KR200393116Y1 - Energy reduction boiler with magnetic forces device - Google Patents

Abstract

Energy-saving boiler with the magnetization device of the present invention is formed in the cylindrical shape of the burner inlet 12 on one side is equipped with a burner (11) provided with a fuel inlet (15) for supplying fuel and the burner (inside) A combustion chamber 13 in which air and fuel are mixed and combusted at 11), and a combustion section 10 having an exhaust port 14 through which exhaust gas combusted is discharged on the combustion chamber 13; The supply water supplied through the water inlet 22 communicated with the heating chamber 21 by disposing a heating chamber 21 having a hollow tube shape outside the combustion chamber 13 of the heating chamber 21 is provided inside the heating chamber 21. The hot water outlet 24 which is heated by the heat energy generated in the combustion chamber 13 while being filled, is circulated and pumped into the hot water chamber 23 located above the combustion chamber 13, and discharges hot water in the upper part of the hot water chamber 23. The hot water unit 20 and formed. Induces combustion gas to be exhausted into the flue gas chamber 31 connected to the outlet 14 of the combustion chamber 13 on the outside of the heating chamber 21 of the heated portion 20, but the exhaust fan 31 in the flue gas chamber 31 32 to form a preheating chamber 41 so as to be connected to the outside of the exhaust chamber 31 of the exhaust portion 30 and the exhaust unit 30 for pumping out the high-temperature combustion gas to the outside, the combustion chamber 13 Preheater formed to heat the water supplied from the preheating water supply port 42 in communication with the flue gas chamber 31 by the high-temperature combustion gas moving through the preheating chamber 41 to supply to the heating chamber 21 ( 40 and the long curved tube communication chamber 54 connected to the exhaust gas chamber 31 of the exhaust part 30 are bent in the communication tank 51 to form a gas outlet 55 to the outside to burn the combustion gas. Discharge to the outside and the communication tank 51 is filled with the supply water through the communication water supply port 52 and at the same time connected to the preheating water supply port 42 of the preheating unit 40 preheating A pair of communication portions 50 formed to receive the heated hot water from the 40 and an outer circumference of the oil supply port 15 and the water supply port 22 and the communication water supply port 52 of the burner 11 are provided. Combining the housing (61, 62) with the magnet means (63) facing each other in the same modification to allow a fluid such as fuel and feed water to pass through a strong magnetic flux to make the molecular structure of the fluid ultra-fine and uniform particle size It consists of a magnetizing unit 60 to have a.

Description

Energy saving boiler with magnetic forces device

The present invention relates to an energy saving boiler equipped with a magnetization device, and the fuel (oil) and the supply water (hot water) by installing the oil supply port and the water supply port of the magnetization device in the boiler and waste heat recovery device used for energy saving purposes By converting the fluid properties of the fluid, the molecular structure of the fluid has a certain particle size and superfine it, thereby maximizing the combustion efficiency of the fuel and the heating water of the boiler and the waste heat recovery device, thereby improving the thermal efficiency of the boiler and the waste heat recovery device. It relates to an energy saving boiler having a magnetizing device to improve.

In general, a boiler is a device that generates steam having a high temperature and pressure by transmitting fuel and combustion heat to water, and is also known as a steam boiler. The boiler is used to supply steam to a steam engine such as a thermal power plant and a ship, and for work or heating in various factories. In use, the fuel of the early boilers was coal, which was a manual type of man putting coal into a grate, but soon a mechanical stalker was used.

Such a boiler is discharged immediately after heating hot water with a heat source heated in a heating chamber, and the combustion gas heat including a large amount of heat source exhausted as well as the environmental loss due to exhaust purification is classified as waste heat and released as it is into the atmosphere. The losses were so great that the waste of energy generated by the combustion of the fuel was severe.

Accordingly, in order to save energy, the waste heat recovery apparatus for recovering waste heat is recovered from the waste heat (exhaust gas) of about 230 to 320 ° C., which is discharged to the atmosphere during combustion of the boiler, to the waste heat recoverer. By supplying hot water at a high temperature to the tank, the waste heat recovery device of such a boiler will be described briefly with reference to FIG. 1 of the accompanying drawings.

As shown in Figure 1, the waste heat recovery apparatus of the boiler is a step of preheating the water (cold water) of the high water tank to the waste water heat recovery to preheat to about 20 ~ 24 ℃, and the boiler receiving oil (fuel) through the oil inlet Directly heating the water in the hot water tank supplied with water through the water inlet with the heat generated by burning the oil in the furnace, and recovering the waste heat discharged from the boiler during the combustion with the waste heat recovery machine It is heated to about 70 ~ 85 ℃ degree is supplied to the hot water tank.

The waste heat recovery device of such a boiler heats the supply water directly to the boiler and at the same time recovers the waste heat that is simply discharged without using any oil and electricity, and heats the supply water supplied to the waste heat recovery unit with this waste heat to a high temperature. Since it is supplied to the hot water tank again, the operating time of the boiler can be drastically shortened, thereby reducing fuel costs.

However, in the conventional boiler, there is a problem that it is insufficient to obtain the energy saving effect by the exchange of waste heat.

That is, the liquid oil supplied to the boiler and the supplied water supplied to the hot water tank have a random arrangement of molecular structure of the fluid, so that the absorbance (transmittance) is poor in the fluid molecular structure in the natural state and the wavelength is irregular. When the combustion is carried out as it is the molecular structure of the mixed fuel mixed with oil and air, the combustion efficiency is only about 60% ~ 70%, there is a problem that causes incomplete combustion.

In addition, the feed water filled in the fuel tank is also in an indeterminate arrangement. When using general tap water instead of pure water (distilled water), impurities are diluted. There was a problem that the thermal efficiency and the heating efficiency is lowered by the difference.

In addition, when heating and circulating the feed water containing impurities, the scale is pinched inside the metal pipe, which hinders the normal operation of the boiler and lowers the thermal conductivity, fuel, feed water flow rate and flow rate. There was this.

Therefore, the main object of the present invention is to install the magnetization device in the fuel inlet for supplying fuel to the burner, to ultra-fine by the change of the physical properties of the fuel to be mixed with the air to completely burn the fuel burned by the burner to improve the combustion efficiency To improve and minimize fuel consumption.

In addition, another object of the present invention is to install a magnetization device in the water supply port and the communication water supply port for supplying and circulating the feed water to the boiler and the waste heat recovery device to change the properties of the supply water to have a very fine granularity, By diluting the impurities to distilled water (pure water) to lower the boiling temperature to improve the heating efficiency of the feed water to improve the thermal efficiency of the boiler and waste heat recovery system.

In addition, another object of the present invention is to maximize the magnetic force by orienting the magnetic particles so that the magnetic lines are concentrated in the oil supply port, water supply port and communication water supply port by applying an anisotropic magnet or neodymium permanent magnet to the magnetization means of the magnetization device And conversion to a functional water having a magnetization property of the feed water.

In addition, another object of the present invention is to decompose finely various impurities contained in the feed water through the strong magnetic force of the magnetization device and to prevent scale pinching while preventing corrosion inside the metal pipe, thereby preventing the hot water circulation of the boiler. It is to improve the thermal conductivity of the boiler by smoothly supplying the flow rate and flow rate.

Finally, another object of the present invention is to maximize the magnetic force by sequentially and continuously mounted a plurality of magnetizers at regular intervals on the outer periphery of the oil inlet and the water inlet and the communication water inlet pipe.

 Energy-saving boiler equipped with a magnetization device of the present invention devised to achieve the above object is formed in the cylindrical shape with a burner inlet formed on one side and equipped with a burner provided with a fuel supply port and the inside of the burner Air and fuel are mixed to form a combustion chamber that is combusted, the combustion unit formed an outlet for discharging the exhaust gas burned in the upper portion of the combustion chamber, and a heating chamber made of a hollow tube form outside the combustion chamber of the combustion unit is heated by heating The feed water supplied through the water inlet communicating with the chamber is filled by the heat energy generated in the combustion chamber while filling the inside of the heating chamber, and is circulated to the hot water chamber located in the upper combustion chamber, and an outlet for discharging hot water is formed in the upper portion of the heating chamber. And a ship connected to the outlet of the combustion chamber in the upper portion outside the heating chamber of the hot water unit. Induces combustion gas to be exhausted in the combustion chamber, but installs an exhaust fan in the exhaust chamber to pump and exhaust high-temperature combustion gas to the outside, and forms a preheating chamber connected to the outside of the exhaust chamber to move through the combustion chamber. The preheating part is formed to heat the water supplied from the preheating water supply port communicated with the flue gas chamber by the high temperature combustion gas in the preheating chamber and to supply the heating chamber, and the communication chamber in the form of a long curved pipe connected with the flue gas chamber of the exhaust part. The exhaust pipe is formed to be discharged to the outside to discharge the combustion gas to the outside, and the communication tank fills the supply water through the communication water supply port and is connected to the preheating water supply port of the preheater to receive hot water heated in the preheater. And a pair of magnetic means facing the same poles on the outer periphery of the oil supply port, the water supply port, and the communication water supply port of the burner. And a combination of a housing having a converted characterized in that it consists of a magnetic force conversion unit to have a uniform particle size and molecular structure of the atomization fluid to a second fluid, such as fuel and feed to pass through the inside of a strong magnetic field.

In addition, the magnetizing portion is formed of a semicircular coupling groove penetrating through the inner center and forming a coupling jaw on the inner circumference to be symmetrical to each other in an upper portion made of a non-metal material coupled to the outer periphery of the oil inlet, the heating water inlet and the communication water inlet Oil and gas inlet and communication port for supplying fuel and supply water to the boiler side by selectively adopting anisotropic magnet or neodymium permanent magnet on the housing and lower housing and the upper housing and lower housing coupling jaw. Coupled to the outer periphery of the fluid supply means of the water supply port is characterized in that the magnetic force line is concentrated on the inner periphery of each fluid supply means to orient the magnetic particles and configured as a magnetic means to maximize the magnetic force.

As described above, the preferred embodiment of the present invention configured as described in more detail with reference to the drawings as follows.

2 is a cross-sectional view showing a boiler having a magnetizing device according to the present invention, Figure 3 is a perspective view showing a magnetizing device according to the present invention, Figure 4 is an exploded perspective view showing a magnetizing device according to the present invention, 5 is a cross-sectional view showing a state in which the magnetizing device according to the present invention is mounted.

As shown in Figure 2 to 5, the energy-saving boiler with the magnetization device of the present invention is supplied with fuel through the water supply port 22, the burner (11) to generate heat by ignition after mixing with air ), A combustion unit 10 for burning fuel, a hot water unit 20 for heating hot water supplied through a water supply port 22 with heat of the combustion unit 10, and the combustion unit 10. In the communication tank 51, the exhaust unit 30 for exhausting the exhaust gas generated by the exhaust gas, the preheating unit 40 for preheating the hot water unit 20, and the exhaust gas exhausted from the exhaust unit 30 are discharged. The hot water is reheated and installed in the communication part 50 which receives the supply water through the communication supply port, and the communication supply port of the water supply port 22 and the communication part 50 of the hot water part 20 respectively. It consists of a magnetization unit 60 for generating a magnetic force to convert the physical properties of the fluid.

The burner 10 has a cylindrical shape and has a burner inlet 12 formed at one side thereof to install a burner 11 provided with an oil inlet 15 for receiving fuel. The combustion chamber 13 is mixed and combusted, and an exhaust port 14 through which the combusted exhaust gas is discharged is formed on the combustion chamber 13.

The hot water unit 20 is supplied through the water supply port 22 arranged in communication with the heating chamber 21 by placing a heating chamber 21 having a hollow tube shape outside the combustion chamber 13 of the combustion unit 10. The supply water is heated by the heat energy generated in the combustion chamber 13 while filling the inside of the heating chamber 21 and is circulated to the hot water chamber 23 located above the combustion chamber 13, and the upper portion of the hot water chamber 23 is A hot water outlet 24 for discharging hot water is formed.

The exhaust unit 30 guides the combustion gas to the exhaust gas chamber 31 connected to the outlet 14 of the combustion chamber 13 on the outside of the heating chamber 21 of the hot water unit 20 so that the combustion gas is exhausted. An exhaust fan 32 is provided at 31 so as to pressurize and exhaust hot combustion gas to the outside.

The preheating unit 40 forms the preheating chamber 41 to be connected to the outside of the exhaust chamber 31 of the exhaust unit 30, and the exhaust chamber 31 is formed by the hot combustion gas moving through the combustion chamber 13. The water supplied from the communicating preheating water supply port 42 is heated in the preheating chamber 41 and formed to be supplied to the heating chamber 21.

The communication part 50 forms a gas discharge port 55 to the outside by bending the communication chamber 54 having a long curved pipe shape connected to the flue gas chamber 31 of the exhaust part 30 in the communication tank 51. The combustion gas is discharged to the outside and the communication tank 51 fills the supply water through the communication water supply port 52 and is connected to the preheating water supply port 42 of the preheater 40 to be heated in the preheater 40. Form to receive hot water.

The magnetizing unit 60 has a pair of magnet means 63 mounted on the outer periphery of the oil supply port 15, the water supply port 22, and the communication water supply port 52 of the burner 11 so that the same poles face each other. The housings 61 and 62 are combined in one modification to allow fluids such as fuel and feed water to pass through a strong magnetic flux so that the molecular structure of the fluid is ultrafine and has a constant particle size.

In addition, the magnetization unit 60 forms a semicircular coupling groove 62a penetrating through the inner center and forming a coupling jaw 62b on the inner circumference thereof so as to be symmetrical with each other so that the oil inlet 15 and the water inlet 22 are symmetrically formed. And an upper metal housing 61 and a lower housing 62 which are made of a non-metal material coupled to the outer circumference of the communication water supply port 52 and integrally coupled by the fastening means 64, and the upper housing 61 and the lower housing. (62) An oil supply port 15 and a water supply port 22 that selectively adopt anisotropic magnets or neodymium permanent magnets on the coupling jaw 62b to provide fuel and supply water to the boiler side by installing them in the same pole. By coupling to the outer periphery of the fluid supply means such as the communication water supply port 52, the magnetic force lines are concentrated on the inner periphery of each fluid supply means, and the magnetic means are arranged to orient magnetic particles and maximize the magnetic force.

The magnetization device composed of the magnetization unit 60 and the like of the present invention can be configured and applied to various boilers.

As described above, the action of the energy-saving boiler with the magnetization device of the present invention configured as follows.

First, when the burner 11 of the combustion unit 10 is ignited, the fuel supplied through the oil supply port 15 is mixed with external air at a predetermined ratio, changed into a spray state, and then ignited to heat the inside of the combustion chamber 13. .

At this time, the liquid fuel supplied through the oil inlet 15 passes vertically to the magnetization unit 60, and the microfluidic and physical properties of the fuel are ionized by a strong magnetic field, and thus have a constant particle size. .

The constant particle size and ultrafine fuel of the fuel is smoothly mixed with the air to achieve complete combustion through the burner 11 can improve the combustion efficiency of the boiler and minimize the fuel consumption.

When the temperature of the combustion chamber 13 is increased, the internal temperature of the heating chamber 21 disposed in a form surrounding the outside of the combustion unit 10 is increased to warm the supply water.

At this time, if the feed water is supplied to the inside of the boiler through the water supply port 22 and the communication water supply port 52, the magnetization device installed in the water supply port 22 and the communication water supply port 52 is changed in the same manner as the properties of the fuel. The coarse feed water is converted into hexagonal water with ultrafine and uniform particle size by the ionization of the fluid molecular structure of the fuel as the hydrogen bonding of water is repeatedly performed during the separation and recombination process.

In other words, the magnetizing device converts general tap water into functional water by magnetic force. When the coil moves orthogonal to the magnet according to Fleming's law, electricity is generated in the water as the current flows in the coil to ionize the supply water. Is converted to a number.

In this way, the feed water converted to physical properties is maintained in a state where water penetration, dissolving power, cleaning power, and purification power are most important, and the ultrafine atomized water from which impurities are removed is cut off at a temperature lower than 100 ° C at 1 atmosphere. The point can be achieved to maximize the thermal efficiency and heating efficiency of the boiler.

The energy saving boiler equipped with the magnetization device of the present invention is thermally efficient by re-supplying hot waste heat combustion gas to the hot water unit 20, the exhaust unit 30, the preheating unit 40, the communicating unit 50, and the like. In addition, it is possible to maximize the heating efficiency of the feed water while maximizing energy efficiency while enabling the complete combustion of fuel.

Here, the magnetization device is to be installed in a plurality of spaced apart in the pipeline to supply the fuel and feed water to the boiler to maximize the generation of the magnetic force to be able to improve the energy efficiency more.

It is apparent that anyone of ordinary skill in the art can make various modifications and imitations without departing from the scope of the technical idea of the present invention.

As described above, the energy-saving boiler with the magnetization device of the present invention is installed in the oil supply port for supplying fuel to the burner by the ultra-fine particles by the change in the physical properties of the fuel and mixed with the air by the burner It is possible to improve the combustion efficiency and minimize the fuel consumption by allowing the fuel to be burned completely.

In addition, another effect of the present invention is to install a magnetizing device in the water supply port and the communication water supply port for supplying and circulating the feed water to the boiler and waste heat recovery device to change the properties of the supply water to have a very fine grain, while having a certain particle size, By diluting the impurity to distilled water (pure water) level to lower the boiling temperature, it is possible to improve the heating efficiency of the feed water to improve the thermal efficiency of the boiler and waste heat recovery device.

In addition, another effect of the present invention is to maximize the magnetic force by orienting the magnetic particles so that the magnetic lines are concentrated in the oil inlet, water supply port and communication water supply port by selectively applying the magnetization means of the magnetization device as anisotropic magnet or neodymium permanent magnet By doing so, there is an effect that the conversion to the functional water having the magnetization property of the fuel and the feed water can be made more surely.

In addition, another effect of the present invention is to decompose various impurities contained in the feed water finely through the strong magnetic force of the magnetization device, and to prevent the scale pinching while preventing corrosion inside the metal pipe, thereby preventing the hot water circulation of the boiler. By smoothly supplying the flow rate and the flow rate, there is an effect of improving the thermal conductivity of the boiler.

Finally, another effect of the present invention is to maximize the magnetic force by sequentially and continuously mounted a plurality of magnetizers at regular intervals on the outer periphery of the oil inlet and the water inlet and the communication water inlet pipe.

1 is a block diagram showing a boiler according to the prior art.

Figure 2 is a sectional view showing a boiler having a magnetizing device according to the present invention.

Figure 3 is a perspective view showing a magnetizing device according to the present invention.

Figure 4 is an exploded perspective view showing a magnetizing device according to the present invention.

5 is a cross-sectional view showing a state equipped with a magnetizing device according to the present invention.

Explanation of symbols on main parts of drawing

10: burner 11: burner

12: burner inlet 13: combustion chamber

14 discharge port 15 oil supply port

20: hot water unit 21: heating chamber

22: water supply port 23: hot water room

24: hot water outlet 30: exhaust

31: flue gas chamber 32: exhaust fan

40: preheating unit 41: preheating chamber

42: preheating water supply port 50: communication unit

51: communication tank 52: communication water supply port

54: communication chamber 55: gas outlet

60: magnetizing unit 61: upper housing

62: lower housing 62a: coupling groove

62b: coupling jaw 63: magnet means

64: fastening means

Claims (2)

A burner inlet 12 is formed at one side in a cylindrical shape, and a burner 11 having an oil supply port 15 for supplying fuel is mounted and formed therein, and an internal combustion chamber 13 in which air and fuel are mixed and burned in the burner 11. And a combustion unit 10 having a discharge port 14 through which the discharged gas is discharged in an upper portion of the combustion chamber 13, The supply water supplied through the water supply port 22 communicating with the heating chamber 21 by arranging the heating chamber 21 having a hollow tube shape outside the combustion chamber 13 of the combustion unit 10 is the heating chamber 21. Heated by the heat energy generated in the combustion chamber 13 while filling the inside) is circulated to the hot water chamber 23 located in the upper combustion chamber 13, the hot water outlet for discharging hot water in the upper portion of the hot water chamber (23) And the hot water part 20 which formed 24. Induces combustion gas to be exhausted into the flue gas chamber 31 connected to the outlet 14 of the combustion chamber 13 on the outside of the heating chamber 21 of the heated portion 20, but the exhaust fan 31 in the flue gas chamber 31 An exhaust unit 30 for providing a high pressure combustion gas to the outside by installing 32; The preheating water supply port formed with the preheating chamber 41 to be connected to the outside of the exhaust chamber 31 of the exhaust part 30 and communicated with the exhaust chamber 31 by the high temperature combustion gas moving through the combustion chamber 13 ( A preheater 40 formed to heat the water supplied from 42 in the preheating chamber 41 to be supplied to the heating chamber 21; The long curved tube-shaped communication chamber 54 connected to the flue gas chamber 31 of the exhaust part 30 is bent into the communication tank 51 to form a gas outlet 55 to discharge the combustion gas to the outside. The communication tank 51 fills the supply water through the communication water supply port 52 and is connected to the preheating water supply port 42 of the preheater 40 to receive hot water heated in the preheater 40. Communication part 50, Housings 61 and 62 having a pair of magnetic means 63 facing the same poles on the outer periphery of the oil supply port 15, the water supply port 22, and the communication water supply port 52 of the burner 11. The magnetizing device is characterized in that the magnetization unit 60 is configured to have a constant particle size while combining the fluid and fuel, such as fuel and feed water through a powerful magnetic flux to make the molecular structure of the fluid ultra-fine Energy saving boiler. The method of claim 1, The magnetizing unit 60, A semicircular coupling groove 62a is formed to penetrate through the inner center and a coupling jaw 62b is formed at the inner circumference thereof so as to be symmetrical with each other so that the oil inlet 15, the water supply port 22, and the communication water supply port 52 are formed. An upper housing 61 and a lower housing 62 made of a non-metal material coupled to an outer circumference; Refueling port which selectively adopts anisotropic magnet or neodymium permanent magnet in the upper housing 61 and lower housing 62 and the coupling jaw 62b, and provides fuel and supply water to the boiler side by installing the anisotropic magnet or neodymium permanent magnet. 15) and magnetic means by aligning magnetic lines on the inner periphery of each fluid supply means by aligning the magnetic force lines on the inner periphery of the fluid supply means of the water supply port 22 and the communication water supply port 52 to maximize the magnetic force ( Energy saving boiler with a magnetizing device, characterized in that consisting of 63).