KR102333320B1 - induction steam boiler using high temperature reheating - Google Patents

Abstract

The present invention relates to an induction steam boiler using high temperature reheating, in which a primary boiler and a secondary boiler are sequentially connected inside a case, the primary and secondary boilers are induction boilers that heat water with electricity, and an atomizing device is provided inside the secondary boiler to reheat primarily heated water after atomizing the water, thereby achieving rapid production of steam.

Description

High temperature reheating induction steam boiler {induction steam boiler using high temperature reheating}

The present invention is an induction boiler in which a primary boiler and a secondary boiler are sequentially connected to the inside of the case, and the primary and secondary boilers are induction boilers that heat water by electricity. It relates to a high-temperature reheating induction steam boiler that enables rapid production of steam by reheating after pulverizing primary heated water.

A boiler is a device that burns fossil fuels such as petroleum, coal, gas, and the like and transfers the combustion heat to water to heat it. In the process of burning, various harmful gases are generated and there is a problem of environmental pollution, so electric boilers using electric energy have been widely used in recent years.

Such an electric boiler employs a direct heating method in which a heating coil is disposed on the outer periphery of a heating tube, and electric energy is applied to the heating coil to heat the heating coil, thereby directly heating the liquid in the heating tube or heating tank. The electric boiler using a coil has disadvantages in that it takes a long time to heat, consumes a lot of power, and has a very complicated structure, such as an insulation structure to prevent the heat generated from the heating coil from dissipating to the outside.

Accordingly, recently, in order to overcome the shortcomings of a boiler using fossil fuel and a direct heat type electric boiler, an electric boiler employing a high frequency induction heating method has been disclosed.

In this high-frequency induction heating method, when a high-frequency current is applied to the induction coil side, a high-frequency magnetic field is generated on the induction coil side. The heater itself heats up.

In relation to this technology, the conventional patent No. 2169526 discloses a technology of a quantum steam boiler. As shown in FIG. 1, an induction coil is built in the housing, and the fluid heated to the upper part of the housing A housing for an induction boiler is formed in the form of a housing having a cylindrical or square column structure so that an outlet 54 for discharging is formed, and an inlet 52 for injecting a circulating fluid is formed at the lower portion of the housing. (20); It is installed inside the housing 20, the pedestal 56 is formed on the bottom, the inlet 52 is formed in the lower side, the pipe 50 is formed in the water outlet 54 is formed in the upper side; a heat storage insulator 40 enclosing the outside of the pipe tube 50 and forming a heat storage part in the outer circumferential space of the induction coil; a lower support 30 for fixing and supporting the heat storage insulator 40 from the outside; and an induction coil wiring line 10 in which an induction coil is built into the housing in the form of a plurality of layers, and (+) (-) electrodes 12 and 14 are formed at the top and bottom.

However, the steam boiler as described above has a disadvantage in that it requires a large amount of heat for the production of steam with a configuration that only provides heat generated by the induction coil.

In addition, in the configuration of producing steam by heating the entire supply of water, there is a disadvantage in that mass production of steam as well as rapid transfer of heat becomes difficult.

An object of the present invention to improve the above and conventional problems is to enable the production of steam and the supply of water for hot water supply, to produce large-capacity steam quickly, and to enable the production of steam by efficient use of power. and to provide a high-temperature reheating induction steam boiler that minimizes external influences caused by magnetic fields or electromagnetic waves.

The present invention, in order to achieve the above object, the primary boiler and the secondary boiler are sequentially connected to the inside of the case,

At least the secondary boiler is an induction boiler that heats water by electricity,

A pulverization device is provided inside the secondary boiler and is installed to micronize the water supplied after being heated in the primary boiler to supply it to the secondary boiler,

The primary and secondary boilers are provided with a heating chamber for heating the supplied water while forming an inlet and an outlet connected thereto while forming a space, a heating element is provided to be located outside the heating chamber, and the outside of the heating element There is provided a high-temperature material heating induction steam boiler comprising a combination of a dielectric coil that is provided with an insulator and is spirally wound on the outer diameter side of the insulator.

And, the pulverization apparatus of the present invention includes a rotary pipe installed so as to be rotatably installed on the inner diameter side of the heating chamber of the secondary boiler while a plurality of nozzles are inclined along the circumferential direction.

Provided is a high-temperature reheating induction steam boiler configured as a pump for supplying water at high pressure to the inside of the rotary pipe.

In addition, in the present invention, the heating chamber is further provided with a collecting chamber having a collecting groove in the upper part to separate and receive water that is condensed and dropped at the lower part while being connected to the bearing so as to rotate freely on the inner diameter side of the heating chamber,

The collection chamber provides a high-temperature reheating induction steam boiler that is installed to supply hot water for hot water supply or re-supply water to a secondary boiler through a two-way valve provided in an outlet pipe.

In addition, the secondary boiler of the present invention provides a high-temperature reheating induction steam boiler further integrally provided with a surface area increasing part made of embossing or unevenness on the inner diameter side of the heating chamber.

Subsequently, in the secondary boiler of the present invention, a radix separator plate is installed in the upper part of the inner diameter side of the heating chamber, the plate shape being porous and the central part protruding toward the upper part,

It provides a high-temperature reheating induction steam boiler provided with a plurality of discharge holes whose diameter is reduced toward the top of the radix separation plate.

In addition, the present invention provides a high-temperature reheating induction steam boiler in which a plurality of induction magnets are provided in a vertical direction along the outer diameter side of the dielectric coil, and a shield plate is provided to be positioned around the outer diameter side of the dielectric coil.

As described above, according to the present invention, it is possible to produce steam and supply water for hot water supply, to produce large-capacity steam quickly, to produce steam by efficient use of power, and to minimize external influences caused by magnetic fields or electromagnetic waves. that has the effect of

1 is a cross-sectional view showing a conventional induction boiler.
2 is an external view showing an induction steam boiler according to the present invention.
3 is a cross-sectional view showing an induction steam boiler according to the present invention.
4 is an installation state diagram of an induction steam boiler according to another embodiment of the present invention, respectively.
5 is a cross-sectional view showing an induction steam boiler according to the present invention.

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

2 to 5 , in the steam boiler 100 of the present invention, the primary boiler 200 and the secondary boiler 300 are sequentially connected to the inside of the case 110 .

At this time, at least the secondary boiler is an induction boiler that heats water by electricity, and a water inlet pipe 210 to which water is supplied is connected to the primary boiler 200 while connecting the primary and secondary boilers ( 230) is connected, and the outlet pipe 250 through which steam is discharged is connected to the secondary boiler.

In addition, various boilers such as an induction boiler or a general electric boiler or oil boiler are applied to the primary boiler.

In addition, a pulverization device 400 is provided inside the secondary boiler 300 to micronize the water supplied after the primary heating in the primary boiler to supply it to the inside of the secondary boiler.

At this time, the primary and secondary boilers 200 and 300 are provided with heating chambers 510 that are connected to each other to form an inlet and an outlet to form a space, and a heating element 530 to be located outside the heating chamber. ) is provided, a heat insulator 550 is provided on the outside of the heating element, and a dielectric coil 570 that is located on the outer diameter side of the heat insulator and is spirally wound is integrally provided.

And, the pulverization apparatus 400 of the present invention is a rotary pipe 410 that is installed rotatably from the inner diameter side of the heating chamber 510 of the secondary boiler while a plurality of nozzles 511 are inclined along the circumferential direction. and a pump 430 for supplying water at high pressure to the inside of the rotary pipe 410 .

In addition, the rotary pipe 410 is connected to the lower side heating chamber by a bearing 515 so as to freely rotate on the inner diameter side of the heating chamber.

At this time, the rotary pipe 410 is rotatably connected to the outer diameter side or the inner diameter side of the connection pipe in a state of maintaining airtightness.

In addition, a collecting chamber 590 having a collecting groove 591 on the upper portion of the heating chamber 510 is further provided to separate and receive hot water that is condensed and dropped.

At this time, the collecting chamber 590 is discharged to supply hot water for hot water supply through a two-way valve 595 provided on one side while the sub-pipe 597 is connected, or is installed to re-supply to the secondary boiler.

In addition, the secondary boiler 300 is further provided with a surface area increasing part 380 made of embossing or unevenness on the inner diameter side of the heating chamber.

Continuing, the secondary boiler 300, the heating chamber 510, the inner diameter of the upper portion of the porous, and the radix separator plate 360 made of a plate-shaped protruding toward the upper portion is further installed.

At this time, a plurality of discharge holes 361 whose diameter is reduced toward the top are formed through the radix separation plate 360 .

In addition, a plurality of induction magnets 571 arranged in a straight line and spaced apart from each other in a vertical direction along the periphery of the outer diameter side of the dielectric coil are provided, and a shielding plate 575 is provided so as to be located on the periphery of the outer diameter side of the dielectric coil. It consists of the provided configuration.

The operation of the present invention configured as described above will be described.

2 to 5, in the primary and secondary boilers 200 and 300 of the present invention, an inlet and an outlet are formed, respectively, and the heating chamber 510 and the heating chamber are connected to each other to form a space. In a configuration in which the heating element 530 located on the outside, the insulator 550 provided on the outside of the heating element, and the dielectric coil 570 located on the outer diameter side of the insulator and spirally wound are integrally provided, the power supply is supplied to the dielectric coil. When supplied, the heating element is heated by the induced current to transfer heat to the water supplied to the inside of the heating chamber 510 .

At this time, the induction magnet 571 performs a function of further increasing the density of the magnetic field formed by the dielectric coil 570 through the magnetic force generated therein, and the magnetic fields generated in the dielectric coil 570 are heated. It is transmitted only to the chamber 510 side and is not leaked to the outside.

In addition, in the dielectric coil 570, when a high-frequency current is applied from the high-frequency current supply unit, a high-frequency magnetic field is formed in the dielectric coil, and an eddy current (eddy current) is generated in the heating chamber 510 adjacent to the inner circumferential surface of the dielectric coil by the high-frequency magnetic field. ) by heat loss or hysteresis loss to heat the liquid supplied to the inner space of the heating chamber 510 .

In addition, in the first and second boilers 200 and 300 of the present invention, the heating element 530, the insulator 550, the dielectric coil 570, and the shielding plate 575 are integrated along the outside of the heating chamber 510. In a configuration provided with a magnetic field generated from the dielectric coil, leakage to the outside is controlled by the shielding plate 575 .

In addition, one or more fans (not shown) for cooling are provided on one side of the shielding plate 575 to discharge heated air to the outside, thereby reducing heat generation of the dielectric coil inside the shielding plate and lowering of efficiency due to heating of the shielding plate. to solve the problem.

Subsequently, the shielding plate 575 positioned on the outer diameter side of the dielectric coil 570 minimizes the loss of magnetic flux by maintaining a certain distance and mounting in a spatial state, and is made of mu-metal and has nano The shielding effect is enhanced by the composition in which the ceramic powder containing metal is coated.

In addition, in the steam boiler 100, the primary boiler 200 and the secondary boiler 300 are sequentially connected to the inside of the case 110, and the water supplied after being heated in the primary boiler is supplied to the secondary boiler. Change it to fine powder and supply it.

At this time, the water flow of the first and second boilers is first heated in the primary boiler through the inlet pipe 210 and then supplied to the secondary boiler through the connection pipe 230, and when steam is generated in the secondary boiler It is discharged through the outlet pipe (250).

In addition, a pulverization device 400 is provided inside the secondary boiler 300 and is pressurized with a pump 430 supplied after being heated in the primary boiler to form a powder by a nozzle in the heating chamber of the secondary boiler. It is supplied to the inside of the 510 to enable rapid generation of steam.

At this time, the pulverization apparatus 400 is provided with a rotary pipe 410 installed so as to be rotatably installed on the inner diameter side of the heating chamber 510 of the secondary boiler while a plurality of nozzles 511 are inclined along the circumferential direction. When the primary heated water is supplied through the pump 430, the water is pulverized and sprayed through the injection pressure of the nozzle. Let the fine powder be sprayed.

In addition, the secondary boiler 300 is further provided with a surface area increasing part 380 made of embossing or unevenness on the inner diameter side of the heating chamber to increase the contact area of the contacting fine powder to facilitate the generation of steam.

That is, when the water sprayed as fine powder through the nozzle comes into contact with the wall surface of the heating chamber 510 of the secondary boiler, heat is transferred quickly, so that steam generation is smoothly and quickly performed.

Subsequently, in the secondary boiler 300, a steam separating plate 360 having a porous shape and a plate shape protruding toward the upper portion of the inner diameter side of the heating chamber 510 is further installed, so that the rising steam is excessively liquid. to prevent it from becoming

At this time, the radix separation plate 360 is provided with a discharge hole 361 whose diameter is reduced toward the top to remove the liquid contained in the steam.

In addition, the lower portion of the heating chamber 510 is further provided with a collecting chamber 590 having a collecting groove 591 at the upper portion to separate and receive condensed and falling water, so that it can be used for hot water supply or re-supplied to a secondary boiler. do.

At this time, the collecting chamber 590 supplies hot water used for hot water supply when the bidirectional valve is operated through the bidirectional valve 595 provided on one side while the sub pipe 597 is connected, or is heated to the secondary boiler. Re-supply water.

100...steam boiler 110...case
200...1st boiler 300...2nd boiler
360... Radix Separator 400... Pulverizer
410...Rotating pipe 510...Heating chamber
511...nozzle 575...shield
590...collection chamber

Claims (6)

The primary and secondary boilers are sequentially connected inside the case,
At least the secondary boiler is an induction boiler that heats water by electricity,
A pulverization device is provided inside the secondary boiler and is installed to micronize the water supplied after being heated in the primary boiler to supply it to the secondary boiler,
The primary and secondary boilers are provided with a heating chamber for heating the supplied water while forming an inlet and an outlet connected thereto while forming a space, a heating element is provided to be located outside the heating chamber, and the outside of the heating element is provided with an insulator, and is made of a combination of a dielectric coil that is located on the outer diameter side of the insulator and is spirally wound,
The pulverization device is a rotary pipe installed rotatably from the inner diameter side of the heating chamber of the secondary boiler while a plurality of nozzles are inclined along the circumferential direction around the circumference, and a pump supplying water at high pressure to the inside of the rotary pipe. under,
The secondary boiler is a high-temperature reheating induction steam boiler having a configuration in which a surface area increasing part made of embossing or unevenness is further provided on the inner diameter side of the heating chamber. delete According to claim 1, wherein the heating chamber is further provided with a collecting chamber having a collecting groove in the upper portion to separate and receive water falling to the lower portion while being connected to the bearing so as to rotate freely on the inner diameter side of the heating chamber,
The high temperature reheating induction steam boiler, characterized in that the collection chamber is installed to supply hot water for hot water supply or re-supply to the secondary boiler through a two-way valve provided in the water outlet pipe. delete According to claim 1, wherein the secondary boiler, a radix separator plate made of a porous plate shape protruding toward the upper portion is installed on the inner diameter side of the heating chamber,
High-temperature reheating induction steam boiler, characterized in that the radix separation plate is provided with a discharge hole whose diameter is reduced toward the top. According to claim 1, wherein a plurality of induction magnets are provided in a vertical direction along the outer diameter side of the dielectric coil,
A high-temperature reheating induction steam boiler, characterized in that a shielding plate is provided to be positioned on the outer diameter side of the dielectric coil.

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