TWI719509B - Permanent magnet device to promote natural gas combustion - Google Patents

Abstract

A permanent magnet device for promoting natural gas combustion, comprising a tube-type permanent magnet device with adjacent near-tube magnets, 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 allow a supply pipe of a natural gas application device to pass through. The tubular permanent magnet device forms a first magnetic field line. When the natural gas reaches the first junction, the depletion zone will be blocked due to the first magnetic field line, and the oscillation and stirring of the coarser combustion particles in the natural gas will be accelerated to make The fuel particles are split into tiny particles by shaking. The invention can miniaturize the fuel molecules in the natural gas to enhance the combustion reaction, and greatly improve the combustion efficiency of the natural gas application device.

Description

Permanent magnet device to promote natural gas combustion

The present invention relates to the technical field of promoting the combustion of natural gas, in particular to a permanent magnet device for promoting the combustion of natural gas.

Liquefied natural gas is a mixture of propane and butane precipitated in the process of crude oil refining or natural gas processing. It is a gas at normal temperature and pressure, and can be liquefied after pressurization or cooling. It is usually pressurized into steel cylinders for users Use, so it is also called liquefied gas or barreled gas. When natural gas is completely burned, it will produce non-toxic carbon dioxide. When it is not completely burned, it will produce toxic carbon monoxide and 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 activated. One is the "magnetic excitation type" in which the magnetism of the magnet acts on the gas molecules to make the liquefied natural gas molecules more active through the lines of magnetic force, thereby enhancing the combustion efficiency. The above technology has the following shortcomings. 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 occupy space to achieve the effect. The other is the "far-infrared excitation type". In order to improve the poor effect of the aforementioned magnet type, ceramics with far-infrared rays are used. Far-infrared rays activate gas molecules more and increase the combustion rate. Although far-infrared rays are better than magnets, their effects will decrease over time. The service life is limited. Generally, synthetic far-infrared materials can only last for half a year. Although the far-infrared material has a long life, the cost is extremely high and it is not good for commercialization. In addition, some far-infrared ceramics also need to be heated to emit far-infrared rays. This heating method requires electricity and has the disadvantage of increasing the amount of electricity and oil.

The purpose of the present invention is to provide a permanent magnet device that promotes the combustion of natural gas. The energy wave generated by the high-frequency oscillation of the permanent magnet device can break the molecular bonds of the natural gas fuel particle molecular clusters and make the macromolecular clusters appear. Small molecules are then dissociated into positively charged ions, so the present invention can make fuel molecules miniaturize 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 objective, the present invention provides a permanent magnet device for promoting natural gas combustion, including a tube-type permanent magnet device with adjacent near-tube magnets, a far-tube magnet, and a combination of the near-tube magnet and the far-tube magnet. The formed first hollow cylindrical space is used to allow a supply pipe of a natural gas application device to pass through, wherein the natural gas application device can be at least one of a gas stove, a water heater, or a gas truck, etc. But the actual situation is not limited to this.

The near tube magnet has a near N pole and a near S pole, the near N pole is close to the natural gas application device, the far tube magnet has a far N pole and a far S pole, and the far N pole is connected 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, 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 far S pole, The first junction between the far N pole and the near S pole will be due to the first magnetic The action of the line of force produces the blocking effect of the depleted zone, and accelerates the oscillating stirring of the coarser fuel particles in the natural gas, so that the fuel particles are oscillated and split into tiny particles to promote the combustion efficiency of the natural gas application device.

Compared with conventional products, the present invention has the following advantages:

1. The magnet used in the present invention is rare earth permanent magnet neodymium iron boron or rare earth permanent magnet samarium cobalt. The permanent magnet neodymium iron boron has higher Gaussian, coercive force and catalyst frequency resonance efficiency.

2. The permanent magnet device of the present invention can split the gas particles into small molecules, so that the fuel aerosol can be fully mixed with the air, and the combination ratio of the fuel particles and oxygen molecules can be increased, so that the fuel can burn more fully and quickly , Improve the combustion effect, increase the combustion power of natural gas application devices, reduce CO and CH hydrocarbon emissions, and reduce energy consumption.

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 junction

2: Supply pipe

20: Burning particles

30: Tiny particles

32: Positively charged combustible ion

34: Electronics

4: Natural gas application device

50: Magnetic field lines

6: Outer pipe wall

60: Second permanent magnet device

62: Top left semicircular tube magnet

622: upper left N pole

624: upper left S pole

64: The bottom left semicircular tube magnet

642: lower left N pole

644: lower left S pole

66: Upper right semicircular tube magnet

662: upper right S pole

664: upper right N pole

68: Lower right semicircular tube magnet

682: lower right S pole

684: Lower right N pole

70: The second hollow cylindrical space

72: second junction

74: The third junction

8: Ignition device

90: second magnetic field line

Fig. 1 is a diagram of an application example of the permanent magnet device of the present invention.

Fig. 2 is a schematic diagram of Embodiment 1 of the permanent magnet device of the present invention.

Fig. 3 is a diagram of magnetic field lines formed by embodiment 1 of the permanent magnet device of Fig. 2 of the present invention.

Fig. 4 is a schematic diagram of the present invention causing fuel particles to form positively charged fuel ions.

Fig. 5 is a schematic diagram of Embodiment 2 of the permanent magnet device of the present invention.

Fig. 6 is a diagram of magnetic field lines formed by embodiment 2 of the permanent magnet device of Fig. 5 of the present invention.

Example 1:

Figures 1 to 4 show the appearance of the permanent magnet device for promoting natural gas combustion in Example 1 of the present invention. Fig. 1 is an application example diagram of the permanent magnet device for promoting the combustion of natural gas according to the present invention. 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, where the natural gas application device 4 can be at least one of a gas stove, a water heater, or a gas truck, but it is not actually used This is limited. The natural gas application device 4 has a set of ignition devices 8, and a tubular permanent magnet device 10 is arranged on the outer wall 6 of the supply pipe 2.

Fig. 2 is a schematic diagram of Embodiment 1 of the permanent magnet device of the present invention. The tubular permanent magnet device 10 has a near-tube magnet 12, a far-tube magnet 14 adjacent to each other, and a first hollow cylindrical space 16 formed by the combination of the near-tube magnet 12 and the far-tube magnet 14. The first hollow cylindrical space 16 is used to allow the supply pipe 2 of the natural gas application device 4 to pass through.

The near-circular 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. There is a first junction 18 between the near-tube magnet 12 and the far-tube magnet 14.

Fig. 3 is a diagram of magnetic field lines formed by the tubular permanent magnet device of embodiment 1 in Fig. 2. The first magnetic field line 50 is emitted from 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 positively charged fuel ions formed by the fuel particles of the present invention. When the fuel 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 depletion zone will be blocked due to the action of the first magnetic field line 50, and the vibration and stirring of the fuel particles 20 will be accelerated. The fuel particles 20 are shaken and split into fine particles 30. Then, when the fine particles 30 subjected to shaking and 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:

Figure 5 is a schematic diagram of a permanent magnet device for promoting natural gas combustion according to Embodiment 2 of the present invention. The four-magnet permanent magnet device 60 has an adjacent upper left semicircular tube magnet 62, a left lower 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 junction 72 between the upper right semicircular tube magnet 66 and the lower right semicircular tube magnet 68; there is a third junction 74 between the upper left semicircular tube magnet 62 and the lower left semicircular tube magnet 64.

Fig. 6 is a diagram of magnetic field lines formed by embodiment 2 of the permanent magnet device of Fig. 5; The second magnetic field lines 90 formed by the four-magnet permanent magnet device 60 are shown in FIG. 6. When the thicker natural gas fuel particles in the supply pipe 2 reach the second junction 72 between the upper right semicircular tube magnet 66 and the lower right semicircular tube magnet 68, the depletion zone blocking effect will be generated due to the action of the second magnetic field line 90, and plus The rapid combustion particles 20 are shaken and stirred, and the shaking and stirring can cause the combustion particles 20 to be oscillated and split into fine particles, as described in Example 1. When the fuel particles 20 reach the third junction 74 between the upper left semicircular tube magnet 66 and the lower left semicircular tube magnet 68, the depletion zone will be blocked due to the action of the second magnetic field line 90, and the oscillation and stirring of the fuel particles 20 will be accelerated. The stirring can cause the fuel particles 20 to be shaken and split into tiny particles, as described above. Then, when the fine particles subjected to vibration 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 the first and second embodiments of the present invention are rare earth permanent magnet NdFeB or rare earth permanent magnet Samarium Cobalt, and the permanent magnet NdFeB has higher Gaussian, coercive force and catalytic frequency resonance efficiency. The permanent magnet device of the present invention can split the fuel particles into small molecules, so that the fuel aerosol can be fully mixed with air, improve the combination ratio of fuel particles 20 and oxygen molecules, so that the fuel can burn more fully and quickly , Improve the combustion effect, increase the output power of the gas furnace, reduce the emissions of CO and CH hydrocarbons, and reduce energy consumption.

In summary, the natural gas application device 4 applicable to the present invention according to Fig. 1, including but not limited to water heaters, gas stoves, or gas trucks that use natural gas as combustion and heating power, can all adopt the above embodiments of the present invention. The technical means and production functions are the same, so they will not be repeated one by one.

Here, only the actual test of the permanent magnet device of the present invention installed on natural gas and barreled gas respectively: (1) Natural gas is applied to the experimental procedure of gas water heater:

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

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

5. Only turn on the hot water, adjust the water heater to the hot water temperature and the water temperature without any products.

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

Experimental results:

According to the adjusted gas meter flow rate, 31.36% of gas can be saved.

(2) Gas bucket (liquid gas), used in general gas water heaters, directly installed in 4 sets before use, experimental results: before installation, it consumes one barrel of gas every 3 months in winter, and consumes one barrel of gas every 4.5 months in summer. . It has been used for 1.5 months after the installation of 4 sets, and currently consumes 0.25 barrels of gas, so it is estimated that it can be used for 6 months after installation, which can save more than 50% of gas.

(3) Gas bucket (liquid gas), the experimental steps applied to gas stove:

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

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 sets of products, and repeat step 1 after installing 8 sets of products for comparison

Experimental results:

2: Supply pipe

4: Natural gas application device

6: Outer pipe wall

8: Ignition device

10: Tube type permanent magnet device

Claims (8)

A permanent magnet device for promoting the combustion of natural gas, comprising: a tubular permanent magnet device with adjacent near-tube magnets, a far-tube magnet, and a first hollow formed by the near-tube magnet and the far-tube magnet A cylindrical space, the first hollow cylindrical space is used to allow a supply pipe of a natural gas application device to pass through; 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, the far N pole is connected to the near S pole; and the tube type permanent magnet device forms a first magnetic field line, which is emitted by the near N pole and enters the The far S pole passes through the far N pole and then enters the near S pole through the outside. When the natural gas in the supply pipe reaches the first junction between the far N pole and the near S pole, it will be The effect produces the blocking effect of the depleted zone, and accelerates the oscillation and stirring of the coarser combustion particles in the natural gas, so that the combustion particles are oscillated and split into tiny particles, so as 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 stove, a water heater, and a gas truck. The permanent magnet device for promoting natural gas combustion according to claim 1, wherein the near-tube magnet and the far-tube magnet are rare earth permanent magnet neodymium iron boron or rare earth permanent magnet samarium cobalt. The permanent magnet device for promoting the combustion of natural gas according to claim 1, wherein when the above-mentioned fine particles subjected to vibration and stirring reach the near-N pole, positively charged fuel ions are formed, which can be further set in the natural gas application device for ignition When the negatively charged electrons in the device meet, the ignition can be accelerated to promote the combustion effect. A permanent magnet device for promoting the combustion of natural gas, including: A four-magnet permanent magnet device has an adjacent upper left semicircular tube magnet, a lower left semicircular tube magnet, an upper right semicircular tube magnet, a lower right semicircular tube magnet, and the upper left semicircular tube magnet, the lower left semicircular tube magnet, the upper right The second hollow cylindrical space formed by the semicircular tube magnet and the lower right semicircular tube magnet, the second hollow cylindrical space is used to allow the supply pipe of a natural gas application device to pass through; the upper left semicircular tube magnet has an upper left N pole and an upper left The lower left semicircular tube magnet has a lower left N pole and a lower left S pole, the upper right semicircular tube magnet has an upper right S pole and an upper right N pole, the lower right semicircular tube magnet has a lower right S pole and a lower right N pole, the upper right There is a second junction between the semicircular tube magnet and the lower right semicircular tube magnet, and a third junction between the upper left semicircular tube magnet and the lower left semicircular tube magnet; and the four-magnet permanent magnet device forms a second junction Two magnetic lines of force. When the natural gas in the supply pipe reaches the second junction or the third junction, the depletion zone will be blocked due to the action of the second magnetic line of force, which will accelerate the oscillation of the coarser combustion particles in the natural gas Stirring causes the fuel particles to be oscillated and split into tiny 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 stove, a water heater, and a gas truck. 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 magnets. Magnetic Samarium Cobalt. The permanent magnet device for promoting the combustion of natural gas as described in claim 5, wherein when the above-mentioned fine particles subjected to vibration and stirring reach the natural gas application device, positively charged fuel ions are formed, which can be further set in the natural gas application device for ignition When the negatively charged electrons in the device meet, the ignition can be accelerated to promote the combustion effect.

Images