CN113350983A - Electric field polarized gas adsorption system - Google Patents
Electric field polarized gas adsorption system Download PDFInfo
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- CN113350983A CN113350983A CN202010150368.1A CN202010150368A CN113350983A CN 113350983 A CN113350983 A CN 113350983A CN 202010150368 A CN202010150368 A CN 202010150368A CN 113350983 A CN113350983 A CN 113350983A
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- B01—PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
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- B01D53/32—Separation of gases or vapours; Recovering vapours of volatile solvents from gases; Chemical or biological purification of waste gases, e.g. engine exhaust gases, smoke, fumes, flue gases, aerosols by electrical effects other than those provided for in group B01D61/00
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Abstract
Electric field polarization is used to increase the storage volume of the stored gas. Increasing the pressure of the loaded gas and simultaneously increasing the polarization voltage, and polarizing the container wall, the pore substances and the loaded gas by an electric field; thereby realizing the polarized adsorption of the container wall and the loaded gas; polarized adsorption of the porous substance and the loaded gas; polarized adsorption between the loading gas and the loading gas. The amount of loading gas is greatly increased. The stronger the field intensity of the external electric field is, the stronger the polarization intensity is, the greater the pressure intensity of the external input gas is, and the more the stored gas is. After polarization is removed, the loaded gas is desorbed with the container wall, the loaded gas is desorbed with the pore substances, and meanwhile, the gas is released to reduce the pressure of the loaded gas and release the gas. The electric field polarized gas adsorption system can store hydrogen, oxygen, nitrogen, helium, chlorine, fluorine, neon, argon, xenon, radon, hydrocarbon compound, etc. at normal temperature in high density.
Description
Technical Field
The invention relates to an electric field polarized gas adsorption system, in particular to an electric field polarized gas adsorption system with an external polarized power supply.
Background
Hydrogen gas requires extremely low temperatures to achieve substantial physical adsorption of hydrogen. The invention aims to improve the physical adsorption capacity of hydrogen at normal temperature. Hydrogen storage in hydrogen fuel cell technology is now the bottleneck in the technology.
Disclosure of Invention
The problems to be solved are as follows:
the existing gas high-density storage method comprises the following steps: physical adsorption, chemical adsorption methods. The method aims to solve the problems that the physical adsorption of gases such as hydrogen, oxygen, nitrogen and the like is weak, extremely low temperature is required, and the energy consumption is too large; the chemical adsorption chemical bond is too strong, so that much energy is needed to realize gas desorption, and a large amount of energy is needed when the gas is required to be subjected to chemical desorption.
The technical scheme is as follows:
an electric field polarized gas adsorption system comprising: a gas container port 1 (101), a gas container port 2 (107), a gas container (102), a conductor shielding shell (103), an electric field electrode 1 (104), an electric field electrode 2 (106), a pore substance (105) or a charge retention pore substance (105), a lead 1 (108), a lead 2 (109), an external polarized power supply (110) and a heating electric heating wire (111);
the gas container (102) is provided with 1, 2 or a plurality of gas container connecting ports for inputting, outputting or inputting/outputting gas; the gas container port 1 (101) and the gas container port 2 (107) are used for gas input, output or input/output of the gas container (102);
conductor shield housing (103): the external electromagnetic shielding shell of the electric field polarized gas adsorption system has the function of avoiding the external influence of the electric field generated by the electric field electrodes 1 (104), 2 (106) and the conductor shielding shell (103) and ensuring the safe operation of the electric field polarized gas adsorption system; the conductor shield housing (103) may be grounded or ungrounded; the conductor shielding shell (103) and the gas container (102) are combined together and bear the pressure of gas together; or the conductor shielding shell (103) is only used as a shielding shell, plays a shielding role on an electric field and does not bear the pressure of gas;
gas container (102): the electric field electrode 1 (104), the electric field electrode 2 (106) are externally applied with voltage to form an electric field, and the electric field acts on: (1) a gas container (102) wall; (2) a porous substance (105); (3) storing gas to polarize the three parts;
the walls of the polarized gas container (102) adsorb the stored gas; the polarized porous substance (105) adsorbs the storage gas; the polarized storage gas adsorbs the polarized storage gas; under the combined action of the pressure intensity and the adsorption force of the added gas, the mass storage of the gas is realized;
the higher the direct-current voltage between the electric field electrodes 1 (104) and 2 (106), i.e. the stronger the field intensity of the external electric field, the higher the polarization field intensity, the higher the polarization intensity of the gas container (102) wall and the pore substance (105) stored gas; the greater the adsorption force between them, the more gas is stored with sufficient gas input; the stronger the polarization intensity is, the greater the pressure of the externally-added input gas is, and the more the stored gas is; the gas stored after the polarization of the external electric field is added is higher than the gas stored by only adding the same pressure by more than several orders of magnitude;
and (3) inflating: (1) the gas container (102) is used for inputting gas, and the gas pressure is increased: continuously pressing gas into the gas container (102) through the gas container port 1 (101) or the gas container port 2 (107) to increase the amount of the gas in the gas container (102) and increase the pressure of the gas in the gas container (102); (2) the direct current voltage at the two ends of the external polarized power supply (110) is increased and is transmitted to the electric field electrodes 1 (104) and 2 (106) through the leads 1 (108) and 2 (109); thereby increasing the voltage difference between the electric field electrodes 1 (104) and 2 (106), increasing the polarization electric field of the pore substance (105) in the gas container (102) and the stored gas in the gas container (102), enhancing the adsorption force of the pore substance (105) on the gas, and increasing the adsorption force between the stored gas and the stored gas;
air bleeding: when gas needs to be output outwards, (1) the polarization voltage is kept unchanged, the gas is discharged outwards by using the pressure inside the stored gas, and when the pressure of the gas inside the stored gas is smaller than a certain value, the polarization voltage is gradually reduced, so that the polarization intensity is reduced, the physical adsorption is further reduced, and the gas discharge is realized; (2) or simultaneously reducing the voltage of the polarized direct-current power supply, and discharging air outwards by gas pressure intensity; (3) or reducing the polarization voltage to discharge air outwards, and then reducing the air pressure to discharge air outwards;
depolarization: when alternating voltage is applied to the electric field electrodes 1 (104) and 2 (106), alternating electric fields are generated between the electric field electrodes 1 (104) and 2 (106) to make the wall of the gas container (102) of the gas container (1); (2) a porous substance (105); (3) storing the gas depolarizations; the adsorption force between the adsorbed storage gas and the adsorbed storage gas is reduced, or the adsorption force between the adsorbed storage gas and the pore substance (105) is reduced, or the adsorption force between the wall of the gas container (102) and the adsorbed storage gas is reduced, desorption occurs, and the gas is released;
when the stored gas is not completely released by the electric field polarized gas adsorption system, the gas container (102) is electrified by a heating electric heating wire (111) arranged in the porous substance (105) to generate heat, so that the porous substance (105) and the stored gas are heated, and the stored gas is released;
or a electret pore substance (105) replacing the pore substance (105), the electret pore substance itself having a polarity, the electret pore substance for adsorbing gas; when the adsorption amount of the gas needs to be increased, the voltages at the two ends of the electric field electrodes 1 and 104 and the electric field electrodes 2 and 106 are increased, so that the polarization of the electret pore substances (105) is further enhanced, and the purpose that more electret pore substances (105) adsorb the pressed gas is realized; simultaneously, the adsorption between the gases is increased; increasing the storage capacity of the gas; when gas needs to be released, the gas is directly released by using the pressure of the gas; or alternating voltage is applied on the electrode, and the electret pore substance in the gas container (102) depolarizes under the action of the alternating electric field to release adsorbed gas; or the gas container (102) is electrified and heated by a heating electric heating wire (111) arranged in the electret pore substance (105), and the electret pore substance (105) is heated to release the stored gas;
or the pore substance (105) or the electret pore substance (105) is removed, the gas container (102) is directly filled with the gas to be stored, and the pressure of the input gas is increased; simultaneously, voltages are applied to the electric field electrodes 1 (104) and the electric field electrodes 2 (106) to polarize (1) the wall of the gas container (102) and (2) the gas stored in the container; the wall of the gas container (102) is adsorbed with the filled gas, and adsorption is generated between the filled storage gas and the storage gas, so that high-density storage of the gas is realized; when gas release is required: opening a valve to directly release gas by using gas pressure; or reducing the polarization voltage at the two ends of the electric field electrodes 1 (104) and 2 (106) to release gas; or the electric field electrode 1 (104) and the electric field electrode 2 (106) are applied with alternating voltage at two ends to further reduce polarization and release gas; or current is applied to two ends of the heating electric heating wire (111), and the electric heating wire generates heat to release gas.
A gas container (102), the conductor shield housing (103) being of spherical shape; or a gas container (102), the conductor shield housing (103) being of an ellipsoidal type; or a gas container (102), the conductor shield housing (103) being a cube; or a gas container (102), the conductor shield housing (103) being square; or a gas container (102), the conductor shield housing (103) being of a spherical irregular shape.
Electric field electrodes 1 (104), electric field electrodes 2 (106) are flat plates; or electric field electrodes 1 (104), electric field electrodes 2 (106) are arc-shaped; or electric field electrodes 1 (104), and electric field electrodes 2 (106) are irregular plates.
The electric field polarized gas adsorption system is composed of 1 conductor shielding shell, the interior of the electric field polarized gas adsorption system is composed of 1 gas container, or 1 conductor shielding shell and 2 gas containers, or 1 conductor shielding shell and 3 gas containers, or 1 conductor shielding shell and n gas containers according to the scale of the system;
the gas storage system consists of a plurality of groups of polarized polar plates and gas containers: a conductor shield case (201); electric field electrodes 1 (210), 2 (211), 3 (212), 4 (213), 5 (214);
gas container 1 (206), gas container 2 (207), gas container 3 (208), gas container n (209);
pore material 1 or electret pore material 1 (219), pore material 2 electret pore material 2 (220), pore material 3 or electret pore material 3 (221), pore material n or electret pore material n (222); heating wires are arranged in each group of pore substances or the pore substances of the electret;
a gas container input/output port 1A (202), a gas container input/output port 1B (215), a gas container input/output port 2A (203), a gas container input/output port 2B (216), a gas container input/output port 3A (204), a gas container input/output port 3B (217), a gas container input/output port nA (205), and a gas container input/output port nB (218);
a conductor shield case (201) in which n gas containers are designed; gas container 1 (206), gas container 2 (207), gas container 3 (208), gas container n (209); the n gas containers are arranged in parallel;
electric field electrodes 1 (301), electric field electrodes 2 (302), electric field electrodes 3 (303), and electric field electrode n (304); the lead (305) is connected with the electric field electrode 1 (301) and the electric field electrode 3 (303); the lead (306) is connected with the electric field electrode 2 (302) and the electric field electrode n (304);
all the odd electric field electrodes are connected together by leads, and all the even electric field electrodes are connected together by leads; the odd electric field electrodes are connected to the positive pole of the external direct current polarization power supply, and the even electric field electrodes are connected to the negative pole of the external direct current polarization power supply; or the odd electric field electrode is connected to the negative electrode of the external direct current polarization power supply, and the even electric field electrode is connected to the positive electrode of the external direct current polarization power supply;
or n-1 independent direct current power supplies are adopted, and each unit electrode can be connected at will;
the gas container may be spherical, or ellipsoidal, or cubic, or square, or irregular in shape;
the field electrodes may be flat, or curved, or irregular;
the gas container 1 (206), the gas container 2 (207), the gas container 3 (208), and the gas container n (209) are all provided with heating resistance wires, and the heating resistance wires and the current generate heat to promote the release of the stored gas.
Porous active carbon is adopted as the porous substance (105); or the porous substance (105) adopts nano porous carbon; or the pore material (105) adopts zeolite; or the pore substance (105) adopts graphene; or the pore substance (105) adopts a nano tube; or the porous substance (105) adopts porous alumina; or the porous material (105) adopts a molecular sieve; or the porous substance (105) adopts porous silica gel; or the porous substance (105) adopts porous aluminum silicate; or the pore substance (105) adopts diatomite; or the porous substance (105) adopts porous ion exchange resin; or the pore substance (105) adopts titanium dioxide; or the pore substance (105) adopts bentonite; or the porous substance (105) adopts sepiolite; or the porous substance (105) adopts fiber carbonized porous material;or the porous substance (105) adopts a metal organic framework material; or the pore substance (105) adopts an organic framework material; or the porous substance (105) adopts foamed aluminum; or other porous substances are adopted as the porous substances (105); the porous material (105) adopts LaNi5Or the porous substance (105) adopts FeTi; or the pore substance (105) adopts a magnesium pore substance; the hydrogen storage material stores gas in combination with polarization.
The electric field polarized gas adsorption system can store hydrogen, oxygen, nitrogen, helium, chlorine, fluorine, neon, argon, xenon, radon, hydrocarbon or hydrocarbon compounds at normal temperature in a high density.
The heating electric heating wire is linear, or the heating electric heating wire is arc-shaped, or the heating electric heating wire is irregular.
The working principle of electric field polarized gas adsorption is that an external electric field polarizes a gas container (102), a pore substance (105) or a electret pore substance (105) and stored gas in the gas container (102); an attractive force between the gas container (102) wall and the stored gas; or the pore substance (105) or the electret pore substance (105) and the storage gas form an attractive force, and high-density storage of the storage gas is realized.
Has the advantages that:
the invention is a new physical adsorption mode, the wall of the container, the pore substance and the loading gas are polarized by using an electric field, and the positive and negative charge centers of the wall of the container, the pore substance and the loading gas are deviated, so that the physical polarization adsorption of the wall of the container and the loading gas is realized; physical polarization adsorption of pore substances and loaded gas; after the polarized electric field is removed, the loaded gas is desorbed with the container wall, and the loaded gas is desorbed with the pore substances, so that the gas is released. For example, a vehicle-mounted hydrogen fuel cell needs to be loaded with 70MPa to store a small amount of hydrogen, the pressure is too high and dangerous, and extra energy is needed for compressing the hydrogen into a hydrogen tank by the high pressure; when liquefied hydrogen is required to be stored, the temperature of the hydrogen needs to be reduced to 20.271K, and the liquid hydrogen state needs to be maintained, so that the required energy is too much, and the liquefied hydrogen cannot be applied to vehicle-mounted hydrogen storage.
Description of the drawings
FIG. 1 schematic diagram of principle of electric field polarized gas adsorption system
FIG. 2 shows an electric field polarized gas adsorption system for a stacked gas container
FIG. 3 is a schematic diagram of multi-field electrode connection.
Fifth, detailed description of the invention
Embodiments of the present invention are described in detail below with reference to the accompanying drawings:
preferred example 1:
as shown in fig. 1, an electric field polarizes a gas adsorption system consisting of: a gas container port 1 (101), a gas container port 2 (107), a gas container (102), a conductor shielding shell (103), an electric field electrode 1 (104), an electric field electrode 2 (106), a pore substance (105) or a charge retention pore substance (105), a lead 1 (108), a lead 2 (109), an external polarized power supply (110) and a heating electric heating wire (111);
the gas container (102) is provided with 1, 2 or a plurality of gas container connecting ports for inputting, outputting or inputting/outputting gas; the gas container port 1 (101) and the gas container port 2 (107) are used for gas input, output or input/output of the gas container (102);
conductor shield housing (103): the external electromagnetic shielding shell of the electric field polarized gas adsorption system has the function of avoiding the external influence of the electric field generated by the electric field electrodes 1 (104), 2 (106) and the conductor shielding shell (103) and ensuring the safe operation of the electric field polarized gas adsorption system; the conductor shield housing (103) may be grounded or ungrounded; the conductor shielding shell (103) and the gas container (102) are combined together and bear the pressure of gas together; or the conductor shielding shell (103) is only used as a shielding shell, plays a shielding role on an electric field and does not bear the pressure of gas;
gas container (102): the electric field electrode 1 (104), the electric field electrode 2 (106) are externally applied with voltage to form an electric field, and the electric field acts on: (1) a gas container (102) wall; (2) a porous substance (105); (3) storing gas to polarize the three parts;
the walls of the polarized gas container (102) adsorb the stored gas; the polarized porous substance (105) adsorbs the storage gas; the polarized storage gas adsorbs the polarized storage gas; under the combined action of the pressure intensity and the adsorption force of the added gas, the mass storage of the gas is realized;
the higher the direct-current voltage between the electric field electrodes 1 (104) and 2 (106), i.e. the stronger the field intensity of the external electric field, the higher the polarization field intensity, the higher the polarization intensity of the gas container (102) wall and the pore substance (105) stored gas; the greater the adsorption force between them, the more gas is stored with sufficient gas input; the stronger the polarization intensity is, the greater the pressure of the externally-added input gas is, and the more the stored gas is; the gas stored after the polarization of the external electric field is added is higher than the gas stored by only adding the same pressure by more than several orders of magnitude;
and (3) inflating: (1) the gas container (102) is used for inputting gas, and the gas pressure is increased: continuously pressing gas into the gas container (102) through the gas container port 1 (101) or the gas container port 2 (107) to increase the amount of the gas in the gas container (102) and increase the pressure of the gas in the gas container (102); (2) the direct current voltage at the two ends of the external polarized power supply (110) is increased and is transmitted to the electric field electrodes 1 (104) and 2 (106) through the leads 1 (108) and 2 (109); thereby increasing the voltage difference between the electric field electrodes 1 (104) and 2 (106), increasing the polarization electric field of the pore substance (105) in the gas container (102) and the stored gas in the gas container (102), enhancing the adsorption force of the pore substance (105) on the gas, and increasing the adsorption force between the stored gas and the stored gas;
air bleeding: when gas needs to be output outwards, (1) the polarization voltage is kept unchanged, the gas is discharged outwards by using the pressure inside the stored gas, and when the pressure of the gas inside the stored gas is smaller than a certain value, the polarization voltage is gradually reduced, so that the polarization intensity is reduced, the physical adsorption is further reduced, and the gas discharge is realized; (2) or simultaneously reducing the voltage of the polarized direct-current power supply, and discharging air outwards by gas pressure intensity; (3) or reducing the polarization voltage to discharge air outwards, and then reducing the air pressure to discharge air outwards;
depolarization: when alternating voltage is applied to the electric field electrodes 1 (104) and 2 (106), alternating electric fields are generated between the electric field electrodes 1 (104) and 2 (106) to make the wall of the gas container (102) of the gas container (1); (2) a porous substance (105); (3) storing the gas depolarizations; the adsorption force between the adsorbed storage gas and the adsorbed storage gas is reduced, or the adsorption force between the adsorbed storage gas and the pore substance (105) is reduced, or the adsorption force between the wall of the gas container (102) and the adsorbed storage gas is reduced, desorption occurs, and the gas is released;
when the stored gas is not completely released by the electric field polarized gas adsorption system, the gas container (102) is electrified by a heating electric heating wire (111) arranged in the porous substance (105) to generate heat, so that the porous substance (105) and the stored gas are heated, and the stored gas is released;
or a electret pore substance (105) replacing the pore substance (105), the electret pore substance itself having a polarity, the electret pore substance for adsorbing gas; when the adsorption amount of the gas needs to be increased, the voltages at the two ends of the electric field electrodes 1 and 104 and the electric field electrodes 2 and 106 are increased, so that the polarization of the electret pore substances (105) is further enhanced, and the purpose that more electret pore substances (105) adsorb the pressed gas is realized; simultaneously, the adsorption between the gases is increased; increasing the storage capacity of the gas; when gas needs to be released, the gas is directly released by using the pressure of the gas; or alternating voltage is applied on the electrode, and the electret pore substance in the gas container (102) depolarizes under the action of the alternating electric field to release adsorbed gas; or the gas container (102) is electrified and heated by a heating electric heating wire (111) arranged in the electret pore substance (105), and the electret pore substance (105) is heated to release the stored gas;
or the pore substance (105) or the electret pore substance (105) is removed, the gas container (102) is directly filled with the gas to be stored, and the pressure of the input gas is increased; simultaneously, voltages are applied to the electric field electrodes 1 (104) and the electric field electrodes 2 (106) to polarize (1) the wall of the gas container (102) and (2) the gas stored in the container; the wall of the gas container (102) is adsorbed with the filled gas, and adsorption is generated between the filled storage gas and the storage gas, so that high-density storage of the gas is realized; when gas release is required: opening a valve to directly release gas by using gas pressure; or reducing the polarization voltage at the two ends of the electric field electrodes 1 (104) and 2 (106) to release gas; or the electric field electrode 1 (104) and the electric field electrode 2 (106) are applied with alternating voltage at two ends to further reduce polarization and release gas; or current is applied to two ends of the heating electric heating wire (111), and the electric heating wire generates heat to release gas.
Preferred example 2:
a gas container (102), the conductor shield housing (103) being of spherical shape; or a gas container (102), the conductor shield housing (103) being of an ellipsoidal type; or a gas container (102), the conductor shield housing (103) being a cube; or a gas container (102), the conductor shield housing (103) being square; or a gas container (102), the conductor shield housing (103) being of a spherical irregular shape.
Preferred example 3:
electric field electrodes 1 (104), electric field electrodes 2 (106) are flat plates; or electric field electrodes 1 (104), electric field electrodes 2 (106) are arc-shaped; or electric field electrodes 1 (104), and electric field electrodes 2 (106) are irregular plates.
Preferred example 4:
the electric field polarized gas adsorption system is composed of 1 conductor shielding shell, the interior of the electric field polarized gas adsorption system is composed of 1 gas container, or 1 conductor shielding shell and 2 gas containers, or 1 conductor shielding shell and 3 gas containers, or 1 conductor shielding shell and n gas containers according to the scale of the system;
as shown in fig. 2, the gas storage system is composed of a plurality of groups of polarized plates and gas containers: a conductor shield case (201); electric field electrodes 1 (210), 2 (211), 3 (212), 4 (213), 5 (214);
gas container 1 (206), gas container 2 (207), gas container 3 (208), gas container n (209);
pore material 1 or electret pore material 1 (219), pore material 2 electret pore material 2 (220), pore material 3 or electret pore material 3 (221), pore material n or electret pore material n (222); heating wires are arranged in each group of pore substances or the pore substances of the electret;
a gas container input/output port 1A (202), a gas container input/output port 1B (215), a gas container input/output port 2A (203), a gas container input/output port 2B (216), a gas container input/output port 3A (204), a gas container input/output port 3B (217), a gas container input/output port nA (205), and a gas container input/output port nB (218);
a conductor shield case (201) in which n gas containers are designed; gas container 1 (206), gas container 2 (207), gas container 3 (208), gas container n (209); the n gas containers are arranged in parallel;
as shown in fig. 3, electric field electrodes 1 (301), electric field electrodes 2 (302), electric field electrodes 3 (303), and electric field electrode n (304); the lead (305) is connected with the electric field electrode 1 (301) and the electric field electrode 3 (303); the lead (306) is connected with the electric field electrode 2 (302) and the electric field electrode n (304);
all the odd electric field electrodes are connected together by leads, and all the even electric field electrodes are connected together by leads; the odd electric field electrodes are connected to the positive pole of the external direct current polarization power supply, and the even electric field electrodes are connected to the negative pole of the external direct current polarization power supply; or the odd electric field electrode is connected to the negative electrode of the external direct current polarization power supply, and the even electric field electrode is connected to the positive electrode of the external direct current polarization power supply;
or n-1 independent direct current power supplies are adopted, and each unit electrode can be connected at will;
the gas container may be spherical, or ellipsoidal, or cubic, or square, or irregular in shape;
the field electrodes may be flat, or curved, or irregular;
the gas container 1 (206), the gas container 2 (207), the gas container 3 (208), and the gas container n (209) are all provided with heating resistance wires, and the heating resistance wires and the current generate heat to promote the release of the stored gas.
Preferred example 5:
porous active carbon is adopted as the porous substance (105); or the porous substance (105) adopts nano porous carbon; or the pore material (105) adopts zeolite; or the pore substance (105) adopts graphene; or the pore substance (105) adopts a nano tube; or the porous substance (105) adopts porous alumina; or the porous material (105) adopts a molecular sieve; or the porous substance (105) adopts porous silica gel; or the porous substance (105) adopts porous aluminum silicate; or the pore substance (105) adopts diatomite; or the porous substance (105) adopts porous ion exchange resin; or the pore substance (105) adopts titanium dioxide; or the pore substance (105) adopts bentonite; or the porous substance (105) adopts sepiolite; or the porous substance (105) adopts fiber carbonized porous material; or the porous substance (105) adopts a metal organic framework material; or the pore substance (105) adopts an organic framework material; or the porous substance (105) adopts foamed aluminum; or other porous substances are adopted as the porous substances (105); the porous material (105) adopts LaNi5Or the porous substance (105) adopts FeTi; or the pore substance (105) adopts a magnesium pore substance; the hydrogen storage material stores gas in combination with polarization.
Preferred example 6:
the electric field polarized gas adsorption system can store hydrogen, oxygen, nitrogen, helium, chlorine, fluorine, neon, argon, xenon, radon, hydrocarbon or hydrocarbon compounds at normal temperature in a high density.
Preferred example 7:
the heating electric heating wire is linear, or the heating electric heating wire is arc-shaped, or the heating electric heating wire is irregular.
Preferred example 8:
the working principle of electric field polarized gas adsorption is that an external electric field polarizes a gas container (102), a pore substance (105) or a electret pore substance (105) and stored gas in the gas container (102); an attractive force between the gas container (102) wall and the stored gas; or the pore substance (105) or the electret pore substance (105) and the storage gas form an attractive force, and high-density storage of the storage gas is realized.
Although the embodiments of the present invention have been described with reference to the accompanying drawings, those skilled in the art will be able to make various changes and modifications within the scope of the appended claims and also some of the present designs.
Claims (8)
1. Electric field polarization gas adsorption system, characterized by:
an electric field polarized gas adsorption system comprising: a gas container port 1 (101), a gas container port 2 (107), a gas container (102), a conductor shielding shell (103), an electric field electrode 1 (104), an electric field electrode 2 (106), a pore substance (105) or a charge retention pore substance (105), a lead 1 (108), a lead 2 (109), an external polarized power supply (110) and a heating electric heating wire (111);
the gas container (102) is provided with 1, 2 or a plurality of gas container connecting ports for inputting, outputting or inputting/outputting gas; the gas container port 1 (101) and the gas container port 2 (107) are used for gas input, output or input/output of the gas container (102);
conductor shield housing (103): the external electromagnetic shielding shell of the electric field polarized gas adsorption system has the function of avoiding the external influence of the electric field generated by the electric field electrodes 1 (104), 2 (106) and the conductor shielding shell (103) and ensuring the safe operation of the electric field polarized gas adsorption system; the conductor shield housing (103) may be grounded or ungrounded; the conductor shielding shell (103) and the gas container (102) are combined together and bear the pressure of gas together; or the conductor shielding shell (103) is only used as a shielding shell, plays a shielding role on an electric field and does not bear the pressure of gas;
gas container (102): the electric field electrode 1 (104), the electric field electrode 2 (106) are externally applied with voltage to form an electric field, and the electric field acts on: (1) a gas container (102) wall; (2) a porous substance (105); (3) storing gas to polarize the three parts;
the walls of the polarized gas container (102) adsorb the stored gas; the polarized porous substance (105) adsorbs the storage gas; the polarized storage gas adsorbs the polarized storage gas; under the combined action of the pressure intensity and the adsorption force of the added gas, the mass storage of the gas is realized;
the higher the direct-current voltage between the electric field electrodes 1 (104) and 2 (106), i.e. the stronger the field intensity of the external electric field, the higher the polarization field intensity, the higher the polarization intensity of the gas container (102) wall and the pore substance (105) stored gas; the greater the adsorption force between them, the more gas is stored with sufficient gas input; the stronger the polarization intensity is, the greater the pressure of the externally-added input gas is, and the more the stored gas is; the gas stored after the polarization of the external electric field is added is higher than the gas stored by only adding the same pressure by more than several orders of magnitude;
and (3) inflating: (1) the gas container (102) is used for inputting gas, and the gas pressure is increased: continuously pressing gas into the gas container (102) through the gas container port 1 (101) or the gas container port 2 (107) to increase the amount of the gas in the gas container (102) and increase the pressure of the gas in the gas container (102); (2) the direct current voltage at the two ends of the external polarized power supply (110) is increased and is transmitted to the electric field electrodes 1 (104) and 2 (106) through the leads 1 (108) and 2 (109); thereby increasing the voltage difference between the electric field electrodes 1 (104) and 2 (106), increasing the polarization electric field of the pore substance (105) in the gas container (102) and the stored gas in the gas container (102), enhancing the adsorption force of the pore substance (105) on the gas, and increasing the adsorption force between the stored gas and the stored gas;
air bleeding: when gas needs to be output outwards, (1) the polarization voltage is kept unchanged, the gas is discharged outwards by using the pressure inside the stored gas, and when the pressure of the gas inside the stored gas is smaller than a certain value, the polarization voltage is gradually reduced, so that the polarization intensity is reduced, the physical adsorption is further reduced, and the gas discharge is realized; (2) or simultaneously reducing the voltage of the polarized direct-current power supply, and discharging air outwards by gas pressure intensity; (3) or reducing the polarization voltage to discharge air outwards, and then reducing the air pressure to discharge air outwards;
depolarization: when alternating voltage is applied to the electric field electrodes 1 (104) and 2 (106), alternating electric fields are generated between the electric field electrodes 1 (104) and 2 (106) to make the wall of the gas container (102) of the gas container (1); (2) a porous substance (105); (3) storing the gas depolarizations; the adsorption force between the adsorbed storage gas and the adsorbed storage gas is reduced, or the adsorption force between the adsorbed storage gas and the pore substance (105) is reduced, or the adsorption force between the wall of the gas container (102) and the adsorbed storage gas is reduced, desorption occurs, and the gas is released;
when the stored gas is not completely released by the electric field polarized gas adsorption system, the gas container (102) is electrified by a heating electric heating wire (111) arranged in the porous substance (105) to generate heat, so that the porous substance (105) and the stored gas are heated, and the stored gas is released;
or a electret pore substance (105) replacing the pore substance (105), the electret pore substance itself having a polarity, the electret pore substance for adsorbing gas; when the adsorption amount of the gas needs to be increased, the voltages at the two ends of the electric field electrodes 1 and 104 and the electric field electrodes 2 and 106 are increased, so that the polarization of the electret pore substances (105) is further enhanced, and the purpose that more electret pore substances (105) adsorb the pressed gas is realized; simultaneously, the adsorption between the gases is increased; increasing the storage capacity of the gas; when gas needs to be released, the gas is directly released by using the pressure of the gas; or alternating voltage is applied on the electrode, and the electret pore substance in the gas container (102) depolarizes under the action of the alternating electric field to release adsorbed gas; or the gas container (102) is electrified and heated by a heating electric heating wire (111) arranged in the electret pore substance (105), and the electret pore substance (105) is heated to release the stored gas;
or the pore substance (105) or the electret pore substance (105) is removed, the gas container (102) is directly filled with the gas to be stored, and the pressure of the input gas is increased; simultaneously, voltages are applied to the electric field electrodes 1 (104) and the electric field electrodes 2 (106) to polarize (1) the wall of the gas container (102) and (2) the gas stored in the container; the wall of the gas container (102) is adsorbed with the filled gas, and adsorption is generated between the filled storage gas and the storage gas, so that high-density storage of the gas is realized; when gas release is required: opening a valve to directly release gas by using gas pressure; or reducing the polarization voltage at the two ends of the electric field electrodes 1 (104) and 2 (106) to release gas; or the electric field electrode 1 (104) and the electric field electrode 2 (106) are applied with alternating voltage at two ends to further reduce polarization and release gas; or current is applied to two ends of the heating electric heating wire (111), and the electric heating wire generates heat to release gas.
2. The electric field polarized gas sorption system of claim 1, wherein:
a gas container (102), the conductor shield housing (103) being of spherical shape; or a gas container (102), the conductor shield housing (103) being of an ellipsoidal type; or a gas container (102), the conductor shield housing (103) being a cube; or a gas container (102), the conductor shield housing (103) being square; or a gas container (102), the conductor shield housing (103) being of a spherical irregular shape.
3. The electric field polarized gas sorption system of claim 1, wherein:
electric field electrodes 1 (104), electric field electrodes 2 (106) are flat plates; or electric field electrodes 1 (104), electric field electrodes 2 (106) are arc-shaped; or electric field electrodes 1 (104), and electric field electrodes 2 (106) are irregular plates.
4. The electric field polarized gas sorption system of claim 1, wherein:
the electric field polarized gas adsorption system is composed of 1 conductor shielding shell, the interior of the electric field polarized gas adsorption system is composed of 1 gas container, or 1 conductor shielding shell and 2 gas containers, or 1 conductor shielding shell and 3 gas containers, or 1 conductor shielding shell and n gas containers according to the scale of the system;
the gas storage system consists of a plurality of groups of polarized polar plates and gas containers: a conductor shield case (201); electric field electrodes 1 (210), 2 (211), 3 (212), 4 (213), 5 (214);
gas container 1 (206), gas container 2 (207), gas container 3 (208), gas container n (209);
pore material 1 or electret pore material 1 (219), pore material 2 electret pore material 2 (220), pore material 3 or electret pore material 3 (221), pore material n or electret pore material n (222); heating wires are arranged in each group of pore substances or the pore substances of the electret;
a gas container input/output port 1A (202), a gas container input/output port 1B (215), a gas container input/output port 2A (203), a gas container input/output port 2B (216), a gas container input/output port 3A (204), a gas container input/output port 3B (217), a gas container input/output port nA (205), and a gas container input/output port nB (218);
a conductor shield case (201) in which n gas containers are designed; gas container 1 (206), gas container 2 (207), gas container 3 (208), gas container n (209); the n gas containers are arranged in parallel;
electric field electrodes 1 (301), electric field electrodes 2 (302), electric field electrodes 3 (303), and electric field electrode n (304); the lead (305) is connected with the electric field electrode 1 (301) and the electric field electrode 3 (303); the lead (306) is connected with the electric field electrode 2 (302) and the electric field electrode n (304);
all the odd electric field electrodes are connected together by leads, and all the even electric field electrodes are connected together by leads; the odd electric field electrodes are connected to the positive pole of the external direct current polarization power supply, and the even electric field electrodes are connected to the negative pole of the external direct current polarization power supply; or the odd electric field electrode is connected to the negative electrode of the external direct current polarization power supply, and the even electric field electrode is connected to the positive electrode of the external direct current polarization power supply;
or n-1 independent direct current power supplies are adopted, and each unit electrode can be connected at will;
the gas container may be spherical, or ellipsoidal, or cubic, or square, or irregular in shape;
the field electrodes may be flat, or curved, or irregular;
the gas container 1 (206), the gas container 2 (207), the gas container 3 (208), and the gas container n (209) are all provided with heating resistance wires, and the heating resistance wires and the current generate heat to promote the release of the stored gas.
5. The electric field polarized gas sorption system of claim 1, wherein:
porous active carbon is adopted as the porous substance (105); or the porous substance (105) adopts nano porous carbon; or the pore material (105) adopts zeolite; or the pore substance (105) adopts graphene; or the pore substance (105) adopts a nano tube; or the porous substance (105) adopts porous alumina; or the porous material (105) adopts a molecular sieve; or the porous substance (105) adopts porous silica gel; or the porous substance (105) adopts porous aluminum silicate; or the pore substance (105) adopts diatomite; or the porous substance (105) adopts porous ion exchange resin; or the pore substance (105) adopts titanium dioxide; or the pore substance (105) adopts bentonite; or the porous substance (105) adopts sepiolite; or the porous substance (105) adopts fiber carbonized porous material; or the porous substance (105) adopts a metal organic framework material; or the pore substance (105) adopts an organic framework material; or the porous substance (105) adopts foamed aluminum; or other porous substances are adopted as the porous substances (105); the porous material (105) adopts LaNi5Or the porous substance (105) adopts FeTi; or the pore substance (105) adopts a magnesium pore substance; the hydrogen storage material stores gas in combination with polarization.
6. The electric field polarized gas sorption system of claim 1, wherein:
the electric field polarized gas adsorption system can store hydrogen, oxygen, nitrogen, helium, chlorine, fluorine, neon, argon, xenon, radon, hydrocarbon or hydrocarbon compounds at normal temperature in a high density.
7. The electric field polarized gas sorption system of claim 1, wherein:
the heating electric heating wire is linear, or the heating electric heating wire is arc-shaped, or the heating electric heating wire is irregular.
8. The electric field polarized gas sorption system of claim 1, wherein:
the working principle of electric field polarized gas adsorption is that an external electric field polarizes a gas container (102), a pore substance (105) or a electret pore substance (105) and stored gas in the gas container (102); an attractive force between the gas container (102) wall and the stored gas; or the pore substance (105) or the electret pore substance (105) and the storage gas form an attractive force, and high-density storage of the storage gas is realized.
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CN114506813A (en) * | 2022-03-01 | 2022-05-17 | 中能氢储(北京)能源工程研究院有限责任公司 | Graphene hydrogen storage device and control method thereof |
CN114873943A (en) * | 2022-05-20 | 2022-08-09 | 青岛理工大学 | Nano titanium dioxide/biochar composite material and preparation method and application thereof |
CN115355444A (en) * | 2022-09-08 | 2022-11-18 | 燕山大学 | Method for efficiently storing methane gas |
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AU6878100A (en) * | 1999-09-09 | 2001-04-10 | Sony Corporation | Carbonaceous material for hydrogen storage and method for preparing the same, and cell and fuel cell |
CA2528629A1 (en) * | 2003-06-10 | 2004-12-23 | General Electric Company | Field-assisted gas storage materials and fuel cells comprising the same |
US7896950B2 (en) * | 2006-02-21 | 2011-03-01 | Yashen Xia | Plasma-aided method and apparatus for hydrogen storage and adsorption of gases into porous powder |
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CN114506813A (en) * | 2022-03-01 | 2022-05-17 | 中能氢储(北京)能源工程研究院有限责任公司 | Graphene hydrogen storage device and control method thereof |
CN114873943A (en) * | 2022-05-20 | 2022-08-09 | 青岛理工大学 | Nano titanium dioxide/biochar composite material and preparation method and application thereof |
CN114873943B (en) * | 2022-05-20 | 2022-12-13 | 青岛理工大学 | Nano titanium dioxide/biochar composite material and preparation method and application thereof |
CN115355444A (en) * | 2022-09-08 | 2022-11-18 | 燕山大学 | Method for efficiently storing methane gas |
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