JPH11173222A - Fuel modifier - Google Patents

Abstract

PROBLEM TO BE SOLVED: To activate the fuel to increase the combustion efficiency and to reduce the exhaust amount of NOx , CO2 , CO, HC or the like by storing the ceramics which release the near infrared ray or far infrared ray, in a fuel modifier mounted between a fuel tank and an engine. SOLUTION: The inside of a fuel modifier 2 for activating the fuel sent out from a fuel tank is divided into three chambers, and the porous alumina ceramics 6 are stored in the A-chamber. In the B-chamber, respective spherical, triangularly conical and hollow pillar shaped aluminium ceramics 7a-7c are mixedly stored. In the C-chamber, the flat zirconia ceramics 8 is stored. First of all, the fuel from the fuel tank receives the radiation of the near and mid infrared ray in the A-chamber and the impurity is removed. Then the fuel is further mixed, and receives more uniform radiation of the near and mid infrared ray in the B-chamber, and the fuel receives the far infrared ray in the C-chamber to be activated.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fuel reformer, and more particularly, to a fuel reformer having a built-in ceramic which emits near infrared rays or far infrared rays.

[0002]

2. Description of the Related Art When a fuel such as light oil or gasoline is burned in a vehicle such as an automobile, black smoke is emitted and NO
_x , CO ₂ , CO, HC, etc. were emitted, causing air pollution. In order to solve this problem, measures such as improving the ignition timing of an engine of an automobile or the like or improving the injection method in a fuel engine have been taken.

[0003]

However, the improvement of the ignition timing of an engine of an automobile or the like, or the improvement of the fuel injection method into the engine can be applied from a new engine, but has already been used. Application to a vehicle such as an automobile that has been performed means a new replacement of the engine, and cannot be easily performed from the viewpoint of cost. The inventor of the present invention has focused on the fuel itself from the viewpoint of being applicable to vehicles such as automobiles that have already been used, and has conducted intensive research to solve the above problem by reforming the fuel. That is, the improvement of the engine itself can be applied only to a new engine as described above, and cannot be applied to a vehicle (engine) already in use, so that the problem of air pollution can be solved at an early stage. I can't. on the other hand,
If the fuel is reformed, it can be applied directly to vehicles that have already been used, and it is thought that an early solution can be achieved.

In the reforming of fuel, attention has been paid to activation of fuel by near to far infrared rays emitted from ceramics. When the fuel receives near-to-far infrared radiation emitted from the ceramic, the oil molecules of the oil contained in the fuel become
Subdivide. That is, the oil molecules in the fuel are usually formed by assembling several oil molecules. However, when irradiated with near to far infrared rays, the aggregated oil molecules are dispersed in one oil molecule and activated. Then, when the fuel is activated, the state of mixing with the air becomes good and the combustion efficiency increases, and NO _x , C
We focused on the fact that emissions of O ₂ , CO, HC and the like can be reduced.

The present invention has been made to solve the above-mentioned technical problems based on the above-mentioned findings. The present invention has been made to improve combustion efficiency by activating a fuel by ceramics emitting near to far infrared rays. suppresses the emission of black smoke, it is an object to provide a NO _x, CO _2, CO, fuel reformer can reduce emissions such as HC.

[0006]

According to another aspect of the present invention, there is provided a fuel reformer disposed between a fuel tank and an engine, the fuel reformer being provided with a fuel tank. A ceramic which emits any one of near-infrared rays and far-infrared rays is stored in the reformer. Here, it is preferable that a plurality of chambers are formed inside the fuel reformer, and the one chamber contains alumina-based ceramics and the other chamber contains zirconia-based ceramics. Also, a plurality of chambers are formed inside the fuel reformer, and the first chamber contains an alumina-based ceramic,
It is desirable that zirconia-based ceramics be stored in the chamber and layered silicate ceramics be stored in the third chamber. Preferably, the chambers are separated by a metal net for preventing the stored ceramics from moving. Further, it is desirable that the inner surface of the fuel reformer is mirror-finished.

The fuel reformer is divided into three chambers,
A first chamber on the fuel inflow side contains porous alumina-based ceramics, and a second chamber contains spherical alumina-based ceramics, triangular pyramid alumina-based ceramics, and hollow cylindrical alumina-based ceramics in a mixed manner. It is desirable that the third chamber contains a zirconia-based ceramic plate. Preferably, a permanent magnet is housed inside the fuel reformer. Further, a reformer main body in which ceramics are stored and an oil outlet is provided above the center of the main body, a lid having an inclined surface formed on the fuel tank side of the reformer main body, It is desirable to have a connection part detachably attached to the body with a screw and a connection part detachably attached to the oil outlet of the main body.

[0008] In the present invention, by adopting the above configuration, the fuel is activated by the infrared effect radiated by the ceramics in the fuel reformer. By fuel is activated, increases the combustion efficiency mixed state becomes a good air fuel, it is possible to suppress the emission of black smoke, NO _x, CO _2, CO, such as HC Emissions can be reduced, and air pollution can be prevented.

In addition, since different types of alumina-based ceramics and zirconia-based ceramics are accommodated in the fuel reformer, infrared rays having different wavelengths (near to mid-infrared rays to far-infrared rays) are provided.
Is emitted, so that the fuel can be more activated. Further, by mirror-finishing the inner surface of the fuel reformer, it is possible to reflect infrared rays emitted by the ceramics, and to further activate the fuel. And by using layered silicate compound ceramics again,
The fuel can be negatively ionized, and the fuel can be more activated by a synergistic effect of near to far infrared rays. In addition, a metal net is provided for separating the ceramics housed in the fuel reformer, and the movement of the ceramics is prevented.

Further, the fuel reformer is divided into three chambers, a first chamber on the fuel inflow side accommodates a porous alumina-based ceramic, and a second chamber includes a spherical alumina-based ceramic and a triangular ceramic. Alumina ceramics in the form of cones and alumina ceramics in the form of hollow cylinders are mixed and housed in the third chamber, and flat zirconia-based ceramics are housed in the third chamber. Absorbed by fuel. As a result, the fuel is more activated, and the emissions of NO _x , CO ₂ , CO, HC and the like can be further reduced.

Further, since the permanent magnet is housed inside the fuel reformer, the activation can be achieved synergistically by the far infrared rays emitted by the ceramic and the magnetic field of the permanent magnet. The reformer has a lid in which ceramics are stored and an oil outlet is provided above the center of the main body, and the reformer has a slope portion formed on the fuel tank side of the reformer main body. Body and a connection portion detachably attached to the lid by screws, and a connection portion detachably attached to the oil outlet of the main body by screws, so that attachment and detachment can be easily performed. Also, the inside of the reformer can be easily cleaned. Further, since the inclined surface portion is formed on the lid, the fuel can be uniformly diffused into the reformer main body. Further, since the oil outlet is provided above the center of the main body, it is possible to send sufficiently activated fuel to an engine or the like.

[0012]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of a fuel reformer according to the present invention will be described below with reference to the drawings. In FIG. 1, reference numeral 1 denotes a fuel tank, 2 denotes a fuel reformer for activating fuel delivered from the fuel tank 1, and 3 denotes a conventionally used fuel filter. Reference numeral 4 denotes an engine of a vehicle such as an automobile. Reference numeral 5 denotes an oil feed pipe connecting the fuel tank 1, the fuel reformer 2, the fuel filter 3, and the engine 4. Although the fuel reformer 4 is provided between the fuel tank 1 and the fuel filter 3, the fuel reformer 4 may be provided between the fuel tank 1 and the engine 4. , Fuel filter-3 and engine 4
And may be arranged between them.

FIG. 2 is a sectional view of the fuel reformer 2. A bamboo shoot-like connecting portion 2a is formed on the right side of the fuel reformer 2 to be connected to an oil feed pipe 5 from the fuel tank 1. On the left side of the fuel reformer 2, a bamboo shoot-like connecting portion 2a (not shown) connected to the oil feed pipe 5 to the engine 4 is formed. The fuel reformer 2 is divided into three chambers.
A first alumina-based ceramic 6 made of a porous material having a particle size of about 1 to 5 mm is accommodated therein. Room B has a second
Is stored. Specifically, a spherical alumina-based ceramic 7a having a diameter of 10 to 15 mm, an alumina-based ceramic 7b having a triangular pyramid with a side of about 10 mm, a hollow cylinder having a height of 7 to 8 mm, an outer diameter of 4 to 5 mm, and an inner diameter of 1 to 3 mm Ceramics 7
c are mixed and stored. The first alumina-based ceramic 6 and the second alumina-based ceramic 7 emit a large amount of near-infrared infrared rays and mid-infrared rays among infrared rays. Further, a flat zirconia ceramic 8 of about 5 to 10 mm is accommodated in the chamber C. The zirconia ceramics 8 emits far infrared rays out of infrared rays. Between each room, a metal net 9a of 5 mm mesh,
9b, 9c and 9d are provided.

Next, the casing of the fuel reformer 2 will be described. A main body 21a of the fuel reformer 2 having a screw portion 2b to which a bamboo shoot-like connecting portion 2a is attached on both sides is provided. It comprises a lid 21b having a taper portion (inclined surface) to be attached, and a bamboo shoot-like connecting portion 2a attached to the screw portion 2b of the lid 21b and the screw portion 2b of the main body 21a. Thus, the lid 21b
Since the taper portion (inclined surface portion) is formed in the main body, the fuel can be uniformly diffused into the reformer main body. The bamboo shoot-like connecting portion 2a, the lid 21b, and the screw portion 2b of the main body 21a are screwed together, and the main body 21a and the lid 21b are fixed by welding.

The oil outlet 22 formed on the left side of the main body 21a of the fuel reformer 2 is formed above the horizontal center line of the main body 21a. Since the oil outlet 22 is formed in the upper part as described above, sufficiently activated fuel can be sent to an engine or the like. Although not shown, a bamboo shoot-like connecting portion 2a is detachably attached to the left screw portion 2b of the main body 21a. Since the threaded portion 2b of the oil outlet 22 and the oil inlet 23 of the main body is formed and the bamboo child-like connecting portion 2a is detachably attached, it can be easily attached and detached, and the inside of the reformer can be cleaned. It can be done easily. Note that the main body 21a and the lid 21b may be configured to be separable and integrated by screwing.

The members constituting the casing of the fuel reformer 2 are made of stainless steel in consideration of corrosion and the like. Also, among the above members, at least the main body 21a of the fuel reformer 2
The inner surface is mirror-finished so that near to far infrared rays emitted from ceramics can be effectively emitted.

As described above, since the fuel reformer 2 is configured, the fuel in the fuel tank 1 first flows into the bottom of the chamber A from the connection portion 2a. In the chamber A, a porous alumina-based ceramics 6 having a particle size of about 1 to 5 mm is accommodated, so that the inflowing fuel gradually rises due to the capillary action and the oil outlet side 2 of the main body 2a.
Move in two directions. During this movement, it receives near-infrared radiation. Also, a porous alumina-based ceramics 6
Therefore, it also functions as a so-called filter and removes impurities.

The fuel that has passed through the chamber A flows into the chamber B, and receives near-mid infrared radiation. At this time, since the ceramics of different shapes such as sphere, triangular pyramid, and hollow cylinder having a relatively large particle size are mixed in the chamber B, the flow of the fuel is disturbed, and the fuel is further mixed and the fuel is further mixed. Can more uniformly receive near-mid infrared radiation.

Further, the fuel that has received the near-infrared radiation in the room B flows into the room C. In the room C, a zirconia-based ceramic 8 different from the alumina-based ceramic housed in the room A and the room B is housed. Therefore,
The fuel can be irradiated with far infrared rays having a wavelength different from that of the alumina-based ceramics. Thus, by irradiating the fuel with far infrared rays of different wavelengths,
More fuel can be activated.

In the description of the above embodiment, the case where alumina-based ceramics and zirconia-based ceramics are used has been described. However, only alumina-based ceramics or only zirconia-based ceramics may be used. Preferably, alumina-based ceramics and zirconia-based ceramics are used so that infrared rays having different wavelengths can be emitted to the fuel.
Further, by using the layered silicate compound ceramics, the fuel can be negatively ionized, and the fuel can be more activated by a synergistic effect of near to far infrared rays.

Next, a second embodiment will be described with reference to FIGS. Note that the same members as those in the first embodiment are denoted by the same reference numerals in FIGS. This embodiment is characterized in that the fuel is further activated by the permanent magnet by storing the permanent magnet inside the fuel improver. That is, the fuel is synergistically activated by the near to far infrared rays emitted by the ceramic and the magnetic field of the permanent magnet. This permanent magnet 10
Is formed in a disk shape having a through hole 10a at the center as shown in FIG. This permanent magnet 10 can obtain the effect of activation as the magnetic field becomes stronger.
With a permanent magnet of about 00 Gauss, the effect can be sufficiently obtained. Then, as shown in FIG. 4, five or six magnets are stored with the permanent magnet 10 standing. Thus, by putting the permanent magnet in the ceramics, the near-far infrared rays emitted by the ceramics and the magnetic field of the permanent magnets are synergistically activated.

When the fuel reformer thus configured is applied to an automobile, the emission of black smoke is suppressed, the combustion efficiency is increased, and the emissions of NO _x , CO ₂ , CO, HC and the like are reduced. Was found to decrease.

Although the above embodiment has been described by exemplifying an automobile engine, the present invention can be widely applied to a combustion engine, and the present invention is not limited to an automobile. The fuel is not limited to gasoline or light oil, but may be kerosene, heavy oil, or the like. In particular, according to the present invention, used vegetable oil can be used as a vehicle fuel for diesel engines. In this case, it is possible to obtain substantially the same engine output as in the case of using light oil, to eliminate the above-mentioned emission of black smoke, to increase the combustion efficiency, and to increase NO _x , CO ₂ , C
The effect of reducing the emission amount of O, HC, etc. can also be obtained.

[0024]

As described above, according to the present invention, the fuel is activated by the infrared ray effect radiated by the ceramics in the fuel reformer, and as a result, the mixed state of the fuel and the air is improved. increased combustion efficiency, it is possible to suppress the emission of black smoke, NO _x, CO _2, CO, it is possible to reduce emissions such as HC, it is possible to prevent contamination of the atmosphere. Also, different types of alumina ceramics and zirconia ceramics, or alumina ceramics, zirconia ceramics,
By storing the layered silicate compound ceramics,
Since infrared rays having different wavelengths (near to far infrared rays) are radiated, the fuel can be more activated, and the inner surface of the fuel reformer is mirror-finished to reflect the infrared rays emitted by the ceramics. it can, more can revitalize the fuel, it is possible to suppress the emission of black smoke, NO _x, CO _2, CO, can reduce emissions such as HC.

Further, the fuel reformer is divided into three chambers, a first chamber on the fuel inflow side contains a porous alumina-based ceramic, and a second chamber contains a spherical alumina-based ceramic and a triangular ceramic. Alumina ceramics in the form of cones and alumina ceramics in the form of hollow cylinders are mixed and housed in the third chamber, and flat zirconia-based ceramics are housed in the third chamber. Absorbed by fuel. As a result, the fuel is more activated, and the emissions of NO _x , CO ₂ , CO, HC and the like can be further reduced. In addition, since the permanent magnet is housed inside the fuel reformer, activation can be achieved synergistically by far-infrared rays emitted by the ceramics and the magnetic field of the permanent magnet, and more NO _x , CO ₂ , CO,
The emission amount of HC and the like can be further reduced.

The reformer includes a reformer body in which ceramics are stored and an oil outlet is provided above the center of the body, and an inclined surface formed on the fuel tank side of the reformer body. A lid, a connection portion detachably attached to the lid with screws, and a connection portion detachably attached to the oil outlet of the main body with screws, so that attachment / detachment is easily performed. The inside of the reformer can be easily cleaned. Further, since the inclined surface portion is formed on the lid, the fuel can be uniformly diffused into the reformer main body. Further, since the oil outlet is provided above the center of the main body, it is possible to send sufficiently activated fuel to an engine or the like.

[Brief description of the drawings]

FIG. 1 is a conceptual diagram showing an arrangement of a fuel improver according to the present invention.

FIG. 2 is a cross-sectional view showing a cross section of the fuel improver according to the first embodiment of the present invention.

FIG. 3 is a side view of a permanent magnet used in a fuel improver according to a second embodiment of the present invention.

FIG. 4 is a cross-sectional view showing a cross section of a fuel improver according to a second embodiment of the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Fuel tank 2 Fuel reformer 2a Bamboo shoot connection part 2b Screw part 21a Main body 21b Lid 22 Oil outlet 23 Oil inlet 3 Fuel filter 4 Engine 5 Oil feed pipe 6 First alumina ceramics 7 Second alumina ceramics 7a Spherical alumina ceramic 7b Triangular pyramid alumina ceramic 7c Hollow cylindrical alumina ceramic 8 Zirconia ceramic 9a Metal net 9b Metal net 9c Metal net 9d Metal net 10 Permanent magnet 10a Through hole

Claims (8)

[Claims] 1. A fuel reformer disposed between a fuel tank and an engine, wherein a ceramic that emits one of near infrared rays or far infrared rays is housed in the fuel reformer. A fuel reformer. 2. The fuel reformer according to claim 1, wherein a plurality of chambers are formed inside the fuel reformer, and the one chamber contains alumina ceramics and the other chamber contains zirconia ceramics. 2. The fuel reformer according to 1. 3. A plurality of chambers are formed inside the fuel reformer, and the first chamber contains an alumina-based ceramic,
2. The fuel reformer according to claim 1, wherein a zirconia-based ceramic is stored in the chamber, and a layered silicate ceramic is stored in the third chamber. 4. The fuel reformer according to claim 2, wherein the chambers are separated by a metal net for preventing the stored ceramics from moving. 5. The fuel reformer according to claim 1, wherein an inner surface of the fuel reformer is mirror-finished. 6. The fuel reformer is divided into three chambers. A first chamber on the fuel inflow side contains porous alumina-based ceramics, and a second chamber contains spherical alumina-based ceramics and triangular ceramics. 6. A method according to claim 1, wherein a conical alumina-based ceramic and a hollow cylindrical alumina-based ceramic are mixed and stored, and a flat zirconia-based ceramic is stored in the third chamber. A fuel reformer described in 1. 7. The fuel reformer according to claim 1, wherein a permanent magnet is housed inside the fuel reformer. 8. A reformer main body in which ceramics are housed and an oil outlet is provided above the center of the main body, and a lid having an inclined surface formed on the fuel tank side of the reformer main body. And a connection portion detachably attached to the lid by a screw and a connection portion detachably attached to an oil outlet of the main body.
A fuel reformer according to any one of claims 1 to 7.