KR101365736B1 - Low nitrogen oxide burner apparatus for fuel saving - Google Patents

Abstract

The present invention relates to a low-nox burner device using the ejector principle, the rear end of which is connected to the blower 210 inside the exterior 310 is connected to the water pipe 120 for supplying water to inject the air to the front end Inner tube 320 is formed to be a dual injection spray mixer 300; including,
When the air supplied from the blower 210 passes through the inner tube 320 at a high speed, moisture is sucked out of the moisture tube 120 by the pressure difference, mixed with air, and injected to the point where the fuel is burned, thereby improving combustion efficiency. By suppressing the generation of rusty,
The present invention relates to a low knox burner apparatus using an ejector principle that maximizes combustion efficiency while minimizing the generation of nox by supplying water to a point where fuel is combusted by mixing water with air.

Description

Low nitrogen oxide burner apparatus for fuel saving

The present invention relates to a burner device, and more particularly to a low knox burner device using the ejector principle.

In general, nitrogen oxides refer to NO and NO _{2 and} are usually referred to as NOx (nox), which is generated when burning fossil fuels. The generation of NOx is influenced by the flame temperature, oxygen concentration and the nitrogen content in the fuel, and the NOx reduction method can be found by changing these conditions by changing operating conditions and combustion methods.

Low-nox burner is a burner to which the rust reduction method is applied. It is a burner that reduces the flame temperature and oxygen concentration during combustion, suppresses the generation of nitrogen oxide and saves fuel by shortening the combustion gas residence time. Recently, as the concern about environmental pollution due to the rust generated during combustion increases, it is a burner that is being actively researched and developed.

On the other hand, the research theory that the combustion efficiency is better when the proper mixing of water and oil is combusted than burning only oil, and the technology for commercializing the research theory as a low-nox burner has been developed. The theory is that when the oil surrounding the water particles is burned, the water particles are vaporized by the conduction of heat, and the vaporized water vapor increases atomization and diffuses the oil layer, causing the complete combustion of the oil. To cause.

Applying the same theory as above, there is a Republic of Korea Patent Publication No. 10-2011-0079406 (2011. 07. 07.) "Fuel-saving low-nox burner device". This is a burner device that achieves low rust by burning solid fuel while supplying reformed fuel by mixing water and oil in a constant ratio.

An object of the present invention is to obtain a low-nox burner that can be applied to a variety of applications, such as domestic, industrial, agricultural and the like by minimizing the generation of NOx, a nitrogen oxide, environmentally friendly and thermal efficiency.

The present invention achieves the above object by suggesting a burner device that maximizes combustion efficiency by minimizing the generation of rust by supplying water to a point where fuel is combusted by mixing moisture with air using the principle of ejector.

According to the present invention it is possible to obtain a burner device that can minimize the generation of rust while maximizing the combustion efficiency by supplying moisture to the point where the fuel is combusted by mixing with air.

1 is an exemplary view showing a schematic configuration of a burner device to which the mixing spray according to the present invention is applied;
2 is an exemplary view showing a state in which the water pipe according to the present invention is connected to the mixing sprayer,
3 is a perspective view of the mixing sprayer applied to the present invention,
Figure 4 is an exemplary view showing the internal configuration of the mixing sprayer applied to the present invention,
5 is an exemplary view showing the operation of the mixing injector according to the present invention,
6 to 8 is an exemplary view showing an installation state of the injection nozzle,
9 is an exemplary view showing a state in which the injection nozzle and the water spray nozzle is installed in the inner tube.

In the present invention, by minimizing the generation of NOx, which is a nitrogen oxide, in order to obtain a low-nox burner that can be applied to various uses such as home use, industrial use, and agriculture by maximizing environmental efficiency, the water pipe for supplying water is connected to the lower part of the exterior. The inner end is connected to the blower and the front end is formed with an inner tube having a length up to the point where the water pipe is connected to include a mixed sprayer which is a dual structure,

When the air supplied from the blower passes through the inner tube at a high speed, moisture is sucked out of the moisture tube by the pressure difference and mixed with the air to be injected to the point where the fuel is burned, thereby improving combustion efficiency and suppressing the generation of nox. We propose a low-nox burner system using the ejector principle.

Hereinafter, with reference to the accompanying drawings, the present invention will be described in detail.

The low knox burner apparatus using the ejector principle according to the present invention includes a mixer sprayer 300 for supplying air mixed with moisture to a combustion point of a fuel to improve combustion efficiency.

The mixing sprayer 300 is an inner tube 320 is formed inside the exterior 310 to form a double tube, the exterior 310 is connected to the water pipe 120 is connected to the lower portion, the inner tube 320 is the rear end It is connected to the blower 210 is supplied with air and sprayed toward the front end. The exterior 310 and the inner tube 320 are preferably formed by adopting a tube having a circular cross section, but is not limited thereto.

The mixing sprayer 300 is formed to be blocked between the exterior 310 and the inner tube 320 at the rear end, and the front end is formed to be opened between the exterior 310 and the inner tube 320. And the inner tube 320 is formed so that the front end has a shorter length than the front end of the exterior 310, wherein the front end of the inner tube 320 is formed to reach the position passing through the point where the water pipe 120 is connected It is preferable.

This configuration uses the principle of ejectors. That is, when the air is injected at high speed through the inner tube 320, the speed of the air also increases inside the exterior 310. According to Bernoulli's theorem, the pressure decreases as the flow rate increases, so the pressure inside the exterior 310 is increased. Water is sucked out of the water pipe 120 connected to the exterior 310 as shown in FIG. 4 while being lowered in proportion to the increase in the speed of air. At this time, since the gap between the exterior 310 and the inner tube 320 is blocked at the rear end of the mixer sprayer 300, the degree of the pressure between the exterior 310 and the inner tube 320 is lowered.

The water sucked as described above is naturally mixed with the air injected through the inner tube 320 is supplied to the combustion point of the fuel formed in front of the exterior 310 in the combustion furnace 200 to help the combustion of the fuel. In other words, when water is mixed with air and supplied to the combustion point, water is mixed with the fuel supplied to the combustion point, whereby water particles are vaporized by heat conduction and vaporized water vapor diffuses the fuel while its volume is increased. It causes atomization and maximizes combustion efficiency, thus suppressing the generation of rust.

The combustion furnace 200 has a hollow interior, and the front end of the exterior 310 is located in the combustion furnace 200, and a point at which the rear end and the water pipe 120 are connected to be exposed to the outside of the combustion furnace 200. Can be. The fuel is supplied to the front of the exterior 310 in the combustion furnace 200 so that the combustion point is formed in front of the exterior 310.

Meanwhile, in the present invention, bubbles are generated by using a bubble generator 500 separately provided as illustrated in FIG. 1 to control the amount of moisture sucked out and to achieve a smooth water supply, and supply the bubbles to the water pipe 120. . When water is supplied in the form of bubbles in this way, when the water is sucked, the air contained in the bubbles is also sucked out, so that a large amount is not sucked rapidly and the air can be smoothly mixed.

The water pipe 120 may be a plurality of pipes are connected to each other as shown in FIG. This allows the water pipe 120 to be installed in consideration of the installation position of the bubble generator 500 and the mixing sprayer 300, and each connection part can be rotated to allow smooth installation while adjusting the angle.

The fuel is supplied through the fuel pipe 110 from the external fuel supply device and supplied to the fuel injection nozzle 400 for injecting fuel into the combustion furnace 200, and then injected in front of the mixing sprayer 300. At this time, the fuel is to be injected in the same direction as the flow direction of air. Naturally, the fuel pipe 110 may be provided with a known valve so as to adjust the injection amount of the fuel.

Injection of the fuel as described above can be achieved by adjusting the installation position of the fuel injection nozzle (400). For example, as shown in FIG. 6, the fuel injection nozzle 400 penetrates the inner tube 320 so that an end thereof passes through the front end of the exterior 310 to allow the fuel to be injected in front of the mixing sprayer 300. Can be. As another example, as illustrated in FIGS. 7 and 8, the fuel injection nozzle 400 may be disposed outside the exterior 310, in which case the fuel injection nozzle 400 may be installed in parallel with the exterior 310 or in front of the exterior 310. Can be installed in a variety of ways, such as to be arranged on the same line as the center line.

On the other hand, the low-nox burner apparatus according to the present invention can be supplied through a separate supply device fuel and moisture. The supply device may be formed in an enclosure form including a device for supplying fuel and a bubble generator 500 for converting and supplying water into a bubble form.

The fuel may be smoothly mixed with moisture by pulverizing and providing the particles through ultrasonic waves. The ultrasonic vibrator is installed in the supply device, and the fuel is injected into the injection nozzle 400 through the fuel pipe 110 after the cohesive force is weakened while passing through the ultrasonic vibrator.

Hereinafter, the operation of the low-nox burner device according to the present invention as described above.

The blower 210 and the bubble generator 500 are operated by applying power. When the blower 210 is operated, air is injected through the inner tube 320 and bubbles are drawn out through the water pipe 120 connected to the exterior 310.

The bubbles are blown while coming into the exterior 310 by the pressure difference, and when the bubbles are blown, the bubbles are instantaneously finely pulverized, and are smoothly mixed with the injected air. At this time, by adjusting the intensity of the wind generated by the blower 210, it is possible to adjust the internal pressure of the bar, thereby controlling the amount of air bubbles coming out by operating the blower 210.

Air mixed with water as described above is injected toward the injection nozzle 400 is installed to inject fuel into the combustion furnace (200). At this time, the injection nozzle 400 is supplied with fuel to be injected and ignited or ignited while injecting air, and the mixed air is mixed with the fuel injected while being supplied at high speed toward the flame and atomized. It causes a phenomenon to promote combustion. Therefore, the combustion efficiency is maximized to minimize the generation of rusty.

The heat of combustion generated according to the above is installed in a boiler device or other heat exchanger to be used in various applications that can use the heat of combustion such as domestic boilers or industrial and agricultural uses.

On the other hand, the low-nox burner apparatus according to the present invention can be installed in the inner tube 32 of the mixing sprayer 300, as shown in Figure 9, the injection nozzle 400. The water spray nozzle 600 is to be able to directly spray water when bubbles are not generated from the bubble generator 500, can be installed as needed, and can be selectively used with the bubble generator 500 It is.

100: supply device, 110: fuel pipe,
120: water pipe, 200: combustion furnace,
300: mixed sprayer, 310: appearance,
320: inner tube, 400: injection nozzle,
500: bubble generator, 600: water spray nozzle.

Claims (7)

Mixing sprayer 300 having a double structure is formed in the inner tube 320 is connected to the blower 210, the rear end is connected to the blower 210 inside the exterior 310 is connected to the water supply pipe 120 for supplying water is a double structure ), And fuel is injected in the same direction as the flow direction of air through the fuel injection nozzle 400 in front of the mixing sprayer 300,
When the air supplied from the blower 210 passes through the inner tube 320 at high speed, moisture is sucked out of the moisture tube 120 by the pressure difference, mixed with air, and injected to the point where the fuel is burned, thereby improving combustion efficiency. Low-nox burner device using the ejector principle characterized by improving the suppression of the generation of nox. The method according to claim 1,
Low moisture burner device using the ejector principle, characterized in that the moisture is supplied to the water pipe 120 to form a bubble. The method according to claim 1,
The front end of the inner tube 320 is a low-nox burner device using the ejector principle, characterized in that formed to reach a position passing through the point where the water pipe 120 is connected. The method according to claim 1,
The mixing sprayer 300 is a low-nox burner device using the ejector principle, characterized in that the rear end is blocked between the exterior 310 and the inner tube (320). delete The method according to claim 1,
The fuel injection nozzle 400 is a low-nox burner device using the ejector principle, characterized in that arranged through the inner tube. The method according to claim 1,
The fuel injection nozzle 400 is a low-nox burner device using the ejector principle, characterized in that disposed outside the appearance (310).

Images