JP2003328889A - Ceramic used for fuel filter, fuel filter using ceramic, and fuel treating device using ceramic - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide ceramics used for a fuel filter for activating fuel and the like, and improving combustion efficiency, and a fuel treating device using the ceramics. <P>SOLUTION: Ceramic is obtained by mixing a base material, an organic material group, and a mineral group with blend water, and sintering them. Clay is used as the base material, and ceramics X, Y obtained by using the organic material group and the mineral group are mixed with the base material, namely clay, again, and sintered, so as to obtain a ceramic Z. This fuel treating device using the ceramic Z comprises a fuel tank installed to an interference wave generator, and a fuel filter using the ceramic installed to the interference wave generator. The interference wave generator comprises four layers of disc-like plates filled and held with a different ceramic powder. <P>COPYRIGHT: (C)2004,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention is used for a fuel filter for improving the combustion efficiency of gasoline, light oil, etc. used as a fuel for an internal combustion engine such as a gasoline engine, or heavy oil used in a combustion device such as a boiler. The present invention relates to a ceramic, a fuel filter using the ceramic, and a fuel processor using the ceramic.

[0002]

2. Description of the Related Art Heretofore, as a device for refining liquid molecular clusters in order to improve fuel combustion efficiency, a magnetic treatment device is disposed on a flow path, and a fuel consumption improving filter device is known.

A magnetic processing apparatus arranged on the fuel flow path has an N-pole and an S-pole on the inner peripheral surface around a magnetic oil passage tube, as described in, for example, Japanese Patent Application Laid-Open No. 09-143480. This is a device in which two roof tile-shaped permanent magnets each having a pole are opposed to each other in an inner surface attraction relationship and adhered closely to each other, and when fuel oil passes through the device, the oil molecules are miniaturized. .

Further, in the fuel efficiency improving filter device, as described in, for example, Japanese Patent Application Laid-Open No. 07-077115, a filter is formed of a ceramic material that radiates far infrared rays, and this filter is mounted on the fuel line. As a result, the molecular bonds of the passing fuel itself are made fine by far infrared rays, and combustion efficiency is improved.

[0005]

As described above, all of the conventionally used devices are arranged on the flow path through which the fuel passes, and are used as a combustion device such as an internal combustion engine such as a gasoline engine or a boiler. It is constructed as one. Therefore, the shape and configuration of the device are limited, and the device cannot be generally mounted.

In view of the above, the present invention intends to activate a fuel or the like by a device separated from an internal combustion engine such as a gasoline engine or a combustion device such as a boiler, and to improve the combustion efficiency. A fuel filter using the above and a fuel processing apparatus using the ceramic are provided.

[0007]

In order to achieve the above object, the present invention has the following constitution. As a result of various studies, the inventor has obtained an excellent ceramic that improves combustion efficiency, a filter that uses this ceramic, and a fuel processor that uses this ceramic. That is, a filter using the ceramic according to the present invention is a ceramic obtained by mixing a base material, an organic material group, and a mineral group with compounding water and sintering the mixture, and using clay as the base material, the organic material group Using seafood, ceramics X obtained by using iron oxide, silica sand alumina as the mineral group, clay as the base material, vegetables and fruits as the organic group, and iron oxide or aluminum as the mineral group The obtained ceramic Y is further mixed with the above-mentioned ceramics X and Y at a constant ratio together with clay as a base material, and is sintered to obtain a ceramic Z. Seawater is preferably used as the compounding water when mixing the ceramic X, and natural water is preferably used as the compounding water when the ceramic Y is mixed. Further, the ceramic Z has the ceramics X and Y as the first stage of 800-
After sintering at 900 ° C for 2 hours, 1100 as the second stage
˜1200 ° C. for 3 hours to obtain the powder, and then the ceramics X and Y are made into powder and mixed with the base material clay at a constant ratio, and this is burned at 900 to 950 ° C. for 3 hours as the first step. In the second step, it can be obtained by sintering at 1200 ° C. or higher for 7 hours.

A fuel filter using a ceramic according to the present invention is a ceramic obtained by mixing a base material, an organic material group, and a mineral group with compounding water and sintering the mixture. Clay is used as the base material. Ceramics obtained by using seafood as the organic group, iron oxide and silica sand alumina as the mineral group, clay as the base material, vegetables and fruits as the organic group, and iron oxide or aluminum as the mineral group. And a ceramic Y obtained by using the above-mentioned ceramics X and Y are mixed at a constant ratio with clay as a base material, and the resulting ceramics are sintered to fill a tube with a ceramic Z. Is characterized by. And the inner diameter of the tube is 10-15m
It is preferable that m is 1600 to 2000 mm.

A fuel processing device using ceramics according to the present invention comprises a fuel tank mounted on the interference wave generator and a fuel filter using ceramics mounted on the interference wave generator. In each of the generators, four disc-shaped plates for filling and holding the ceramic powder are arranged, and a container filled with the ceramic powder is fixed to the central portion of the lower surface of the disc-shaped plate of the second layer from the top. , The top and bottom disc-shaped plates are filled with the same ceramic, the other disc-shaped plates and the container are respectively filled with different ceramics, and the ceramics filled in the disc-shaped plates are mutually perpendicular to each other. The fuel filter is filled in an overlapping position, and the fuel filter is a ceramic-filled filter. The container filled with the ceramic powder may be a cylindrical container having a height of 20 mm and a radius of 15 mm. Also,
The distance between the uppermost disk-shaped plate and the second disk-shaped plate is 15 to 25 mm, the distance between the second disk-shaped plate and the third disk-shaped plate is 25 to 52 mm, and the third layer It is preferable to set the distance between the disc-shaped plate and the disc-shaped plate of the lowermost layer to 15 to 25 mm, and fix the disc-shaped plates to the columns. The disk-shaped plate has a thickness of 0.5 mm and a radius of 110 mm, and four ceramic filling holes of the same shape having a radius of 25 mm are formed along the peripheral edge portion at equal intervals. It can be formed by closing the bottom surface of the ceramic filling hole with a lower surface sheet, filling ceramics, and then closing with an upper surface sheet.

Conventionally known magnetic processing devices utilize magnetic lines of force and magnetic fields, but magnets have many unusual characteristics.
It may have no magnetic force or may be magnetized very strongly depending on the blending amount of materials such as C and C.

On the other hand, it is well known that all substances are a group of molecules, a molecule is a combination of atoms, and an atom is an aggregate of elementary particles, but the elementary particles vibrate at a specific cycle. It is said to be a repeating element. That is, each substance or object has its own cycle (natural vibration).
There is. However, when gathering as a substance from the state of atoms and molecules, not all atoms and molecules have the same frequency (wave), and some do not.

[0012] Here, in the substance formed by being combined in a state where the frequencies (waves) are matched, the natural vibration originally generated from the atoms is effectively utilized, and the potential energy is sufficiently extracted. However, such a substance in an ideal state rarely actually exists, and many substances are bonded in a state where their natural frequencies (waves) do not match.

Therefore, assuming that it is possible to create a substance in an ideal state in which the frequencies (waves) resonate by combining existing substances, as in the case of a magnet, the results of repeated intensive research and research A ceramic used for a fuel filter for improving fuel combustion efficiency, a fuel filter using the ceramic, and a fuel processing device using the ceramic can be obtained.

Further, in the fuel processed by the processing apparatus according to the present invention, the molecular clusters of the liquid are extremely finely divided, and a fuel which has a chemical reaction close to ideal is obtained.
It is possible to use these fuels as they are,
It is also possible to use it as an additive by mixing it in a small amount with a normal fuel.

The reason why the fuel treated by this treatment device is used as an additive is also effective for the following reason. That is, since the ceramic according to the present invention is manufactured by setting the sintering conditions so as to approach the ideal state, the amplitude of the composite wave is strengthened by the influence of the crustal wave (silicon wave in the ground). For example, if a magnet is placed in iron scrap and all the iron scrap is magnetized, it is governed by the law of being susceptible to substances of higher energy rank, regardless of the substance.

Therefore, since the fuel processed by the processing apparatus using this ceramic is extremely activated, the whole fuel is activated when it is added to the inactive fuel. As a result, a fuel having an improved combustion efficiency can be obtained by simply mixing a small amount of an additive with a normal fuel.

[0017]

BEST MODE FOR CARRYING OUT THE INVENTION First, a fuel processing apparatus using a ceramic according to the present invention will be described. A fuel processing device using ceramics includes an interference wave generator 10 on which a fuel tank 1 is placed, an interference wave generator 10A on which a ceramic filter 2 is placed, and an interference wave generator 10B on which a fuel tank 1A is placed. Consists of. The interference wave generator 10
10B are mounted and fixed on the gantry 11. Since the interference wave generators 10 to 10B have the same structure, only the interference wave generator 10 will be described, and the description of the interference wave generators 10A and 10B will be omitted.

In the interference wave generator 10, as shown in FIGS. 1 and 2, disk-shaped plates 12 to 15 for filling and holding ceramic powder are attached to a nut 17 screwed to a column 16 having a screw thread on the outer peripheral surface. The disk-shaped plate 13 is supported at appropriate intervals via washers 18, and a container 19 filled with ceramic powder is fixed to the approximate center of the lower surface of the disk-shaped plate 13.
Although the disk-shaped plates 12 to 15 are filled with different ceramic powders, respectively, as will be described later, they have the same structure for filling the ceramic powders. Therefore, the disk-shaped plate 12 will be described, and the description of the other plates will be omitted.

Based on FIGS. 3 to 6, the disk-shaped plate 1
2 is a ceramic filling hole 2 of the same shape along the periphery.
Four holes 0, 20 are provided at equal intervals, and the holes 20,
It is formed by closing the bottom surface of 20 with a bottom sheet 21, filling ceramic powder, and then closing with a top sheet 22. Disc-shaped plate 12 of the illustrated embodiment
Has a thickness t of about 0.5 mm, a radius R of about 110 mm, a dimension from the center of the disk-shaped plate to the centers of the holes 20, 20 of about 65 mm, and a radius r of the hole 20 of about 25 mm.

Further, on the periphery of the disk-shaped plate 12,
A column hole 23 for inserting the column 16 is formed between the holes 20, 20. The support 16 is inserted into the support hole 23 and is fixed by tightening the nut 17 that is screwed. A cylindrical container 19 containing a ceramic is fixed to the central portion of the lower surface of the disk-shaped plate 13. The container has a height of about 20 mm and a radius of about 15 mm.

When the distance between the disk-shaped plate 12 and the disk-shaped plate 13 is 15 to 25 mm, the disk-shaped plate 1
3 and the disk-shaped plate 14 are fixed to the support 16 so that the distance between the disk-shaped plate 14 and the disk-shaped plate 15 is 15 to 25 mm, and the distance between the disk-shaped plate 14 and the disk-shaped plate 14 is 25 to 52 mm. Holes 2 in the disk-shaped plates 12 to 15 having the above structure
0s are arranged so as to overlap each other in the vertical direction. The interference wave generators 10 to 10B are configured as described above.

In the disk-shaped plates 12 to 15, four ceramic filling holes 20 are formed at equal intervals, but the number of the holes 20 is not particularly limited, and a plurality of holes 20 can be formed. The shape is not limited, either. Alternatively, the holes 20 may be connected to form a single ring. Further, the container 19 is a container that can be filled with a large amount of ceramic, and the shape of the container is not limited to a circular container, and can be any shape.

In the interference wave generators 10 to 10B having the above structure, the container 19 and the disk-shaped plates 12 to 15 are
Different ceramic powders are used. For example, as described later, ceramic A is used for the container 19, ceramic B is used for the disk-shaped plates 12 and 15, ceramic C is used for the disk-shaped plate 13, and ceramic is used for the disk-shaped plate 14. D is used. As described above, the different ceramics A to D are arranged for the purpose of changing the wave and amplifying and strengthening the composite wave of the ceramic A of the container 19 arranged at the center. If you dare to shift the wavelength or the cycle, Ceramic A
The resulting composite wave is more influential than the ceramic itself.

Next, the ceramic filter 2 mounted on the interference wave generator 10A will be described. The ceramic filter 2 is made by filling a synthetic resin tube 30 having fuel oil resistance with ceramic powder. Tube 3
The reason why 0 is used is to prolong the contact time with the ceramic. In the illustrated embodiment, the inner diameter of the tube 30 is 10-15 mm, preferably 12 mm, and the tube length is 1600-2000 mm, preferably 180.
It is 0 mm. The ceramic filter 2 is formed by filling the tube 30 with ceramic and winding it in a spiral shape.

The ceramic powder used in the above structure is formed as follows. That is, the ceramic used in the fuel processing apparatus according to the present invention is formed by mixing the base material clay with auxiliary materials such as organic matter, minerals, and compounding water and sintering the mixture at a constant temperature. It forms two types of ceramics. Ceramics X were those in which seafood was used as an organic material as a supplementary material, and ceramics Y were those in which plants were used as an organic matter as an auxiliary material.

Next, the above-mentioned two types of ceramics are further mixed at a fixed ratio with clay as a base material and sintered. Ceramics A to D were obtained by changing the mixing ratio of the two types of ceramics.

The reason why the two kinds of ceramics are mixed is that a ceramic having a sufficient effect cannot be obtained by firing once. The combination of ceramics that gives the highest effect was selected as follows. First,
For the ceramic X, seafood was used as an organic substance. I used seafood because I ingested enough minerals in the sea,
Since it exists under the influence of crustal waves (silicon waves in the ground), it controls the molecular arrangement of silicon compounds in the base metal by combining with minerals, which are one of the constituent elements of the crust, and as a result, This is because it is expected that resonance with waves (silicon waves in the ground) will be achieved.

On the other hand, for the ceramic Y, plants were used as organic substances. Plants also grow by absorbing nutrients and minerals in the ground, and like seafood, by combining with minerals, which are one of the constituent elements of the crust, the molecular arrangement of silicon compounds in the base material is controlled, As a result, it is expected that resonance with the crustal wave (silicon wave in the ground) may be achieved.

Table 1 shows an example of the composition of the ceramic X.

[0030]

[Table 1]

Table 2 shows an example of compounding the ceramic Y.

[0032]

[Table 2]

The materials shown in Tables 1 and 2 were all powdered and blended. The size of the powder is 50 to 200 μm
Is. The water content of seawater used for Ceramic X is 15
0 to 400 ml, preferably 240 ml, and the water content of the natural water used for the ceramic Y is 70 to 150 ml,
The volume is preferably 89 ml. This is because if the water content is too small, it will be difficult to mix, and if the water content is too large, sintering will be difficult.

The relative effect when the water content is gradually increased is shown in the table and graph as follows. The ceramic X is shown in Table 3 and FIG. 7, and the ceramic Y is shown in Table 4 and FIG. Here, the relative effect is the degree of decrease in the effect due to the increase or decrease of the water content when the water content that gives the optimum ceramic in water content is 100, and the numbers indicate relative values.

[0035]

[Table 3]

[0036]

[Table 4]

The compounded material is formed into microspheres of about 20 g so that heat can penetrate to the inside and is sintered. As for sintering, both ceramic X and ceramic Y are sintered at two temperatures. First, in the first stage, after baking at 800 to 900 ° C., preferably 830 to 840 ° C. for 2 hours, in the second stage, 1100 to 1200 ° C., preferably 1150.
Sinter at ~ 1170 ° C for 3 hours. Cool after sintering.

If the sintering temperature is lower than 800 ° C. in the first stage, the effect as unglazed is small, the bonding force after sintering is incomplete, and cracks may occur during the second stage sintering.
Also, at 900 ° C. or higher, cracking may occur at the stage of unglazed baking. On the other hand, if the sintering temperature is lower than 1100 ° C. in the second stage, the mixed material material is not completely sintered and the effect as a ceramic tends to vary. Also, at 1200 ° C. or higher, carbonization occurs and the inside becomes too porous.

By the second-stage sintering, the molecular arrangement of the silicon compound in the ceramic base material once becomes free, and the wave of the mixed auxiliary material and the wave of the base material are synthesized. By cooling in that state, the wave is fixed inside the ceramic. If the blending amount and combination of the base material and the auxiliary material do not match, the synthesized wave will be fixed without matching well.

The degree of activation of the fuel, in which the ceramic obtained as described above improves the combustion efficiency, was measured. To measure the effect here, first, by using the above-mentioned ceramics X and Y as the ceramics of the ceramic filter 2 shown in FIG. 1 and passing the fuel, the fuel consumption and the vehicle speed feeling of the vehicle when the treated fuel is used as the fuel , Is a comprehensive judgment of changes in the tone. In the effects shown in Tables 1 and 2, a high fuel efficiency improvement rate of around 5%, a slightly high fuel efficiency improvement rate of around 10%, a slight fuel efficiency improvement rate of around 5%, a low fuel efficiency improvement rate of 3% or less, none Indicates a fuel efficiency improvement rate of 0%.

As described above, in the examples, both the ceramics X and Y showed an improvement in fuel consumption of about 10%.
Therefore, the above ceramics can be used for fuel filters. Further, a ceramic Z was obtained as a new ceramic in which the ratio of the ceramics X and Y was changed based on the assumption that a higher effect could be obtained by mixing the ceramics X and Y. The new ceramic Z is obtained by combining clay as a base material with a mixing ratio of ceramics X and Y, and the mixing ratio of ceramics X and Y is as shown in Table 5.

[0042]

[Table 5]

Ceramic Z is composed of 10 ceramics X and Y.
It is crushed to a particle size of 0 to 200 g, and at the ratio shown in Table 5, 16
After mixing while adding 0 to 170 ml of distilled water, 20
Make a spherical shape of about g. This is sintered at two stages of temperature.
In the first stage, 850 to 950 ° C, preferably 920 ° C
For 3 hours, and in the second step, 1200 ° C. or higher, preferably 1280 ° C. for 7 hours. The reason why the sintering temperature is higher than that of the ceramics X and Y is that the molecular arrangement of the silicon compound in the ceramics X and Y mixed in the base material is reset (set to a free state) again. Otherwise, the whole of the base material and the ceramics X and Y do not resonate well.

The degree of activation of the fuel, which improves the combustion efficiency, was measured as the effect of the ceramic obtained by the above mixing ratio. To measure the effect here, first, by using the ceramic Z as the ceramic of the ceramic filter 2 shown in FIG. 1 and passing the fuel, the fuel consumption, the vehicle speed feeling of the vehicle, and the change in the condition when used as the fuel are comprehensively measured. It was decided on a positive basis.

As shown in Table 5, these effects relatively show how much the ceramic X is improved when the ceramic X is 50. Judging that the fuel economy improvement rate is around 10% and the acceleration feeling is slightly higher, the fuel economy improvement rate is around 15%.
A high fuel efficiency improvement rate of around 20% means a high fuel efficiency improvement rate of around 20%.
% Or more, it was rated as the highest with a significant improvement in acceleration feeling.

As described above, the ceramics of Examples 7 to 10 in the ceramic Z showed a high fuel activating effect, and an extremely high quality fuel was obtained for use as a fuel. However, the inventor has found that Examples 7-10
As a result of various studies from the assumption that resonance with the crustal wave (gravitational field) can be obtained by combining the ceramics of, and more activated fuel can be obtained,
The fuel processor shown in FIG. 1 was obtained.

In the fuel processor of FIG. 1, as described above, the disc-shaped plates 12 to 15 of the interference wave generator are filled with different ceramics. That is, Example 7 is used as ceramic C, Example 8 is used as ceramic B, Example 9 is used as ceramic A, and Example 10 is used as ceramic D. These are crushed to a size of 5 to 10 mm and filled. In the interference wave generators 10 to 10B having the above configuration,
The container 19 is filled with ceramic A, and the disk-shaped plate 1
2 and 15 are filled with ceramic B, and the disc-shaped plate 1
3 is filled with ceramic C, the disk-shaped plate 14 is filled with ceramic D, and the filter 2 is filled with ceramic A.

The method of using the fuel processor shown in FIG. 1 will be described. The fuel tank 1 is placed on the interference wave generator 10, and the fuel tank 1 is filled with fuel. The fuel sucked by the pump 25 from the fuel tank 1 is poured into the ceramic filter 2. The fuel passes between the ceramics A in the ceramic filter 2 to atomize the liquid molecular clusters. The fuel stored in the fuel tank 1A is further affected by the interference wave generator 10B.

By arranging the different ceramics A to D on the respective disc-shaped plates in this way, the wave of the ceramic A arranged at the center is amplified and strengthened, and the resultant composite wave is a single ceramic. Will be more influential than. The fuel in the fuel tank 1A is returned to the fuel tack 1 again and passed through the filter 2. It is preferable to repeat these steps multiple times. As a result, as the fuel, a highly efficient combustion fuel was obtained in which liquid molecular clusters were miniaturized.

However, since it is excellent as a fuel but actually expensive, it is disadvantageous in terms of economy to use it as it is as a fuel. Therefore, a small amount of the above-mentioned activated fuel obtained by using the interference wave generator was mixed with normal fuel, and a running test was conducted using an actual vehicle when used as an additive, and a sufficient fuel activation effect was obtained. It was It is considered that the conventional non-activated fuel is also activated by mixing the activated fuel based on the law that the substance is influenced by the substance having higher energy rank.

The test results are as follows. The result is that the test car has a 50 liter fuel tank filled with regular gasoline and 20 ml of activated fuel added. The test vehicle is run in normal operation, and when 80% or more is consumed, the fuel is fully filled and 20 ml of activated fuel is added. The results obtained by repeating this 5 times are shown in Tables 7 and 8. Table 7 shows the results for the general passenger car sedan type (1000 to 3000cc), and Table 8 shows the results for the general passenger vehicle wagon type (1000 to 3000c).
This is the result of c).

[0052]

[Table 6]

[0053]

[Table 7]

Next, the combustion efficiency was checked by exhaust gas inspection to determine CO
It was investigated from the contents of (carbon monoxide) and HC (hydrocarbon). This means that the higher the degree of complete combustion, the more CO
Since the contents of (carbon monoxide) and HC (hydrocarbon) are reduced, it was investigated how much CO (carbon monoxide) and HC (hydrocarbon) were reduced. Similar to the above fuel activation effect test, an inspection was carried out in the case where a 50-liter fuel tank was filled with regular gasoline and 20 ml of activated fuel was added. "Toudi" (660cc, Honda 1993 model) in the vehicle
It was used. The inspection results are shown in Table 8.

[0055]

[Table 8]

The exhaust gas measurement shown in Table 8 above was carried out by requesting NTT-ME signaling Wakamatsu Service Center Co., Ltd., and the component analysis was carried out by requesting Tiger Motor Co., Ltd. From this result, CO
Is 1.25 to 0.00, and HC is 181 ppm
It turns out that it is 52 ppm, and the combustion efficiency is extremely high, close to complete combustion.

[0057]

INDUSTRIAL APPLICABILITY The ceramic used in the fuel filter according to the present invention is made of finely divided molecular clusters such as gasoline and light oil used as fuel for internal combustion engines such as gasoline engines, or heavy oil used in combustion devices such as boilers. Can be converted. In addition, the fuel filter using the ceramic according to this waiting niece can obtain the fuel that improves the combustion efficiency by efficiently filtering. Further, the fuel processing device using the ceramic according to the present invention can amplify and strengthen the composite wave of the ceramic, and can increase the influence of the ceramic.
Further, since the structure is simple, it can be easily used without taking up a place for installation.

[Brief description of drawings]

FIG. 1 is a front view showing the entire fuel processing apparatus.

FIG. 2 is an exploded perspective view of an interference wave generator.

FIG. 3 is a plan view of a disc-shaped plate.

FIG. 4 is a sectional view of a disc-shaped plate.

FIG. 5 is a plan view of a disc-shaped plate before ceramic filling.

FIG. 6 is a sectional view of a disk-shaped plate to which a container is fixed.

FIG. 7 is a graph showing the relative effect of water content in Table 3.

FIG. 8 is a graph showing the relative effect of water content in Table 4.

[Explanation of symbols]

1,1A: Fuel tank 2: Ceramic filter 10, 10A, 10B: Interference wave generator 12 to 15: disk-shaped plate 16: Support 17: Nut 18: Washer 19: Container 20: Ceramic filling hole 21: Bottom sheet 22: Top sheet 23: Hole for support 30: tube

[Procedure amendment]

[Submission date] May 16, 2002 (2002.5.1)
6)

[Procedure Amendment 1]

[Document name to be amended] Statement

[Name of item to be corrected] 0032

[Correction method] Change

[Correction content]

[0032]

[Table 2]

[Procedure Amendment 2]

[Document name to be amended] Statement

[Correction target item name] 0040

[Correction method] Change

[Correction content]

The degree of activation of the fuel, in which the ceramic obtained as described above improves the combustion efficiency, was measured. To measure the effect here, first, by using the above-mentioned ceramics X and Y as the ceramics of the ceramic filter 2 shown in FIG. 1 and passing the fuel, the fuel consumption and the vehicle speed feeling of the vehicle when the treated fuel is used as the fuel. , Is a comprehensive judgment of changes in the tone. In the effects shown in Tables 1 and 2, a high fuel efficiency improvement rate of around 15% , a slightly high fuel efficiency improvement rate of around 10%, a slight fuel efficiency improvement rate of around 5%, a low fuel efficiency improvement rate of 3% or less, none Indicates a fuel efficiency improvement rate of 0%.

[Procedure 3]

[Document name to be amended] Statement

[Correction target item name] 0041

[Correction method] Change

[Correction content]

As described above, in the examples, both the ceramics X and Y showed an improvement in fuel consumption of about 15% .
Therefore, the above ceramics can be used for fuel filters. Further, a ceramic Z was obtained as a new ceramic in which the ratio of the ceramics X and Y was changed based on the assumption that a higher effect could be obtained by mixing the ceramics X and Y. The new ceramic Z is obtained by combining clay as a base material with a mixing ratio of ceramics X and Y, and the mixing ratio of ceramics X and Y is as shown in Table 5.

[Procedure amendment 4]

[Document name to be amended] Statement

[Correction target item name] 0043

[Correction method] Change

[Correction content]

Ceramic Z is composed of 10 ceramics X and Y.
It was crushed to a particle size of 0 to 200 μm and
After mixing while adding 60 to 170 ml of distilled water, 2
Make a spherical shape of about 0 g. This is sintered at two stages of temperature. In the first stage, 850 to 950 ° C, preferably 92
Sintering at 0 ° C for 3 hours, 1200 ° C or higher in the second stage,
Sintering is preferably performed at 1280 ° C. for 7 hours. The reason why the sintering temperature is higher than that of the ceramics X and Y is that the molecular arrangement of the silicon compound in the ceramics X and Y mixed in the base material is reset (set to a free state) again. Otherwise, the whole of the base material and the ceramics X and Y do not resonate well.

[Procedure Amendment 5]

[Document name to be amended] Statement

[Correction target item name] 0046

[Correction method] Change

[Correction content]

As described above, the ceramics of Examples 7 to 10 in the ceramic Z showed a high fuel activating effect, and an extremely high quality fuel was obtained for use as a fuel. However, the inventor has found that Examples 7-10
Crustal wave (earth
1) was obtained as a result of various studies conducted on the assumption that a more activated fuel could be obtained.

[Procedure correction 6]

[Document name to be amended] Statement

[Correction target item name] 0056

[Correction method] Change

[Correction content]

The measurement of the exhaust gas shown in Table 8 was carried out by requesting NTT-ME Fukushima Co., Ltd. and Aizu-Wakamatsu Branch , and the component analysis was carried out by requesting Tiger Motor Co., Ltd. . From this result, CO is 1.
From 25% to 0.00% , HC from 181 ppm to 52 ppm, and it can be seen that the combustion efficiency is extremely high, close to complete combustion.

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Claims (11)

[Claims] 1. A ceramic obtained by mixing a base material, an organic matter group, and a mineral group with compounding water and sintering the mixture, wherein clay is used as the base material, seafood is used as the organic matter group, and the mineral group is used. Further, ceramic X obtained by using iron oxide and silica sand alumina, and ceramic Y obtained by using clay as a base material, vegetables and fruits as an organic matter group, and iron oxide or aluminum as a mineral group are further added. A ceramic used for a fuel filter, which is ceramic Z obtained by mixing the ceramics X and Y together with a clay as a base material in a predetermined ratio and sintering the mixture. 2. The fuel filter according to claim 1, wherein seawater is used as the compounding water when the ceramic X is mixed, and natural water is used as the compounding water when the ceramic Y is mixed. Ceramic to use. 3. Ceramics X and Y are used as the first stage of 8
After sintering at 00-900 ° C for 2 hours, 1 as the second stage
After sintering at 100 to 1200 ° C. for 3 hours, the ceramics X and Y are made into powder and mixed with the clay as a base material at a constant ratio, and this is used as the first step at 900 to 950 ° C. for 3 hours.
The ceramic for use in a fuel filter according to claim 1 or 2, which is ceramic Z obtained by performing time sintering and sintering as a second stage at 1200 ° C or higher for 7 hours. 4. A ceramic obtained by mixing a base material, an organic matter group, and a mineral group with compounding water and sintering the mixture, wherein clay is used as the base material, seafood is used as the organic matter group, and the mineral group is used. Further, ceramic X obtained by using iron oxide and silica sand alumina, and ceramic Y obtained by using clay as a base material, vegetables and fruits as an organic matter group, and iron oxide or aluminum as a mineral group are further added. A filter for fuel using a ceramic, characterized in that the ceramics X and Y are mixed at a constant ratio with clay as a base material, and a ceramic Z obtained by sintering the mixture is filled in a tube. . 5. The fuel filter according to claim 4, wherein the inner diameter of the tube is 10 to 15 mm and the length is 1600 to 2000 mm. 6. A fuel tank mounted on the interfering wave generator, and a fuel filter using ceramic mounted on the interfering wave generator. Each of the interfering wave generators is filled and held with ceramic powder. 4 disk-shaped plates
Containers filled with ceramic powder are fixed to the center of the lower surface of the second-layer disk-shaped plates from the top, and the same ceramics are packed in the uppermost and lowermost disk-shaped plates. However, the other disk-shaped plates and the container are respectively filled with different ceramics, the ceramics packed in the disk-shaped plates are filled in positions where they overlap each other in the vertical direction, and the fuel filter is a ceramic-filled filter. A fuel processing device using ceramics. 7. The fuel processor according to claim 6, wherein the container filled with the ceramic powder is a cylindrical container having a height of 20 mm and a radius of 15 mm. 8. The distance between the uppermost disc-shaped plate and the second-layer disc-shaped plate is 15 to 25 mm, and the distance between the second-layer disc-shaped plate and the third-layer disc-shaped plate is 25.
The ceramic according to claim 6 or 7, characterized in that the distance between the disc-shaped plate of the third layer and the disc-shaped plate of the lowermost layer is 15 to 25 mm, and each is fixed to a column. Fuel processing device using. 9. The disk-shaped plate has a thickness of 0.5 mm,
A ceramic filling hole having a radius of 110 mm and a radius of 25 mm is formed along the peripheral edge at equal intervals, and the bottom surface of the ceramic filling hole is closed by a lower surface sheet. The fuel processing device using ceramics according to claim 6 or 7, wherein the fuel processing device is formed by filling the ceramics and then closing the top surface sheet. 10. A container filled with ceramic powder is a cylindrical container having a height of 20 mm and a radius of 15 mm, and the distance between the uppermost disk-shaped plate and the second disk-shaped plate is 15 to 25 mm. And the distance between the second layer disk-shaped plate and the third layer disk-shaped plate is 25 to 52 mm.
The ceramic plate according to claim 6 or 7, wherein the third layer disc-shaped plate and the lowermost layer disc-shaped plate have an interval of 15 to 25 mm and are fixed to columns. Had a fuel processor. 11. A container filled with ceramic powder is a cylindrical container having a height of 20 mm and a radius of 15 mm, and the distance between the uppermost disc-shaped plate and the second disc-shaped plate is 15 to 25 mm. And the distance between the second layer disk-shaped plate and the third layer disk-shaped plate is 25 to 52 mm.
And the distance between the disk-shaped plate of the third layer and the disk-shaped plate of the lowermost layer is 15 to 25 mm, and the disk-shaped plate is
The ceramic filling hole has a thickness of 0.5 mm and a radius of 110 mm, and four ceramic filling holes of the same shape having a radius of 25 mm are formed along the peripheral edge portion at equal intervals. The fuel processing apparatus using ceramics according to claim 6 or 7, wherein the bottom surface is closed by a bottom sheet, the ceramic is filled, and then the top sheet is closed.