body 210. The heater main body 210 is formed in a hollow square shape with a hollow inside, and an operation panel 211 Is formed.

The water supply pipe 212 is connected to the water supply outlet 112 of the distribution tank 100 through a water supply pipe 130 at the rear of the heater main body 210. As shown in FIG.

At this time, a water supply pipe 131 is formed in the water supply pipe 130 so that water can be discharged from the distribution tank 100.

The discharge pipe connecting hole 213 is connected to the hot water inlet 121 of the distribution tank 100 through a hot water discharge pipe 140 at the outer rear side of the heater main body 210. At this time, And is located at a position higher than the water pipe connector 212.

At this time, a hot water discharge pipe 141 is formed in the hot water discharge pipe 140 so that hot water heated by the distribution tank 100 can be supplied.

The induction heater 200 includes a transformer 220 for generating magnetic induction heat in the heater main body 210.

In this case, the transformer 220 may not be newly realized but may be a coil 222 wound around a conventional iron core 221.

In addition, a wall-shaped circulation heating tube fixing stand 230 is formed in the induction heating furnace 200 so as to be spaced from the inside of the heater main body 210 to the rear of the transformer 220.

In addition, the induction heating furnace 200 is provided with a circulation heating tube 240 for circulating the fluid.

At this time, the circulation heating tube 240 is composed of a copper material having a high thermal conductivity, and is wound around the coil 222 of the transformer 220 in a helical manner so as to surround the coil 222. The wrapping process And is configured to have a fixing force in a state of being wound via the circulation heating tube fixing table 230.

One end of the circulation heating pipe 240 is connected to the water supply pipe connection port 212 of the heater main body 210 and is configured to be able to supply water (cold water) through the water supply pipe 130.

The other end of the circulation heating pipe 240 is connected to the discharge pipe connection port 213 of the heater main body 210 and is capable of discharging heated hot water to the hot water discharge pipe 140 during circulation of the transformer 220 .

At this time, the circulation heating pipe 240 is configured to be upwardly spirally directed from the water supply pipe connection pipe 212 located at the lower part to the discharge pipe connection pipe 213 located at the upper part in the process of winding the transformer 220.

The transformer 220 for generating the magnetic induction heat may be constructed by a single-phase transformer 220 constituting one coil 222 as shown in FIG. 3, or may be constituted by three coils 222, Phase transformer 220. The single-phase transformer 220 is capable of outputting a voltage of 220 V. When the three-phase transformer 220 is applied, the transformer 220 is capable of outputting a voltage of 380 V. Will be possible.

When the single-phase transformer 220 is applied, the circulation heating tube will wind one coil 222. When the three-phase transformer 220 is applied, It will be wound via coil 222.

That is, in the case of the three-phase transformer 220, the circulation heating tube 240 drawn out from the water supply pipe connector 212 is firstly wound on the middle coil 222 in a state where the coil 222 at one end is wound And connected to the outlet pipe connection port 213 in a state that the other end coil 222 is wound continuously.

Hereinafter, the operation of the fluid boiler using the magnetic induction heat of the present invention having the above-described structure will be described in detail with reference to the accompanying drawings.

First, when heating a fluid (water or oil) using the fluid boiler 1 using the magnetic induction heat of the present invention, as shown in FIG. 1 to FIG. 3 and referring to FIG. 5, (Cold water) is supplied through the formed water inlet 111 and the supplied water is discharged to the water supply pipe 130 through the water outlet 112 on the other side and supplied to the magnetic induction heater 200 .

Thereafter, as described above, the water supplied to the magnetically induction furnace 200 is heated by the magnetic induction heat generated in the magnetism inducing furnace 200.

The heated hot water is then stored in the distribution tank 100 through the hot water discharge pipe 140 and the hot water inlet 121 of the distribution tank 100 so that the heated hot water can be distributed through the distribution port 122 do.

3 and 4, the supplied water is heated in the heater main body 210, which is connected to the water pipe connector 212 (see FIG. 3 and FIG. 4) The circulating heating pipe 240 is heated and circulated through the circulating heating pipe 240. The circulating heating pipe 240 is heated and discharged to the hot water discharge pipe 140 through the outlet pipe 213.

At this time, in the transformer 220, when a voltage is generated in the coil 222 by the operation of the operation panel 211 like a normal transformer, a current flows, and when a current is changed, a magnetic field is generated, The magnetic field is applied to the circulating heating tube 240 corresponding to the coil 222 to induce the eddy current and the eddy current is induced by the electrical resistivity of the circulating heating tube 240, The full flow is converted into heat by the inherent resistance to heat the circulating heating tube 240 and to heat the circulated water.

That is, when the single-phase transformer 220 is applied as shown in FIG. 3, the circulation heating tube 240 is configured to wind one coil 222, And is heated by the magnetic induction heat in the process of circulating in the direction of spiraling toward.

When the three-phase transformer 220 having three coils 222 is applied as shown in FIG. 4, the circulation heating tube 240 winds the coils 222 in succession, Is heated by the magnetic induction heat in the process of circulating around the coil (222).

At this time, when the three-phase transformer 220 is applied as described above, high-voltage output becomes possible, and high efficiency can be obtained when the single-phase transformer 220 is applied.

As described above, in the fluid boiler using the magnetic induction heat of the present invention, it is possible to heat the circulation heating tube and the cold water using the heat generated in the electromagnetic induction operation using the transformer, and convert the electric energy into heat energy The induction heating system can heat the fluid through the induction heating system. In particular, since the direct heating can be performed without using a separate heat exchanger, the energy efficiency and the thermal efficiency can be remarkably improved.

100: dispensing tank 111: water inlet
112: Water outlet 121: Hot water inlet
122: a volleyball ball 130: a water supply pipe
131: Water supply pump 140: Hot water discharge pipe
141: Hot water discharge pump
200: magnetic induction heater 210: heater body
211: operation panel 212: water pipe connector
213: outlet pipe connection 220: transformer
230: Circulation heating tube fixing table 240: Circulation heating tube

Claims (3)

And a hot water inlet 121 is formed at an upper portion of the water supply port 121 so that hot water can be discharged through the inlet and outlet port 122, A dispensing tank (100); And
A water supply pipe 130 having a water supply port 112 of the distribution tank 100 and a water supply pump 131 is connected to the heating and hot water inlet 121 and the hot water discharge pump And a magnetic induction heater (200) connected to the hot water discharge pipe (140) having the discharge pipe (141) and supplying the hot water to the distribution tank (100)
The magnetic induction heater 200,
An operation panel 211 for interrupting the supply of current is formed at the upper portion and a water supply connection port 212 for connecting the water supply outlet 112 of the distribution tank 100 to the water supply outlet 112 of the distribution tank 100 through the water supply pipe 130, And a discharge pipe connecting hole 213 for connecting the hot water inlet 121 of the distribution tank 100 to the hot water inlet pipe 121 through a hot water discharge pipe 140.
A transformer 220 formed inside the heater main body 210 to generate magnetic induction heat;
A circulation heating tube holder 230 formed in a wall shape so as to be spaced apart from the rear of the transformer 220; And
And is wound around the coil 222 so as to be spirally wrapped around the coil 222 so as to be spaced apart from the coil 222 of the transformer 220 and is fixed to the circulation heating tube fixing table 230. One end of the coil 222 is connected to the water supply pipe connection hole 212, And a circulation heating pipe (240) connected to the circulation pipe (213) to circulate the feed water,
The circulation heating pipe 240 is configured such that water is supplied through the water supply pipe 130 and discharged to the heating and hot water discharge pipe 140 by the magnetic induction heat in the process of circulating the coil of the transformer 220 Fluid boiler using magnetic induction heat.
delete The method according to claim 1,
The transformer (220)
A single-phase transformer or a three-phase transformer,
When applying a three-phase transformer,
The circulation heating tube 240 drawn out from the water supply pipe connector 212 is wound from the coil 222 at one end to the coil 222 at the other end via the intermediate coil 222. [ Used fluid boiler.

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