Fuel-efficient and fuel-saving device

Abstract

A fuel-efficient and fuel-saving device is provided and includes a first fuel-modification device, an air-refining device, and a tubing-type fuel-modification device. The first fuel-modification device is arranged in a fuel tank. The air-refining device is arranged under a filter screen of an air filter of an internal combustion engine, and the tubing-type fuel-modification device is arranged above a pipeline between the internal combustion engine and the fuel tank. The first fuel-modification device includes a first metal box body and a plurality of nano far-infrared ceramic particles. The surface of the first metal box body has a plurality of uniformly arranged air holes. The plurality of nano far-infrared ceramic particles is arranged in the first metal box body. The ball diameter of the nano far-infrared ceramic particles is larger than the diameter of the air holes.

Claims

1. A fuel-efficient and fuel-saving device comprising a first fuel-modification device, an air-refining device, and a tubing-type fuel-modification device; wherein the first fuel-modification device is arranged in a fuel tank, the air-refining device is arranged under a filter screen of an air filter of an internal combustion engine, and the tubing-type fuel-modification device is arranged above a pipeline between the internal combustion engine and the fuel tank; and wherein the first fuel-modification device comprises a first metal box body and a first plurality of nano far-infrared ceramic particles; a surface of the first metal box body comprises a first plurality of air holes uniformly arranged on the surface of the first metal box body, the first plurality of nano far-infrared ceramic particles is arranged in the first metal box body, and a ball diameter of each of the first plurality of nano far-infrared ceramic particles is larger than a diameter of each of the first plurality of air holes.

2. The fuel-efficient and fuel-saving device according to claim 1, wherein the air-refining device comprises a second metal box body and a second plurality of nano far-infrared ceramic particles; a surface of the second metal box body comprises a second plurality of air holes uniformly arranged on the surface of the second metal box body, the second plurality of nano far-infrared ceramic particles is arranged in the second metal box body, and a ball diameter of each of the second plurality of nano far-infrared ceramic particles is larger than a diameter of each of the second plurality of air holes.

3. The fuel-efficient and fuel-saving device according to claim 2, wherein the second metal box body is a cylindrical structure, and an upper end and a lower end of the second metal box body are provided with arc chamfers.

4. The fuel-efficient and fuel-saving device according to claim 1, wherein the tubing-type fuel-modification device comprises a metal cylinder body and a second fuel-modification device; a plurality of tubular channels is arranged on an inside of the metal cylinder body, a hollow interface is arranged on two sides of the metal cylinder body, a first end of the hollow interface is in communication with an inlet pipe, and a second end of the hollow interface is in communication with an outlet pipe; slots are arranged in the plurality of tubular channels, elastic buckles are arranged in the slots, and the elastic buckles are internally fixed with the second fuel-modification device.

5. The fuel-efficient and fuel-saving device according to claim 4, wherein a structure of the first fuel-modification device and a structure of the second fuel-modification device are identical.

6. The fuel-efficient and fuel-saving device according to claim 1, wherein a composition of each of the first plurality of nano far-infrared ceramic particles is 90% of kaolin and 10% of a remaining mixture, and a composition of the remaining mixture is 30%-40% of nano-titanium dioxide, 50%-70% of nano-zirconia, and 10%-20% of nano-tourmaline.

7. The fuel-efficient and fuel-saving device according to claim 6, wherein a particle size of each of the nano-titanium dioxide, the nano-zirconia, and the nano-tourmaline particle is 1000-10000 mesh.

8. The fuel-efficient and fuel-saving device according to claim 1, wherein the first metal box body comprises a box body and a box cover; the box cover is covered on the box body, and bottom ends of the box cover and the box body are chamfered.

9. The fuel-efficient and fuel-saving device according to claim 1, wherein the first metal box body is a cuboid structure, and an upper end and a lower end of the first metal box body are provided with arc-shaped grooves.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a front view of a first fuel-modification device of the present invention.

(2) FIG. 2 is a side view of the first fuel-modification device of the present invention.

(3) FIG. 3 is a schematic diagram of a split structure of the first fuel-modification device of the present invention.

(4) FIG. 4 is a schematic diagram of the structure of an air-refining device of the present invention.

(5) FIG. 5 is a cross-section view of the air-refining device of the present invention.

(6) FIG. 6 is a schematic diagram of the structure of the tubing-type fuel-modification device of the present invention.

(7) FIG. 7 is a schematic diagram of the internal mechanisms of the tubing-type fuel-modification device of the present invention.

(8) FIG. 8 is a schematic diagram of the inner structure of the tubular channels in the tubing-type fuel-modification device of the present invention.

(9) In the figures: 1. first fuel-modification device; 2. first metal box body; 201. box cover; 202. box body; 3. second metal box body; 4. metal cylinder body; 401. tubular channels; 402. hollow interface; 403. elastic buckles; 5. nano far-infrared ceramic particles; 6. second fuel-modification device.

DETAILED DESCRIPTION OF THE EMBODIMENTS

(10) The technical solution in the embodiment of the present invention will be clearly and completely described below in conjunction with the attached drawings in the embodiment of the present invention.

(11) In the description of the present invention, it should be noted that the orientation or position relationship indicated by the terms “up,” “down,” “left,” “right,” “level,” “inside,” “outside,” etc., is based on the orientation or position relationship shown in the attached drawings only to describe the present invention and simplify the description, rather than indicating or implying that the device or element indicated must have a specific orientation or be constructed and operated in a specific orientation, and therefore should not be construed as a limitation of the present invention. The terms “first,” “second,” and “third” are only used to describe distinct features and cannot be understood as instructions or indications of relative importance. In addition, unless otherwise noted, the terms “installation,” “connected,” and “linked” should be given the broadest interpretation. For example, it can be a fixed, detachable, or integral connection; a mechanical or an electrical connection; directly or indirectly connected through an intermediary, or a connection between two components. For those skilled in the art, the specific meaning of the above terms in the present invention can be understood based on the specific circumstances.

Embodiment 1

(12) As shown in FIGS. 1-8, the present invention discloses a fuel-efficient and fuel-saving device, which includes a first fuel-modification device 1, an air-refining device, and a tubing-type fuel-modification device. The first fuel-modification device 1 is arranged in a fuel tank. The air-refining device is arranged under a filter screen of an air filter of an internal combustion engine. The tubing-type fuel-modification device is arranged above a pipeline between the internal combustion engine and the fuel tank. The first fuel-modification device 1 includes a first metal box body 2 and a plurality of nano far-infrared ceramic particles 5. The first metal box body 2 is a flat cuboid structure, which is convenient for the first metal box body 2 to be sunk to the bottom of the fuel tank, thereby avoiding the danger caused by hanging the fuel-modification device in the fuel tank. The first metal box body 2 includes a box body 202 and a box cover 201. The bottom ends of the box cover 201 and the box body 202 are chamfered, which saves materials, makes the first fuel-modification device 1 more aesthetically pleasing and avoids collision with the fuel tank. The upper end and the lower end of the first metal box body 2 are provided with arc-shaped grooves. The surface of the first metal box body 2 has a plurality of uniformly arranged air holes. The plurality of nano far-infrared ceramic particles 5 is arranged in the first metal box body 2. The ball diameter of the nano far-infrared ceramic particles 5 is larger than the diameter of the air holes to prevent the nano far-infrared ceramic particles 5 from leaving the first metal box body 2 while the fuel fully contacts with the nano far-infrared ceramic particles 5.

(13) The air-refining device includes a second metal box body 3 and a plurality of nano far-infrared ceramic particles 5. The second metal box body 3 is a cylindrical structure. The upper end and the lower end of the second metal box body 3 are provided with arc chamfers. The surface of the second metal box body 3 has a plurality of uniformly arranged air holes. The nano far-infrared ceramic particles 5 are arranged in the second metal box body 3. The ball diameter of the nano far-infrared ceramic particles 5 is larger than the diameter of the air holes. The air-refining device uses negative nano ions to release the negative charge of the oxygen molecule and thus make the oxygen molecule active, thereby improving the oxygen solubility of fuel molecules, effectively reducing the particles, dust, bacteria, and moisture in the air, and fully stimulating the activity of the air. The air-refining device is installed under the filter screen of the air filter so that the fuel molecules and oxygen can be uniformly mixed to achieve full combustion.

(14) The tubing-type fuel-modification device includes a metal cylinder body 4 and a second fuel-modification device 6. A plurality of tubular channels 401 is arranged on the inside of the metal cylinder body 4. A hollow interface 402 is arranged on both sides of the metal cylinder body 4. One end of the hollow interface 402 is in communication with an inlet pipe, and the other end of the hollow interface 402 is in communication with an outlet pipe. Slots are arranged in the tubular channels 401, and elastic buckles 403 are arranged in the slots. The elastic buckles 403 are internally fixed with the second fuel-modification device 6. The elastic buckle 403 is arranged to facilitate the fixation of the second fuel-modification device 6. The designer may install a different plurality of the second fuel-modification devices 6 according to the customized requirements. Fuel enters from one side of the metal cylinder body 4, goes through the tubular channels 401 in the central part of the metal cylinder body 4, contacts the second fuel-modification device 6, and outputs to a combustion device from the other side of the metal cylinder body 4, thereby increasing combustion efficiency, saving fuel consumption, and increasing the output power. In this embodiment, the structure of the second fuel-modification device 6 is the same as the structure of the first fuel-modification device 1.

(15) Nano far-infrared ceramic particles 5, specifically, the weight ratio of the composition of the nano far-infrared ceramic particles is 90% of kaolin and 10% of the remaining mixture. The weight ratio of the composition of the remaining mixture is 30%-40% of nano-titanium dioxide, 50%-70% of nano-zirconia, and 10%-20% of nano-tourmaline. The particle size of the nano-titanium dioxide, the nano-zirconia, and the nano-tourmaline is independently 1000-10000 mesh. By changing the diameter of nano far-infrared ceramic particles, the contact area between the nano far-infrared ceramic particles 5 and fuel is increased, thereby improving the fuel-saving rate of an internal combustion engine.

(16) In the present invention, the far-infrared rays released by the nano far-infrared ceramic particles 5 can promote the stretch of molecular bonds and vibration of carbon-hydrogen molecules to increase the kinetic energy of the molecular bonds so that the molecular bonds are easier to break into smaller free radicals during combustion. This increases the possibility of fully and evenly mixing with oxygen for combustion and activates and facilitates efficient fuel combustion and reduction of exhaust emissions. At the same time, the special vibration frequencies can make gasoline molecules smaller, disintegrate, and re-organize to improve the activity of molecules, thereby effectively improving the performance of cars, reducing fuel consumption, reducing exhaust emissions, and enhancing the horsepower and torque of cars. Therefore, it is suitable for all kinds of internal combustion engines such as Diesel, Petrol, Bio-Diesel, Ethanol fuel, LPG, and LNG; automobiles, boilers, heating furnaces, heating devices, dryers, thermal processors, or other devices and machines which obtains power or heat through fuel combustion.

(17) The above is only a preferred embodiment of the present invention and does not impose any limitation on the technical scope of the present invention. Therefore, any modification, equivalent change, or modification of the above embodiment based on the technical substance of the present invention still belongs to the scope of the technical solution of the present invention.