CN112224637A

CN112224637A - Storage device and storage method for biological ceramic nano photocatalyst for air purification

Info

Publication number: CN112224637A
Application number: CN202011121048.XA
Authority: CN
Inventors: 王嘉璐; 刘宇; 其他发明人请求不公开姓名
Original assignee: Shanxi Huicheng Jinhai Technology Co ltd
Current assignee: Shanxi Huicheng Jinhai Technology Co ltd
Priority date: 2020-10-19
Filing date: 2020-10-19
Publication date: 2021-01-15

Abstract

The invention relates to a device and a method for storing a biological ceramic nano photocatalyst for air purification. According to the invention, the movable plate slides in the first sliding groove through the first sliding block, the space in the box body can be adjusted according to the tank bodies with different sizes, the movable plate is moved to one side of the tank body, the butt joint block connected to one side of the telescopic rod is moved to the inside of the butt joint groove, the tank body is conveniently fixed through the movable plate and the second baffle plate, collision between the tank body and the box body is prevented, the limiting plate can be downwards extruded by the first T-shaped rod at the bottom end of the first cover body through the acting force of the first reset spring at the bottom end of the first cover body, the limiting plate can limit the top end of the tank body, the tank body is prevented from shaking, and the nano photocatalyst in the tank body.

Description

Storage device and storage method for biological ceramic nano photocatalyst for air purification

Technical Field

The invention relates to a device and a method for storing a biological ceramic nano photocatalyst for air purification, and belongs to the technical field of nano photocatalyst storage equipment.

Background

The photocatalyst is also called as photocatalyst, and is a general name of semiconductor materials with a photocatalytic function represented by nano-scale titanium dioxide, and a representative photocatalyst material is titanium dioxide, which can generate substances with strong oxidizing property under light irradiation and can be used for decomposing organic compounds, partial inorganic compounds, bacteria, viruses and the like.

The existing nano photocatalyst storage device is generally directly arranged in a bottle or a pot and can be placed in a shade, the bottle or the pot is easy to damage under the collision of external force without good protection, the nano photocatalyst in the bottle or the pot is wasted, and the nano photocatalyst is generally directly slid and directly used when being used, so that the mixing of the nano photocatalyst is insufficient, and the using condition of the nano photocatalyst is influenced.

Disclosure of Invention

The invention aims to solve the technical problems and overcome the existing defects, and provides a device and a method for storing a biological ceramic nano photocatalyst for air purification.

In order to solve the technical problems, the invention provides the following technical scheme:

a bioceramic nano photocatalyst storage device for air purification comprises a box body, wherein a first cover body is hinged to the top end of the box body, a first partition plate is connected to the bottom end of one side of the box body in an embedded mode, a filter screen is connected to the first partition plate in an embedded mode, a sponge block is installed at the bottom end of the box body, a tank body is connected to the top end of the sponge block, a first baffle is fixedly connected to one side of the box body, an adjusting mechanism is installed inside the box body, a plurality of first sleeves are arranged inside the adjusting mechanism, the first sleeves are fixedly connected to the bottom end of the first cover body, a first reset spring is fixedly connected to the inside of each first sleeve, a first T-shaped rod is fixedly connected to the bottom end of each first reset spring, a limiting plate is installed at the bottom end of each first T-shaped rod, two second baffle plates are fixedly connected to two sides of each first baffle, and be fixed connection between the inner wall one side of second baffle and box, the both sides of first baffle gomphosis respectively are connected with first spout, and the inside of first spout cup joints and inserts and be equipped with first slider, one side fixedly connected with movable plate of first slider, and one side fixedly connected with backup pad of movable plate, one side fixedly connected with telescopic link of backup pad, and one side fixedly connected with butt joint piece of telescopic link, the inner wall both sides of box gomphosis respectively are connected with a plurality of butt joint grooves, and are connected for the block between the surface of butt joint groove and butt joint piece, the internally mounted of the jar body has mixing mechanism, the internally mounted of box has receiving mechanism.

Furthermore, the first T-shaped rod and the first sleeve form an elastic telescopic structure through a first return spring, and the moving plate and the first sliding groove form a sliding structure through a first sliding block.

Furthermore, the butt joint block forms a telescopic moving structure through the telescopic rod and the supporting plate, and the telescopic rod forms a clamping structure through the butt joint block and the butt joint groove.

Further, the mixing mechanism comprises a second cover body inside, the second cover body is in threaded connection with the top end of the tank body, an electric motor is fixedly mounted at the top end of the second cover body, a rotating shaft is fixedly connected to the bottom end of the second cover body, the electric motor penetrates through the second cover body and is connected with the inside of the rotating shaft in an embedded mode, the bottom end of the rotating shaft is rotatably connected with a rotating rod, a plurality of stirring rods are fixedly connected to the surface of the rotating rod, sleeves are respectively in threaded connection with the two sides of the rotating rod, a plurality of through holes are formed in the top ends of the sleeves, clamping grooves are fixedly connected to the bottom ends inside the sleeves, clamping blocks are connected to the inside of the clamping grooves in a clamping mode, sleeve rods are fixedly connected to the top ends of the clamping blocks, cleaning blocks are fixedly mounted on one side of the sleeve rods, the cleaning blocks are movably connected with the inner wall of, and the inside fixedly connected with second reset spring of second sleeve, second reset spring's top fixedly connected with second T type pole, and be swing joint between the inside of second T type pole and through-hole.

Further, the rotating rod and the second cover body form a clamping structure through the rotating shaft, and the loop bar and the clamping groove form a clamping structure through the clamping block.

Furthermore, the second T-shaped rod forms an elastic telescopic structure with the second sleeve through the second return spring, and forms a clamping structure with the sleeve through the through hole.

Further, the containing mechanism comprises a box body inside, the box body is fixedly connected with one side of the inner wall of the box body, the top end of the box body is hinged with a third cover body, the bottom end of the third cover body is fixedly provided with an ultraviolet lamp, one side of the inner wall of the box body is fixedly provided with a hanging buckle, the front end and the rear end of the inner wall of the box body are respectively connected with a second sliding chute in an embedded mode, a second sliding block is inserted in the second sliding chute in a sleeved mode, one side of the second sliding block is fixedly connected with a second partition plate, one side of the inner wall of the box body is fixedly provided with a switch, one side of the inner wall of the box body is connected with a limiting groove in an embedded mode, one side of the top end of the third cover body is fixedly connected with a third sleeve, a third reset spring is fixedly connected in the third sleeve, the top end of the third reset spring is fixedly connected with a third T-, the top fixedly connected with movable rod of third lid, and the top fixedly connected with stopper of movable rod to be connected for relative between the inside of stopper and spacing groove.

Furthermore, the second partition board forms a sliding structure through the second sliding block and the second sliding groove, and the second sliding groove is symmetrical about the central axis of the box body.

A method for storing a biological ceramic nano photocatalyst for air purification mainly comprises 3 steps: the method comprises the following steps: loading the nano photocatalyst into the tank body, and performing the second step: adjusting the movable plate to fix the tank body, and step three: the first cover body is covered.

The detailed content of the first step is as follows; the second cover body can be taken down from the top end of the tank body through threaded connection between the second cover body and the tank body, so that the nano photocatalyst is conveniently loaded into the tank body;

the details of the second step are as follows; the movable plate moves in the first sliding groove through the first sliding block, so that the movable plate can be conveniently moved to one side of the tank body, the butt joint block connected to one side of the telescopic rod can be moved to the inside of the butt joint groove through the telescopic action of the telescopic rod, the tank body is conveniently fixed between the second baffle plate and the movable plate, and the nano photocatalyst in the tank body is prevented from shaking out;

the detailed content of the third step is as follows; through being hinged joint between first lid and the box, can remove the top of box with first lid, through the effort of the first reset spring of first lid bottom, can make the limiting plate of the first T type pole of first reset spring bottom extrude its bottom downwards, can make the limiting plate fix the jar body in appointed place, prevent to bump between the inner wall of its and box.

The invention has the technical effects and advantages that:

1. according to the invention, the adjusting mechanism is arranged, the movable plate slides in the first sliding groove through the first sliding block, the space in the box body can be adjusted according to the tank bodies with different sizes, the nano-photocatalysts with different sizes and types can be conveniently stored, the movable plate is moved to one side of the tank body, the butt joint block connected to one side of the telescopic rod can be moved to the inside of the butt joint groove through the action of the telescopic rod on one side of the movable plate, the tank body is conveniently fixed through the movable plate and the second baffle plate, the tank body and the box body are prevented from colliding, the damage of the tank body is avoided, the nano-photocatalyst in the tank body is wasted, the first cover body is moved to the top end of the box body, the first T-shaped rod at the bottom end of the first cover body can downwards extrude the limiting plate through the acting force of the first reset spring at the bottom end of the first, prevent rocking of jar body, rock out its inside nanometer photocatalyst.

2. According to the invention, the mixing mechanism is arranged, the rotating rod can drive the stirring rod to stir in the tank body through the work of the electric motor, so that the nano photocatalyst is prevented from being deposited at the bottom end of the tank body and the subsequent use of the nano photocatalyst is prevented, the sleeve rod in the sleeve can slide in the clamping groove through the clamping block by pressing the second T-shaped rod into the sleeve, the sleeve rod can move, the cleaning block connected to one side of the sleeve rod can be conveniently moved to one side of the inner wall of the tank body, the sleeve rod and the cleaning block can be conveniently moved on the inner wall of the tank body through the rotation of the rotating rod, the residual nano photocatalyst on the inner wall of the tank body can be conveniently removed, and the nano photocatalyst can be conveniently and subsequently loaded into the tank body.

3. The invention can lead the second clapboard to change the space in the box body by arranging the containing mechanism, lead the second clapboard to slide in the second chute through the second slide block, lead the second clapboard to be convenient to store different kinds of articles in the box body so as to be used when in need, lead the articles in the box body to be convenient to be sterilized through the action of the ultraviolet lamp on the third cover body, lead personnel to be convenient to use directly, lead the movable rod at the top end of the third cover body to move telescopically by turning the third cover body, lead the limit block at the top end of the third cover body to move to the inside of the limit groove, lead the third cover body to be fixed at one side of the box body, lead the third T-shaped rod at the top end of the third cover body to extrude and open the switch at one side of the box body through the acting force of the third reset spring at the top end of the third cover body, lead the electric motor to be convenient to electrify and lead the, facilitating subsequent use.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention.

FIG. 1 is a front view of the present invention;

FIG. 2 is a schematic view of the structure of the adjustment mechanism portion of the present invention;

FIG. 3 is a schematic structural view of a top portion of the adjustment mechanism of the present invention;

FIG. 4 is a schematic structural view of the mixing mechanism of the present invention;

FIG. 5 is an enlarged schematic view of the structure at A in FIG. 4;

FIG. 6 is a schematic view of the structure of the receiving mechanism portion of the present invention;

FIG. 7 is a schematic top view of the receiving mechanism of the present invention;

fig. 8 is a schematic structural view of a housing mechanism portion of the present invention.

Reference numbers in the figures: 1. a box body; 2. a first cover body; 3. a first separator; 4. a filter screen; 5. a sponge block; 6. a tank body; 7. a first baffle plate; 8. an adjustment mechanism; 801. a first sleeve; 802. a first return spring; 803. a first T-bar; 804. a limiting plate; 805. a second baffle; 806. a first chute; 807. a first slider; 808. moving the plate; 809. a support plate; 8010. a telescopic rod; 8011. a butt joint block; 8012. a butt joint groove; 9. a mixing mechanism; 901. a second cover body; 902. an electric motor; 903. a rotating shaft; 904. rotating the rod; 905. a stirring rod; 906. a sleeve; 907. a through hole; 908. a card slot; 909. a clamping block; 9010. a loop bar; 9011. a cleaning block; 9012. a second sleeve; 9013. a second return spring; 9014. a second T-bar; 10. a storage mechanism; 1001. a box body; 1002. a third cover body; 1003. an ultraviolet lamp; 1004. hanging and buckling; 1005. a second chute; 1006. a second slider; 1007. a second separator; 1008. a switch; 1009. a limiting groove; 1010. a third sleeve; 1011. a third return spring; 1012. a third T-bar; 1013. a movable rod; 1014. and a limiting block.

Detailed Description

The preferred embodiments of the present invention will be described in conjunction with the accompanying drawings, and it will be understood that they are described herein for the purpose of illustration and explanation and not limitation.

As shown in fig. 1-8, a bioceramic nano photocatalyst storage device for air purification comprises a box body 1, a first cover body 2 is hinged to the top end of the box body 1, a first partition plate 3 is embedded and connected to the bottom end of one side of the box body 1, a filter screen 4 is embedded and connected to the inside of the first partition plate 3, a sponge block 5 is installed at the bottom end of the box body 1, a tank body 6 is connected to the top end of the sponge block 5, a first baffle 7 is fixedly connected to one side of the box body 1, an adjusting mechanism 8 is installed inside the box body 1, a plurality of first sleeves 801 are included inside the adjusting mechanism 8, the first sleeves 801 are fixedly connected to the bottom end of the first cover body 2, a first return spring 802 is fixedly connected to the inside of the first sleeves 801, a first T-shaped rod 803 is fixedly connected to the bottom end of the first return spring 802, and a limit plate 804 is installed at the bottom end of the first T, two sides of the first baffle 7 are fixedly connected with two second baffles 805 respectively, the second baffles 805 are fixedly connected with one side of the inner wall of the box body 1, two sides of the first baffle 7 are connected with a first sliding chute 806 in an embedded manner respectively, a first sliding block 807 is inserted in the first sliding chute 806 in a sleeved manner, one side of the first sliding block 807 is fixedly connected with a moving plate 808, one side of the moving plate 808 is fixedly connected with a supporting plate 809, one side of the supporting plate 809 is fixedly connected with an expansion link 8010, one side of the expansion link 8010 is fixedly connected with a butt joint block 8011, two sides of the inner wall of the box body 1 are connected with a plurality of butt joint grooves 8012 in an embedded manner respectively, the surfaces of the butt joint grooves 8012 and the butt joint block 8011 are in a clamping manner, a mixing mechanism 9 is installed in the tank body 6, a containing mechanism 10 is installed in the moving plate 1, the 808 moves in the first sliding chute 806 through the first sliding block 807, the tank bodies 6 with different sizes can be conveniently placed.

As shown in fig. 1 to 8, the first T-shaped rod 803 passes through the first return spring 802 and the first sleeve 801 to form an elastic telescopic structure, the moving plate 808 passes through the first slider 807 and the first sliding slot 806 to form a sliding structure, and the telescopic rod 8010 can move the abutting block 8011 connected to one side of the moving plate into the abutting slot 8012, so as to fix the moving plate 808 and the second stopper 805 between the moving plate 808 and the second stopper 805.

As shown in fig. 1-8, the docking block 8011 forms a telescopic moving structure through the telescopic rod 8010 and the supporting plate 809, the telescopic rod 8010 forms a clamping structure through the docking block 8011 and the docking groove 8012, the first T-shaped rod 803 at the bottom end of the telescopic rod 8010 can downwards press the limiting plate 804 through the acting force of the first return spring 802, the limiting plate 804 can be pressed to the top end of the tank body 6 to limit the tank body 6, so that the tank body 6 is prevented from shaking, and the nano photocatalyst in the tank body is shaken out.

As shown in fig. 4 and 5, the mixing mechanism 9 includes a second cover 901 inside, the second cover 901 is in threaded connection with the top end of the tank 6, an electric motor 902 is fixedly mounted at the top end of the second cover 901, a rotating shaft 903 is fixedly connected at the bottom end of the second cover 901, the electric motor 902 passes through the second cover 901 and is in embedded connection with the inside of the rotating shaft 903, a rotating rod 904 is rotatably connected at the bottom end of the rotating shaft 903, a plurality of stirring rods 905 are fixedly connected to the surface of the rotating rod 904, sleeves 906 are respectively in threaded connection with two sides of the rotating rod 904, a plurality of through holes 907 are formed at the top end of each sleeve 906, a slot 908 is fixedly connected at the bottom end of each sleeve 906, a block 909 is fixedly connected inside the slot 908 in a clamped manner, a sleeve 9010 is fixedly connected at the top end of each block 909, a cleaning block 9011 is fixedly mounted on one side of each sleeve 9010, and the cleaning block, the top end of the loop bar 9010 is fixedly connected with a second sleeve 9012, the inside of the second sleeve 9012 is fixedly connected with a second return spring 9013, the top end of the second return spring 9013 is fixedly connected with a second T-shaped bar 9014, the second T-shaped bar 9014 is movably connected with the inside of the through hole 907, through the work of the electric motor 902, the rotating rod 904 can drive the stirring rod 905 to stir in the inside of the tank body 6, so that the nano photocatalyst in the tank body 6 can be uniformly mixed, the use effect of the nano photocatalyst can be prevented from being affected, the sleeve 906 is in threaded connection with the rotating rod 904, and when the inside of the tank body 6 needs to be cleaned, the sleeve 906 can be installed on one side of the rotating rod 904.

As shown in fig. 4 and 5, the rotating rod 904 and the second cover 901 form a fastening structure through the rotating shaft 903, the sleeve 9010 and the fastening groove 908 form a fastening structure through the fastening block 909, and the cleaning block 9011 is convenient for driving the cleaning block 9011 to move on the inner wall of the tank 6 when the rotating rod 904 rotates, so as to clean the nano photocatalyst remaining on the inner wall of the tank 6.

As shown in fig. 4 and 5, the second T-shaped rod 9014 passes through the second return spring 9013 to form an elastic telescopic structure with the second sleeve 9012, the second T-shaped rod 9014 passes through the through hole 907 to form a snap-fit structure with the sleeve 906, and the second T-shaped rod 9014 can be pushed out of the sleeve 906 by the second return spring 9013, so that the sleeve rod 9010 can be fixed conveniently.

As shown in fig. 6, 7 and 8, the receiving mechanism 10 includes a box 1001 inside, the box 1001 is fixedly connected to one side of the inner wall of the box 1, a third cover 1002 is hinged to the top end of the box 1001, an ultraviolet lamp 1003 is fixedly mounted at the bottom end of the third cover 1002, a buckle 1004 is fixedly mounted at one side of the inner wall of the box 1001, a second chute 1005 is respectively embedded and connected to the front and rear ends of the inner wall of the box 1001, a second slider 1006 is inserted into the second chute 1005 in a sleeved manner, a second partition 1007 is fixedly connected to one side of the second slider 1006, a switch 1008 is fixedly mounted at one side of the inner wall of the box 1, a limit groove 1009 is embedded and connected to one side of the inner wall of the box 1, a third sleeve 1010 is fixedly connected to one side of the top end of the third cover 1002, a third return spring 1011 is fixedly connected to the inside of the third sleeve 1010, a third T-shaped rod 1012 is fixedly connected to the top, the third T-shaped rod 1012 is connected to one side of the switch 1008 relatively, the top end of the third cover 1002 is fixedly connected to the movable rod 1013, the top end of the movable rod 1013 is fixedly connected to the limit block 1014, the limit block 1014 is connected to the inside of the limit groove 1009 relatively, some necessities using nano-photocatalyst can be placed inside the box 1001, the objects inside the box 1001 can be sterilized through the action of the ultraviolet lamp 1003, so that the objects can be used directly by a user, the electric motor 902 and the switch 1008 are connected to a power supply through a connection line, and the power supply can be installed inside the box 1 for the electric motor 902 to use.

As shown in fig. 6, 7 and 8, the second partition plate 1007 forms a sliding structure between the second slider 1006 and the second sliding groove 1005, the second sliding groove 1005 is symmetrical with respect to the central axis of the box 1001, and the second partition plate 1007 slides inside the second sliding groove 1005 through the second slider 1006, so that the second partition plate 1007 changes the space inside the box 1001, and different types of necessities can be placed inside the box 1001.

As shown in fig. 1-8, a method for storing a bioceramic nano photocatalyst for air purification mainly comprises 3 steps: the method comprises the following steps: and (2) filling the nano photocatalyst into the tank body 6, and performing the second step: fixing the tank body 6 by the adjusting moving plate 808, and the third step: the first lid body 2 is closed.

The detailed content of the step one is as follows; the second cover 901 can be taken down from the top end of the tank 6 by the threaded connection between the second cover 901 and the tank 6, so that the nano photocatalyst can be conveniently loaded into the tank 6;

the details of the second step are as follows; the moving plate 808 moves in the first sliding groove 806 through the first slider 807, so that the moving plate 808 can be conveniently moved to one side of the tank body 6, the abutting block 8011 connected to one side of the telescopic rod 8010 can be moved to the inside of the abutting groove 8012 through the telescopic action of the telescopic rod 8010, the tank body 6 can be conveniently fixed between the second slider 805 and the moving plate 808, and the nano photocatalyst in the tank body 6 can be prevented from shaking out;

the detailed content of the third step is as follows; through being hinged joint between first lid 2 and the box 1, can remove the top of box 1 with first lid 2, through the effort of the first reset spring 802 of first lid 2 bottom, can make the limiting plate 804 of the first T type pole 803 of first reset spring 802 bottom extrude its bottom downwards, can make limiting plate 804 fix the jar body 6 in appointed place, prevent to bump between its and the inner wall of box 1.

For the convenience of understanding the technical solutions of the present invention, the following detailed description will be made on the working principle or the operation mode of the present invention in the practical process.

The working principle of the invention is as follows: when in use, the second cover 901 is firstly taken down from the top end of the tank 6, the nano photocatalyst is poured into the tank 6, the tank 6 is placed into the box 1, one side of the tank 6 is connected with one side of the second baffle 805, the moving plate 808 is slid in the first sliding slot 806 through the first slider 807, the space in the box 1 can be adjusted according to the tanks 6 with different sizes, so as to store the nano photocatalyst in the tanks 6 with different sizes and different types, the moving plate 808 is moved to one side of the tank 6, the docking block 8011 connected to one side of the telescoping rod 8010 can be moved to the inside of the docking slot 8012 through the action of the telescoping rod 8010 on one side of the moving plate 808, so as to fix the tank 6 through the moving plate 808 and the second baffle 805, prevent the tank 6 from colliding with the box 1, causing damage to the tank 6 and waste the nano photocatalyst in the tank, the first cover body 2 is moved to the top end of the box body 1, the first T-shaped rod 803 at the bottom end of the first cover body 2 can downwards extrude the limit plate 804 by the acting force of the first reset spring 802 at the bottom end of the first cover body 2, the limit plate 804 can limit the top end of the tank body 6, the nano photocatalyst in the tank body 6 is prevented from shaking, the nano photocatalyst in the tank body 6 is shaken out, the second clapboard 1007 slides in the second chute 1005 through the second sliding block 1006, the space in the tank body 1001 can be changed by the second clapboard 1007, different types of articles can be stored in the tank body 1001 conveniently, so that the articles in the tank body 1001 can be used when needed, the articles in the tank body 1001 can be sterilized conveniently through the action of the ultraviolet lamp 1003 on the third cover body 1002, so that the articles in the tank body 1001 can be directly used by a person, when the tank is used, the movable rod 1013 at the top end of the third cover body 1002 is, the limit block 1014 at the top end of the third cover body 1002 can be moved into the limit groove 1009, so that the third cover body 1002 can be conveniently fixed at one side of the box body 1, the acting force of the third return spring 1011 at the top end of the third cover body 1002 can enable the third T-shaped rod 1012 at the top end of the third cover body to extrude and open the switch 1008 at one side of the box body 1, so that the electric motor 902 can be electrified, the electric motor 902 can work, the rotating rod 904 can drive the stirring rod 905 to stir in the tank body 6, so that the nano-photocatalyst in the tank body can be uniformly mixed, the using effect of the nano-photocatalyst can be improved, when the interior of the tank body 6 needs to be cleaned, the second T-shaped rod 9014 can be pressed into the sleeve 906, the sleeve rod 9010 in the sleeve 906 can slide in the clamping groove 908 through the clamping block 909, the sleeve rod 9010 can be moved, so that the cleaning block 9011 connected to one side of the sleeve rod 9010 can be conveniently moved to one, through the rotation of dwang 904, can make loop bar 9010 and cleaning block 9011 remove at the inner wall of jar body 6, be convenient for clear away the remaining nanometer photocatalyst on jar body 6 inner wall, be convenient for follow-up with the nanometer photocatalyst packing into the inside of jar body 6.

The above embodiments are preferred embodiments of the present invention, and those skilled in the art can make variations and modifications to the above embodiments, therefore, the present invention is not limited to the above embodiments, and any obvious improvements, substitutions or modifications made by those skilled in the art based on the present invention are within the protection scope of the present invention.

Claims

1. The utility model provides a biological ceramic nanometer photocatalyst strorage device for air purification, includes box (1), its characterized in that: the top end of the box body (1) is hinged with a first cover body (2), the bottom end of one side of the box body (1) is connected with a first partition plate (3) in an embedded mode, the inside of the first partition plate (3) is connected with a filter screen (4) in an embedded mode, the bottom end of the box body (1) is provided with a sponge block (5), the top end of the sponge block (5) is connected with a tank body (6), one side of the box body (1) is fixedly connected with a first baffle (7), the inside of the box body (1) is provided with an adjusting mechanism (8), the inside of the adjusting mechanism (8) comprises a plurality of first sleeves (801), the first sleeves (801) are fixedly connected with the bottom end of the first cover body (2), the inside of the first sleeves (801) is fixedly connected with first return springs (802), and the bottom end of the first return springs (802) is fixedly connected with first T-shaped rods (803, and the bottom end of the first T-shaped rod (803) is provided with a limiting plate (804), two sides of the first baffle plate (7) are respectively and fixedly connected with two second baffle plates (805), the second baffle plates (805) are fixedly connected with one side of the inner wall of the box body (1), two sides of the first baffle plate (7) are respectively connected with a first sliding chute (806) in a jogged manner, a first sliding block (807) is inserted in the first sliding chute (806) in a sleeved manner, one side of the first sliding block (807) is fixedly connected with a moving plate (808), one side of the moving plate (808) is fixedly connected with a supporting plate (809), one side of the supporting plate (809) is fixedly connected with an expansion link (8010), one side of the expansion link (8010) is fixedly connected with a butt joint block (8011), two sides of the inner wall of the box body (1) are respectively connected with a plurality of butt joint grooves (8012) in a jogged manner, and the surfaces of the butt joint grooves, the internal mounting of jar body (6) has mixing mechanism (9), the internal mounting of box (1) has receiving mechanism (10).

2. The device for storing the bioceramic nano-photocatalyst for air purification according to claim 1, wherein the device comprises: the first T-shaped rod (803) and the first sleeve (801) form an elastic telescopic structure through a first return spring (802), and the moving plate (808) and the first sliding groove (806) form a sliding structure through a first sliding block (807).

3. The device for storing the bioceramic nano-photocatalyst for air purification according to claim 1, wherein the device comprises: the butt joint block (8011) forms a telescopic moving structure with the supporting plate (809) through the telescopic rod (8010), and the telescopic rod (8010) forms a clamping structure with the butt joint groove (8012) through the butt joint block (8011).

4. The device for storing the bioceramic nano-photocatalyst for air purification according to claim 1, wherein the device comprises: the mixing mechanism (9) comprises a second cover body (901) inside, the second cover body (901) is in threaded connection with the top end of the tank body (6), an electric motor (902) is fixedly installed at the top end of the second cover body (901), a rotating shaft (903) is fixedly connected to the bottom end of the second cover body (901), the electric motor (902) penetrates through the second cover body (901) to be in embedded connection with the inside of the rotating shaft (903), the bottom end of the rotating shaft (903) is rotatably connected with a rotating rod (904), a plurality of stirring rods (905) are fixedly connected to the surface of the rotating rod (904), sleeves (906) are respectively in threaded connection with the two sides of the rotating rod (904), a plurality of through holes (907) are formed in the top end of each sleeve (906), a clamping groove (908) is fixedly connected to the bottom end inside each sleeve (906), and a clamping block (909) is clamped inside each clamping groove (908, and the top end of the clamping block (909) is fixedly connected with a loop bar (9010), one side of the loop bar (9010) is fixedly provided with a cleaning block (9011), the cleaning block (9011) is movably connected with the inner wall of the tank body (6), the top end of the loop bar (9010) is fixedly connected with a second sleeve (9012), the inside of the second sleeve (9012) is fixedly connected with a second return spring (9013), the top end of the second return spring (9013) is fixedly connected with a second T-shaped rod (9014), and the second T-shaped rod (9014) is movably connected with the inside of the through hole (907).

5. The device for storing the bioceramic nano-photocatalyst for air purification according to claim 4, wherein: the rotating rod (904) and the second cover body (901) form a clamping structure through the rotating shaft (903), and the sleeve rod (9010) and the clamping groove (908) form a clamping structure through the clamping block (909).

6. The device for storing the bioceramic nano-photocatalyst for air purification according to claim 4, wherein: the second T-shaped rod (9014) and the second sleeve (9012) form an elastic telescopic structure through the second return spring (9013), and the second T-shaped rod (9014) and the sleeve (906) form a clamping structure through the through hole (907).

7. The device for storing the bioceramic nano-photocatalyst for air purification according to claim 1, wherein the device comprises: the storage mechanism (10) comprises a box body (1001), the box body (1001) is fixedly connected with one side of the inner wall of the box body (1), a third cover body (1002) is hinged to the top end of the box body (1001), an ultraviolet lamp (1003) is fixedly mounted at the bottom end of the third cover body (1002), a hanging buckle (1004) is fixedly mounted at one side of the inner wall of the box body (1001), the front end and the rear end of the inner wall of the box body (1001) are respectively connected with a second sliding groove (1005) in an embedded mode, a second sliding block (1006) is sleeved and inserted in the second sliding groove (1005), a second partition plate (1007) is fixedly connected to one side of the inner wall of the box body (1), a limit groove (1009) is connected to one side of the inner wall of the box body (1), a third sleeve (1010) is fixedly connected to one side of the top end of the third cover body (1002), and the inside fixedly connected with third reset spring (1011) of third sleeve (1010), the top fixedly connected with third T type pole (1012) of third reset spring (1011), and be connected for relatively between one side of third T type pole (1012) and switch (1008), the top fixedly connected with movable rod (1013) of third lid (1002), and the top fixedly connected with stopper (1014) of movable rod (1013), and be connected for relatively between the inside of stopper (1014) and spacing groove (1009).

8. The device for storing the bioceramic nano-photocatalyst for air purification according to claim 7, wherein: the second partition plate (1007) forms a sliding structure through the second sliding block (1006) and the second sliding groove (1005), and the second sliding groove (1005) is symmetrical about the central axis of the box body (1001).

9. A method for storing a biological ceramic nano photocatalyst for air purification is characterized by comprising the following steps: mainly comprises 3 steps: the method comprises the following steps: filling the nano photocatalyst into the tank body (6), and the second step: fixing the tank body (6) by adjusting the moving plate (808), and the third step: the first cover body (2) is covered.

10. The method for storing the bioceramic nano-photocatalyst for air purification according to claim 9, wherein the method comprises the following steps: the detailed content of the first step is as follows; the second cover body (901) can be taken down from the top end of the tank body (6) through threaded connection between the second cover body (901) and the tank body (6), so that the nano photocatalyst can be conveniently loaded into the tank body (6);

the details of the second step are as follows; the moving plate (808) moves in the first sliding groove (806) through the first sliding block (807), so that the moving plate (808) can move to one side of the tank body (6), the butt joint block (8011) connected with one side of the telescopic rod (8010) can move to the inside of the butt joint groove (8012) through the telescopic action of the telescopic rod (8010), the tank body (6) is conveniently fixed between the second baffle plate (805) and the moving plate (808), and the nano photocatalyst in the tank body (6) is prevented from shaking out;

the detailed content of the third step is as follows; through being hinged joint between first lid (2) and box (1), can remove the top of box (1) with first lid (2), through the effort of first reset spring (802) of first lid (2) bottom, can make first T type pole (803) of first reset spring (802) bottom extrude limiting plate (804) of its bottom downwards, can make limiting plate (804) fix jar body (6) in appointed place, prevent to bump between the inner wall of its and box (1).