KR200365861Y1 - Apparatus for Water Treatment using Quartz Pipe immobilized with Photocatalyst - Google Patents

Abstract

The present invention is made by slurrying a photocatalyst, such as titanium dioxide, onto a small diameter quartz tube and baking it at 550 ° C. to a small diameter quartz tube with a fixed photocatalyst on a large diameter quartz tube without photocatalyst coating. A water treatment apparatus for charging a packed quartz tube module to a reactor and removing contaminants in water by shining a UV light source on top of the quartz tube module, wherein UV light is photocatalyst through the upper portion of a small diameter quartz tube coated with a photocatalyst. The coated side and contaminants in water come into contact with the photocatalyst to decompose the contaminants, and the light of the UV light source irradiated through the upper part of the large diameter quartz tube without the photocatalyst is evenly transmitted in water to increase the reaction speed. , The upper part of the UV light source relates to a water treatment device having a high arc light utilization by installing an arc-shaped UV light reflector.

Description

Apparatus for Water Treatment using Quartz Pipe immobilized with Photocatalyst}

The present invention relates to a water treatment apparatus for removing contaminants in water using a quartz tube module and a UV light source filled with a large diameter quartz tube bundle coated on a side of a photocatalyst and a large diameter quartz tube not coated with a photocatalyst.

The existing biological treatment method using a lot of microorganisms is not an effective water treatment method in the case of hardly degradable oh wastewater due to the disadvantages of environmentally adverse effects due to the difficult treatment environment of the facility. Because of this, a lot of research is being done on the advanced oxidation treatment technology.

Advanced oxidation treatment that decomposes organic substances in water into harmless compounds such as carbon dioxide and water by using OH radicals, which have stronger oxidizing power than existing oxidizers, uses photocatalysts such as ozone, UV irradiation or titanium dioxide. There is. The ozone system has a low UV production rate, selectively treats organic matter, and excludes the risk of ozone. In UV irradiation, scale generation due to iron salt used as a catalyst becomes a problem.

Photocatalytic oxidation technology that irradiates and oxidizes photocatalysts such as titanium dioxide by UV light is harmless to the human body and is safe as a clean material. In addition, the organic removal rate is faster than the existing methods, and has the ability to completely decompose almost all organic materials.

Currently, the water treatment system using a photocatalyst is divided into a powder and a stationary phase. In the case of a powder, the particle size is difficult to recover due to the small size of the powder, and thus the photocatalyst needs to be immobilized.

The present invention is designed to solve the problems of the prior art as described above, by fixing a photocatalyst, such as titanium dioxide, on the side of a small diameter quartz tube with high UV light transmittance and fixing the photocatalyst coated quartz tube bundle. A quartz tube module filled with a large diameter uncoated quartz tube was charged to the reactor, and a UV light source was mounted on the reactor and the top of the quartz tube module so that UV light was irradiated onto the quartz tube module to provide water treatment apparatus for water contaminants. Its purpose is to.

Therefore, the object of the present invention is to coat the photocatalyst on the side of small diameter quartz tube and heat-fix it, and to fill the large diameter quartz tube without photocatalyst coated small quartz tube bundle to make the quartz tube module. UV light mounted on the reactor and irradiated by the UV light source is transmitted to the photocatalyst through the small diameter quartz tube coated with the photocatalyst of the quartz tube module to decompose pollutants in the water by the photocatalyst coated on the quartz tube. The large diameter quartz tube, which corresponds to the shell of, not only fills and fixes the bundle of small diameter quartz tubes, but also transmits UV light to the top, bottom, and side surfaces of the quartz tube, thereby increasing the light utilization of the water and treating the pollutants in the water. It is to provide a water treatment device with improved efficiency.

The small quartz tube in which the photocatalyst, such as titanium dioxide, is fixed is impregnated with a small diameter quartz tube in a photocatalyst solution made of slurry of powdered titanium dioxide (TiO ₂ ) and dried at room temperature for 24 hours, and then The lower part was washed with a sponge soaked with water and calcined at 550 ° C. for 3 hours to prepare an immobilized quartz tube coated only with a photocatalyst. The large diameter quartz tube, which serves as the shell of the quartz tube module, drills a 3-5 mm hole in the side to increase contact between the water and the air in the device with the smaller diameter quartz tube.

Provided is a water treatment apparatus with high light utilization by attaching an arc-shaped reflector that reflects UV light on top of the UV light source and dissipates heat by the UV light source.

1 is a plan view of a quartz tube module composed of a combination of a small quartz tube bundle and a large quartz tube coated with a photocatalyst;

2 is a perspective view of a quartz tube module

3 is a perspective view of a water treatment apparatus using a photocatalyst fixed to a quartz tube

4 is a right side view of a water treatment apparatus using a photocatalyst fixed to a quartz tube equipped with a UV light reflector;

Description of the main parts of the drawing

1. device 3. UV light source

5. large quartz tube 7. small quartz tube

9. Flow hole 11. Photocatalyst

13. Air pump 15. Diffuser

17. Return line 19. Pump

21. Inlet 23. Outlet

25. Valve 27. Reflector

29. Perforated Plate 31. Perforated Plate Support

33. Water level 35. Photocatalyst module

Hereinafter, described with reference to the accompanying drawings, preferred embodiments of the present invention is as follows.

A plan view of a quartz tube module consisting of a combination of small quartz tube bundles and a large quartz tube coated with a photocatalyst, FIG. 2 is a perspective view of a quartz tube module, FIG. 3 is a perspective view of a water treatment apparatus using a photocatalyst fixed to a quartz tube, and FIG. Right side view of a water treatment apparatus using a photocatalyst fixed to a quartz tube provided with a UV light reflector.

As shown in FIG. 1,

The quartz tube module 35 is composed of a large quartz tube 5 having an inner diameter of 20 mm and an outer diameter of 22 mm, and a bundle of small quartz tubes 7 having an inner diameter of 1.5 mm having an outer diameter of 3 mm coated with a photocatalyst 11 on the side. consist of. The small quartz tube 7 was washed with 1 M sulfuric acid solution, washed three times with distilled water, impregnated with a photocatalyst solution such as 3 g / L titanium dioxide, and dried at room temperature for 24 hours. After wiping the upper and lower portions of (7) to remove the photocatalyst, it was fired for 3 hours in an electric furnace maintained at 550 ° C. and cooled at room temperature to produce a small quartz tube 7 coated with the photocatalyst 11 on the side. When the small quartz tube 7 coated with the photocatalyst 11 is filled with the large quartz tube 5, the quartz tube module 35 is completed, and the small quartz tube 7 coated with the photocatalyst 11 is UV The light transmitted from the light source to the lower part of the light is contacted with the photocatalyst 11 to remove contaminants in the water.

As shown in FIG. 2,

The large quartz tube (5) outside the quartz tube module (35) has a 3-5 mm flow hole (9) on the side to increase contact between the water and the air in the device with a small diameter quartz tube. Constantly drilled at intervals and do not coat the photocatalyst, where the lengths of the large quartz tube 5 and the small quartz tube 7 are the same. The large quartz tube 5 serves as a shell of the quartz tube module 35 and transmits light irradiated from the UV light source into the water to transmit light from the side to the small quartz tube 7 coated with the photocatalyst 11. ,

As shown in FIG. 3,

The quartz tube module 35 is filled in the device 1 and a UV light source 3 is installed on the device 1 cm above the device 1. Wastewater flowing into the inlet 21 is introduced into the apparatus 1, and the light irradiated by the UV light source 3 is transferred from the top to the bottom and side to side through the large quartz tube 5, and the quartz The UV light transmitted from the top to the bottom of the small quartz tube 7 in the tube module 35 is removed by the photochemical reaction with the photocatalyst on the side of the small quartz tube 7 and at the side of the large quartz tube 5 The transmitted UV light is also transmitted to the photocatalyst 11 on the side of the small quartz tube 7 to decompose contaminants in the water incidentally. The air supplied by the air pump 13 is supplied to the apparatus 1 through the diffuser 15. The supplied air induces a flow inside the device 1, and oxygen in the air serves to maintain high activity of the photocatalyst by inhibiting recombination of electrons and holes generated by the photocatalytic action. The lower portion of the photocatalyst module 35 is located above the hole plate 29 having a smaller hole than the quartz tube 7 having a smaller diameter supported by the hole plate support 31. The hole plate 29 serves to help circulation of the aqueous solution decomposed by the quartz tube module. The treated water is discharged through an outlet 23 having a valve 25 capable of adjusting the flow rate, and the outlet 23 through the pump 19 and the conveying pipe 17 for the complete mixing of the aqueous solution in the apparatus 1. Return the water in the part.

As shown in FIG.

On top of the UV light source 3 is placed an arc reflector 27 having a width of 140% of the width of the device 1 and a length of 120% of the length of the device 1 so that the UV light above the UV light source 3 is lowered. Reflects heat and emits heat from the UV light source.

As described above, according to the present invention, a small quartz tube is filled with a small quartz tube bundle coated with a photocatalyst on its side in a large quartz tube with a flow hole, and the quartz tube is irradiated from the top of the quartz tube module. The light irradiated on the top is irradiated to the photocatalyst coated on the side of the small quartz tube to remove contaminants in the water, and serves as a shell of the quartz tube module and at the same time, the large quartz tube not coated with the photocatalyst is irradiated with UV light source. UV light utilization is high by dispersing the UV light evenly in the device.

In addition, the water in the apparatus 1 is agitated through the air supplied through the diffuser inside the apparatus, and a pump and a return pipe can be installed to circulate the water to form a complete mixture inside the apparatus, thereby increasing the treatment rate of water contaminants. Can be.

Claims (3)

A small quartz tube with an inner diameter of 1.5 mm and an outer diameter of 3 mm was impregnated with a photocatalyst solution such as titanium dioxide, dried, and heat-treated at 550 ° C. for 3 hours to obtain a coated small quartz tube bundle having an inner diameter of 20 mm and an outer diameter of 22 mm. A quartz tube module made by filling a large quartz tube is mounted on a hole plate supported by a hole plate support in the device, and a UV light source is installed on the top of the quartz tube module so that a small quartz tube coated with a photocatalyst is brought into contact with UV light. Due to the photocatalytic action and UV light radiated to the upper side of the large quartz tube uncoated by the photocatalyst, the UV light transmitted to the side and the lower side of the large quartz tube additionally treats contaminants in the water, and And a conveying pump and a conveying pipe to convey the water in the apparatus and to mix the water in the apparatus. The method of claim 1, A water treatment apparatus, characterized in that the coating is coated with a photocatalyst only on the side of a small quartz tube having an inner diameter of 1.5 mm and an outer diameter of 3 mm, with no upper and lower coatings. The method of claim 1, The large quartz tube filling the small quartz tube coated with the photocatalyst does not coat the photocatalyst, so it receives UV light emitted from the UV light source from the top and irradiates it to the bottom and side evenly, and is processed on the side of the small quartz tube coated with the photocatalyst. A water treatment device characterized in that a 3-5 mm hole is drilled at an interval of 3-5 mm to smoothly mix the water with the bulk water.