KR20170085751A - an eletric heating element for nozzled spray droplet and the liquid fuel spraying and mixing device uisng both multistage-perforated heating plate and an eletric heating element - Google Patents

Abstract

In the present invention, a liquid droplet in a spray state generated from a conventional pressure nozzle is passed through a heating device to cause a phase change to a superfine droplet or a gaseous phase. In this process, premixing of air and fuel is achieved and a high- The present invention relates to an electric resistance heating element of a nozzle spray droplet for generating a flame of blue flame capable of discharging, and a liquid fuel atomizing apparatus by heating the multi-stage perforated plate using the same.
The present invention provides a liquid fuel mixing apparatus comprising a casing unit (100), an electric resistance heating element (10), an air injection hole (20), a nozzle (30), and a perforated plate (40).
The present invention also provides a liquid fuel mixing apparatus, wherein the perforated plate unit 40 is a multi-perforated plate unit composed of a plurality of perforated plate units.
The present invention is characterized in that the casing unit 100 has a cylindrical shape including a front portion 101 as a fuel injection portion and a rear portion 102 connected to a flame radiation portion 110 through which a flame is radiated Fuel mixture mixing device.

Description

[0001] The present invention relates to an electric resistance heating element of a nozzle spray droplet and a liquid fuel atomizing apparatus using the same, element}

The present invention aims at making a phase change very efficiently in a gaseous state or a superfine droplet by passing a droplet in a spray state generated in a conventional pressure nozzle through a heating device. The heating apparatus of the present invention is different from the heating method before passing through the existing pressure nozzle. In this process, a complete premixing of air and fuel is achieved to create a flame of blue flame capable of high efficiency low NOx emission such as meteorological fuel. Electric resistance heating element of spraying droplet and liquid fuel mixing by heating multi- ≪ / RTI >

Generally, burners and nozzles of liquid fuel using light oil or heavy oil have high viscosity of fuel. Therefore, for efficient atomization, the fluidity of the fuel is firstly increased by heating to a certain temperature, and then high pressure is applied to the nozzle, . The fine droplets formed in this way are usually burned through a turbulent mixing process using a large excess of air. In this case, the heavy oil is sprayed at a pressure of Bar (20 ~ 25) in the state of cSt viscosity (10 ~ 14) at the temperature range of (60 ~ 100) ℃ to make fine liquid droplets. ~ 12) cSt. There is less need for preheating than heavy oil.

Despite the fact that in the past 100 years, both boilers using liquid fuels both domestically and externally have been carrying out comprehensive studies on improving efficiency and reducing pollutant emissions, they have not achieved both the goals of improving efficiency and reducing emissions of pollutants This is probably due to the fact that proper countermeasures for the complex phenomenon of two-phase turbulent reaction occurring in the boiler have not been adequately addressed. Specifically, although the liquid fuel is atomized into small particles by the pressure nozzle, oxidation with a large amount of surplus air is required because efficient contact with the oxidizing agent air is not achieved due to small specific surface area. In this process, the local high temperature or fuel surplus caused by the inhomogeneous mixing state results in the reduction of the overall efficiency as well as the generation of pollutants.

One of the most visible examples of this is not the combustion problem of the boiler, but it appears in the diesel engine. In the combustion of the boiler, the unbalanced mixture of fuel and air in the diesel engine is mitigated to some degree. Therefore, it is considered that the example of the diesel engine showing the unbalance phenomenon is more clearly understood. As with the boiler combustion of liquid fuel, the problem of mixing imbalance between diesel fuel and air in diesel engine is incomplete combustion phenomenon and large amount of NOx emission phenomenon. That is, the diesel engine compresses the air as much as possible and then injects diesel fuel into the compressed air to automatically ignite the air. In this case, the diesel fuel is diffused into the compressed air in a short time, so that it is divided into the fuel excess region and the air excess region locally. In the fuel surplus region, incomplete combustion occurs, but in the excess air region, there is a large amount of air with a high temperature, so that the possibility of thermal NOx is increased. As a result, the diesel engine has a higher compression ratio, so the fuel consumption is higher than that of the gasoline engine, but the amount of NOx, which is a nitrogen oxide, increases along with incomplete combustion materials which are pollutants. The mixing imbalance between the droplet and the air is likely to be the same even though the boiler using the heavy oil or the heavy oil droplet is used as the fuel.

In general, since the time required for the droplet combustion is reduced according to the square of the diameter, atomization of droplets must be solved in order to improve efficiency and reduce pollutants such as unburned carbon and carbon monoxide (CO) It is an essential technology.

In order for a liquid fuel such as light oil or heavy oil to mix with air and burn effectively, it is necessary to go through a three-step process that occurs in a two-phase turbulent reaction process. The first is the process of droplet atomization and vaporization according to the dispersion of the fuel and the second is the process in which the vaporized fuel is mixed with the oxidizing agent such as air by turbulent mixing. Third, it can be said that the mixed fuel depends on the chemical kinetic rate of reacting with oxygen in the air. In this series of processes, the overall reaction rate is given by the phenomenological empirical formula of the harmonic mean form of each process.

In the above equation, RR1, RR2, and RR3 denote the progress speed of the three detailed processes, respectively. RR1 is the rate at which the fuel atomization and vaporization process occurs, RR2 is the mixing rate due to the turbulence of the fuel and air, RR3 represents the rate at which the fuel and air chemically react in a well-premixed state. Generally, the chemical reaction rate (RR3) in the turbulent combustion of liquid fuel is much faster than the atomization and vaporization rate (RR1) or the turbulent mixing rate (RR2). Therefore, since the process of RR3 in the whole reaction is fast (RR3 ~ ∞), the term 1 / RR3 in Equation (1) given as the reciprocal of RR3 is generally ignored. In this case, the progress speed of the total combustion is expressed as follows.

(2)

(2)

In particular, the first step, the atomization and vaporization process (RR1) of the fuel, is a time-consuming process for fuels such as diesel or heavy oil with low volatility or high viscosity compared to gasoline. Therefore, this process is a rate-limiting reaction step that plays a decisive role in lowering the overall reaction rate. Therefore, the technique described in this patent focuses on shortening this process, namely the time (RR1) required for atomization and vaporization and the mixing time (RR2) for air and fuel.

In fact, for a typical oil burner, atomizing 1 gallon of oil at a pressure of 100 psi (industry standard operating pressure) collapses into 55 billion small particles with a particle size of 0.002 to 0.010 inches (0.05 mm to 0.25 mm) The surface area of the droplet is increased to 690,000 square inches (445m2). ("A total look at oil burner nozzles", www.delavaninc.com/pdf/total_look.pdf )

However, even if the liquid fuel collapses into fine droplets with a diameter of 0.002 to 0.010 inch due to high pressure, combustion delay due to vaporization and turbulent mixing of liquid droplets still occurs compared to the combustion rate of the gaseous fuel. Therefore, in order to improve the efficiency, it is absolutely required to make a phase change to a smaller liquid droplet or a vapor phase. As a contradiction to this, it can be said that the study on the burner is continuously carried out to improve the thermal efficiency of the oil boiler.

[Prior Art]

1. Registration Utility Model Bulletin (20-0420829): Fuel atomizer

2. Open Patent Publication (10-2010-0113316): Combustion device using liquid fuel atomizer nozzle

3. Patent US 2010/0248173 combustion apparatus

4. Patent US 4,280,806 (July 28, 1981) -Prevaporizing oil burner and method.

5. Patent No. 2,964,101

6. Patent No. 1,968,360

7. Patent No. 2,069,960

8. Patent No. 1.049,382

SUMMARY OF THE INVENTION It is an object of the present invention to reheat an atomized liquid droplet generated in a conventional heavy oil or heavy oil pressure nozzle to a combustion furnace so as to effectively produce a fuel in a super-atomized state or a vapor- And to provide an electric resistance heating element of a nozzle spray droplet which achieves high efficiency / low pollution combustion with minimum surplus air by premixing air and fuel at the same time, and a liquid fuel atomizing apparatus by heating the multi-stage perforated plate using the same .

In order to achieve the above object,

There is provided a liquid fuel mixing apparatus comprising a casing unit 100, an electric resistance heating body 10, an air injection hole 20, a nozzle 30, and a perforated plate unit 40.

The present invention also provides a liquid fuel mixing apparatus, wherein the perforated plate unit 40 is a multi-perforated plate unit composed of a plurality of perforated plate units.

The present invention is characterized in that the casing unit 100 has a cylindrical shape including a front portion 101 as a fuel injection portion and a rear portion 102 connected to a flame radiation portion 110 through which a flame is radiated Fuel mixture mixing device.

In the present invention, the perforated plate portion 10 is formed with a hole 41 in the plate-shaped main body 41, and functions to mix the fuel droplets with air while passing the atomized fuel droplets. Lt; / RTI >

In the present invention, the electric resistance heating body 10 is disposed at a predetermined interval in a circumferential direction of the casing and arranged at a constant interval.

The liquid fuel atomizing apparatus according to the present invention reheats the atomized liquid droplets generated in the conventional hard oil or heavy oil pressure nozzle to the combustion furnace and supplies the liquid droplets to the superfine state more effectively than the existing liquid droplets, And at the same time premixing the air and the fuel to achieve a high efficiency / low pollution combustion with the minimum surplus air.

In addition, the liquid fuel atomizing apparatus according to the present invention effectively reheats liquid droplets generated in the pressure nozzle to make the fuel into a superfine droplet or a vaporized state, so that the use of surplus air is minimized, that is, It is possible to minimize the energy waste discharged to the exhaust gas, thereby improving the efficiency and positively affecting emission of pollutants such as unburned carbon and nitrogen oxides.

1 is a conceptual diagram of a liquid fuel atomizing apparatus according to the present invention;
FIG. 2 is a view showing a multi-perforated plate in the liquid fuel atomizing apparatus according to the present invention. FIG.
FIG. 3 is a photograph showing spray patterns in an ultrafine vapor state generated by electrical resistance of the electric resistance heating element of the liquid fuel atomizing apparatus according to the present invention. FIG.
4 is a photograph showing a blue flame of combustion by an atomizer of the present invention.
FIG. 5 is a photograph showing an iridescent flame generated by a simple pressure nozzle which is not heated in a general boiler. FIG.
Fig. 6 is a photograph showing a sword-shaped flame made from general heavy oil combustion.

BRIEF DESCRIPTION OF THE DRAWINGS FIG.

The present invention provides a liquid fuel mixing apparatus comprising a casing unit (100), an electric resistance heating element (10), an air injection hole (20), a nozzle (30), and a perforated plate (40).

1 is a conceptual diagram of a liquid fuel atomizing apparatus of the present invention.

The casing unit 100 of the present invention means a device or means that is formed in a cylindrical shape and performs a function of injecting a liquid fuel into the interior thereof to atomize the liquid fuel.

The casing unit 100 has a cylindrical shape including a front portion 101 as a fuel injection portion and a rear portion 102 connected to a flame radiation portion 110 through which a flame is radiated.

As shown in FIG. 1, the core of a three-stage atomization technique in which a spray droplet generated by a pressure nozzle is heated through an electric resistance and a heated perforated plate is to atomize a liquid fuel such as a hard oil or heavy oil only at a high pressure Unlike conventional nozzle technology, which ends with a mechanical method of atomizing droplets, it easily reheats droplets sprayed with pressure to atomize more finely, and even vaporizes.

Specifically, the atomized liquid droplets generated from the nozzles using high pressure are firstly heated by using an electric resistance heating element, and 2) a porous structure composed of one or two or three multilayer plates heated by a flame Air) steel plate so as to be heated again and to be mixed well with the air.

At this time, the number of the perforated plate portions and the size and distribution of the perforated plate apertures are adjusted so that the mixing and flow of the heated fine droplets and air are uniformly and well performed.

The reason for this multi-stage atomization and reheating is to make the liquid fuel close to the vapor fuel in the process of heating and sufficiently mix the air and the fuel, and at the same time, the minimum surplus air close to the theoretical air- It is aimed to improve the efficiency and minimize the generation of nitrogen oxides.

Nitrogen oxides More thermal NOx is generated when there is a lot of surplus air in a high temperature combustion environment. Therefore, in order to minimize the amount of nitrogen oxides generated, the surplus air should be minimized so that the combustion can be carried out only by the optimum amount of air. In order for the combustion to be clean only by the minimum amount of air, fuel and air can be mixed well in the ratio of theoretical ratio in the gas phase. However, even if the liquid fuel is atomized by applying pressure to the nozzle, it still remains in a liquid droplet state. Even when mixed well with the air, the droplet vaporizes and reacts with oxygen in the air and takes time to burn.

As a result, during a short period of time during which a flame is formed, vaporization does not sufficiently take place at the surface of the fuel in the droplet state, and the combustion can not proceed sufficiently. Therefore, when only the minimum amount of air is supplied, incomplete combustion occurs because the reaction time is not sufficient, so that the surplus air can not be supplied. As a result, when the conditions of high temperature and excess air are met, the possibility of generating a large amount of nitrogen oxides is increased.

In order to burn the liquid fuel with the optimum air suited to the stoichiometric air-fuel ratio, the liquid fuel should be converted into the vapor or gas state and then mixed with the oxygen in the air. The oldest and simplest way to burn a liquid fuel well is to heat and vaporize the liquid fuel. However, the method of heating the liquid fuel present in the form of a lump by heating with a port type burner or the like has a disadvantage in that the heating rate is low and the vaporization rate is too slow. Specifically, since the heating rate is proportional to the surface area per unit volume, the specific surface area of the droplet having the diameter R is 4πR ² / (4 / 3πR ³ ) (R) is proportional to ~ 1 / R, the relative heating area (surface area) decreases in proportion to the increase in the heat capacity (volume) as R increases. Therefore, the method of direct gasification and combustion by heating the liquid fuel present in a lump state is not suitable for a modern boiler system requiring high-speed combustion, and a device called a nozzle in a burner using liquid fuel has appeared to overcome it. Therefore, one of the functions of the nozzle is to atomize the fuel into a small droplet, thereby maximizing the specific surface area.

Generally, the liquid fuel has a certain degree of difference, but the temperature is raised to some extent for improving fluidity before injecting into the nozzle. It is then a technique that atomizes in a mechanical manner by spraying using a high pressure of (100 to 150) psi. Many methods have been attempted to increase droplet size by increasing pressure to increase atomization efficiency or by applying various geometric changes to other nozzles. For example, many studies have been made to control the flow rate, particle size, and spray pattern through various nozzle shape design such as "hollow cone nozzle" or "solid cone nozzle", but there is still much research on atomization of liquid droplets and oxidation Continuous research has been conducted to improve combustion efficiency through efficient mixing with air.

The above-mentioned electric resistance heating element 10 of the present invention means an apparatus or means for generating heat by electric resistance.

The electric resistance heating element 10 may be a coil device or the like that allows electricity to flow through a normal coil or the like.

1, the electric resistance heating element 10 is formed in one or more than two in the direction of the inner space of the side surface portion of the casing portion 100 and is formed in the direction of the rear surface portion 102 from the front surface portion 101, It is preferable that the casing unit 100 is provided with a plurality of the casing units 100 at regular intervals.

The electric resistance heating elements 10 are arranged at regular intervals around the circumference of the casing portion.

It is effective that the electric resistance heating element 10 is formed in the direction of the rear part 102 from the front part 101 of the casing part 100 and is preferably formed to the front of the perforated plate part 40. [

The reason why the electric resistance heating body is used is to prevent the heating reliability from being deteriorated because the heating by the flame usually involves complicated combustion and control of the flow.

The air injection hole 20 of the present invention means a device or means which is formed in the front part 101 of the casing part 100 and injects the air necessary for burning the fuel.

As shown in FIG. 1, the air injection holes 20 are formed in the front part 101 of the casing part.

The air injection holes 20 are preferably formed at equal intervals in the front portion 101 and are formed outwardly of the nozzles 30 to enhance the mixing power between the fuel and the air do.

The above-described nozzle 30 of the present invention means an apparatus or means for injecting fuel injected into the casing portion.

As shown in FIG. 1, the nozzle 30 may be mounted on a central portion of the front portion 101 of the casing portion, and a device for applying pressure to the fuel may be added, thereby uniformly injecting the fuel into the casing portion do.

The technical feature of the present invention resides in that the atomized liquid droplets generated in the nozzle using high pressure are firstly heated by using an electrical resistance heating element, and 2) a single or double or triple multilayer plate So that they are heated again and mixed well with the air.

The perforated plate portion 40 of the present invention means a device or means having a hole 42 formed in the plate-shaped main body 41 to perform the function of passing the atomized fuel droplets while mixing with the air.

As shown in FIG. 1, the perforated plate 40 may be installed inside the casing unit 100 and may be disposed in the vicinity of the rear surface 102 of the casing unit 100.

The present invention is preferably a multi-perforated plate portion in which the above-mentioned perforated plate portions 40 are formed of two or more.

As shown in FIGS. 1 and 2, the perforated plate portion 40 is formed of a plurality of perforated plate portions 1 40, a perforated plate portion 2 40 - 2, a perforated plate portion 3 40 - 3, The function of mixing the fuel droplets with the air is remarkably enhanced.

More preferably, the perforated plate portion 1 (40), the perforated plate portion 2 (40-2), the perforated plate portion 3 (40-3), and the perforated plate portion 3 It is not necessary to arrange the formed diameter in the order of a constant size, but it is preferable that the formed diameter is formed in a large order or in a small order, or vice versa.

2, the diameter D1 of the perforated plate section 40 is larger than the diameter D2 of the perforated section 2 40-2 and the diameter D2 of the perforated section 2 40-2 The function of mixing the fuel droplets and the air, which is formed to be larger than the diameter D3 of the perforated plate portion 3 (40-3) or vice versa, significantly improves.

As shown in FIG. 2, the distances l1 and l2 between the perforated plate portions can be set according to the kind of the fuel and the flow rate, and the red arrow in the right direction indicates the radiant heat direction by the flame.

The number of the perforated plate portions is effective from 1 to 4, and the number and spacing of the perforated plates and the size and arrangement of the perforated holes in the perforated plate portion may vary depending on the type of fuel and the flow rate.

The technical feature of the present invention is that the perforated plate portion 40 is heated because the perforated plate portion is provided close to the above-described flame propagating portion, and the hole of the perforated plate portion thus heated is vaporized And the combustion efficiency is remarkably increased as the effect of air mixing is maximized.

As shown in FIG. 2, in particular, the perforated plate portion 3 closest to the combustion furnace (flame propagating portion) is different from the perforated plate which is directly heated by the radiation of the flame or convection, and the flow for efficient heating or the control of the combustion phenomenon is required It differs from conventional low-NOx burners in that it does not.

The flame propagating unit 110 of the present invention means an apparatus or means for performing the function of burning fuel in the flue gas apparatus of the present invention.

As shown in FIG. 1, the flame propagating unit 110 is connected to the rear portion 102 of the casing unit 100 and is formed adjacent to the perforated plate unit.

The operation of the liquid fuel fuel atomizer according to the present invention will now be described.

The liquid droplets generated by the above-mentioned nozzle by the above-mentioned nozzle are further atomized while being heated by the electric resistance by the second step. In the third step, the droplets generated by the vaporization and air A white and blue flame is generated by the mixing effect.

That is, the fuel droplet sprayed at a constant pressure from the nozzle is directed toward the inner wall of the casing portion and collides with the inner wall in accordance with the spray pattern, and is heated at the surface of the electric resistance heating element to be atomized and vaporized.

It should be noted that the liquid fuel is in a fine droplet state sprayed by the pressure nozzle, so that it is easily heated. This is an advantage and advantage over the port type burner or similar heating system that does not pass through the pressure nozzle.

In addition, it differs from boiler system which must consider complicated heat flow and radiant heat by using combustion heat inside the combustion furnace after passing through pressure nozzle and spraying into combustion furnace.

After the superfine is achieved through the substantial heating by the electric resistance, a more complete two-stage heating and pre-mixing with the air are achieved by the multiple perforated plates.

The following shows an example in which the combustion is carried out by the liquid fuel mixing apparatus composed of the above structure and function.

3 is a photograph showing the state of spraying in an ultra-fine vapor state caused by electrical resistance of the electric resistance heating element of the liquid fuel atomizer of the present invention.

Accordingly, the present invention is a technique for vaporizing a droplet in a spray state generated by a pressure nozzle primarily in a droplet state or a complete gas state.

The physical core theory inherent in the present invention is an improvement of the disadvantage that the vaporization rate is slow when vaporizing the liquid fuel present in a lump form, and when the atomized droplet is reheated, the specific surface area of the atomized droplet becomes the initial liquid state , It is possible to effectively heat in a short space of time and in a narrow space. In this way, microdroplets generated by conventional pressure nozzles can be changed to almost 100% vapor state.

The photograph shown in FIG. 4 is a photograph showing the blue flame of the combustion by the atomizer of the present invention.

The photograph shown in FIG. 5 shows an iridescent flame generated by a simple pressure nozzle which is not a heating process as a general boiler.

On the other hand, the photograph of FIG. 6 shows a dark red flame produced in general heavy oil combustion, which is significantly different from the blue flame generated by the heating atomization demonstrated in the present invention.

(Study on Combustion Characteristics of Additive (Power-Z) to the Source of Trace, Heavy Oil and Heavy Residue, Research Report of Plant Engineering Center of KIER (February 2003) www.technobio.co.kr/download/k-report2 .pdf)

As described above, the liquid fuel mixing apparatus according to the present invention for heating the multi-stage perforated plate has the effect of achieving complete combustion by completely vaporizing the liquid fuel and mixing with the complete air.

INDUSTRIAL APPLICABILITY The present invention is useful in industries that produce, manufacture, sell, distribute and research fuming devices or combustion devices for burning liquid fuel.

The electric resistance heating element 10,
The air injection holes 20,
The nozzles 30,
The perforated plate portion 40, the plate-shaped main body 41, the hole 41,
The casing portion 100, the front portion 101, the flame propagation portion 110, the rear portion 102,

Claims (5)

The liquid fuel atomizing apparatus according to any one of claims 1 to 3, wherein the casing (100), the electric resistance heating element (10), the air injection hole (20), the nozzle (30) and the perforated plate section (40)
The method according to claim 1,
Wherein the perforated plate part (40) is a multi-perforated plate part composed of a plurality of perforated plate parts.
3. The method according to claim 1 or 2,
The casing unit 100 is formed in a cylindrical shape including a front portion 101 as a fuel injection portion and a rear portion 102 connected to a flame radiation portion 110 through which a flame is radiated. Atomizing device.
3. The method according to claim 1 or 2,
Wherein the perforated plate portion (10) is formed with a hole (41) in the plate-shaped main body (41), and functions to mix the fuel droplets while passing the atomized fuel droplets.
The method according to claim 1 or 2,
Characterized in that the electric resistance heating elements (10) are disposed at regular intervals around the circumference of the casing part at a constant length.

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