KR20130104693A - Exhaust gas reduction apparatus - Google Patents

Abstract

PURPOSE: An apparatus for reducing exhaust gas is provided to minimize foreign matters in the exhaust gas, and to completely burn fuel in a combustion chamber. CONSTITUTION: An apparatus for reducing exhaust gas comprises an input body (100), a main body (200), an output body (300), and an impeller (400). The input body comprises an inlet (112), and a fluid path for generating vortex. The main body comprises a first unit with a reduced plane (210), a first unit (220) with an enlarged plane. The output body comprises a second unit (310) with the reduced plane, and a discharge port (330). The impeller is installed in the main body, and induces a collision with fluid. [Reference numerals] (AA) Fourth section; (BB) Third section; (CC) Second section; (DD) First section

Description

Exhaust gas reduction device {EXHAUST GAS REDUCTION APPARATUS}

The present invention relates to an exhaust gas reducing device, and more particularly, is provided in a fuel supply line to impart constant fluidity in one direction and promote atomization of fluid particles due to collision with impellers and multi-stepped surfaces. The present invention relates to an exhaust gas reducing device for inducing complete combustion of fuel in a combustion chamber and minimizing the generation of harmful components.

In general, the internal combustion engine is a device that can obtain power by using the explosive power generated through the combustion of the fuel in the combustion chamber. This combustion process necessarily involves the generation of exhaust gases containing harmful components. In addition, the fuel necessary for the combustion process of the internal combustion engine requires the development of countermeasures that can be saved more in accordance with various international circumstances including a lack of resources.

Accordingly, various types of fuel savers are being developed, and among them, the invention of Korean Patent Laid-Open Publication No. 2003-0065258 is one of them. Korean Patent Laid-Open Publication No. 2003-0065258 is a smoke reduction fuel reducer for an internal combustion engine, and has an inlet side housing (1) to which a fuel pipe (2) on the fuel tank side is connected, and is fixed to an inside of the inlet side housing and has a through hole (8a). A first permanent magnet (8) having a discharge side housing (3) coupled to the inlet side housing by a coupling means and having an engine side fuel pipe (4) connected at one end thereof, and a first permanent magnet inside the discharge side housing; And a second permanent magnet 9 fixed to face the same polarity and having a through hole 9a, and installed at an intermediate portion of the housing to partition an interior of the housing, and a plate having a fuel passage hole 10a formed at the center thereof. ) And third and fourth permanent magnets 11 and 12 having the same polarity as the first and second permanent magnets on both sides of the diaphragm and having through holes 11a and 12a in the center thereof, respectively. A first diffusion plate 13 installed between the first and third permanent magnets to diffuse fuel primarily; The second diffusion plate 14 is installed between the second and fourth permanent magnets to diffuse the fuel again.

That is, the smoke reduction fuel saver for an internal combustion engine of WO 2003-0065258 installs a diaphragm 10 in a space between the inlet side housing 1 and the discharge side housing 3, and the left / right centered around the diaphragm 10. The second permanent magnet (9) and the fourth permanent magnet (12), the first permanent magnet (8) and the third permanent magnet (11) are respectively installed on both sides, and the first permanent magnet (8) and the third permanent magnet are respectively installed. While the first diffusion plate 13 is rotatably installed in the space between the magnets 11, the second diffusion plate 14 is placed in the space between the second permanent magnet 9 and the fourth permanent magnet 12. The rotatable installation.

Accordingly, the fuel introduced into the inlet-side housing 1 by the pressure of the fuel pump passes through the through hole 8a of the first permanent magnet 8 and hits the wing of the first diffusion plate 13, thereby inducing the inlet-side housing 1. The primary diffusion in (1) and the fuel diffused through the magnetic force by the first permanent magnet 8 and the third permanent magnet 11 in this process are pressurized and accelerated to further atomize.

In addition, when the first diffused fuel enters the discharge side housing 3 through the passage hole 10a of the diaphragm 10, the first diffused fuel is diffused again by the wing of the second diffusion plate 14 and the second permanent magnet The fuel diffused through the magnetic force by (9) and the fourth permanent magnet 12 is pressurized and accelerated again to further atomize, thereby contributing to the complete combustion of the fuel in the combustion chamber.

However, in the conventional smoke reduction fuel saver for an internal combustion engine as described above, the first to second diffusion plates 13 and the second diffusion plate 14 are installed in the space between the inlet-side housing 1 and the discharge-side housing 3. The installation of the fourth permanent magnets 8, 9, 11 and 12 is required, and above all, the diaphragm 10 having the fuel passage hole 10a which enables communication between the inlet-side housing 1 and the discharge-side housing 3. With the installation of), the permanent magnets (8, 9, 11, 12) are required to be assembled so that they can be arranged in different polarities.

Therefore, the conventional fuel saver for reducing soot requires many components in its construction, and it is necessary to install a large number of permanent magnets so that they can be arranged in opposite polarities. Will result. In addition, the conventional fuel saver is accompanied with a problem that the atomization degree of the fuel is greatly reduced due to the deterioration of the magnetism at the time of durability because the means for generating a magnetic force for atomization of the fuel is implemented by a permanent magnet.

As a result, unlike the conventional fuel saver, the performance that can smoothly help fuel atomization is ensured even when it is durable, thereby requiring the development of a new type of fuel saver that can contribute to the complete combustion of fuel in the combustion chamber. It is emerging.

Patent Publication No. 2003-0065258 (Soot Reduction Fuel Saver for Internal Combustion Engine)

Accordingly, the present invention has been made in view of the above-mentioned matters, and induces vortex generation in a predetermined direction with respect to the fluid flowing through the fuel supply line, and increases the pressure of the fluid by reducing the flow cross-sectional area. In order to promote atomization of fluid particles by sequentially impinging the impeller and the multi-stage stepped surface, it is possible to induce complete combustion by atomization of fuel in the combustion chamber and to minimize the harmful components of the exhaust gas generated accordingly. The purpose is to make it.

The present invention for achieving the above object is an input body having an inlet port for communicating with the supply line of the fuel, and a vortex generation flow path for communicating with the inlet port and providing a direction to the flow of the fluid;

A first cross-sectional reduction portion coupled to the input body and reducing a flow cross-sectional area of the fluid between the vortex generating flow path and a first cross-sectional enlargement portion at a rear end of the first cross-sectional reduction portion to enlarge the flow cross-sectional area of the fluid; Main body;

An output body coupled to the main body and having a second cross-sectional reduction portion for reducing a flow cross-sectional area of the fluid, and an outlet for discharging the fluid to the outside at a rear end of the second cross-sectional reduction portion; And

It is installed on the main body characterized in that it comprises an impeller for inducing a rotational collision with the fluid.

In the present invention, the vortex flow passages communicate with the inlet port and provide a flow cross sectional area of the fluid while providing a directionality to the flow, while communicating with the first spiral channel and reducing the flow cross sectional area of the fluid. And a second spiral passage communicating with the first cross-sectional reduction portion of the main body by providing directionality to the flow.

In the present invention, the first spiral passage is formed through the body portion of the input body, and the second spiral passage is formed along the entire circumference of the outer circumferential surface of the conical protrusion protruding from the body portion.

In the present invention, the second cross-sectional reduction portion of the output body forms a multi-step step surface concentrically stepped, the multi-step step surface is characterized by forming a plurality of flow guide grooves radially disposed toward the center. It is done.

In the present invention, the output body is formed at the rear end of the second cross-sectional reduction portion to form a second cross-sectional enlargement for gradually expanding the flow cross-sectional area of the fluid, the second cross-sectional enlarged portion is provided with a network for promoting atomization of the fluid It is characterized by.

The present invention provides a fluid flow of a vortex having a constant direction through the vortex generation flow path for the fluid introduced into the input body through the supply line of the fuel, and increases the pressure of the fluid through the reduction of the flow cross-sectional area In this state, atomization can be promoted through atomization of the fluid particles resulting from the collision with the impeller and the collision with the multi-stage stepped portions formed in the reduction in cross section. It can be induced, through which it is possible to minimize the content of various harmful components in the exhaust gas to the atmosphere.

In addition, the present invention by installing the orifice portion between the cross-sectional reduced portion and the cross-sectional enlarged portion at a certain distance in the exhaust gas reduction device by a plurality of stages through the pressure increase of the fluid accompanying the respective orifice portion, The atomization of fuel particles in the next flow stage can be promoted, and the fine particle network through the final flow stage can further accelerate the atomization of the fuel particles. The savings can also be expected.

In particular, the present invention can induce heat generation by rotational friction at the contact between the impeller and the fixed support rotatably supporting the impeller from the rotation of the impeller due to the collision between the fluid and the impeller having a constant directionality, such a heat generation phenomenon This further facilitates atomization of the fuel passing through the helical flow path of the impeller, thereby reducing the amount of fuel required for combustion to a significant level.

1 is a perspective view showing an exhaust gas reducing device according to the present invention.
2 is a cross-sectional view of the exhaust gas reducing device shown in FIG.
3 is a cross-sectional view taken along the line AA of FIG. 2 and showing a first spiral passage formed in the inlet of the input body.
4 is a perspective view of the input body shown in FIGS. 1 and 2, respectively.
5 is a perspective view of the main body shown in FIGS. 1 and 2, respectively.
6 is a perspective view of the output body shown in FIGS. 1 and 2, respectively.
7 is a front view showing the flow guide groove of the second cross-sectional reduction portion of the output body shown in FIG.
8 is a front view and a side view of the impeller shown in FIG. 2.
9 is a perspective view of the fixing support shown in FIG.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying exemplary drawings. The following examples are provided to more easily understand the present invention, and the present invention is not limited to these examples.

The present invention is the input body 100 is connected to the supply line of fuel, the main body 200 is coupled to the input body 100, the output body is coupled to the supply line of fuel and coupled to the main body 200 ( 300, an impeller 400 rotatably installed in the main body 200, and fixed between the main body 200 and the output body 300 to rotatably support the impeller 400. By providing the support 500, the fuel corresponding to the fluid is atomized and converted into the atomized state.

1 to 4, the input body 100 is formed integrally with the body portion 110 and the body portion 110 having the inlet 112 of fluid in communication with the supply line and the main Conical projection 120 inserted into the body 200, and the vortex flow passage for communicating with the inlet 112 and providing a constant direction to the flow of the fluid while gradually reducing the flow cross-sectional area of the fluid. The body portion 110 forms a threaded portion 114 for screwing with the main body 200 at an outer circumferential portion, and forms a threaded portion 116 for screwing with a supply line on the inner circumferential surface of the inlet 112. do.

The vortex flow passage is formed in the inlet 112 of the input body 100, the first spiral passage 130 formed through the body portion 110 and the conical shape formed integrally with the body portion 110 The second spiral passage 140 is formed to be exposed to the outside along the entire circumference of the protrusion 120.

In this case, the first spiral passage 130 communicates with the inlet 112 and performs a function of providing a constant direction to the flow while gradually expanding the overall flow cross-sectional area of the fluid. That is, the first spiral passage 130 enters the inside of the body portion 110 from each inlet 118 located at a plurality of radially spaced points within the inlet 112, and the torsion radius is generally extended. It consists of a spiral structure of the form. Accordingly, as the first spiral passage 130 enters the inside of the body portion 110 from the inlet 112, the torsion radius is increased to gradually expand the overall flow cross-sectional area.

In addition, the second spiral passage 140 continuously communicates with the first spiral passage 130 and gives a constant direction to the flow of the fluid while gradually reducing the overall flow cross-sectional area of the fluid, Communicate with the inside.

1, 2 and 5, the main body 200 is coupled to the body portion 110 of the input body 100 and between the second spiral passage 140 of the vortex generation flow path. A first cross-sectional enlargement portion for forming a first cross-sectional reduction portion 210 to gradually reduce the flow cross-sectional area of the fluid, and gradually increasing the flow cross-sectional area of the fluid following the rear end of the first cross-sectional reduction portion 210 220 is integrally formed. In this case, the first cross-sectional reduction portion 210 forms a space allowing the flow of the fluid between the body portion 110 of the input body 100. Accordingly, a first orifice is formed between the first end face reduction part 210 and the first end face extension part 220 to minimize the flow cross-sectional area of the fluid, and when the first orifice passes, the flow pressure of the fluid It is the maximum.

And one side of the main body 200 is formed with a screw portion 230 for screwing the threaded portion 114 of the input body 100, the other side of the screw portion for screwing the output body 300 ( 240 is formed. In addition, a sealing material 600 for maintaining airtightness such as an O-ring in the coupling portion between the input body 100 and the main body 200 and the coupling portion between the main body 200 and the output body 300, respectively. ) Is installed.

1, 2, 6, and 7, the output body 300 is engaged with the threaded portion 240 of the main body 200 and collides with the fluid while gradually reducing the flow cross-sectional area of the fluid. Forming a second cross-sectional reduction part 310 that performs a function of the collision part, and a second cross-sectional enlargement part 320 for gradually increasing the flow cross-sectional area of the fluid subsequent to the rear end of the second cross-sectional reduction part 310. And a discharge port 330 connected to a supply line of fuel at a rear end of the second cross-sectional enlarged part 320. Accordingly, a second orifice is formed between the second end face reduction part 310 and the second end face expansion part 320 to minimize the flow cross-sectional area of the fluid, and when the second orifice passes, the flow pressure of the fluid It can be increased to the maximum again.

Here, the second end face reduction portion 310 of the output body 300 forms a multi-stepped step surface having a concentric stepped shape in order to maximize the crushing effect by the collision with the fluid. In addition, a plurality of flow guide grooves 312 are formed in the second end reduction portion 310 of the output body 300 so as to be radially disposed toward the center, and the flow guide grooves 312 are formed in the second cross section. The fluid collides with the stepped surface of the multi-stage formed in the reduction part 310 and serves as a guide for smoothly flowing to the outlet 330 through the second end surface expansion part 320.

In addition, the second section enlarged portion 320 is provided with a fine mesh 340 to further promote the atomization of the fluid discharged. In addition, the output body 300 forms a threaded portion 350 for screwing with the threaded portion 240 of the main body 200 on one side, and also with a supply line on the inner circumferential surface of the outlet 330 located on the other side. To form a screw portion 360 for screwing.

1, 2 and 8, the impeller 400 is provided in the first cross-sectional expansion portion 220 of the main body 200 is provided with a plurality of blades to induce rotational collision with the fluid. do. Accordingly, the impeller 400 is rotated by the collision with the fluid flowing through the first cross-sectional enlarged portion 220 of the main body 200. In addition, the impeller 400 forms an opening 410 for coupling with the fixed support 500 at the rear side rotation center.

1, 2, and 9, the fixed supporter 500 is coupled to an opening 410 formed on the rotation center of the impeller 400 to form an axial shape for supporting the impeller 400 to be idle. The boss 510 having the protruding end 520 is formed. In addition, the fixed support 500 is coupled to the plurality of spokes 530 protruding radially from the outer circumferential surface of the boss 510 and the free end of the spoke 530 to contact the inner circumferential surface of the output body 300. In addition, it is provided with an annular rim 540 which is supported in contact with one end of the main body 200. In addition, a space for free flow of fluid is formed between the plurality of spokes 530.

In the fixed supporter 500, the rear side portion facing the axial projecting end portion 520 located in front of the boss 510 is a kind of vortex that prevents the flow of fluid toward the outlet 330. In order to reduce the occurrence of the Eddy current (Eddy current) to form a protruding end portion 550 of the protruding to the outside.

Therefore, the fuel introduced through the inlet 112 of the input body 100 has a certain direction while passing through the first spiral passage 130 of the vortex generation flow path, so that the vortex is accompanied by the flow caused by the vortex generation. do. At this time, the flow rate of the fluid in the first spiral passage 130 is primarily increased by the gradual expansion of the flow cross-sectional area.

Subsequently, the pressure of the fluid rapidly increases due to the gradient of the cross-sectional reduction by the first cross-sectional reduction portion 210 of the main body 200 while passing through the second spiral passage 140. The particle size shows a large state as shown in the first section of FIG.

Subsequently, the fluid with the maximum pressure in the first orifice region between the first end face reduction part 210 and the first end face expansion part 220 meets the impeller 400 and passes through the spiral flow path between the respective blades. While the flow velocity of the vortex is further increased secondary, in this state it is sprayed on the multi-stage stepped surface formed in the second cross-sectional reduction portion 310 of the output body (300). In this process, the impeller 400 is rotated at a high speed by the flow of the fluid, wherein the heat generated by the rotational friction between the impeller 400 and the fixed support 500 may contribute to the fuel atomization Will be. In other words, the primary atomization of fuel is involved in this region. In this state, as shown in the second section of FIG. 2, the size of the fluid particle is changed to a state smaller than the first section with the first atomization following the initial collision with the impeller 400.

Subsequently, the fluid sprayed on the second end face reduction part 310 of the output body 300 further atomizes the particles by collision with the multi-stepped step surface, and in this process, secondary atomization of the fuel is involved. In this state, as shown in the third section of FIG. 2, the size of the fluid particles is changed to a smaller state than the second section due to the secondary atomization caused by the collision with the stepped surface of the second section reduction part 310. do.

Subsequently, the fluid gathered into the second orifice region along the flow guide groove 312 of the second cross-sectional reduction part 310 may again increase the pressure to the maximum, followed by the second cross-sectional enlargement part 320. As it flows into and collides with the fine mesh 340 in a state in which the flow rate is increased again. In this process, the fluid passing through the second cross-sectional enlarged part 320 is atomized to a third degree so as to substantially nanoparticles by collision with the mesh 340, and finally, the fuel supply line through the outlet 330. Is provided. In this state, as shown in the fourth section of FIG. 2, the size of the fluid particles is converted to a smaller state than the third section due to the third atomization caused by the additional collision with the mesh 340.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be construed as limited to the particular details of the embodiments set forth herein. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the appended claims.

100-input body 110-body
112-Inlet 114,116-Thread
120-conical protrusion 130-first spiral passage
140-second spiral passage 200-mainbody
210-Section 1 Section Reduction 220-Section 1 Section Expansion
230,240-threaded 300-output body
310-Second Section Reduction 312-Flow Guideway
320-Section 2 enlarged section 330-outlet
340-net 350,360-thread
400-impeller 410-opening
500-fixed support 510-boss
520-projection 530-spoke
540-Rim 550-Protrusion
600-sealing material

Claims (9)

An exhaust gas reducing device installed in a fuel supply line to atomize fuel and atomize it,
An input body (100) having an inlet (112) in communication with said supply line and a vortex generating flow path in communication with said inlet (112) and providing directionality to the flow of fluid;
A first cross-sectional reduction unit 210 coupled to the input body 100 to reduce a flow cross-sectional area of the fluid between the vortex generating flow path and a flow of fluid at a rear end of the first cross-sectional reduction unit 210. A main body 200 having a first cross-sectional enlargement part 220 for enlarging the cross-sectional area;
The second end face reduction portion 310 coupled to the main body 200 and to reduce the flow cross-sectional area of the fluid, and the outlet 330 for discharging the fluid to the outside at the rear end of the second end surface reduction portion 310 Output body 300; And
The exhaust gas reducing device, characterized in that provided with the impeller 400 is installed on the main body 200 to induce a rotational collision with the fluid. The method according to claim 1,
The vortex flow passage is in communication with the inlet 112 and expands the flow cross-sectional area of the fluid while providing a direction to the flow and the first spiral passage 130, and the first spiral passage 130 in communication with the fluid flow Exhaust gas reduction device, characterized in that consisting of a second spiral passage 140 in communication with the first section reduction portion 210 of the main body 200 by providing a direction to the flow while reducing the cross-sectional area. The method according to claim 2,
The first spiral passage 130 is formed through the body portion 110 of the input body 100, the second spiral passage 140 is a conical projection 120 protruding from the body portion 110 Exhaust gas reduction apparatus, characterized in that formed along the entire circumference of the outer circumference. The method according to claim 1,
The second cross-sectional reduction portion 310 of the output body 300 is characterized in that the exhaust gas reducing device characterized in that to form a stepped surface of the multi-stage stepped concentrically. The method of claim 4,
The second cross-sectional reduction portion 310 is exhaust gas reducing device, characterized in that to form a plurality of flow guide grooves (312) disposed radially toward the center. The method according to claim 1,
The output body 300 forms a second cross-sectional enlargement portion 320 for enlarging the flow cross-sectional area of the fluid at the rear end of the second cross-sectional reduction portion 310, the atomization of the fluid in the second cross-sectional enlargement portion 320 Exhaust gas reduction device, characterized in that the mesh 340 is installed to facilitate the. The method according to claim 1,
Exhaust gas reduction device further comprises a fixed support (500) installed between the main body (200) and the output body (300) rotatably supporting the impeller (400). The method of claim 7,
The fixed supporter 500 has a boss 510 having a protruding end 520 engaged with the rotational center of the impeller 400, and the impeller 400 has the protruding end 520 at its rotational center. Exhaust gas reduction device, characterized in that for forming an opening (410) for coupling. The method according to claim 8,
The fixed supporter 500 is coupled to a plurality of spokes 530 radially protruding from the outer circumferential surface of the boss 510 and an annular shape coupled to the free ends of the spokes 530 and supported on the inner circumferential surface of the output body 300. The rim 540, and the exhaust gas reducing device characterized in that it comprises a protruding end 550 of the rectangular protruding toward the outlet 330 at the portion facing the protruding end (520).

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