KR200428266Y1 - Hot air blower by water gas generated from water gas generator - Google Patents

Abstract

The present invention is to provide a hot air fan by the water gas generated in the water gas generator, a water gas hose for supplying the water gas generated in the water gas generator; A nozzle which is ignited by an automatic combustion device to combust the water gas supplied through the water gas hose and supported by the nozzle support; A primary heating furnace heated by the water gas combusted by the nozzle and having a primary heating furnace discharge port; A secondary heating furnace which is heated by receiving heat from the primary heating furnace and the primary heating furnace discharge port; A motor installed at a lower end of the primary heating furnace so that heat generated in the primary heating furnace moves through the primary heating furnace discharge port; A heat shield device installed between the primary heating furnace and the water gas hose to prevent backflow of heat; A copper tube heater heated by receiving heat from the primary heating furnace and the primary heating furnace discharge port; A discharge port through which heat generation from the copper tube heater is moved; By including the upper 시키는 for discharging the heat generated through the discharge port to the outside, by using the water gas generated from the water gas to be able to maximize the thermal efficiency suitable for the burner heating apparatus.

Water Gas, Heat Fan, Copper Tube, Heater, Energy

Description

Hot wind apparatus by water gas generated by the water gas generator {Hot wind apparatus by water gas generated water gas generator}

1 is a conceptual diagram showing an example of the configuration of a water gas generator used in the present invention.

Figure 2 is a cross-sectional view of the hot air blower by the water gas generated in the water gas generator according to an embodiment of the present invention.

FIG. 3 is a perspective view illustrating a configuration example of a water gas hose, a nozzle support, a nozzle, and a motor in FIG. 2.

4 is a perspective view illustrating an example of a primary heating furnace in FIG. 2.

FIG. 5 is a perspective view of the secondary heating furnace in FIG. 2.

FIG. 6 is a perspective view illustrating a configuration example of a heat fan case having a fan installed in FIG. 2.

Explanation of symbols on the main parts of the drawings

51: water gas hose 52: nozzle support

53: nozzle 54: automatic combustion device

55: primary furnace 56: secondary furnace

57: motor 58: 홴

59: heat shield 60: copper tube heater

61: heat generation gauge 62: glass check

63: top 홴 64: hot air fan case

65 discharge port 66 primary heating furnace discharge port

The present invention relates to a hot air blower by the water gas generated in the water gas generator, in particular in a water gas generator that is suitable to maximize the thermal efficiency of the burner heating apparatus using the water gas generated from the water gas It relates to a hot air fan by the generated water gas.

In general, water gas refers to hydrogen generated by the electrolysis of water. This hydrogen can be used as an energy source.

However, in the past, there was no device capable of generating such a water gas, and there was no product applicable to this.

In this regard, the present invention is proposed to solve the conventional problems as described above, and an object of the present invention is to generate a water gas that can be thermally maximized according to a burner heating apparatus using the water gas generated from the water gas. It is to provide a hot air fan by the water gas generated in the device.

In order to achieve the above object, the hot air blower generated by the water gas generated in the water gas generator according to an embodiment of the present invention,

A water gas hose for supplying the water gas generated by the water gas generator; A nozzle which is ignited by an automatic combustion device to combust the water gas supplied through the water gas hose and supported by the nozzle support; A primary heating furnace heated by the water gas combusted by the nozzle and having a primary heating furnace discharge port; A secondary heating furnace which is heated by receiving heat from the primary heating furnace and the primary heating furnace discharge port; A motor installed at a lower end of the primary heating furnace so that heat generated in the primary heating furnace moves through the primary heating furnace discharge port; A heat shield device installed between the primary heating furnace and the water gas hose to prevent backflow of heat; A copper tube heater heated by receiving heat from the primary heating furnace and the primary heating furnace discharge port; A discharge port through which heat generation from the copper tube heater is moved; It characterized in that the technical configuration consisting of; the upper 시키는 to discharge the heat generated through the discharge port to the outside.

Hereinafter, an embodiment according to the technical idea of the hot air blower by the water gas generated in the present invention, the water gas generator as described above with reference to the drawings as follows.

2 is a cross-sectional view of a hot air blower by the water gas generated in the water gas generator according to an embodiment of the present invention, Figure 3 is a perspective view showing a configuration example of the water gas hose, nozzle support, nozzle, motor in FIG. 4 is a perspective view illustrating an example of a primary heating furnace in FIG. 2, FIG. 5 is a perspective view illustrating a secondary heating furnace in FIG. 2, and FIG. 6 is a perspective view illustrating a configuration example of a hot air blower case having a fan installed in FIG. 2. .

As shown therein, a water gas hose 51 for supplying the water gas generated by the water gas generator; A nozzle (53) ignited by the automatic combustion device (54) to combust the water gas supplied through the water gas hose (51) and supported by the nozzle support (52); A primary heating furnace (55) heated by the water gas burnt by the nozzle (52) and having a primary heating furnace discharge port (66); A secondary heating furnace 56 which is heated by receiving heat from the primary heating furnace 55 and the primary heating furnace discharge port 66; A motor (58) installed at a lower end of the primary heating furnace (55) so that heat generated in the primary heating furnace (55) moves through the primary heating furnace discharge opening (66); A thermal cutoff device (59) installed between the primary heating furnace (55) and the water gas hose (51) to prevent backflow of heat; A copper tube heater 60 which is heated by being supplied with heat by the primary heating furnace 55 and the primary heating furnace discharge port 66; A discharge port 65 through which the heat generation from the copper tube heater 60 is moved; And an upper fin 63 for dissipating heat generated through the discharge port 65 to the outside.

A plurality of nozzles 53 are provided, and the plurality of nozzles are characterized by being installed at an angle of 45 degrees to 50 degrees with respect to the copper tube heater 60.

The hot air blower by the water gas generated by the water gas generator, is installed on the lower end of the discharge port 65, the heat measurement gauge 61 for checking the excess efficiency of the heat amount; characterized in that it further comprises a configuration.

Referring to the preferred embodiment of the hot air blower by the water gas generated in the water gas generator according to the present invention configured as described above in detail as follows. In the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. In addition, terms to be described below are terms defined in consideration of functions in the present invention, which may vary according to intentions or precedents of users or operators, and accordingly, the meaning of each term should be interpreted based on the contents throughout the present specification. will be.

First, the present invention intends to maximize the thermal efficiency of the burner heating apparatus using the water gas generated from the water gas. Therefore, the heat is heated at an angle to the copper pipe wall at an angle of 45 degrees to 50 degrees to maximize the heat by transferring the heated heat to the secondary furnace, and then stay in the secondary furnace to the tertiary furnace. It is a hot air fan that can maximize the water gas energy supplied by moving more than 5 times.

In addition, since water gas is a completely pollution-free fuel, it is completely burned, and the completely burned gas is reduced to water vapor so that it does not harm the natural environment including humans such as plants and animals.

LPG, bunker seed oil, and oil have been used on farms to grow and raise plants and animals on farms. For this reason, the present invention intends to contribute to the development of alternative energy in farms by devising a hot air fan using water energy.

To this end, first, the water gas generator used in the present invention will be described with reference to FIG. 1 and then the present invention will be described with reference to FIGS. 2 to 6.

1 is a conceptual diagram showing an example of the configuration of a water gas generator used in the present invention.

When water is first electrolyzed, pure water does not conduct electricity. To make it electricity, chemicals such as sulfuric acid, sodium hydroxide and potassium hydroxide are used to facilitate the electrolysis. Therefore, in the water gas generator, sodium hydroxide, potassium hydroxide, and the like are mixed in water to maximize the electrolysis efficiency of water to generate high efficiency water gas.

Thus, the direct water (1), which is tap water, passes through a water filter (2) that filters iron and various foreign matters through the water moving path, and the water purified by the water purification filter (2) passes through the electrolyte auxiliary tank (7) and the electrolyzer tank. Pass through barrel (11).

The electrolyzer 9 allows gas to be formed during electrolysis, and a check valve No. N5 was used when the purified water entered the auxiliary tank 7 to prevent the gas from going backward, and the check valve No. N5 ), A rubber tube (non-rubber) was inserted into the nozzle to allow the purified water to pass through but to prevent the gas from entering the reverse. Also, the nozzles N5, N14, N21, N23, N30, N34, and N35 may have a liquid or gas flow from left to right, but if they want to proceed from right to left, they may not be blocked by the nozzle. Form.

In addition, the electrolytic cell 9 has a constant gap between the pole plate and the pole plate, and is configured to be assembled to engage the groove so that the gas is smoothly generated in the electrolytic cell 9. In addition, the gas generated in the electrolytic cell 9 is collected in the upper space of the electrolytic cell tank 11. In addition, when assembling the upper lid 32, the electrolytic cell tank rubber packing 31 is assembled so as to be in close contact with the electrolytic cell lower tank so that the gas does not leak.

When electrolysis is performed in the electrolytic cell 9, heat is generated. When the electrolyte passes through the radiator 16 to cool the heat, the electrolyte cooled by the fin 15 is forced into the forced circulation pump 33 ) To maintain a constant temperature during electrolysis while repeating the cycle.

When electrolysis in the electrolytic cell 9, pressure is formed when the gas is electrolyzed in the electrolytic cell 9 while passing through the lid 32. Thus, in order to make the gas pressure the maximum pressure, the nozzle N14 is inserted to increase the pressure three times or more, so that the gas moves to the connection pipe P17. The moved gas forms a tube to be connected to the lower end of the normal nucleic acid tank 18 for maximizing thermal efficiency, and since the gas entering the normal nucleic acid solution 19 is bubble gas, the normal nucleic acid solution 19 and As they burst together, they are ejected out.

In addition, in order to control the maximum pressure by installing a pressure gauge 20 in the upper portion of the normal nucleic acid water tank (18) to adjust the gas pressure, when the normal nucleic acid and the gas is discharged while moving out of the water gas nozzle outlet 22 ignition do.

When the ignition was stopped, a reverse flow prevention nozzle N21 was installed to prevent the gas from entering in the reverse direction to prevent the remaining gas from entering the reverse.

In addition, when the auxiliary tank 7 and the electrolytic cell tank 11 are replaced, the electrolyte solution blended in the recycled electrolytic cell tank 27 is put in the electrolytic cell tank 11.

When the electrolyte is replaced, the electrolyte 10 is forcibly replaced, and the electrolyte is filtered through a purified water filter 25 using magnesium sulfate and placed in a recycled electrolyte tank 27. And it is automatically formulated by the electrolyte dilution screw 28, which is a tool for the automatic solution of the electrolyte is to be used for the replacement of the electrolyte (10).

Meanwhile, the configuration and operation of the present invention will be described in more detail with reference to FIGS. 2 to 6.

First, the water gas ejected from the water gas nozzle ejection port 22 of the water gas generator is transferred to the hot air blower through the water gas hose 51.

Thus, when water gas is supplied through the water gas hose 51, the automatic combustion device 54 purifies the nozzle 53 supported by the nozzle support 52. Then, the supplied water gas is burned at the nozzle 53.

Then, the heat burned by the nozzle 53 heats the primary heating furnace 55 of the copper tube.

The primary heating furnace 55 allows the nozzle 53 to be heated in a state having an angle of about 45 degrees. In order to avoid continuous heating in heating the primary heating furnace 55 of the copper tube, an AC motor 57 is installed at the lower end of the primary heating furnace 55 to rotate the nozzle support 52 so that the primary heating furnace ( 55) Install the wall hitting the wall evenly.

A fin 58 is provided at the lower end of the hot air blower case 64 to move the heat 58 generated in the primary heating furnace 55 to the primary heating furnace discharge port 66.

The heat moved to the primary heating furnace discharge port 66 is to stay in the secondary heating furnace 56, the upper end of the secondary heating furnace 56 to heat the copper tube heater 60 to maximize the heat generation. In addition, the secondary heating furnace 56 to check the excess efficiency of the heat amount through the glass check port 62 and the exothermic measuring gauge 61.

The checked heat causes the heat generated at the upper end of the secondary heat path 56 to move to the discharge port 65, and the moved heat is discharged out by the upper fin 63.

In addition, a thermal cutoff device 59 is installed to prevent backflow of heat.

As such, the present invention is to maximize the thermal efficiency of the burner heating apparatus using the water gas generated from the water gas.

As described above, the hot air blower by the water gas generated in the water gas generator according to the present invention has the effect of maximizing the thermal efficiency according to the burner heating apparatus using the water gas generated from the water gas. .

As described above, the present invention is limited to the preferred embodiment, but the present invention is not limited thereto, and various changes, modifications, and equivalents may be used. Therefore, the present invention can be applied by appropriately modifying the above embodiment, and such application will be within the scope of the right of the present invention as long as it is based on the technical idea described in the utility model registration claims below.

Claims (3)

A water gas hose 51 for supplying the water gas generated by the water gas generator; A nozzle (53) ignited by the automatic combustion device (54) to combust the water gas supplied through the water gas hose (51) and supported by the nozzle support (52); A primary heating furnace (55) heated by the water gas burnt by the nozzle (52) and having a primary heating furnace discharge port (66); A secondary heating furnace 56 which is heated by receiving heat from the primary heating furnace 55 and the primary heating furnace discharge port 66; A motor (58) installed at a lower end of the primary heating furnace (55) so that heat generated in the primary heating furnace (55) moves through the primary heating furnace discharge opening (66); A thermal cutoff device (59) installed between the primary heating furnace (55) and the water gas hose (51) to prevent backflow of heat; A copper tube heater 60 which is heated by being supplied with heat by the primary heating furnace 55 and the primary heating furnace discharge port 66; A discharge port 65 through which the heat generation from the copper tube heater 60 is moved; An upper fan (63) for discharging heat generated through the discharge port (65) to the outside. The method according to claim 1, wherein the nozzle 53, A plurality of nozzles, the plurality of nozzles are hot air fan by the water gas generated in the water gas generator, characterized in that installed at an angle of 45 degrees to 50 degrees with respect to the copper tube heater (60). The hot air blower by the water gas generated in the water gas generator, And a heat generation gauge (61) installed at the lower end of the discharge port (65) to check the excess efficiency of the heat amount. The hot air blower caused by the water gas generated by the water gas generator.

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