KR102449488B1 - Hybrid photocatalyst air purifying apparatus of double tube structure - Google Patents

Abstract

The present invention relates to a hybrid photocatalytic purification apparatus having a double tube structure. The hybrid photocatalytic purification apparatus, according to the present invention, comprises: an external tube (100); an internal tube (200); a lamp shaft (300); a first photocatalyst plate (400); a second photocatalyst plate (500); a rotary impeller (600); and a fluid accelerator (700). According to the present invention, purification efficiency can be improved.

Description

Hybrid photocatalyst air purifying apparatus of double tube structure

The present invention relates to a hybrid photocatalytic purification device having a double tube structure, and more particularly, the introduced air moves along the spiral first photocatalyst plate fixed to the outer periphery of the inner tube disposed inside the outer tube while moving along the outer periphery of the lamp shaft placed in the inner tube again. It moves along the spiral second photocatalyst plate fixed to the It relates to a hybrid photocatalytic purification device having a double tube structure to improve air purification ability.

In general, a photocatalytic purification device contacts an electrolyte made of titanium dioxide (Ti02) and irradiates the light of a lamp capable of photochemical reaction to a photocatalyst that is separated into electrons and holes having negative and positive charges. Contamination through OH- (hydroxyl group) It is a device for purifying gas or liquid.

Such a photocatalyst purification apparatus is disclosed in prior art documents as being composed of a plurality of photocatalyst plates coated with a photocatalyst, and a lamp for generating light capable of photochemical reaction on the photocatalyst plates.

However, although the prior art has an effect of purifying a fluid such as air through a photocatalyst, there is a problem in selectively applying it to a narrow space or a specific space because the utilization of the purifier is low.

In addition, the problem of the prior art is that the air inlet and outlet of the purifier have a directional structure, so that the circulation of the fluid rapidly passes between the inlet and the outlet, thereby reducing the purification efficiency of the polluted air.

In addition to the problems of the prior art, there is a need to develop a photocatalytic purification device capable of using a technique for increasing purification efficiency by sufficiently generating a photochemical reaction in the process of receiving or flowing inside the purification device itself.

Literature 1. Korean Patent Registration No. 10-2084828 (Registration Date: 2020.03.03) Literature 2. Korean Patent Registration No. 10-1601246 (Registration Date: 2016.03.02) Literature 3. Korean Patent Registration No. 10-2174986 (Registration Date: 2020. 10. 30)

An object of the present invention is to solve the above problems, and it is composed of an inner tube inside the outer tube and the inner tube and a lamp shaft inside the inner tube. A hybrid photocatalytic purifier with a double-tube structure that can improve purification efficiency by increasing the residence time of air in the purifier as the air passing between the outer and inner tubes passes between the inner tube and the lamp shaft again by providing 2 photocatalyst plates. is to do

An embodiment of the present invention for achieving the above object is a hollow exterior formed in a horizontal length,

An inner tube provided inside the exterior and formed in a hollow transverse length while having an outer diameter smaller than the inner diameter of the exterior;

A lamp shaft provided inside the inner tube and formed in a horizontal length having an outer diameter smaller than the inner diameter of the inner tube;

A first photocatalyst plate having an outer circumferential surface in contact with the inner circumferential surface of the outer tube as the inner circumferential surface is coupled to the outer circumferential surface of the inner tube and spirally formed along the transverse direction of the inner tube;

a second photocatalyst plate having an outer circumferential surface interfacing with the inner circumferential surface of the inner tube as the inner circumferential surface is coupled to the outer periphery of the lamp shaft, and spirally formed along the transverse direction of the lamp shaft;

A rotating impeller, which is mounted on the inner surface of the coupling socket sealing the other end of the exterior, protrudes horizontally in the center, and is composed of a rotating shaft with the end facing the other end of the inner tube and a rotating blade formed on the outer circumferential surface of the rotating shaft,

It is mounted inside a tubular guide tube formed with a predetermined horizontal length so as to communicate with one end of the inner tube located inside one end of the exterior, and the other end is connected to the second optical axis plate and has a double tube structure including a vortex prevention fluid accelerator formed to protrude A hybrid photocatalytic purification device is provided.

On the other hand, the outer diameter of the rotation shaft of the impeller is formed to be smaller than the inner diameter of the inner tube while being larger than the outer diameter of the ramp shaft, and a plurality of rotor blades are formed on the outer peripheral surface of the rotation shaft to be spaced apart in a curved shape, and a plurality of rotor blade units formed on the outer periphery of the rotation shaft are There is provided a hybrid photocatalytic purification device having a double tube structure in which the outer diameter is gradually reduced toward the end of the rotation shaft.

On the other hand, a socket part connected to one end of the exterior in communication with the other end is connected and fixed to one end of the exterior, and one end of the socket part is connected to the exterior in communication with the exterior, and a columnar first space having a large inner diameter compared to the exterior of the exterior is formed. Provided is a hybrid photocatalytic purification device having an inlet socket configured as an inlet, wherein one end of the guide tube accommodating the fluid accelerator protrudes and extends to the outside of the inlet through the first space.

On the other hand, the inner tube provides a hybrid photocatalytic purification device having a double tube structure formed of a transparent material so that the light source emitted from the lamp shaft is transmitted.

On the other hand, a ring-shaped support disk provided at the rear side of the inner tube and whose outer peripheral surface is in close contact with the inner peripheral surface of the exterior, a round-bar-shaped support rod disposed in the inner center of the support disk, and a connecting plate having both ends connected to the inner peripheral surface of the support disk and the outer peripheral surface of the support rod, respectively A hybrid photocatalytic purification device having a double tube structure in which three places are arranged on the inner periphery of the support disk at equal intervals, at this time, a stepped step is formed on one side of the connecting plate, and the step of the connecting plate is surface-bonded to the inner peripheral surface of the other end of the inner tube. provides

On the other hand, the first and second photocatalyst plates provide a hybrid photocatalytic purification device having a double tube structure in which a plurality of through holes are formed.

According to the present invention as described above, while having a double tube structure composed of an outer tube and an inner tube, when moving through each tube, it comes into contact with the spiral first and second photocatalyst plates to increase the air purification efficiency through a photocatalytic reaction, and to purify the double tube structure It has the effect of improving the purification efficiency by increasing the residence time of the air in the device to cause a sufficient photocatalytic reaction.

1 is a perspective view of a hybrid photocatalytic purification device having a double tube structure according to an embodiment of the present invention;
2 is an internal cross-sectional view of a hybrid photocatalytic purification device having a double tube structure according to an embodiment of the present invention.
3 is an exploded view of a hybrid photocatalytic purification device having a double tube structure according to an embodiment of the present invention.
4 is a perspective view (a) of an impeller and a perspective view (b) of a support socket in a hybrid photocatalytic purification device having a double tube structure according to an embodiment of the present invention.
5 is a front view (a) and a perspective view (b) of a fluid accelerator installed inside a guide tube in a hybrid photocatalytic purification device having a double tube structure according to an embodiment of the present invention.
6 is a cross-sectional view of the coupling structure of the main shaft - the first tube - the second tube connected and installed in front of the support socket in the hybrid photocatalytic purification device having a double tube structure according to an embodiment of the present invention.
7 is a partial structural diagram in which a straight guide and a collision rod are installed on the outer periphery of the first tube in the hybrid photocatalytic purification device having a double tube structure according to an embodiment of the present invention.

In order to achieve the above object, the following embodiments will be described in detail with reference to the drawings.

As shown in Figures 1 to 5, an embodiment of the present invention is a hollow exterior 100 formed in a horizontal length,

An inner tube 200 provided inside the exterior 100 and formed in a hollow transverse length while having an outer diameter smaller than the inner diameter of the exterior 100,

A ramp shaft 300 provided inside the inner tube 200 and formed in a horizontal length having an outer diameter smaller than the inner diameter of the inner tube 200,

The first photocatalyst plate 400 is formed in a spiral along the transverse direction of the inner tube 200, the outer circumferential surface is interviewed on the inner circumferential surface of the outer surface 100 while the inner circumferential surface is coupled to the outer circumferential surface of the inner tube 200;

A second photocatalyst plate 500, which is spirally formed along the transverse direction of the lamp shaft 300, with the outer circumferential surface facing the inner circumferential surface of the inner tube 200 while the inner circumferential surface is coupled to the outer periphery of the lamp shaft 300;

It is mounted on the inner surface of the coupling socket 110 sealing the other end of the outer tube 100 and protrudes horizontally in the center so that the end is adjacent to the other end of the inner tube 200 and the outer peripheral surface of the rotating shaft 610. A rotary impeller 600 consisting of a rotary blade 620 formed on the

It is mounted inside a tubular guide tube 800 formed with a predetermined horizontal length to communicate with one end of the inner tube 200 located inside one end of the exterior 100, and the other end is connected to the second optical storage plate 500 and protrudes It provides a hybrid photocatalytic purification device (10, hereinafter referred to as a 'purifying device') having a double tube structure including the formed vortex prevention fluid accelerator 700 .

The purification device 10 of the present invention is formed in a double tube structure of the outer tube 100 and the inner tube 200, and the air introduced from the outside is moved through the outer tube 10) and the air is moved through the inner tube 200 again. has a movement path of

As shown in FIGS. 2 and 3, the exterior 100 is formed in a predetermined horizontal length as a hollow shape with both ends open, and the interior tube 200 is provided in a horizontal length in the inner center of the exterior 100. 100) is formed in a hollow shape with both ends open while having a small outer diameter compared to the inner diameter, in this case, the horizontal length of the inner tube 200 is formed to be smaller than the horizontal length of the outer tube 100, the inner tube 200 Silver may be formed of a transparent material through which light is transmitted.

And, as shown in FIG. 2, the lamp shaft 300 is provided in a horizontal length at the inner center of the inner tube 200 and has an outer diameter smaller than the inner diameter of the inner tube 200, and the lamp shaft 300 has a vertical cross section. It has a circular shape, and may be any one of a UV-C lamp, a UV-A or UV-B lamp, and is not limited thereto, and may be any lamp that causes a photochemical reaction, for example, an ozone lamp or an LED lamp. can

And, as shown in FIGS. 2 and 3 , the first photocatalyst plate 400 has the inner peripheral end coupled to the outer peripheral surface of the inner tube 200 while the outer peripheral end is interviewed on the inner peripheral surface of the outer tube 200, the inner tube 200 is formed in a spiral along the transverse direction of

When the inner peripheral end of the first photocatalyst plate 400 is surfaced on the outer peripheral surface of the inner tube 200, it is formed in a fixed coupling form, and at this time, the pitch between the pitches of the first photocatalyst plate 400 is maintained constant by the air flow rate. will become

And, as shown in FIGS. 2 and 3, the second photocatalyst plate 500 has an inner peripheral end coupled to the outer periphery of the lamp shaft 300, and the outer peripheral end faces the inner peripheral surface of the inner tube 200, and the lamp shaft ( 300) is formed in a spiral along the transverse direction.

When the inner peripheral end of the second photocatalyst plate 500 is surfaced on the outer peripheral surface of the lamp shaft 300, it is formed in a fixed coupling form, and at this time, the pitch between the pitches of the second photocatalyst plate 500 is constant by the air flow rate. will be maintained

And as shown in FIGS. 2 and 4 (a), the impeller 600 is rotated by receiving power through an external power source, and by forcibly sucking the air introduced through the exterior 100, the inner tube 200 As to be discharged to the inside, it is mounted on the inner surface of the coupling socket 110 that seals the other end of the outer tube 100 and protrudes horizontally in the center so that the end is adjacent to the other end of the inner tube 200 with the rotating shaft 610 and It is composed of a rotary blade 620 formed on the outer peripheral surface of the rotary shaft (610).

The rotating shaft 610 has the other end connected and fixed to the center of the inner surface of the coupling socket 110, and the other end is disposed adjacent to the other end of the lamp shaft 300 located at the other end of the inner tube 200, and the rotating blade 620 is a rotating shaft. A plurality of pieces are arranged on the outer periphery of the 610 connected at equal intervals.

More specifically, the outer diameter of the rotary shaft 610 of the impeller 600 is formed to be smaller than the inner diameter of the inner tube 200 while being larger than the outer diameter of the ramp shaft 300, and the rotary blade 620 is the rotary shaft 610 ) A plurality of pieces are formed to be spaced apart in a curved shape on the outer circumferential surface, and the outer diameter of the plurality of rotary blades 620 units formed on the outer circumference of the rotary shaft 610 is gradually reduced toward the end of the rotary shaft 610, where the rotary shaft 610 ) refers to an end of the rotation shaft 610 adjacent to the other end of the ramp shaft 300 .

When describing the space shape between the rotating shaft 610 and the rotating blade 620 in more detail, the impeller 600 has rotating blades 620 on the outer circumferential surface of the rotating shaft 610 at equal radial intervals to form the rotating shaft 610 . ) has a space shape between the rotor blades 620 forming a flow path that is gradually narrowed toward the rotation blade 620 in the direction of rotation and the forward direction in the axial radial direction of the axial direction.

In addition, it is okay to form a flow path in which the rotor blades 620 are bent in the rotation direction and gradually widen.

In addition, although not shown in the drawings, a fan member having a bell mouth portion may be provided instead of the impeller 600 , and a bell mouth portion is formed at the edge of the fan member to suck in air introduced through the exterior and discharge formed in the center A fan member having a structure for discharging air back to the inner tube through the fan is provided.

And, as shown in FIGS. 2 and 5 , the air moved through the second photocatalyst plate 500 in the inner tube 200 is forcibly moved by the operation of the impeller 600 , and at this time, one end of the inner tube 200 is inside the inner tube 200 . Air discharged to one end of the second photocatalyst plate 500 located at Since the rectilinear kinetic energy to move in the rectilinear direction is reduced, the airflow discharged from the guide tube 800 does not reach a long distance, spreads in all directions, and the speed is rapidly lowered.

Accordingly, the fluid accelerator 700 is installed inside the guide tube 800 while being connected to one end of the ramp shaft 300, and is purified through between the outer periphery of the fluid accelerator 700 and the inner periphery of the guide tube 800 . The exhausted air is accelerated and discharged in a straight airflow.

The fluid accelerator 700 is provided inside the guide tube 800 and the other end is connected to or interviewed at one end of the ramp shaft 300 and a cylindrical first body 711 and one end of the first body 711. A derivative 710 composed of a second body 712 of a sharp type whose outer diameter is gradually reduced toward one end by connecting the other end, and a second photocatalyst plate 500 on the outer peripheral surface of the first body 711 of the derivative 710 ) has a structure in which a plurality of guide blades 720 bent in the same rotational direction as the rotational direction are formed at equal intervals.

That is, when the impeller 600 disposed on the other side of the inner tube 200 rotates, the air flow moves through the spiral second photocatalyst plate 500 while rotating in the rotational direction, that is, in the circumferential direction. The air that escaped causes a vortex, and the airflow generated in this way moves toward the outlet of the guide pipe 800 and collides with the side wall surface of the rotary guiding blade 720 formed in the guide pipe 800. It exits through the liver flow path and collides with the outer peripheral surface of the second body 712 of the derivative 710 to induce the air flow in a straight direction, thereby forming a straight air flow.

At this time, it is preferable that the second body 712 of the derivative 710 has a progressively sharp shape so that the airflow discharged through the passage between the induction blades 720 induces a long-distance straightening.

In addition, although not shown, it is preferable that a large space airflow circulation fan or a jet fan is coupled to one end of the guide tube 800 or to the front of the guide tube 800 .

Accordingly, the first photocatalyst plate 400 is formed in the form of a spiral screw around the outer periphery of the inner tube 200 , and at this time, the entire surface of the first photocatalyst plate 400 is coated with a photocatalyst material, which is generated by the lamp shaft 300 . The light passed through the transparent material of the inner tube and photochemically reacts with the photocatalyst of the first photocatalyst plate 400 to first purify the air moving the first photocatalyst plate 400 in the exterior 100,

In addition, the second photocatalyst plate 500 is formed in the form of a spiral screw wing around the outer periphery of the lamp shaft 300 , and the entire surface of the second photocatalyst plate 500 is coated with a photocatalyst, and the photocatalyst is titanium dioxide (TiO2), zinc oxide (ZnO), tin oxide (SnO2), tungsten oxide (WO3), lead sulfide (Zn), iron oxide (Fe2O3), cadmium sulfide (CdS) can be formed by known materials, In the present invention, titanium dioxide (TiO2) will be described by applying as an embodiment.

The light generated from the lamp shaft 300 undergoes a photochemical reaction with the photocatalytic material of titanium dioxide coated on the second photocatalyst plate 500 to purify the air moving along the second photocatalyst plate 500 of the inner tube. The titanium dioxide photocatalyst material generates polar electrons (e-) and holes (h+), and the generated electrons and holes are oxygen (O2) and It collides with water molecules (H2O) to generate OH- (hydroxyl groups) and O2- ions.

OH- (hydroxyl group) and O2- anion generated by the photochemical reaction oxidize and decompose organic compounds into water (H2O) and carbon dioxide (CO2), thereby removing and purifying bacteria in the air.

That is, the OH- and O2- ions flow out through the guide tube 800 connected to one end of the inner tube 200 and react with the air around the purifier and all pathogenic contaminants present on the surface to oxidatively decompose. .

The titanium dioxide is an eco-friendly material that receives light energy and changes various pollutants into harmless substances as a medium that promotes chemical reactions of other organic materials without changing itself.

And, as shown in FIGS. 2 and 3 , the other end is connected to one end of the exterior 100 in communication with the socket part 121 that is connected and fixed to one end of the exterior 100 and the socket part 121 is connected to one end of the exterior. An inlet socket 120 comprising an inlet 122 in which a columnar first space 122-1 having a larger inner diameter than the outer appearance of the exterior 100 is formed while communicating with the 100 is further included, It provides a purification device 10 in which one end of the guide tube 800 accommodating the fluid accelerator 700 protrudes to the outside of the inlet 122 through the first space 122-1.

In addition, the end of the guide tube 800 is formed in a protruding form in the center of the first space 122-1 of the inlet socket 120 .

In addition, the inner tube 200 provides a purification device 10 formed of a transparent material so that the light source emitted from the lamp shaft 300 is transmitted.

The light emitted from the lamp shaft 300 passes through the inner tube 200 made of a transparent material, and the light is irradiated between the outer tube 100 and the inner tube 200 to separate the photocatalytic material and the photochemical panel of the first photocatalyst plate 400. to purify the air.

In addition, a plurality of lamps (not shown) attached and fixed at equal intervals to the outer circumferential surface of the inner tube 200 or the inner circumferential surface of the outer tube 100 are provided, and the lamps individually irradiate a light source to irradiate the first photocatalyst plate 400 . directly reacts with the photocatalyst of

That is, it is attached to the outer circumferential surface of the inner tube 200 exposed between the pitch and the pitch of the spiral first photocatalyst plate 400 or the inner circumferential surface of the outer tube 100 .

And, as shown in Figs. 2 and 4 (b), provided on the rear side of the inner tube 200, the outer peripheral surface of the ring-shaped support disk 910 and the support disk 910 in close contact with the inner peripheral surface of the exterior 100 A round bar-shaped support rod 920 disposed in the inner center and a connecting plate 930 having both ends connected to the inner peripheral surface of the support disk 910 and the outer peripheral surface of the support rod 920, respectively, are provided at equal intervals in three places on the inner circumference of the support disk 910 is provided with a support socket 900, in which a stepped step 931 is formed on one side of the connecting plate 930, and the step 931 of the connecting plate 930 is formed on the inner peripheral surface of the other end of the inner tube 200. It provides a purification device (10) having a structure that is bonded to the surface.

The support socket 900 is composed of a cylindrical support disk 910 and a connecting plate 930 positioned at three equal intervals connected from the inside of the support disk 910 to the outside of the support rod 920, and the inner tube A stepped 931 is formed on one side of the connecting plate 930 facing the other end of the 200, and the stepped 931 respectively formed on the three connecting plates 930 is fitted inside the other end of the inner tube 200. The other end of the inner tube 200 is fixed to the connecting plate 930 .

In addition, the first and second photocatalyst plates 400 and 500 provide a purification device 10 in which a plurality of through holes (not shown) are formed.

The fluid can freely pass through the through hole to increase the contact efficiency with the hydroxyl radical generated by the photocatalytic reaction.

And, as shown in FIG. 6, a round bar-shaped main shaft 210 is connected to the center of the support rod 920 of the support socket 900, and the cylindrical first tube 220 is the outer periphery of the main shaft 210, and A second pipe 230 is disposed on the outer periphery of the first pipe 220,

A plurality of ribs 240 are connected at equal intervals between the main shaft 210 and the first tube 220 and between the first tube 220 and the second tube 230,

A first tube 220 and a main shaft 210 are disposed in the inner center of the first tube 220 in the inner center of the second tube 230 , the first tube 220 facing the end of the lamp shaft 300 . has a structure in which the end of the tube is formed to protrude further than the end of the second tube 230 .

A coupling structure of the main shaft 210 , the first tube 220 and the second tube 230 is provided between the support rod 920 and the lamp shaft 300 , and air is passed through the impeller 600 into the inner tube 200 . ), the contact area between the lamp shaft 300 and the second photocatalyst plate 500 formed in the inner tube 200 is increased by guiding the rotated air in a straight direction before being introduced into the inner tube 200 .

And the end of the first tube 220 facing the ramp shaft 300 is formed to protrude more than the end of the second tube 220, that is, the first tube 220 and the second tube facing the support rod 920 Each end of the two tubes 230 has a structure in which the other end of the first tube 220 is extended longer than the other end of the second tube 230 while being positioned on the same line, and thus the main shaft 210 and the first The circumferential space 221 between the pipes 220, the circumferential space 231 between the first pipe 220 and the second pipe 230, and the circumferential space between the second pipe 230 and the inner pipe 200 (not shown) The air passing through the city) accelerates the air as it is guided in a straight line.

In addition, the end of the second tube 230 is formed to be longer than the end of the first tube 220 to reduce the movement speed of the air while guiding the airflow in a straight line.

And, as shown in FIG. 7 , a plurality of straight-line guide parts 250 are mounted at equal intervals on the outer peripheral surface of the end of the first tube 220 , and the straight-line guide part 250 has an end at the end of the first tube 220 . A pair of straight plate portions 251 of a vertical plate type protruding horizontally to the front are formed to be spaced apart.

A plurality of the straight line guide part 250 is arranged at equal intervals on the outer peripheral surface of the end of the first pipe 220, and the straight line guide part 250 is composed of a pair of spaced straight plate parts 251 and a straight plate part 251. The end of the first pipe 220 is formed to protrude horizontally in front of the end.

As the accelerated air is ejected in a straight direction between the straight plate part 251 and the straight plate part 251 of the straight-line guide part 250, it controls the flow direction of the surrounding air by collision control to induce it in a low-speed straight direction.

In addition, the straight guide unit 250 is mounted on the end of the second tube 230 and the end of the main shaft 210 in addition to the end of the first tube 220 to control the flow of air.

And, as shown in FIG. 7 , one side adjacent to each other in the linear induction part 250 and the other linear induction part 250 adjacent to each other among the plurality of linear induction parts 240 arranged on the outer periphery of the end of the first tube 220 . A bar-shaped collision rod 252 is formed in a curved shape between the straight plate part 251 of the straight line induction part 250 and the straight plate part 251 of the other straight straight part 250, and the collision rods 252 are adjacent to each other. By connecting in a curved form between the straight plate part 251 of the one straight line induction part 250 and the straight plate part 251 of the other straight straight induction part 250, the air moving between the one straight plate part 251 and the other straight plate part 251 is The flow is controlled and dispersed around the lamp shaft 300 and the second photocatalyst plate 500 is guided.

That is, a pair of linear induction parts 250 spaced apart from each other in the space between the ribs 240 and the ribs 240 formed on the outer periphery of the first tube 220 are formed. A collision rod 252 is formed to be interconnected in a curved shape between the straight plate part 251 of the adjacent one-side straight-line induction part 250 and the straight plate part 251 of the other-side straight-line guide part 250 .

In addition, in addition to the outer peripheral surface of the first tube 220, a straight line formed on the outer peripheral surface of the second tube 230 and the main shaft 210 so as to be arranged in the same structure as the collision rod 252 formed on the first tube 220. A collision rod 252 may be formed between the straight plate portions 251 of the induction portion 250 .

The above description is merely illustrative of the technical idea of this embodiment, and a person skilled in the art to which this embodiment belongs may make various modifications and variations without departing from the essential characteristics of the present embodiment. Accordingly, the present embodiments are intended to explain rather than limit the technical spirit of the present embodiment, and the scope of the technical spirit of the present embodiment is not limited by these embodiments. The protection scope of this embodiment should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be interpreted as being included in the scope of the present embodiment.

Purifier 10 Appearance 100 Combination Socket 110
Inlet Socket 120 Socket 121 Inlet 122
Inner tube 200 Spindle 210 Tube 1 220
Sub-Section 230 Straight guiding part 250 Straight plate part 251
Collision rod 252 Lamp shaft 300 First photocatalyst plate 400
2nd photocatalyst plate 500 Impeller 600 Rotating shaft 610
Rotor blade 620 Fluid accelerator 700 Inductor 710
1st body 711 2nd body 712 Induction blade 720
Guide tube 800 Support socket 900 Support plate 910
Support bar 920 Connection plate 930 Step 931

Claims (12)

An exterior 100 formed in a horizontal length of a hollow type,
An inner tube 200 provided inside the exterior 100 and formed in a hollow transverse length while having an outer diameter smaller than the inner diameter of the exterior 100,
A lamp shaft 300 provided inside the inner tube 200 and formed in a horizontal length having an outer diameter smaller than the inner diameter of the inner tube 200,
A first photocatalyst plate 400 formed in a spiral shape along the transverse direction of the inner tube 200, the outer peripheral surface is interviewed on the inner peripheral surface of the exterior while the inner peripheral surface is coupled to the outer peripheral surface of the inner tube 200;
The second photocatalyst plate 500 is formed in a spiral along the horizontal direction of the lamp shaft 300, the outer peripheral surface is surfaced with the inner peripheral surface of the inner tube 200 while the inner peripheral surface is coupled to the outer periphery of the lamp shaft 300,
It is mounted on the inner surface of the coupling socket 110 that seals the other end of the outer tube 100 and protrudes horizontally in the center so that the end is adjacent to the other end of the inner tube 200 and the outer circumferential surface of the rotating shaft 610. A rotary impeller 600 consisting of a rotary blade 620 formed on the
It is mounted inside the tubular guide tube 800 formed with a predetermined horizontal length to communicate with one end of the inner tube 200 located inside one end of the exterior 100, and the other end is connected to the second optical axis plate 500 and protrudes A hybrid photocatalytic purification device having a double tube structure, characterized in that it includes the formed vortex prevention fluid accelerator (700). According to claim 1,
The lamp shaft 300 is a hybrid photocatalytic purification device having a double tube structure, characterized in that any one selected from UV-C lamp, UV-A, UV-B lamp, ozone lamp, and LED lamp. According to claim 1,
The impeller 600 is rotated by receiving power through an external power source, and forcibly sucks the air introduced through the exterior 100 to be discharged into the inner tube 200,
It is mounted on the inner surface of the coupling socket 110 sealing the other end of the outer tube 100 and protrudes horizontally in the center so that the end is adjacent to the other end of the inner tube 200 and the outer peripheral surface of the rotating shaft 610. It consists of a rotary blade 620 formed in,
The outer diameter of the rotary shaft 610 of the impeller 600 is formed to be smaller than the inner diameter of the inner tube 200 while being larger than the outer diameter of the ramp shaft 300, and the rotary blade 620 is curved on the outer circumferential surface of the rotary shaft 610. A hybrid photocatalyst having a double tube structure, characterized in that a plurality of units are formed to be spaced apart from each other, and the outer diameter of the plurality of rotary blades 620 units formed on the outer periphery of the rotary shaft 610 is gradually reduced toward the end of the rotary shaft 610. purifier. According to claim 1,
The impeller 600 has rotary blades 620 formed at equal radial intervals on the outer peripheral surface of the rotation shaft 610, and the rotation blade 620 is bent A hybrid photocatalytic purification device having a double tube structure, characterized in that it has a space shape between the rotor blades 620 that form a flow path that is gradually narrowed toward the purifier. According to claim 1,
A fan member having a bell mouth portion formed thereon may be provided instead of the impeller 600, and a bell mouth portion is formed at the edge of the fan member to suck air introduced through the exterior and return air to the inner tube through an exhaust fan formed in the center. Hybrid photocatalytic purification device having a double tube structure, characterized in that it has a structure for discharging. According to claim 1,
The fluid accelerator 700 is provided inside the guide tube 800 and the other end is connected to or interviewed at one end of the ramp shaft 300 and a cylindrical first body 711 and one end of the first body 711. A derivative 710 composed of a second body 712 of a sharp type whose outer diameter is gradually reduced toward one end by being connected to the other end;
A double tube, characterized in that it has a structure in which a plurality of guide blades 720 bent in the same rotational direction as the rotational direction of the second photocatalyst plate 500 are formed on the outer peripheral surface of the first body 711 of the derivative 710 at equal intervals A hybrid photocatalytic purification device with a structure. According to claim 1,
A photocatalyst is coated on the entire surface of the first photocatalyst plate 400 and the second photocatalyst plate 500, and the photocatalyst is titanium dioxide (TiO2), zinc oxide (ZnO), tin oxide (SnO2), tungsten oxide ( WO3), lead sulfide (Zn), iron oxide (Fe2O3), and cadmium sulfide (CdS) hybrid photocatalytic purification device having a double tube structure, characterized in that using any one selected from. According to claim 1,
A socket part 121 that is connected to one end of the exterior 100 and the other end is connected in communication with one end of the exterior 100, and the socket part 121 is connected to one end of the exterior 100 while communicating with the exterior 100. An inlet socket 120 comprising an inlet 122 having a columnar first space 122-1 having a larger inner diameter compared to the outer diameter of (800) A hybrid photocatalytic purification device having a double tube structure, characterized in that one end protrudes outward through the inlet 122 through the first space 122-1. According to claim 1,
The inner tube 200 is a hybrid photocatalytic purification device having a double tube structure, characterized in that it is formed of a transparent material so that the light source emitted from the lamp shaft 300 is transmitted. According to claim 1,
A ring-shaped support disk 910 provided on the rear side of the inner tube 200 and the outer peripheral surface is in close contact with the inner peripheral surface of the exterior 100, and a round-bar-shaped support rod 920 and the support arranged in the inner center of the support disk 910 Connecting plates 930 having both ends connected to each of the inner peripheral surface of the disk 910 and the outer peripheral surface of the support rod 920 are provided with a support socket 900 in which three locations are disposed on the inner periphery of the support disk 910 at equal intervals. At this time, the connection plate is provided. A hybrid having a double tube structure, characterized in that a stepped stepped 931 is formed on one side of the 930 and the stepped 931 of the connecting plate 930 is surface-bonded to the inner circumferential surface of the other end of the inner tube 200 . Photocatalytic purification device. 11. The method of claim 10,
A round bar-shaped main shaft 210 is connected to the center of the support rod 920 of the support socket 900 , and the cylindrical first tube 220 and the outer periphery of the first tube 220 are the outer periphery of the main shaft 210 . The second pipe 230 is disposed,
A plurality of ribs 240 are connected at equal intervals between the main shaft 210 and the first tube 220 and between the first tube 220 and the second tube 230,
A first tube 220 and a main shaft 210 are disposed in the inner center of the first tube 220 in the inner center of the second tube 230 , the first tube 220 facing the end of the lamp shaft 300 . A hybrid photocatalytic purification device having a double tube structure, characterized in that the end of the second tube 230 has a structure in which it protrudes more than the end of the second tube 230 . 12. The method of claim 11,
A plurality of straight-line guide parts 250 are mounted on the outer peripheral surface of the end of the first tube 220 at equal intervals, and the straight-line guide part 250 has a vertical plate-shaped end that protrudes horizontally in front of the end of the first tube 220 . A pair of straight plate portions 251 of the are formed to be spaced apart,
Among the plurality of linear induction parts 240 disposed on the outer periphery of the end of the first pipe 220, one side of the linear guide part 250 and the other side of the linear guide part 250 adjacent to each other have a straight plate part of the one side straight guide part 250. A hybrid photocatalytic purification device having a double-tube structure, characterized in that a rod-shaped collision rod 252 is formed in a curved shape between the straight plate part 251 of the other straight line guide part 250 and the other side linear guide part 250 .

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