CN109758879B - A composite air dehumidification and drying system using silica gel and high-voltage electric field - Google Patents

Abstract

The invention relates to a composite air dehumidification and drying system using silica gel and high-voltage electric field, which includes a silica gel dehumidification device, a high-voltage electric field dehumidification device and an exhaust device; the silica gel dehumidification device is provided with an air inlet duct, and the silica gel dehumidification device is connected with The high-voltage electric field dehumidification devices are connected to each other, and the exhaust device is also connected to the high-voltage electric field dehumidification device; the silica gel dehumidification device is provided with a silica gel coating that absorbs moisture in the air; the high-voltage electric field dehumidification device is formed to absorb moisture in the air. The moisture excites and separates the high-voltage electric field, and the high-voltage electric field dehumidification device is also provided with lithium chloride that absorbs and excites the separated moisture. The beneficial effects of the present invention are: the air is dehumidified twice in sequence before being discharged. The high dehumidification efficiency can ensure the dryness of the discharged air, and one dehumidification does not consume any energy. The entire system has the advantage of low energy consumption.

Description

A composite air dehumidification and drying system using silica gel and high-voltage electric field

Technical field

The invention relates to the field of air drying, and in particular to a composite air dehumidification and drying system utilizing silica gel and high-voltage electric field.

Background technique

The field of air dehumidification has a wide range of applications in various industries, including heating, ventilation and air conditioning; flue gas dehydration, natural gas and organic vapors; compressed air drying, vapor recovery and air treatment in packaging and processing industries, etc. Air dehumidification methods include ventilation dehumidification, heating dehumidification, freezing dehumidification, solution dehumidification, solid dehumidification, dry dehumidification, etc., as well as hybrid dehumidification that combines the above multiple dehumidification methods.

As a new type of drying technology, high-voltage electric field drying technology has a good retention effect on materials due to its unique normal temperature drying characteristics; and its advantages of low equipment cost and low operating costs make it easier to enter industrial production and can play a role significant role.

Contents of the invention

To sum up, the technical problem to be solved by the present invention is to provide a composite air dehumidification and drying system using silica gel and high-voltage electric field.

The technical solution of the present invention to solve the above technical problems is as follows: a composite air dehumidification and drying system using silica gel and high-voltage electric field, including a silica gel dehumidification device, a high-voltage electric field dehumidification device and an exhaust device; the silica gel dehumidification device is provided with an air inlet duct , and the silica gel dehumidification device and the high-voltage electric field dehumidification device are connected to each other, and the exhaust device is also connected to the high-voltage electric field dehumidification device to draw outside air into the air inlet pipe and pass through the silica gel dehumidification device and the high-voltage electric field dehumidification device in sequence. The high-voltage electric field dehumidification device; the silica gel dehumidification device is provided with a silica gel coating that absorbs moisture in the air; the high-voltage electric field dehumidification device forms a high-voltage electric field that excites and separates moisture in the air. The device is also equipped with lithium chloride that absorbs the moisture separated by stimulation.

The beneficial effects of the present invention are: the air is first dehumidified once by the silica gel coating absorbing moisture, and then enters the high-voltage electric field to stimulate and separate the entrained moisture and is absorbed by lithium chloride for secondary dehumidification. The air is sequentially dehumidified twice and then dehumidified. The high efficiency of discharge and dehumidification can ensure the dryness of the discharge air, and one dehumidification does not consume any energy. The entire system has the advantage of low energy consumption.

On the basis of the above technical solutions, the present invention can also make the following improvements:

Further, the silica gel dehumidification device includes a first housing and a plastic pillar; the air inlet pipe is provided on one side of the first housing; there are multiple plastic pillars, which are evenly arranged on the first Inside the housing, the surface of each plastic pillar is coated with the silicone coating; the side of the first housing opposite to the air inlet duct is connected to the high-voltage electric field dehumidification device through a first air duct .

The beneficial effect of adopting the above further solution is that the contact area between the air and the silica gel coating is large, which is conducive to the silica gel coating absorbing moisture in the air.

Further, the high-voltage electric field dehumidification device includes a high-voltage generator, a second housing, an electrode plate and a ground plate; one side of the second housing is connected to the first housing through the first air duct, and the other side is connected to the first housing through the first air duct. One side is connected to the exhaust device through a second air duct; the lithium chloride is located in the second housing and corresponds to the position of the second air duct port;

The electrode plate and the ground plate are relatively fixed up and down inside the second housing through insulating rods, and the high voltage generator is located outside the second housing and connected to the electrode plate through wires. The ground plate is grounded to form a high-voltage electric field with the electrode plate; a plurality of electrode needles are evenly provided on the electrode plate.

The beneficial effect of adopting the above further solution is that the moisture in the air is excited and separated by the high-voltage electric field and absorbed by lithium chloride for secondary dehumidification.

Further, the exhaust device includes a third housing, an exhaust fan and an exhaust duct; one side of the third housing is connected to the second housing through the second air duct, and the other side is provided with The exhaust duct; the exhaust fan for discharging dry air through the exhaust duct is provided in the third housing.

Further, the first housing, the second housing and the third housing are respectively provided with openable and closable doors.

The beneficial effect of adopting the above-mentioned further solution is that it facilitates inspection and repair of the internal working conditions of each housing.

Description of the drawings

Figure 1 is an overall three-dimensional view of the present invention;

Figure 2 is a cross-sectional view of the present invention;

Figure 3 is an internal structural diagram of the high-voltage electric field dehumidification device and the exhaust device.

In the drawings, the parts represented by each number are listed as follows:

1. Air inlet duct, 2. Lithium chloride, 3. First shell, 4. Plastic pillar, 5. First air duct, 6. High voltage generator, 7. Second shell, 8. Electrode plate, 9 , Ground plate, 10. Second air duct, 11. Insulating tube, 12. Motor needle, 13. Third housing, 14. Exhaust fan, 15. Exhaust duct.

Detailed ways

The principles and features of the present invention are described below with reference to the accompanying drawings. The examples cited are only used to explain the present invention and are not intended to limit the scope of the present invention.

As shown in Figure 1-3, a composite air dehumidification and drying system using silica gel and high-voltage electric field includes a silica gel dehumidification device, a high-voltage electric field dehumidification device and an exhaust device. An air inlet pipe 1 is provided on the silica gel dehumidification device, and the silica gel dehumidification device and the high-voltage electric field dehumidification device are connected to each other. The exhaust device is also connected to the high-voltage electric field dehumidification device to pass the external air through the inlet. The air duct 1 is drawn in and passes through the silica gel dehumidification device and the high-voltage electric field dehumidification device in sequence. The silica gel dehumidification device is equipped with a silica gel coating that absorbs moisture in the air. A high-voltage electric field is formed in the high-voltage electric field dehumidification device to excite and separate the moisture in the air. The high-voltage electric field dehumidification device is also provided with lithium chloride 2 that absorbs the excited and separated moisture.

The silicone dehumidification device includes a first housing 3 and a plastic support 4 . The air inlet pipe 1 is provided on one side of the first housing 3 . There are multiple plastic pillars 4 , which are evenly arranged inside the first housing 3 . The surface of each plastic pillar 4 is coated with the silicone coating. The side of the first housing 3 opposite to the air inlet duct 1 is connected to the high-voltage electric field dehumidification device through the first air duct 5 . Silica gel coating, that is, silica gel desiccant, is a highly active adsorbent material. It is usually produced by reacting sodium silicate and sulfuric acid and undergoing a series of post-treatment processes such as aging and acid bubbles. Silica gel is an amorphous material, and its chemical formula is mSiO2.nH2O. It is insoluble in water and any solvent, non-toxic, tasteless, chemically stable, and does not react with any substances except strong alkali and hydrofluoric acid. The chemical composition and physical structure of silica gel determine that it has many characteristics that are difficult to replace by other similar materials. Silica gel desiccant has high adsorption performance, good thermal stability, stable chemical properties, and high mechanical strength. The air is first dehumidified by absorbing moisture from the silica gel coating of the silica gel dehumidification device. The surface of each plastic pillar 4 is coated with the silica gel coating, so that the contact area between the air and the silica gel coating is large, which is conducive to the absorption of the silica gel coating. Moisture in the air.

The high-voltage electric field dehumidification device includes a high-voltage generator 6 , a second housing 7 , an electrode plate 8 and a ground plate 9 . One side of the second housing 7 is connected to the first housing 3 through the first air duct 5 , and the other side is connected to the exhaust device through the second air duct 10 . The lithium chloride 2 is located in the second housing 7 and corresponds to the port of the second air duct 10 . The electrode plate 8 and the ground plate 9 are relatively fixed up and down inside the second housing 7 through insulating rods 11 respectively. The high-voltage generator 6 is located outside the second housing 7 and connected through wires. The electrode plate 8 and the ground plate 9 are grounded to form a high voltage electric field with the electrode plate 8 . A plurality of electrode needles 12 are evenly arranged on the electrode plate 8 . When there is no charge source inside the medium, charge conservation determines the charge accumulation at the interface of the two media. Its polarity is: Under the action of the electric field, charges are generated on the interface of two stacked ohmic fluids. If there is The charge relaxation time of the medium near the excitation electrode is greater than the charge relaxation time of the medium far away from the electrode. The charge on the interface has the opposite polarity to that of the excitation electrode. The shear force on the interface is in the same direction as the traveling wave and is driven forward; if the excitation electrode The charge relaxation time in the vicinity is shorter than the charge relaxation time in the farther medium, then the charge on the interface has the same polarity as the excitation electrode, and the direction of the shear force is opposite to the direction of the traveling wave, forming a backward drive. Under normal circumstances, the material can be assumed to be a homogeneous dielectric. The dielectric constant is less affected by the outside world. The charge relaxation time is mainly determined by the conductivity. For low voltage or high frequency conditions, the charge emitted by the electrode mainly gathers near the electrode. From the order of magnitude See, when a dielectric is charged, its conductivity is greater than when it is uncharged, and the conductivity gradient causes the relaxation time to increase outward from the electrode, driving it backward. When at high voltage or low frequency, before the polarity of the electrode is reversed, the charge emitted by the electrode crosses the center line, forming the opposite situation to the previous situation, thus driving forward. Regardless of forward driving or reverse driving, the material will be neutralized. The water molecules are released or the hydrogen bonds are broken to achieve the purpose of dehydration. The high-voltage electric field in the high-voltage electric field dehumidification device effectively stimulates and separates the remaining moisture in the air. The separated moisture is absorbed by lithium chloride for secondary dehumidification. The high dehumidification efficiency can ensure the dryness of the discharged air.

The exhaust device includes a third housing 13 , an exhaust fan 14 and an exhaust pipe 15 . One side of the third housing 13 is connected to the second housing 7 through the second air duct 10 , and the other side is provided with the exhaust duct 15 . The exhaust fan 14 for discharging dry air through the exhaust pipe 15 is provided in the third housing 13 . The first housing 3, the second housing 7 and the third housing 13 are respectively provided with openable and closable doors to facilitate inspection of the internal working conditions of each housing.

The above are only preferred embodiments of the present invention and are not intended to limit the present invention. Any modifications, equivalent substitutions, improvements, etc. made within the spirit and principles of the present invention shall be included in the protection of the present invention. within the range.

Claims (3)

1. The composite air dehumidifying and drying system utilizing the silica gel and the high-voltage electric field is characterized by comprising a silica gel dehumidifying device, a high-voltage electric field dehumidifying device and an air exhausting device; an air inlet pipe (1) is arranged on the silica gel dehumidification device, the silica gel dehumidification device is communicated with the high-voltage electric field dehumidification device, and the air suction device is also communicated with the high-voltage electric field dehumidification device so as to suck external air through the air inlet pipe (1) and sequentially pass through the silica gel dehumidification device and the high-voltage electric field dehumidification device; a silica gel coating for absorbing moisture in the air is arranged in the silica gel dehumidification device; a high-voltage electric field which is used for exciting and separating water in the air is formed in the high-voltage electric field dehumidification device, and lithium chloride (2) which is used for absorbing the water which is excited and separated is also arranged in the high-voltage electric field dehumidification device;

the silica gel dehumidification device comprises a first shell (3) and a plastic pillar (4); one side of the first shell (3) is provided with the air inlet pipe (1); the plastic struts (4) are uniformly arranged in the first shell (3), and the surface of each plastic strut (4) is coated with the silica gel coating; the side, opposite to the air inlet pipe (1), of the first shell (3) is communicated with the high-voltage electric field dehumidification device through a first air pipe (5);

the high-voltage electric field dehumidification device comprises a high-voltage generator (6), a second shell (7), an electrode plate (8) and a grounding plate (9); one side of the second shell (7) is communicated with the first shell (3) through the first air pipe (5), and the other side of the second shell is communicated with the air draft device through a second air pipe (10); the lithium chloride (2) is positioned in the second shell (7) and corresponds to the position of the port of the second air pipe (10);

the electrode plate (8) and the grounding plate (9) are respectively fixed inside the second shell (7) vertically relatively through an insulating rod (11), the high-voltage generator (6) is positioned on the outer side of the second shell (7) and is connected with the electrode plate (8) through a wire, and the grounding plate (9) is grounded so as to form a high-voltage electric field with the electrode plate (8); a plurality of electrode needles (12) are uniformly arranged on the electrode plate (8).

2. The composite air dehumidifying and drying system using silica gel and high-voltage electric field according to claim 1, wherein the air extracting device comprises a third housing (13), an air extracting fan (14) and an air exhausting pipe (15); one side of the third shell (13) is communicated with the second shell (7) through the second air pipe (10), and the other side of the third shell is provided with the exhaust pipe (15); the third housing (13) is provided with the exhaust fan (14) for exhausting the dry air through the exhaust duct (15).

3. The composite air dehumidifying and drying system using silica gel and high-voltage electric field according to claim 2, wherein the first housing (3), the second housing (7) and the third housing (13) are respectively provided with a door which can be opened and closed.