KR20010010047A - Fuel Injection System Of The Boiler Having an Ultrasonic-Type Vibrator - Google Patents

Abstract

PURPOSE: A fuel injector of a boiler is provided to enhance combustion efficiency by minimizing the size of a fuel spraying droplet and to adjust fuel flow by changing the frequency of an electric signal. CONSTITUTION: A fuel injector consists of a fuel transferring pump, a supersonic sprayer(11) and an igniter(12). The fuel transferring pump is connected to the supersonic sprayer by a fuel supplying pipe(13) and the supersonic sprayer sprays fuel into a combustor(18). The supersonic sprayer contains a vibrator(14) generating supersonic wave with an electric signal, a front horn(15), a back horn and a nozzle tip(17). The igniter generates a flame with high voltage discharged by injecting spraying droplet from the nozzle tip and feeding current to the igniter at the same time.

Description

FUEL INJECTION SYSTEM OF THE BOILER WITH AN ULTRASONIC TYPE VIBRATOR}

The present invention relates to a fuel injection device for a boiler, and more particularly, to a fuel injection device for a boiler capable of atomizing fuel by an ultrasonic spray generator.

In general, a boiler is a device that injects fuel with a high pressure injection nozzle and heats the fuel by igniting the injected fuel to generate high heat. The boiler is divided into a high-pressure injection method, a two-fluid injection method, and a rotary cylinder by the method of injecting fuel. That is, in the case of the high-pressure injection method, the fuel compressed at high pressure in the high-pressure fuel pump is injected at high speed through the orifice to atomize the fuel, and the two-fluid injection method is a method of atomizing air or steam by colliding with the fuel.

In addition, according to the difference between the spray angle and the penetration force, the spray angle is divided into a non-orbital type having a narrow penetration force and a large penetration force, and a spray type having a wide and easy-to-distribute spray type.

1 is a cross-sectional view showing the fuel injection value of such a boiler. As shown, the fuel injection device 1 is a high-pressure injection for injecting the high-pressure fuel supplied from the high-pressure fuel transfer pump 2, the high-pressure fuel transfer pump 2 for compressing the fuel to a high pressure into the combustion chamber It consists of a nozzle 3, a holder 6 for fixing the high pressure injection nozzle, and an ignition device 4 mounted at a position adjacent to the tip of the high pressure injection nozzle 3 to ignite the fuel.

When the fuel injection device 1 is driven by a motor (not shown) to operate the high pressure fuel transfer pump 2, the fuel is compressed to high pressure and supplied to the high pressure injection nozzle 3 through the fuel pipe 5. . The fuel supplied to the high pressure injection nozzle 3 passes through a plurality of fine holes (not shown) formed in the high pressure injection nozzle 3 and is atomized while being injected outside the high pressure injection nozzle 3. Then, the atomized fuel is ignited by the ignition device 4 to be burned to generate predetermined heat.

However, this fuel injection device is a high-cost fuel transfer pump and a high-pressure injection nozzle of the domestic production of the high-pressure injection nozzle is not imported, so there is a high manufacturing cost.

In addition, due to the limitation of fuel atomization, the combustion efficiency is low, and the exhaust gas concentration of the exhaust gas is high. In addition, there is a problem that the size of the combustion chamber increases due to an increase in the penetration distance due to the high pressure injection.

Accordingly, an object of the present invention is to reduce the production cost by replacing the high-pressure injection nozzle depending on the import with a domestic ultrasonic spray device, and to minimize the size of the spray droplets of the fuel to increase the combustion efficiency to reduce the emission of environmental pollutants In addition, it is to provide a fuel injection value that can facilitate the control of the heating calorific value by adjusting the fuel flow rate by changing the frequency of the electrical signal.

1 is a cross-sectional view showing a fuel injection value of a conventional boiler.

Figure 2 is a cross-sectional view showing a fuel injection device equipped with an ultrasonic spray generator according to an embodiment of the present invention.

Figure 3 is a cross-sectional view showing in detail the ultrasonic spray generating apparatus according to an embodiment of the present invention.

4 is a cross-sectional view showing a fuel injection device equipped with an ultrasonic atomizer according to another embodiment of the present invention.

* Description of Signs of Main Parts of Drawings *

10: high pressure fuel injection device 11: ultrasonic spray generator

12: igniter 14: oscillator

15: Front Horn 17: Spray Nozzle

In order to achieve the above object, the present invention is a fuel transfer pump, a fuel injection device fluidly connected to the fuel transfer pump to inject fuel, a combustion chamber for burning the fuel injected from the fuel injection device, fuel injected into the combustion chamber In a boiler equipped with an ignition device for ignition, the fuel injection device is integrally coupled to a vibrating member and a vibrating member vibrating by a predetermined electrical frequency, and propagates the vibration generated from the vibrating member, and a hollow is provided therein. It is formed of a front horn formed to supply the fuel, and a nozzle tip for injecting the fuel supplied through the end of the front horn to the atomization state to the combustion chamber.

According to one embodiment of the invention, the vibrating member is composed of a vibrator vibrating by an electric signal, by varying the vibration of the vibrating member by converting the electrical signal to change the vibration of the nozzle tip, to control the amount of atomization of fuel Can be.

The front horn is inclined at a predetermined angle so that the front horn can effectively transmit vibration to the nozzle tip.

According to another embodiment of the present invention, in the boiler having a fuel transfer pump, the boiler is connected to the fuel transfer pump, the ultrasonic spray generator for vibrating the fuel and sprayed in the atomized state, the ultrasonic spray generator is mounted on one side, It is integrally connected by a vaporization chamber, a vaporization chamber, and a connection tube having a predetermined diameter, which mixes atomized fuel injected from the ultrasonic spray generator and air sucked through a suction tube mounted on the upper portion thereof. It consists of a combustion chamber which burns the fuel supplied from the firebox, and an ignition device which ignites the fuel injected into the combustion chamber.

According to the present invention, the ultrasonic spray generator is a vibrator vibrating by a predetermined electrical frequency, a front horn which is integrally coupled to the vibrator to propagate the vibration by propagating the vibration generated from the vibrator, and the fuel through the end of the front horn The nozzle tip is sprayed into the vaporization chamber in an atomized state, and the nozzle tip is located inside the vaporization chamber.

The front horn has a hollow having a predetermined diameter in the longitudinal direction therein, one end of the hollow is connected to the fuel supply pipe of the fuel transfer pump fuel can be introduced, the other end of the hollow is in communication with the nozzle tip. In addition, a nozzle is mounted inside the connection pipe to atomize fuel flowing through the connection pipe and to inject it into the combustion chamber.

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

Figure 2 is a cross-sectional view showing a fuel injection device equipped with an ultrasonic spray generator according to an embodiment of the present invention, Figure 3 is a cross-sectional view showing in detail the ultrasonic spray generator according to an embodiment of the present invention.

As shown, the fuel injection device 10 generates an ultrasonic spray for injecting the fuel supplied from the fuel transfer pump (not shown) for supplying fuel and the fuel supplied from the fuel transfer pump (not shown) into the combustion chamber 18. And an ignition device 12 mounted inside the combustion chamber 18 to ignite the fuel injected from the ultrasonic atomizer 11.

The fuel transfer pump (not shown) and the ultrasonic spray generator 11 are connected to each other by the fuel supply pipe 13. Therefore, the fuel supplied from the fuel transfer pump (not shown) is supplied to the ultrasonic spray generator 11 through this fuel supply pipe 13.

Ultrasonic spray generator 11 is coupled to the vibrator 14, the vibrator 14 for generating ultrasonic waves by vibrating by an electrical signal to propagate the vibration and the front of the hollow 16 is formed in the axial direction therein It consists of a horn 15, a back horn which is integrally coupled to the rear of the front horn 15 and vibrates, and a nozzle tip 17 formed integrally with the front end of the front horn 15.

The vibrator 14 is vibrated by the electric signal of the controller (not shown). That is, the vibrator 14 operates at a specific idle frequency, the idle frequency being determined by the length of the front horn 15. The vibration of the vibrator 14 can be varied by appropriately converting an electrical signal.

As for the front horn 15, the inclined surface 15a is formed in the outer peripheral surface at a predetermined angle. Therefore, the vibrator 14 generates vibration waves by vibrating by an electric signal, and as the vibration waves are forwarded, the amplitude thereof increases, and becomes maximum at the nozzle tip 17.

In addition, the front horn 15 has a hollow 16 having a predetermined diameter in the longitudinal direction therein, the one end is connected to the fuel supply pipe 13 connected to the fuel transfer pump (not shown), the hollow The other end of 16 is communicated to the combustion chamber 18 via the nozzle tip 17. Therefore, the fuel supplied from the fuel transfer pump (not shown) is supplied to the nozzle tip 17 through the hollow 16 of the front horn 15 through the fuel supply pipe 13.

The hollow end 16a is formed in the center of the nozzle tip 17, and this hollow end 16a is in communication with the hollow 16. As shown in FIG. Then, the inclined surface 19a is formed at an end of the nozzle tip 17 at a predetermined angle.

Therefore, the fuel passing through the hollow 16 at a predetermined pressure flows into the hollow end portion 16a of the nozzle tip 17 and is applied to the inclined surface 19a by surface tension. Then, since the nozzle tip 17 vibrates at a predetermined frequency, the fuel applied to the inclined surface 19a is atomized and finally injected in the atomized state.

At this time, the injection angle of the fuel can be adjusted by adjusting the inclination of the inclined surface 19a of the nozzle tip 17.

The ignition device 12 is mounted at a predetermined position of the combustion chamber 18. In the ignition device 12, spray droplets are injected from the nozzle tip 17, and a high voltage is discharged by applying a current to the ignition device 12 to generate a spark. Therefore, this flame combusts by burning the atomized fuel.

In addition, the fuel flow rate can be adjusted by appropriately converting an electrical signal applied to the vibrator 14 to vary the vibration of the vibrator 14. Therefore, the calorific value can be appropriately adjusted.

As described above, the fuel transferred from the fuel transfer pump (not shown) passes through the hollow 16 of the front horn 15 and is supplied to the nozzle tip 17, and the fuel applied by vibrating the nozzle tip 17 is applied. Is atomized and sprayed, and is ignited by the ignition device 12.

On the other hand, Fig. 4 shows another embodiment according to the present invention. As shown, another embodiment according to the present invention forms a mixer by injecting the fuel injected from the fuel injection device 20 into the vaporization chamber 22 to mix with the outside air, and supply the mixer to the combustion chamber 26 By the ignition device 25 to be ignited.

The fuel injection device 20 has the same structure as the embodiment according to the present invention, except that the ignition device 25 is separately separated and mounted in the combustion chamber 26. That is, the fuel injection device 20 includes a fuel transfer pump (not shown) for transferring fuel and an ultrasonic spray generator for injecting fuel supplied from the fuel transfer pump (not shown) into the combustion chamber 26 ( 21).

In addition, a vaporization chamber 22 is provided at one side of the fuel injection device 20, and the nozzle tip 17 is positioned inside the vaporization chamber 22. Therefore, the spray droplets injected from the nozzle tip 17 are injected into the vaporization chamber 22.

The spray droplets injected into the vaporization chamber 22 are mixed with the air sucked through the intake pipe 27 of the vaporization chamber 22, and the mixed droplets and the air are connected to the connection pipe 24 by a predetermined pressure. It is supplied to the combustion chamber 26 through. The connecting tube 24 has a predetermined diameter, and the air vortex 28 is mounted therein.

Therefore, the spray droplets passing through the connecting pipe 24 are ignited by the ignition device 25 so that the spray droplets are combusted in the combustion chamber 26.

As described above, the fuel injection device according to the present invention has an advantage of reducing the fuel consumption amount by increasing the harmful gas emission and combustion efficiency by inducing complete combustion by minimizing spray particles by installing the ultrasonic spray generator.

In addition, by controlling the fuel flow rate by varying the electrical signal applied to the ultrasonic atomizer there is an advantage that can easily adjust the amount of heat generated.

In addition, since the ultrasonic spray generator can be produced domestically, there is an advantage that the manufacturing cost is reduced, as well as import substitution.

In addition, by forming the front horn inclined to increase the transmission effect of the vibration has the advantage of improving the atomization efficiency.

Claims (3)

A fuel transfer pump, a fuel injection device fluidly connected to the fuel transfer pump to inject fuel, a combustion chamber for combusting the fuel injected from the fuel injection device, and a boiler equipped with an ignition device for igniting the fuel injected into the combustion chamber. To Vibrating means for vibrating the fuel injection device by a predetermined electrical frequency; A front horn integrally coupled to the vibration means to propagate vibration generated from the vibration means, and having a hollow formed therein to supply fuel; And And an ultrasonic spray generator which is integrally formed at an end of the front horn and comprises a nozzle tip for injecting the fuel supplied through the hollow into the atomization state and injecting the fuel into the combustion chamber. The method of claim 1, wherein the vibration means comprises a vibrator vibrating by an electrical signal, by varying the vibration of the vibrator by converting the electrical signal to vary the vibration of the nozzle tip, by adjusting the amount of fuel atomization calorific value Boiler which can be adjusted. The boiler of claim 2, wherein the front horn is inclined at a predetermined angle to effectively transmit vibration to the nozzle tip.