KR101836773B1 - The burner without a nozzle - Google Patents

Abstract

The present invention relates to a burner without a nozzle. The burner without a nozzle according to an embodiment of the present invention includes: a combustion housing; a fuel supply device for supplying fuel; a heating device for preheating the fuel; and an air supply device for supplying air; an ignition device for igniting the fuel supplied to the fuel supply unit and the air supplied to the air supply device; and a guide mechanism for guiding the air supplied from the air supply device. The combustion housing includes a first housing and a second housing. A receiving member is formed on the lower side of the first housing. The receiving member has a supply port and a plurality of receiving grooves. Therefore, the present invention can prevent environmental problems and the deterioration of efficiency due to incomplete combustion.

Description

[0001] THE BURNER WITHOUT A NOZZLE [0002]

[0001] The present invention relates to a burner, and more particularly, to a burner in which a nozzle is clogged due to the use of a nozzle, a paraffin-based adsorption of fuel to the nozzle, The present invention relates to a non-nozzle burner capable of solving the problem of environmental problems caused by incomplete combustion and deterioration of efficiency, The present invention relates to a non-nozzle burner having economical efficiency and environment-friendly characteristics by using a low-grade fuel having high viscosity such as waste oil.

A burner is a device that burns gas or liquid fuel, and is a device that burns fuel and air to generate a certain amount of heat. Such burners include a gas burner or an oil burner depending on the kind of fuel, and among these gas burners, there are LNG and LPG gas burners. In the case of oil burners, there are burners such as light oil or kerosene, The burner is generally used to vary the diameter and fuel supply pressure of each nozzle depending on the nature of the fuel.

Such a general burner includes a fuel supply device for supplying fuel, an air supply device for supplying air, a combustion housing having a combustion chamber in which fuel and air are mixed and combusted, and a nozzle for spraying fuel, .

Among the above-mentioned nozzles, the nozzle of the liquid fuel has a nozzle hole for spraying the fuel toward the combustion chamber side, and becomes atomized as the fuel passes through the nozzle hole at a high pressure. The atomized fuel droplet evaporates from its surface, The fuel is combusted by reacting with oxygen in the air supplied in a temperature atmosphere above the ignition source or the ignition temperature.

In the conventional burner, the nozzle hole is made smaller to improve the atomization of the fuel, and the fuel supply pressure is set to a higher pressure. In such a case, the fuel having a low fuel quality or containing a large amount of impurities or highly viscous fuel can not be easily clogged by the nozzle hole and can not exhibit the function of the nozzle. In addition, even if the nozzle is not clogged, atomization can not be performed well and the incomplete combustion or combustion efficiency Is greatly reduced.

In addition, in the conventional burner, paraffin-based fuel or the like can be easily adsorbed to the nozzle hole due to the minute fineness of the nozzle hole, which makes it possible to easily clog the nozzle hole, and the burner is normally operated There was a disadvantage that it could not.

In addition, the conventional burner has a disadvantage in that nozzle corrosion can easily occur due to the fuel containing a large amount of acidic components in the fuel property, and therefore, the nozzle is easily damaged and the fuel can not be sprayed smoothly.

Conventional burners do not utilize highly viscous fuel such as waste oil or oil because the nozzle holes can be easily clogged with highly viscous fuel such as waste oil and oil, and as a result, recycling of resources is difficult, But the economical efficiency and the energy availability are deteriorated.

In addition, since the conventional burner nozzle has a dedicated structure corresponding to the type of fuel such as a gas burner, a petroleum burner, an oil burner, and a waste oil, all kinds of fluid fuels such as gas, oil, There was a disadvantage that it was not available.

Prior Art 1: Korean Patent Publication No. 10-1995-0010615 Prior Art 2: Korean Patent Publication No. 10-1997-0046994 Prior Art 3: Korean Patent Publication No. 10-1999-0076369 Prior Art 4: Korean Patent Publication No. 10-1998-0043048 Prior Art 5: Korean Patent Publication No. 10-2001-0109503

SUMMARY OF THE INVENTION It is an object of the present invention to provide a nozzleless burner which can solve problems such as clogging of nozzles, environmental problems caused by incomplete combustion, deterioration of efficiency, and the like.

It is another object of the present invention to provide a non-nozzle burner that can use gaseous fuel and can easily improve fuel economy and environmental friendliness by easily utilizing a fuel having a high viscosity such as waste oil or heavy oil.

It is also an object of the present invention to provide a non-nozzle burner which can use all kinds of fluid fuels such as gas, oil, waste oil, oil, etc. in a compatible manner.

In addition, the present invention can effectively achieve complete combustion through thermal decomposition (decomposition of water into hydrogen and oxygen) by mixing air and fine water particles by spraying water to the air supplied to the combustion chamber, Minimization of Secondary Environmental Pollution and Evaporation of Water Particles By reducing the temperature of flame in combustion by latent heat, it is possible to reduce NOx or inject part of exhaust gas (EGR), steam or high temperature hot water to promote combustion and reduce NOx The present invention has been made to solve the above problems.

A combustion housing defining a combustion chamber;

A fuel supply device for supplying fuel to the combustion chamber side of the combustion housing; And

A heating device capable of preheating fuel in the fuel supply device; And

An air supply device for supplying air to the combustion chamber side of the combustion housing; And

An ignition device for igniting the fuel supplied to the fuel supply and the air supplied to the air supply device; And

And a guide mechanism for guiding air supplied from the air supply device,

The combustion housing includes a first housing defining a lower space of the combustion chamber and a second housing defining an upper space of the combustion chamber,

Wherein a housing member for distributing fuel supplied from the fuel supply device is provided in a lower portion of the first housing,

And a rectifying grid having a through hole formed in the upper end of the receiving member,

The housing member may be composed of a supply port connected to the fuel supply pipe of the fuel supply device and a plurality of receiving grooves uniformly spaced around the supply port.

The ignition device may be ignited in the form of an ignition flame without directly using the pilot burner of the ignition device and the heating device of the fuel supply pipe when the gas is used as the fuel in the fuel supply device and the fuel may be directly supplied to the supply port have.

A pilot burner for igniting fuel and air mixed in the combustion chamber may be provided on one side wall of the first housing and an ignition device for directly heating and igniting the rectification lattice of the flame of the burner.

The ignition device is installed on one side wall of the first housing so as to face the center of the rectifying lattice in the combustion chamber. The ignition device directs the flame toward the center of the rectifying lattice to directly heat and ignite the rectifying lattice Lt; / RTI >

And the coupling between the rectifying grid and the receiving member may be coupled with a protrusion formed on the rectifying grid.

The rectifying grid may be made of stainless steel or the like having high thermal conductivity.

The receiving recesses may be conically shaped such that the diameter of the upper end is a cone shape larger than the diameter of the lower end.

The receiving grooves may be semicircular or polygonal.

The gas or liquid fuel supplied from the supply port of the fuel supply device may be configured to flow into the plurality of receiving grooves and spread on the bottom surface of the receiving member.

The gas or liquid fuel supplied from the feeder of the fuel supply device may be configured such that the fuel flows to the receiving groove through the constant distance d between the rectifying grid and the receiving member.

The gas or liquid fuel supplied from the supply port of the fuel supply device may be configured to spread while flowing fuel to the receiving groove at the same time through the constant distance d between the bottom of the receiving member and the rectifying grid and the receiving member.

The fuel supply pipe of the fuel supply device may be connected to the bottom surface of the housing member and the fuel supply pipe may be constituted by an expansion pipe whose portion connected to the bottom surface of the housing member is larger than the diameter of the fuel supply pipe.

And the fuel supply pipe of the fuel supply device and the bottom surface of the housing member are integrated with each other.

A heater is provided on the bottom surface of the housing member, a flame is generated in the combustion chamber, and the heater is stopped after the vaporization of the fuel is stabilized.

And the vertical axis of the through hole in the rectifier grid and the vertical axis of each receiving groove of the receiving member coincide with each other.

And one or more heating devices may be provided on the outer surface of the fuel supply device between the fuel tank, the fuel control valve, and the supply port.

Instead of the heating device, hot water or steam of the heat exchanger or the steam generator may be added to the heat exchanger to heat the fuel supply pipe.

Instead of the heating device, a part of the exhaust gas may be added to the heat exchanger to heat the fuel supply pipe.

A fuel supply pipe connected to the combustion housing from the fuel tank; and a fuel supply pipe connected to the fuel supply pipe to supply fuel and supply the fuel, wherein the fuel supply device includes a fuel tank in which fuel is stored, a fuel supply pump for supplying fuel in the fuel tank to the combustion chamber, And a fuel control valve for regulating the speed of the fuel.

Wherein the first housing is formed in a cone shape in which the diameter of the upper end is larger than the diameter of the lower end and the second housing is formed in a cone shape in which the diameter of the lower end is larger than the diameter of the upper end .

Wherein the air supply device includes an air blower for blowing air, an air supply pipe connected to the blower, and a water atomizer for spraying water into the air supply pipe,

And a mixed gas in which air and water vapor are mixed is generated as water is sprayed to the air by the water atomizer.

The air supply device may be configured to add hot water or steam of the heat exchanger or the steam generator without spraying water to the air supply pipe and directly supply the hot water or steam to the opening.

The air supply device may be configured to add a part of the exhaust gas to the air supply pipe without spraying water and directly supply the exhaust gas to the opening.

The air supply device may be configured to add water injection and additional exhaust gas, or a part of steam or hot water, to the air supply pipe and directly supply the water to the opening or air supply at the same time.

The water sprayer includes a water supply pump, a water supply pipe connected to the inside of the air supply pipe from the water supply pump, a spray nozzle provided at an end of the water supply pipe, and a water control valve installed in the middle of the water supply pipe to adjust a supply flow rate of water ≪ / RTI >

The guide mechanism may include an outer guide pipe and an inner guide pipe disposed inside the outer guide pipe, and the air supply pipe may be connected to one side of the outer guide pipe.

The outer guide pipe may be configured to swirl the mixed gas supplied through the air supply pipe by a centrifugal force and to ascend.

The upper end of the inner guide tube in the guide mechanism may extend in the direction of the combustion chamber between the outer guide pipes in a predetermined length and may have an opening communicating with the inner guide pipe and the outer guide pipe.

In the guide mechanism, the inner guide tube may be configured so that the mixed gas passing through the outer guide tube is spirally turned by the centrifugal force and lowered.

In the guide mechanism, the outer guide pipe may be bent in an elbow shape, and the inner guide pipe may be bent in correspondence with the outer guide pipe.

In the guide mechanism, the second housing may be connected to the lower end of the inner guide tube by the same body, and a combustion flame discharge pipe may be mounted on the upper end of the inner guide tube to discharge the combustion flame.

And may be connected to a closure plate at the end of the guide mechanism by a heat exchanger or a steam generator.

In order to stop the non-nozzle burner, the mixer is supplied to the air supply device for a certain period of time while the fuel supply of the fuel supply device is stopped, so that a certain purge time is set so as to burn the fuel remaining in the receiving groove of the accommodation member . ≪ / RTI >

The non-nozzle burner according to the present invention having the above-described features can solve problems such as clogging of nozzles, environmental problems due to incomplete combustion, deterioration of efficiency, and the like, It has the advantage of being able to utilize the fuel in a compatible manner.

In addition, the present invention can utilize fuel having high viscosity such as waste oil or oil by distributing and storing the fuel by the receiving grooves of the housing member, thereby improving the economy, environment-friendly characteristics, energy utilization, and the like There are advantages.

Further, the present invention adopts a structure for distributing the fuel to the housing member and the rectification lattice in place of the fuel nozzle, and has the advantage that all kinds of fluid fuels such as gas, oil, diesel, kerosene, and waste oil can be used interchangeably.

In the present invention, fine droplets of air and water (the liquid is converted into water vapor while passing through the guide mechanism by the heat of combustion in the combustion chamber, so that the term 'water vapor' is used hereinafter) by spraying water into the air supplied to the combustion chamber. It is possible to effectively realize complete combustion through pyrolysis in the combustion chamber, thereby minimizing secondary environmental pollution due to incomplete combustion.

According to the present invention, air and water vapor can be generated as a mixed gas by spraying water to the air side through the air supply pipe, and since such a mixed gas can lower the flame temperature at the time of combustion, NOx) and the like, and oxygen and hydrogen can be produced through thermal decomposition of steam, thereby promoting the chemical reaction of the fuel and the mixed gas to thereby achieve more complete combustion, In addition, it has an effect of reducing atmospheric pollutants (CO, HC, etc.) or NOx by injecting steam, hot water or a part of exhaust gas directly into the opening.

According to the present invention, the outer guide tube, the inner guide tube and the mixed gas moving along the second housing can be preheated from the whirling type swirl flame generated by ignition in the combustion chamber so that the preheated mixed gas The combustion efficiency can be significantly improved.

1 is a cross-sectional view illustrating a nozzleless burner according to an embodiment of the present invention.
2 is an enlarged view of a first housing portion of a nozzleless burner according to an embodiment of the present invention.
3 is a front sectional view showing a housing member of the non-nozzle burner according to the embodiment of the present invention.
4 is a plan view showing a housing member of the nozzleless burner according to the embodiment of the present invention.
5 is a front sectional view showing a rectifying grid of a non-nozzle burner according to an embodiment of the present invention.
6 is a plan view showing a rectifying grid of a nozzleless burner according to an embodiment of the present invention.
7 is an enlarged view of a fuel supply device for a non-nozzle burner according to an embodiment of the present invention.
8 is an enlarged view of an air supply device for a nozzleless burner according to an embodiment of the present invention.
9 is a cross-sectional view taken along the line KK in Fig.

The term used in the present invention is a general term that is widely used at present. However, in some cases, there is a term selected arbitrarily by the applicant. In this case, the term used in the present invention It is necessary to understand the meaning.

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

Here, it should be noted that the expressions related to the directions of up and down, left and right, right, left, and bottom are all described based on the drawings.

1, a nozzleless burner according to an embodiment of the present invention includes a combustion housing 10 defining a combustion chamber 11, a fuel supply device 10 for supplying fuel to the combustion chamber 11 side of the combustion housing 10, An air supply device 30 for supplying air to the combustion chamber 11 side of the combustion housing 10 and a guide mechanism 40 for guiding air supplied from the air supply device 30 have.

The combustion housing 10 may include a first housing 51 defining a lower space of the combustion chamber 11 and a second housing 52 defining an upper space of the combustion chamber 11. [

The first housing 51 may be formed in a cone shape larger in diameter than the diameter of the lower end of the upper end and the second housing 52 may be formed in a cone shape in which the diameter of the lower end is larger than the diameter of the upper end. ). Since the first housing 51 and the second housing 52 are formed in a vertically symmetrical cone shape, the combustion cross-sectional area of the combustion chamber 11 can be increased, and the amount of fuel and air supplied thereto can be increased .

A housing member 12 for distributing and supplying the fuel supplied from the fuel supply unit 20 may be provided in the lower portion of the first housing 51. The inner guide pipe 42 of the guide mechanism 40 for guiding air supplied from the air supply device 30 may be connected to the upper portion of the second housing 52.

The receiving member 12 may have a plurality of receiving grooves 14 disposed around the feeding port 13 and the feeding port 13, as shown in Figs. 2, 3 and 4.

The fuel supply pipe 23 of the fuel supply device 20 can be connected or integrally connected to the supply port 13 and the plurality of receiving grooves 14 can be connected to the supply port 13 around the supply port 13 And can be uniformly spaced at regular intervals along the circumferential and radial directions.

2 and 3, each of the receiving grooves 14 may be formed in a cone shape having a cone shape whose width at the top is larger than width at the lower end, The liquid fuel or gaseous fuel supplied from the supply port 20 to the supply port 13 can flow into the plurality of receiving grooves 14 on the bottom surface of the receiving member 12, The liquid fuel or the gaseous fuel can be smoothly distributed and accommodated.

The heater 48 can be constituted so that the vaporization or evaporation of the liquid fuel can be promoted and the vaporization can be stably performed on the bottom surface of the housing member and the flame is generated in the combustion chamber so that the vaporization of the fuel is stabilized, . ≪ / RTI >

According to another example, each receiving groove 14 may be formed in various shapes such as semicircular or polygonal shapes.

A distributor may be disposed on the upper portion of the housing member 12 and the rectifier grid 15 may have a plurality of through holes 16. [ The plurality of through-holes 16 may be uniformly spaced at regular intervals along the circumferential and radial directions of the rectifying grid 15, as shown in Figs. 5 and 6.

According to the embodiment of the present invention, as shown in Fig. 2, each of the through holes 16 of the rectification grating 15 can be positioned to correspond to each of the receiving grooves 14 of the receiving member 13. According to an example, the vertical axis of each of the through holes 16 and the vertical axis of each of the receiving grooves 14 may coincide with each other.

2, the bottom surface of the rectifying grid 15 and the upper surface of the receiving member 12 may be spaced apart from each other by a predetermined distance d, The gas or liquid fuel can smoothly flow to the receiving groove 14 side. A protrusion 15a protruding downward can be formed at the bottom edge of the rectifier grid 15 and a protrusion 15a of the rectifier grid 15 can be attached to the top edge of the housing member 12 So that the rectification grating 15 and the housing member 12 can be stably stacked in the vertical direction.

An ignition device 17 may be provided on one side wall of the first housing 51 and the ignition device 17 may be configured to ignite the mixed fuel and air in the combustion chamber 11, 23 and the ignition flame H of the pilot burner is heated for a predetermined time in the horizontal direction by heating the rectification grid 15 to evaporate the fuel and air is supplied to the air supply device 30, The pilot burner can be stopped when the temperature of the combustion chamber is raised and the pilot burner can be inclined to collide the flame of the pilot burner with the center of the rectification lattice to shorten the evaporation time of the fuel, 11) may ignite the mixed fuel and air. The ignition device 17 may be disposed adjacent to the housing member 12, as shown in Figs. The evaporation of the liquid fuel contained in the receiving grooves 14 of the receiving member 12 by the ignition flame H of the ignition device 17 can be accelerated by the rectifying lattice 15. [ In summary, since the evaporation of the liquid fuel can be accelerated by the ignition device 17, the housing member 12 and the rectification grid 15, the mixing and combustion reaction of the liquid fuel and the air can be accelerated, Can be greatly improved.

According to another embodiment, the ignition device 17 may be configured to generate an ignition spark, such as an ignition plug, when the fuel supply device 20 supplies gaseous fuel. So that the air and gaseous fuel mixed in the combustion chamber 11 can be ignited by the ignition flame of the spark plug.

A flange 19 may be formed on the upper edge of the first housing 51 and a flange 49 may be formed on the lower edge of the second housing 52. The flange 49 of the first housing 51 And the flange 49 of the second housing 52 can be coupled through a fastener or welding.

7, the fuel supply device 20 includes a fuel tank 21 that stores fuel, a fuel supply pump 22 that supplies fuel in the fuel tank 21 to the combustion chamber 11, A fuel supply pipe 23 connected to the housing member 12 of the combustion housing 10 from the fuel supply pipe 21 and a fuel control valve 24 mounted on the fuel supply pipe 23 for regulating the supply flow rate, .

The fuel tank 21 may be configured to have pressure resistance and hermeticity such as a pressure vessel or the like to store liquid fuel or gaseous fuel.

The fuel supply pump 22 such as a hydraulic jockey may be configured to supply the fuel in the fuel tank 21 to the housing member 12 side of the first housing 51 (see arrow G direction in Fig. 1). According to one example, the oil feed pump 22 can be configured to smoothly supply liquid fuel such as highly viscous oil, waste oil and the like.

One end of the fuel supply pipe 23 may be connected to the fuel tank 21 and the other end of the fuel supply pipe 23 may be connected to the first housing 51 of the combustion housing 10 or integrally connected thereto. In particular, the other end of the fuel supply pipe 23 is hermetically connected to the supply port 13 of the housing member 12.

On the outer surface of the fuel supply pipe 23, one or more heating devices 25 for heating fuel passing through the fuel supply pipe 23 may be provided. The heating device 25 can preheat the fuel passing through the fuel supply pipe 23 in order to reduce the viscosity of the liquid fuel by heating at the outer surface of the fuel supply pipe 23 or to freeze the water contained in the waste oil. When the fuel preheated by this heating device 25 is mixed with air, the combustion reaction can be accelerated.

According to one embodiment, the heating device 25 may be composed of an electric heater that generates heat by electric energy.

According to another embodiment, the heating device 25 may be configured to recover the waste heat of the exhaust gas discharged from the combustion flame discharge pipe 18. For example, a part of the exhaust pipe for discharging the high-temperature exhaust gas from one side of the discharge pipe 18 of the combustion flame is connected to the heating device 25 side by constituting the spindle 47, And can also be utilized as the heating device 25 by adding a portion 47 of hot water or steam of a heat exchanger or steam generator 45. [

A plurality of heating devices 25 are provided between the fuel tank 21 and the fuel supply pump 22, between the fuel supply pump 22 and the fuel control valve 24, between the fuel control valve 24 And may be separately installed between the first housings 51. [ Accordingly, when the fuel is a highly viscous liquid fuel such as waste oil, the plurality of heating devices 25 can appropriately adjust the viscosity of the liquid fuel by appropriately heating the liquid fuel, thereby facilitating the supply of the liquid fuel have.

The fuel control valve 24 may be configured to adjust the supply amount and the supply speed of the fuel so as to match the combustion speed in the combustion chamber 11. [

8, the air supply device 30 includes a blower 31 for blowing air, an air supply pipe 32 connected to the blower 31, and an air supply pipe 32 for spraying water into the air supply pipe 32 And may include a water atomizer 35. The air supplied by the blower 31 can be supplied through the air supply pipe 32 (see the direction of arrow A in Fig. 1).

The water spraying device 35 includes a water supply pump 36, a water supply pipe 37 connected from the water supply pump 36 to the inside of the air supply pipe 32, a spray nozzle 38 provided at an end of the water supply pipe 37, And a water control valve 39 installed in the middle of the water supply pipe 37 to adjust the supply flow rate or supply speed of the water.

The water spraying device 35 can generate a mixed gas in which air and water vapor are mixed by spraying water toward the air (refer to arrow A in Fig. 1) side that passes through the air supply pipe 32, The flame temperature at the time of combustion can be lowered, so that the generation of nitrogen oxides (NOx) and the like can be suppressed.

In addition, water vapor added in the heat exchanger or the steam generator 47 may be directly injected into the opening 44 and sprayed into the air guide mechanism 40 to mix air and water vapor to produce a mixed gas.

In addition, as water is sprayed toward the air side by the water spraying device 35, oxygen and hydrogen can be generated through mixed thermal decomposition of water vapor and air, and the complete combustion of fuel and air can be performed more effectively.

The guide mechanism 40 may be configured to guide the air supplied from the air supply device 30 to the combustion housing 10 side.

The guide mechanism 40 may include an outer guide pipe 41 and an inner guide pipe 42 disposed inside the outer guide pipe 41.

An air supply pipe 32 can be connected to one side of the outer guide pipe 41 and a mixed gas (air and water vapor) supplied through the air supply pipe 32 can be moved through the outer guide pipe 41.

1 and 9, the outer guide pipe 41 is moved upward (in the direction of arrow B in FIGS. 1 and 9) in the direction of the arrows B and C while spirally rotating the mixed gas (air and water vapor) supplied through the air supply pipe 32 by a centrifugal force, (See FIG.

The outer guide pipe 41 may have a structure bent in an elbow shape as shown in FIG. The upper end of the outer guide pipe 41 can be closed by the engagement of the closing plate 43. [ The flange 49 of the outer guide pipe 41 may be formed at the lower end of the outer guide pipe 41 and the flange 49 of the outer guide pipe 41 may be fastened to the flange 39 of the second housing 52 The lower end of the outer guide tube 41 can be closed.

As shown in Figs. 1 and 9, the inner guide tube 42 rotates the mixed gas moved on the outer guide tube 41 in a spiral manner by the centrifugal force so as to descend (see the arrow C direction in Figs. 1 and 9) Lt; / RTI >

An opening 44 communicating with the outer guide pipe 41 may be formed at an upper end of the inner guide pipe 42. The mixture gas (air and water vapor) rising along the spiral flow between the inner surface of the outer guide tube 41 and the outer surface of the inner guide tube 42 passes through the opening 44 of the inner guide tube 42, (Refer to the direction of arrow C in Figs. 1 and 9) while spirally turning by the centrifugal force along the inner surface of the pipe 42. Fig.

1, the inner guide tube 42 may have a bending structure corresponding to the outer guide tube 41. The second housing 52 can be connected to the lower end of the inner guide tube 42 by the same body so that the mixed gas (air and water vapor) supplied along the inner guide tube 42 is supplied to the inner surface of the second housing 52 And can move along the inner surface of the first housing 51 (see arrow D direction in Fig. 1). Meanwhile, a cone portion 45 may be formed on the lower end of the outer guide tube 41 in correspondence with the second housing 52.

A discharge pipe 18 for discharging a combustion flame may be disposed at the upper end of the inner guide pipe 42 and a discharge pipe 18 for discharging the combustion flame may be installed through the closing plate 43.

A heat exchanger or a steam generator 45 capable of producing hot water or steam to utilize the burned heat of the closing plate 43 can be constructed.

The high temperature hot water or steam added from the heat exchanger or the steam generator can be injected into the heating device 25 mounted on the fuel supply pipe 23 to preheat the highly viscous fuel and the exhaust gas from the exhaust pipe 46 The fuel can be preheated by injecting the fuel into the opening 14 or the heat exchanger (heating device) 25 in a partly additive manner, or the flame temperature of the combustion chamber 11 can be lowered to reduce NOx.

The fuel supply of the fuel supply device is stopped when the non-nozzle burner is stopped, and the air supply device supplies the mixer to the air supply device for a predetermined period of time So as to have a certain purge time so as to remain in the receiving groove of the housing member and burn the fuel.

The operation of the nozzleless burner of the present invention constructed as described above will be described in detail as follows.

First, air can be moved from the blower 31 of the air supply device 30 along the air supply pipe 32 (see the direction of arrow A in Fig. 1), and when the air moves along the air supply pipe 32, A mixed gas in which air and water vapor are mixed can be generated as water is sprayed from the spray nozzle 38 of the spray nozzle 35.

(See arrows B and B in Figs. 1 and 9) while rotating in a spiral manner by centrifugal force along the outer guide tube 41, and then mixed with the centrifugal force along the inner guide tube 42 (See arrows C and C in Figs. 1 and 9). The mixed gas moves in the combustion chamber 11 due to the centrifugal force by the centrifugal force so that the mixed gas moves along the inner surface of the second housing 52 and the inner surface of the first housing 32 It can be turned.

When the fuel is supplied from the fuel tank 21 of the fuel supply device 20 to the housing member 12 side of the first housing 51 (see the direction of arrow G in Fig. 1) The fuel can be uniformly distributed and accommodated in the fuel cells 14. At this time, the fuel moving through the fuel supply pipe 23 is preheated by the heating device 25, so that the combustion reaction of the fuel preheated in the combustion chamber 11 can be made more efficiently.

The fuel contained in the receiving grooves 14 of the receiving member 12 by the operation of the ignition device 17 can be accelerated by the rectifying grating 14 so that the fuel is mixed with the air of the mixed gas And then ignited at a specific ignition temperature of the fuel to generate a flame. At this time, the flame may be in the form of a diffusion flame.

On the other hand, the combustion reaction can be continuously performed by the flame generated in the combustion chamber 11, and the generated flame in the combustion chamber 11 can be generated in a whirling type flame (E in FIG. 1) have.

Such a whirlwind flame E can be spirally raised through the center portion of the inner guide tube 42 and then discharged from the combustion flame outlet 18.

When the whirlwind type flame E is generated in this way, radiation and convection from the whirlwind flame E can be transmitted to the housing member 12 and the rectification lattice 15 side, Conduction is transferred between the combustion chamber 15 and the housing member 12, so that the temperature atmosphere of the combustion chamber 11 can be quickly and stably raised to a temperature suitable for combustion.

The mixed gas (see the arrow B direction in FIG. 1) moving along the outer guide pipe 41 as the whirlwind flame E passes through the center portion of the inner guide pipe 42 flows from the inner guide pipe 42 The mixed gas (refer to the direction of the arrow C in Fig. 1) that moves along the inner guide tube 42 can be preheated by the whirlwind type flame E in a second step. The mixed gas (see the direction of arrow D in Fig. 1) moving along the inner surface of the second housing 52 can be tertiary preheated (up to a temperature of approximately 600 to 700 캜). That is, the mixed gas (air and water vapor) passing through the outer guide pipe 41 and the inner guide pipe 42 can be gradually preheated by the whirlpool flame E generated in the combustion chamber 11.

As described above, the present invention can be applied to the mixing chamber (11) which is moved from the whirlwind flame (E) generated by ignition in the combustion chamber (11) along the outer guide pipe (41), the inner guide pipe (42), and the second housing (See arrows B, C and D in Fig. 1) can be preheated stepwise, and the steam of the mixed gas is pyrolyzed by the high temperature fuel and vaporized, so that the combustion efficiency can be greatly improved.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the present invention. Various modifications and variations will be possible without departing from the spirit of the invention. Therefore, the scope of the present invention should be construed as being covered by the scope of the appended claims, and technical scope within the scope of equivalents thereof should be construed as being included in the scope of the present invention.

10: combustion housing 11: combustion chamber
12: housing member 15: alignment grid
17: ignition device 20: fuel supply device
21: Fuel tank 22: Lubrication pump
23: fuel supply pipe 24: fuel control valve
25: heating device or heat exchanger 30: air supply device
31: blower 32: air supply pipe
35: Water atomizer 36: Feed pump
37: water pipe 38: spray nozzle
39: water control valve 40: guide mechanism
41: outer guide tube 42: inner guide tube

Claims (33)

A combustion housing defining a combustion chamber;
A fuel supply device for supplying fuel to the combustion chamber side of the combustion housing; And
A heating device capable of preheating fuel in the fuel supply device; And
An air supply device for supplying air to the combustion chamber side of the combustion housing; And
An ignition device for igniting the fuel supplied to the fuel supply device and the air supplied to the air supply device; And
And a guide mechanism for guiding air supplied from the air supply device,
The combustion housing includes a first housing defining a lower space of the combustion chamber and a second housing defining an upper space of the combustion chamber,
A pilot burner for igniting fuel and air mixed in the combustion chamber is installed on one side wall of the first housing, and an ignition device for heating and igniting the rectification grill directly by the flame of the burner; Or an ignition device is installed on one side wall of the first housing so as to face the center of the rectification grid in the combustion chamber and the ignition device directs the flame toward the center of the rectification lattice to directly heat and ignite the rectification lattice, ; And
Wherein a housing member for distributing fuel supplied from the fuel supply device is provided in a lower portion of the first housing,
And a rectifying grid having a through hole formed in the upper end of the receiving member,
Wherein the housing member has a supply port to which the fuel supply pipe of the fuel supply device is connected and a plurality of receiving grooves uniformly spaced around the supply port.
The method according to claim 1,
Wherein when the gas is used as fuel in the fuel supply device, the ignition device is ignited in the form of an ignition flame without using the pilot burner and the heating device for the fuel supply pipe of the ignition device, and the fuel is directly supplied directly to the supply port No nozzle burner.
delete delete The method according to claim 1,
And the coupling of the rectifying grid and the receiving member is engaged with a protrusion formed on the rectifying grid.
The method according to claim 1,
Wherein the rectifying lattice is made of a material such as stainless steel having high thermal conductivity.
The method according to claim 1,
Wherein the receiving groove is formed in a conical shape having a cone shape in which the diameter of each upper end is larger than the diameter of the lower end.
The method according to claim 1,
Wherein the receiving groove has a semicircular or polygonal shape.
The method according to claim 1,
Wherein the gas or liquid fuel supplied from the supply port of the fuel supply device flows into the plurality of receiving grooves and spreads on the bottom surface of the housing member.
The method according to claim 1,
Wherein the gas or liquid fuel supplied from the feed gun of the fuel supply apparatus flows while flowing fuel into the receiving groove through a constant distance d between the rectifying grid and the housing member.
The method according to claim 1,
Characterized in that the gas or liquid fuel supplied from the supply port of the fuel supply apparatus flows while the fuel flows into the receiving groove at the same time through the constant distance (d) between the bottom surface of the receiving member and the rectifying grid and the receiving member burner.
The method according to claim 1,
Wherein the fuel supply pipe of the fuel supply device is connected to the bottom surface of the housing member and the fuel supply pipe is formed by an enlargement tube whose portion connected to the bottom surface of the housing member is larger than the diameter of the fuel supply pipe.
The method of claim 12,
And the fuel supply pipe of the fuel supply device and the bottom surface of the housing member are integrated with each other.
The method according to claim 1,
Wherein a heater is provided on a bottom surface of the housing member, a flame is generated in the combustion chamber, and after the vaporization of the fuel is stabilized, the heater is stopped.
The method according to claim 1,
Wherein the vertical axis of the through hole and the vertical axis of each of the receiving grooves of the receiving member are coincident with each other in the rectifying lattice.
The method according to claim 1,
Wherein at least one heating device is provided on an outer surface of the fuel supply device between a fuel tank, a fuel control valve, and a supply port.
17. The non-nozzle burner according to claim 16, wherein the heat exchanger is used to heat hot water or steam of the heat exchanger or the steam generator to heat the fuel supply pipe.
17. The non-nozzle burner according to claim 16, wherein a part of the exhaust gas is added to the heat exchanger in place of the heating device to heat the fuel supply pipe.
The method according to claim 1,
A fuel supply pipe connected to the combustion housing from the fuel tank; and a fuel supply pipe connected to the fuel supply pipe to supply fuel and supply the fuel, wherein the fuel supply device includes a fuel tank in which fuel is stored, a fuel supply pump for supplying fuel in the fuel tank to the combustion chamber, And a fuel control valve for regulating the speed of the fuel.
The method according to claim 1,
The first housing is formed in a cone shape in which the diameter of the upper end is larger than the diameter of the lower end and the second housing is formed in a cone shape in which the diameter of the lower end is larger than the diameter of the upper end No nozzle burner.
The method according to claim 1,
Wherein the air supply device includes an air blower for blowing air, an air supply pipe connected to the blower, and a water atomizer for spraying water into the air supply pipe,
And a mixed gas in which air and water vapor are mixed is generated as water is sprayed to the air by the water atomizer.
23. The method of claim 21,
Wherein the air supply device supplies the hot water or steam of the heat exchanger or the steam generator directly to the opening without adding water to the air supply pipe.
23. The method of claim 21,
Wherein the air supply device adds a part of the exhaust gas to the air supply pipe without spraying water and directly supplies the exhaust gas to the opening.
The method according to claim 1,
Wherein the air supply device is adapted to supply water to the air supply pipe and to supply a portion of the exhaust gas or the steam or the hot water directly to the opening or the air supply at the same time.
23. The method of claim 21,
The water sprayer includes a water supply pump, a water supply pipe connected to the inside of the air supply pipe from the water supply pump, a spray nozzle provided at an end of the water supply pipe, and a water control valve installed in the middle of the water supply pipe to adjust a supply flow rate of water Wherein the burner is a nozzle.
The non-nozzle burner according to claim 1, wherein the guide mechanism includes an outer guide pipe and an inner guide pipe disposed inside the outer guide pipe, and an air supply pipe is connected to one side of the outer guide pipe.
27. The method of claim 26,
Wherein the outer guide tube is configured to swirl and raise the mixed gas supplied through the air supply tube by a centrifugal force.
27. The method of claim 26,
Wherein an upper end of the inner guide tube extends in a direction of the combustion chamber between the outer guide pipes in the guide mechanism and an opening communicating with the inner guide pipe and the outer guide pipe is formed.
27. The method of claim 26,
Wherein the inner guide tube in the guide mechanism is configured to descend the mixed gas passing through the outer guide tube while spirally turning the mixed gas by centrifugal force.
27. The method of claim 26,
Wherein the outer guide pipe in the guide mechanism is bent in an elbow shape and the inner guide pipe is bent in correspondence with the outer guide pipe.
27. The method of claim 26,
Wherein the inner guide tube is connected to the lower end of the inner guide tube in the same manner as the second housing, and a combustion flame discharge tube for discharging a combustion flame is mounted on the upper end of the inner guide tube.
The method according to claim 1,
And connected to a closure plate at an end of the guide mechanism by a heat exchanger or a steam generator.
2. The fuel supply system according to claim 1, wherein when the non-nozzle burner is to be stopped, the mixer is supplied to the air supply device for a certain period of time while the fuel supply of the fuel supply device is stopped, Wherein the nozzle has a constant purge time.

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