TWM584835U - Permanent magnet device for promoting natural gas combustion - Google Patents

Abstract

A permanent magnet device for promoting the combustion of natural gas includes a tube-type permanent magnet device having an adjacent near-tube magnet, a far-tube magnet and a first hollow cylinder formed by the near-tube magnet and the far-tube magnet. Space, the first hollow cylindrical space is used to pass a supply pipe of a natural gas application device. The tubular permanent magnet device forms a first magnetic field line. When the natural gas reaches the first interface, the blocking effect of the empty area is generated due to the effect of the first magnetic field line, which accelerates the oscillation and stirring of the coarser fuel particles in the natural gas, so that This fuel particle is broken into fine particles by shaking. This creation can miniaturize the fuel molecules in natural gas to enhance the combustion reaction, and greatly improve the combustion efficiency of natural gas application devices.

Description

Permanent magnet device for promoting natural gas combustion

This creation relates to a technical field for promoting the combustion of natural gas, and more particularly to a permanent magnet device for promoting the combustion of natural gas.

Liquefied natural gas is a mixture of propane and butane precipitated during crude oil refining or natural gas processing. It is a gas at normal temperature and pressure and can be liquefied by being pressurized or cooled. Usually, it is pressurized and packed into a steel cylinder for users. It is also called liquefied gas or barrel gas. When natural gas is completely burned, it produces non-toxic carbon dioxide, and when it is not completely burned, it will produce toxic carbon monoxide to cause environmental pollution.

In order to reduce the CO and CH hydrocarbons during natural gas combustion, the best solution is to increase the combustion rate of gas. There are two existing technologies for increasing the combustion rate of gas, which can make the gas molecules of the fuel more active. One is the ｢magnetic excitation type｣, which uses the magnetism's magnetism to act on gas molecules and makes the LNG molecule activity more active through the magnetic lines of force, thereby improving the combustion efficiency. The above-mentioned technology has the following disadvantages. The magnetic field lines can only make the gas molecules more active, and cannot split the gas molecules to be smaller. Therefore, the effect is limited, and a large-volume magnet pole must be used to achieve the effect. The other is ｢far-infrared excitation type. In order to improve the above-mentioned magnet type, the effect is not good. Ceramics with far-infrared rays are used. Far-infrared rays activate gas molecules to increase the combustion rate. Although far-infrared rays have a better effect than magnets, their effects will diminish over time and their service life is limited. Generally, artificially produced far-infrared rays materials can only last about half a year, while natural far-infrared rays materials have a long life but are extremely costly, which is disadvantageous for commercialization. In addition, some ceramics with far-infrared rays need to be heated to emit far-infrared rays. This heating method requires electricity, which increases the disadvantages of electricity and oil consumption.

The purpose of this creation is to provide a permanent magnet device that promotes the combustion of natural gas. This creation uses the energy waves generated by the high-frequency oscillation of the permanent magnet device to break the molecular bonds of the natural gas fuel particle clusters and make the large molecular clusters present. Small molecules are then released into positively charged ions, so this creation can miniaturize fuel molecules and dissociate into positively charged ions to increase the combustion reaction with the negatively charged electrons of the ignition device, which can accelerate the ignition and promote the combustion effect.

In order to achieve the above object, the present invention provides a permanent magnet device for promoting the combustion of natural gas. The permanent magnet device includes a tube-type permanent magnet device having a near-round tube magnet, a far-round tube magnet, and a near-round tube magnet and the far-round tube magnet. The first hollow cylindrical space formed is used to pass the supply pipe of a natural gas application device, wherein the natural gas application device may be at least one of a gas furnace, a water heater, or a gas car, But it is not limited to this.

The near-circular-tube magnet has a near-N pole and a near-S-pole, and the near-N pole is close to the natural gas application device. The far-round-tube magnet has a far-N pole and a far-S pole, and the far-N pole is close to the near-S pole. Extremely connected.

The tube-type permanent magnet device forms a first magnetic field line, which is emitted by the near N pole and enters the far S pole through the outside world, and then passes through the far N pole and then enters the near S pole through the outside world. When the natural gas in the supply pipe reaches the When the first interface between the far N pole and the near S pole is caused by the action of the first magnetic field line, the blocking effect of the empty zone is accelerated, and the oscillating stirring of the coarser fuel particles in the natural gas is accelerated, so that the fuel particles are Oscillation splits into tiny particles to promote the combustion efficiency of natural gas applications.

Compared with the known products, this creation has the following advantages:

1. The magnet used in this creation is a rare earth permanent magnet neodymium iron boron or a rare earth permanent magnet samarium cobalt, which has higher Gauss, coercive force and frequency resonance efficiency of the catalyst.

2. The permanent magnet device of this creation can split the gas particles into small molecules, so that the combustible aerosol can be fully mixed with the air, improve the combination ratio of the fuel particles and the oxygen molecules, and make the fuel more fully and quickly burn. , Improve the combustion effect, increase the combustion power of natural gas applications, reduce the emissions of CO and CH hydrocarbons, and reduce energy consumption.

Example 1:

FIG. 1 to FIG. 4 show the appearance of the permanent magnet device for promoting the combustion of natural gas according to the first embodiment of the present invention. Figure 1 is a diagram of an application example of a permanent magnet device that promotes the combustion of natural gas. A supply pipe 2 is connected to the natural gas application device 4 to supply natural gas (gas) to the natural gas application device 4, wherein the natural gas application device 4 may be at least one of a gas furnace, a water heater, or a gas car, but it is not actually This is limited. The natural gas application device 4 has a set of ignition devices 8, and a tube-type permanent magnet device 10 is disposed outside the tube wall 6 of the supply tube 2.

FIG. 2 is a schematic diagram of Embodiment 1 of a creative permanent magnet device. The tubular permanent magnet device 10 has a near-round tube magnet 12, a far-round tube magnet 14, and a first hollow cylindrical space 16 formed by a combination of the near-round tube magnet 12 and the far-round tube magnet 14. The first hollow cylindrical space 16 is used to pass the supply pipe 2 of the natural gas application device 4.

The near-tube magnet 12 has a near-N pole 122 and a near-S pole 124, and the near-N pole 122 is close to the natural gas application device 4. The far tube magnet 14 has a far N pole 142 and a far S pole 144, and the far N pole 142 is connected to the near S pole 124. A first interface 18 is formed between the near-tube magnet 12 and the far-tube magnet 14.

FIG. 3 is a magnetic field line diagram formed by the tube type permanent magnet device of Embodiment 1 of FIG. 2. The first magnetic field line 50 is emitted by the near N pole 122 of the near-tube magnet 12 and enters the far S pole 144 through the outside, and then passes through the far tube magnet 14 to the far N pole 142 and then enters the near S pole 124 through the outside.

FIG. 4 is a schematic diagram of the formation of positively-charged fuel ions by the original fuel particle. When the fuel gas particles 20 with relatively thick natural gas in the supply pipe 2 pass through the first magnetic field lines 50 formed by the tubular permanent magnet device 10, the fuel particles 20 will be slightly magnetized near the S pole 124 first. When the fuel particles 20 reach the first junction 18 between the far N pole 142 and the near S pole 124, the blocking effect of the empty area is caused by the action of the first magnetic field lines 50, which accelerates the vibrational stirring of the fuel particles 20 and makes the fuel The particles 20 are split into minute particles 30 by oscillation. Then, when the minute particles 30 subjected to the vibrational stirring reach the near-N pole 122, positively-charged fuel ions 32 are formed. Finally, when the positively charged fuel ions 32 meet the negatively charged electrons 34 generated by the ignition device 8 in the natural gas application device 4, the ignition can be accelerated to promote the combustion effect.

Example 2:

FIG. 5 is a schematic diagram of a permanent magnet device for promoting natural gas combustion according to the second embodiment of the invention. The four-magnet permanent magnet device 60 has an adjacent upper left semicircular tube magnet 62, a lower left semicircular tube magnet 64, a right upper semicircular tube magnet 66, a right lower semicircular tube magnet 68, and a second hollow formed by a combination of the above magnets. Cylindrical space 70. The second hollow cylindrical space 70 is used to allow the supply pipe 2 to pass through. The upper left semicircular tube magnet 62 and the lower left semicircular tube magnet 64 are arranged close to the natural gas application device 4.

The upper left semicircular tube magnet 62 has an upper left N pole 622 and an upper left S pole 624, and the lower left semicircular tube magnet 64 has a lower left N pole 642 and a lower left S pole 644. The upper right semicircular tube magnet 66 has an upper right S pole 662 and an upper right N pole 664, and the lower right semicircular tube magnet 68 has a lower right S pole 682 and a lower right N pole 684.

There is a second interface 72 between the upper right semicircular tube magnet 66 and the lower right semicircular tube magnet 68; a third interface 74 between the upper left semicircular tube magnet 62 and the lower left semicircular tube magnet 64.

FIG. 6 is a magnetic line diagram formed by the second embodiment of the permanent magnet device of FIG. 5. The second magnetic field line 90 formed by the four magnetic group permanent magnet device 60 is shown in FIG. 6. When the coarser fuel particles in the natural gas in the supply pipe 2 reach the second interface 72 between the upper right semicircular tube magnet 66 and the lower right semicircular tube magnet 68, the blocking effect of the empty area will be caused by the action of the second magnetic field line 90, and Accelerating the shaking and stirring of the fuel particles 20, the shaking and stirring can cause the fuel particles 20 to be broken into small particles by shaking, as described in Example 1. When the fuel particles 20 reach the third interface 74 of the upper left semicircular tube magnet 66 and the lower left semicircular tube magnet 68, the blocking effect of the empty region is caused by the action of the second magnetic field line 90, which accelerates the oscillation and stirring of the fuel particle 20 Stirring can cause the fuel particles 20 to be broken into minute particles by shaking, as described above. Then, when the fine particles subjected to the oscillation and stirring reach the natural gas application device 4, positively charged fuel ions are formed. Finally, when the positively charged fuel ions meet the negatively charged electrons generated by the ignition device 8 in the natural gas application device 4, the ignition can be accelerated to promote the combustion effect.

The magnets used in Examples 1 and 2 of this creation are rare earth permanent magnet neodymium iron boron or rare earth permanent magnet samarium cobalt. The Gauss, coercive force and frequency resonance efficiency of the permanent magnet neodymium iron boron are higher. The permanent magnet device of this creation can split the fuel particle clusters into small molecules, so that the combustible aerosol can be fully mixed with the air, improve the combination ratio of the fuel particle 20 and the oxygen molecules, and allow the fuel to burn more fully and quickly. , Improve the combustion effect, increase the output of the gas furnace, reduce the emissions of CO and CH hydrocarbons, and reduce energy consumption.

As mentioned above, the natural gas application device 4 applicable to this creation according to FIG. 1 includes, but is not limited to, a water heater that uses natural gas as a combustion heater, a gas stove, or provides the combustion power of a gas car. The above embodiments of this creation can be adopted. Its technical means and generating function content are the same, so it will not be repeated one by one.

Here, just take the actual test of this creative permanent magnet device installed on natural gas and barrel gas respectively:

Among them (1) natural gas, experimental steps applied to gas water heaters:

1. Stick the thermometer to the water outlet of the faucet, turn on the hot water only, and record the final water temperature after turning on for 30 seconds.

2. Turn on the hot water and record the flow rate of the gas meter for 3 minutes.

3. Install 2 sets of products, only turn on the hot water, record the final water temperature after 30 seconds.

4. Add 2 more products (total 4 groups on top), turn on the hot water only, and record the final water temperature after 30 seconds.

5. Just turn on the hot water and adjust the water heater to the hot water temperature and the water temperature without any goods installed.

6. The hot water is turned on and the flow rate of the gas meter is recorded for 3 minutes.

Experimental results:
Not installed Pack two Install four groups Hot water temperature 32 degrees 35 degrees 38 degrees Time spent per 10 liters of natural gas 35.4 seconds 46.5 seconds According to the adjusted gas meter flow rate, it can be determined that 31.36% of gas is saved.

(2) Gas drum (liquid gas), used in general gas water heaters, directly installed in 4 groups, the experimental results:

Before installation, it consumes one barrel of gas every 3 months in winter and one barrel of gas every 4.5 months in summer. It has been used for 1.5 months after installing 4 sets, and currently consumes 0.25 barrels of gas, so it is expected to be used for 6 months after installation, which can save more than 50% of gas.

(3) Gas cylinder (liquid gas), the experimental steps applied to the gas furnace:

1. Take 360cc of cold water and place it in a stainless steel pot, and record the time from normal temperature to 100 degrees.

2. Repeat step 1 after installing 2 sets of products and repeat step 1 after installing 4 sets of products.

3. Repeat step 1 after installing 6 groups of products, repeat step 1 after installing 8 groups of products, and compare

Experimental results:
Not installed Pack two Pack two Pack two Pack two Use seconds 152 seconds 138 seconds 134 seconds 130 seconds 129 seconds save% 9.21% 11.84% 14.47% 15.13%

10‧‧‧ tube type permanent magnet device
12‧‧‧Near round tube magnet
122‧‧‧Near N pole
124‧‧‧Near S pole
14‧‧‧Far round tube magnet
142‧‧‧far N pole
144‧‧‧far S pole
16‧‧‧ the first hollow cylindrical space
18‧‧‧ first meet
2‧‧‧ supply tube
20‧‧‧ Burning plasmid
30‧‧‧ tiny particles
32‧‧‧Positively charged fuel ions
34‧‧‧Electronics
4‧‧‧ natural gas application device
50‧‧‧ magnetic lines
6‧‧‧ outer tube wall
60‧‧‧Second permanent magnet device
62‧‧‧Left upper semicircular tube magnet
622‧‧‧Top N pole
624‧‧‧Top left S pole
64‧‧‧Lower left half round tube magnet
642‧‧‧bottom left pole
644‧‧‧lower left S pole
66‧‧‧Right upper semi-circular tube magnet
662‧‧‧ Top right S pole
664‧‧‧Top right N pole
68‧‧‧Right lower semi-circular tube magnet
682‧‧‧ bottom right S pole
684‧‧‧ bottom right N pole
70‧‧‧ Second hollow cylindrical space
72‧‧‧ Second meet
74‧‧‧ third encounter
8‧‧‧Ignition device
90‧‧‧ second magnetic field line

Figure 1 is a diagram of an application example of a creative permanent magnet device.
FIG. 2 is a schematic diagram of Embodiment 1 of a creative permanent magnet device.
FIG. 3 is a magnetic field line diagram formed in the first embodiment of the permanent magnet device of FIG.
FIG. 4 is a schematic diagram of the original creation of the fuel particles to form positively charged fuel ions.
FIG. 5 is a schematic diagram of Embodiment 2 of a creative permanent magnet device.
FIG. 6 is a magnetic field line diagram formed in Embodiment 2 of the creative permanent magnet device of FIG. 5.

Claims (8)

A permanent magnet device for promoting natural gas combustion includes:
A tube-type permanent magnet device has an adjacent round tube magnet, a far tube magnet, and a first hollow cylindrical space formed by the near tube magnet and the far tube magnet. To pass the supply pipe of a natural gas application;
The near-circular-tube magnet has a near-N pole and a near-S-pole, and the near-N pole is close to the natural gas application device. The far-round-tube magnet has a far-N pole and a far-S pole, and the far-N pole is close to the near-S pole. Poles are connected; and the tube-type permanent magnet device forms a first magnetic field line, which is emitted from the near N pole and enters the far S pole via the outside, and then passes through the far N pole and then enters the near S pole through the outside, when the supply tube When the internal natural gas reaches the first interface between the far N pole and the near S pole, the blocking effect of the empty zone will be caused by the action of the first magnetic field line, and the oscillating stirring of the coarser fuel particles in the natural gas will be accelerated. The fuel particles are oscillated and split into fine particles to promote the combustion efficiency of the natural gas application device. The permanent magnet device for promoting natural gas combustion according to claim 1, wherein the natural gas application device includes at least one of a gas furnace, a water heater, and a gas car. The permanent magnet device for promoting natural gas combustion according to claim 1, wherein the near-circular tube magnet and the far-circular tube magnet are rare earth permanent magnets neodymium iron boron or rare earth permanent magnet samarium cobalt. The permanent magnet device for promoting the combustion of natural gas as described in claim 1, wherein when the above-mentioned minute particles subjected to oscillation and stirring reach the near N pole, positively-charged fuel ions are formed, and the ignition is further provided in a natural gas application device. The negatively charged electrons in the device meet to accelerate the ignition and promote the combustion effect. A permanent magnet device for promoting natural gas combustion includes:
A four-magnet permanent magnet device has an adjacent upper left semicircular tube magnet, a lower left semicircular tube magnet, a right upper semicircular tube magnet, a lower right semicircular tube magnet, and an upper left semicircular tube magnet, the lower left semicircular tube magnet, and the upper right A second hollow cylindrical space formed by the semi-circular tube magnet and the lower right semi-circular tube magnet, the second hollow cylindrical space is used to pass a supply pipe of a natural gas application device;
The upper left semicircular tube magnet has upper left N pole and upper left S pole, the lower left semicircular tube magnet has lower left N pole and lower left S pole, the upper right semicircular tube magnet has upper right S pole and upper right N pole, and the lower right semicircular tube magnet has right A lower S pole and a lower right N pole, a second interface between the right upper semicircular tube magnet and the lower right semicircular tube magnet, and a third interface between the upper left semicircular tube magnet and the lower left semicircular tube magnet; And the four magnetic group permanent magnet device forms a second magnetic field line. When the natural gas in the supply pipe reaches the first interface or the second interface, the blocking effect of the empty area is caused by the action of the second magnetic field line. Accelerate the oscillation and stirring of the coarser fuel particles in the natural gas, so that the fuel particles are oscillated and split into small particles to promote the combustion efficiency of the natural gas application device. The permanent magnet device for promoting natural gas combustion according to claim 5, wherein the natural gas application device includes at least one of a gas furnace, a water heater, and a gas car. The permanent magnet device for promoting natural gas combustion according to claim 5, wherein the upper left semicircular tube magnet, the lower left semicircular tube magnet, the upper right semicircular tube magnet, and the lower right semicircular tube magnet are rare earth permanent magnet neodymium iron boron or rare earth permanent magnet Magnetic samarium cobalt. The permanent magnet device for promoting the combustion of natural gas as described in claim 5, wherein when the above-mentioned minute particles subjected to oscillation and stirring reach the near N pole, positively-charged fuel ions are formed, and the ignition is further provided in a natural gas application device. The negatively charged electrons in the device meet to accelerate the ignition and promote the combustion effect.