CN209646405U - The storage device and its plugging mechanism of the super hydrophilic material of nanometer - Google Patents

Abstract

The plugging mechanism of this nanometer of super hydrophilic material storage means includes the closing cap connecting with container open end outer wall thread, mechanism further includes column plug, the small inner-diameter end of conical through-hole and conical through-hole is equipped with outwardly in the axial centre of column plug, annulus part is equipped on the inner end end face of column plug, equipped with mixed organization after the grid type of structure in a ring on the inner face of annulus part, and across the arch piece in annulus part inner end, arch piece is to arching upward inside container, it is equipped at the top of the arc of arch piece and impeller is freely rotated, it is connected separately with straight-bar on the every blade that impeller is freely rotated and straight-bar stretches to inside container, the straight-bar is parallel to each other, it is arranged at least one movable sleeving that can be moved axially along straight-bar respectively on every straight-bar, outer convex retaining point is respectively equipped at the both ends of every straight-bar, movable sleeving is located at It is moved between two outer convex retaining points and between two outer convex retaining points.

Description

The storage device and its plugging mechanism of the super hydrophilic material of nanometer

Technical field

The utility model belong to building material technical field more particularly to a kind of super hydrophilic material of nanometer storage device and Its plugging mechanism.

Background technique

In building trade, glass is a kind of common material.

Glass its after being used for a long time, surface will form one layer of dust, especially skyscraper, and cleaning presence is very big Difficulty.

Have inventor to devise a kind of super hydrophilic material can achieve after being sprayed on glass etc. building surface Self-cleaning purpose.

However, super hydrophilic material its be generally stored in container, can only be reached by rocking especially in small containers To the purpose of stirring, still, its purpose for being still unable to reach uniform stirring of this mode, cause injection super hydrophilic material its Uniformity is poor.

Utility model content

The purpose of this utility model be in view of the above-mentioned problems, provide it is a kind of can be improved injection uniformity nanometer it is super hydrophilic The storage device and its plugging mechanism of material.

In order to achieve the above objectives, the utility model uses following technical proposal: the storage dress of this nanometer of super hydrophilic material It sets, is arranged in inside the open end of container, mechanism includes the closing cap connecting with container open end outer wall thread, and mechanism is also Including column plug, the small inner-diameter end of conical through-hole and conical through-hole is equipped with outwardly in the axial centre of column plug, in column The inner end end face of plug is equipped with annulus part, and mixing machine after the grid type of structure in a ring is equipped on the inner face of annulus part Structure, and across the arch piece in annulus part inner end, arch piece to arching upward inside container, be equipped at the top of the arc of arch piece from By wheel rotor, it is connected separately with straight-bar on the every blade that impeller is freely rotated and straight-bar stretches to inside container, it is described Straight-bar be parallel to each other, be arranged with respectively on every straight-bar at least one can along straight-bar move axially movable sleeving, In The both ends of every straight-bar are respectively equipped with outer convex retaining point, and movable sleeving is located between two outer convex retaining points and between two outer convex retaining points It is mobile.

Container then forces the super hydrophilic material of the nanometer in container to spray outward after being squeezed, when injection, nanometer is super hydrophilic It with impeller is freely rotated contacts that wheel rotation is freely rotated to forcing material, and rotation while then drives straight-bar in container Nanometer super hydrophilic material mixing, achieve the purpose that stirring in injection.

After straight-bar is stirred nanometer super hydrophilic material, mixed organization is then super hydrophilic to nanometer after grid type at this time Material carries out stirring again, achievees the purpose that stirring in injection, uniformity is more preferable.

Before ejecting, container is rocked in the effect of axial force, movable sleeving at this time then can be to the super hydrophilic material of nanometer Material is hit, and achievees the purpose that mixing.

Preferably, the movable sleeving inner wall is equipped with several inner convex ribs for moving along set and being axially arranged.

It can reduce contact area to inner convex rib, so as to further increase movably smoothness.

Preferably, the movable sleeving both ends outer wall is equipped with circular arc chamfering.

Circular arc chamfering can form guiding, to improve movement speed.

Preferably, mixed organization includes interior blended sliver after several C shapes being circumferentially distributed after the grid type, and The outer blended sliver after several C-shapeds on the outside of interior blended sliver after the C-shaped, it is outer after interior blended sliver quantity and C-shaped after the C-shaped Blended sliver quantity is equal and inside and outside is dislocatedly distributed.

That is, inside and outside dislocation is to form latticed mixed structure.

Alternatively scheme, mixed organization includes annular grid part after grid type.

Preferably, it is equipped with positioning through hole at the top of the described arch piece arc, the axial line of positioning through hole and conical through-hole Axial line is overlapped, and impeller center is freely rotated and is connected with shaft, shaft is mounted in positioning through hole and shaft and positioning through hole turn Dynamic connection.

It is arranged in shaft there are two circlip, circlip is stuck in the both ends of positioning through hole, and which obviate obscissions.

Preferably, the shaft outer end extends on the outside of the outer end of positioning through hole, matches in the outer end of shaft equipped with tool Close slot.

After opening closing cap, stirring can be realized by tool to cooperate with tool mating groove.

Tool mating groove includes any one in cross recess and interior hex slot.

Preferably, the column plug outer end is equipped with outside extended flange, and the outer diameter of flange is less than container open end Outer diameter and flange stick on container opening end face.

Column plug and flange are integrally formed, and are made of anti-corrosive rubber material.

Preferably, the flange outer end face is equipped with several ring annular grooves.

It can be further improved leakproofness.

The storage device of this nanometer of super hydrophilic material includes the upper end opening of container and container, its radial direction of container is squeezed Radial deformation can occur when power, the open end of container be equipped with plugging mechanism, the plugging mechanism include with outside container open end The closing cap that wall is threadedly coupled, mechanism further includes column plug, is equipped with conical through-hole and cone in the axial centre of column plug The small inner-diameter end of shape through-hole outwardly, annulus part is equipped on the inner end end face of column plug, is equipped on the inner face of annulus part Mixed organization after the grid type of structure in a ring, and across the arch piece in annulus part inner end, arch piece is to encircleing inside container It rises, is equipped at the top of the arc of arch piece and impeller is freely rotated, be connected separately on the every blade that impeller is freely rotated straight Bar and straight-bar stretches to inside container, the straight-bar is parallel to each other, and being arranged at least one respectively on every straight-bar can Along the movable sleeving that straight-bar moves axially, it is respectively equipped with outer convex retaining point at the both ends of every straight-bar, movable sleeving is located at two evaginations It is moved between catch point and between two outer convex retaining points；

The application method of storage device includes the following steps:

S1, preparation prepare the super hydrophilic material of nanometer, container and plugging mechanism, and the super hydrophilic material of nanometer includes following components With parts by weight content:

20-26 parts of sodium hydroxide

0.5-0.9 parts of dehydrated alcohol

1-3 parts of ethyl acetate

10-15 parts of carbon nanotube

0.1-0.3 parts of methyl orange；

At room temperature, sodium hydroxide, dehydrated alcohol, carbon nanotube and methyl orange are first added in stirring container, is stirred It mixes, then adds ethyl acetate again, obtain the super hydrophilic material of nanometer.

S2, bottling, the super hydrophilic material of nanometer is initially charged with to container, is mixed after being then connected with annulus part, grid type Mechanism, arch piece, the column plug for being freely rotated impeller, straight-bar and movable sleeving is closed to squeeze into the open end of container, until Flange sticks on container opening end face, finally by closing cap and the seal with screwed joint of container open end；

S3, injection, unscrew closing cap, and the super hydrophilic material of nanometer is ejected with the conical through-hole of column plug, sprayed During, the super hydrophilic material of nanometer contacts to be freely rotated to force and impeller is freely rotated with impeller is freely rotated, and freely turns Dynamic wheel rotation is to drive straight-bar to be stirred the super hydrophilic material of nanometer in container, and mixed organization is also right after grid type The super hydrophilic material of nanometer is stirred.

Compared with prior art, the advantages of storage device and its plugging mechanism of this nanometer of super hydrophilic material, is:

1, the super hydrophilic material of the nanometer in container is then forced to spray after container is squeezed outward, when injection, nanometer is super close It with impeller is freely rotated contacts that wheel rotation is freely rotated to forcing water material, and rotation while then drives straight-bar in container The super hydrophilic material mixing of interior nanometer, achievees the purpose that stirring in injection.

2, after straight-bar is stirred nanometer super hydrophilic material, mixed organization is then super to nanometer close after grid type at this time Water material carries out stirring again, achievees the purpose that stirring in injection, uniformity is more preferable.

3, container before ejecting, is rocked in the effect of axial force, movable sleeving at this time then can be super hydrophilic to nanometer Material is hit, and achievees the purpose that mixing.

Detailed description of the invention

Fig. 1 is structural schematic diagram provided by the utility model.

Fig. 2 is annulus part structural schematic diagram provided by the utility model.

Fig. 3 is pivot structure schematic diagram provided by the utility model.

Fig. 4 is movable sleeving structural schematic diagram provided by the utility model.

In figure, 10, container；20, closing cap；30, column plug；300, flange；3001, ring annular groove；301, taper Through-hole；302, annulus part；303, mixed organization after grid type；3031, interior blended sliver after C-shaped；3032, outer blended sliver after C-shaped； 304, arch piece；3041, positioning through hole；305, impeller is freely rotated；3051, shaft；3052, tool mating groove；306, straight-bar； 307, movable sleeving；3071, inner convex rib；3072, circular arc chamfering；308, outer convex retaining point.

Specific embodiment

It is the specific embodiment of utility model and in conjunction with attached drawing below, the technical solution of the utility model is made further Description, but the utility model is not limited to these examples.

As shown in Figs 1-4,

Embodiment one

The plugging mechanism of the super hydrophilic material storage means of plugging mechanism nanometer of this nanometer of super hydrophilic material is arranged in container Inside 10 open end, mechanism includes the closing cap 20 connecting with 10 open end outer wall thread of container, and container 10 is by transparent modeling Material material is made, volume 3-5L.

Closing cap 20 is also made of plastics.

Mechanism further includes column plug 30, and column plug 30 is made of anti-corrosive rubber, in the axial direction of column plug 30 Small inner-diameter end of the center equipped with conical through-hole 301 and conical through-hole 301 outwardly, is equipped with circle on the inner end end face of column plug 30 Ring 302, prioritization scheme are equipped with annular positioning groove on the inner end end face of column plug 30, and annulus part 302 passes through several spiral shells Nail is fixed in annular positioning groove.

Equipped with mixed organization 303 after the grid type of structure in a ring, specifically, this reality on the inner face of annulus part 302 Mixed organization 303 includes interior blended sliver 3031 after several C-shapeds being circumferentially distributed after applying the grid type of example, and is located at the C Outer blended sliver 3032 after several C-shapeds in 3031 outside of interior blended sliver after shape, interior 3031 quantity of blended sliver and C after the C-shaped Outer 3032 quantity of blended sliver is equal after shape and inside and outside is dislocatedly distributed.

Outer blended sliver 3032 is mutually close together after interior blended sliver 3031 and C-shaped after the C-shaped being arranged inside and outside.

Outer blended sliver 3032 is made of stainless steel material respectively after interior blended sliver 3031 and C-shaped after C-shaped.

And across the arch piece 304 in 302 inner end of annulus part, arch piece 304 is made of stainless steel material, arch piece 304, to arching upward inside container 10, are equipped at the top of the arc of arch piece 304 and impeller 305 are freely rotated, impeller 305 is freely rotated Blade have 3-5 piece, straight-bar 306 is connected separately on the every blade that impeller 305 is freely rotated and straight-bar 306 stretches to Inside container 10, the straight-bar 306 is parallel to each other, and being arranged at least one respectively on every straight-bar 306 can be along straight Bar 306 move axially movable sleeving 307, quantity should not be excessive, two be it is most, be respectively equipped at the both ends of every straight-bar 306 Outer convex retaining point 308, movable sleeving 307 are located between two outer convex retaining points 308 and move between two outer convex retaining points 308.

Outer convex retaining point 308 is the self threading pin being threadedly coupled with straight-bar 306.

Straight-bar 306 its be made of stainless steel material.

Several inner convex ribs 3071 for moving along set 307 and being axially arranged are equipped in 307 inner wall of movable sleeving.

Circular arc chamfering 3072 is equipped in 307 both ends outer wall of movable sleeving.

Movable sleeving 307 is made of stainless steel material.

Prioritization scheme is equipped with positioning through hole 3041, the axial line and cone of positioning through hole 3041 at the top of 304 arc of arch piece The axial line of shape through-hole 301 is overlapped, and 305 center of impeller is freely rotated and is connected with shaft 3051, it is logical that shaft 3051 is mounted on positioning In hole 3041 and shaft 3051 and positioning through hole 3041 are rotatablely connected.

Secondly, 3051 outer end of shaft extends on the outside of the outer end of positioning through hole 3041, work is equipped in the outer end of shaft 3051 Has mating groove 3052.

It is equipped with outside extended flange 300 in 30 outer end of column plug, the outer diameter of flange 300 is less than outside 10 open end of container Diameter and flange 300 stick on the open end face of container 10.

In addition, being equipped with several ring annular grooves 3001 on 300 outer end face of flange.

The storage device of this nanometer of super hydrophilic material includes that the upper end of container 10 and container 10 is open, its radial direction of container 10 by Radial deformation can occur when to extruding force, be equipped with plugging mechanism, specifically, the envelope of the present embodiment in the open end of container 10 Stifled mechanism includes the closing cap 20 connecting with 10 open end outer wall thread of container, and mechanism further includes column plug 30, in column The axial centre of plug 30 is equipped with the small inner-diameter end of conical through-hole 301 and conical through-hole 301 outwardly, in column plug 30 It holds end face to be equipped with annulus part 302, mixed organization after the grid type of structure in a ring is equipped on the inner face of annulus part 302 303, and across the arch piece 304 in 302 inner end of annulus part, arch piece 304 is to arching upward inside container 10, in arch piece 304 Arc at the top of be equipped with impeller 305 is freely rotated, straight-bar 306 is connected separately on the every blade that impeller 305 is freely rotated And straight-bar 306 stretches to inside container 10, the straight-bar 306 is parallel to each other, and is arranged with respectively at least on every straight-bar 306 One movable sleeving 307 that can be moved axially along straight-bar 306, is respectively equipped with outer convex retaining point at the both ends of every straight-bar 306 308, movable sleeving 307 is located between two outer convex retaining points 308 and moves between two outer convex retaining points 308；

The application method of storage device includes the following steps:

S1, preparation prepare the super hydrophilic material of nanometer, container 10 and plugging mechanism；

The super hydrophilic material of nanometer is initially charged with to container 10, then will be connected with annulus part 302, grid type by S2, bottling Afterwards mixed organization 303, arch piece 304, be freely rotated impeller 305, straight-bar 306 and movable sleeving 307 column plug 30 squeeze into Inside the open end of container 10, until flange 300 sticks on the open end face of container 10, finally by closing cap 20 and container 10 Open end seal with screwed joint；

S3, injection, unscrew closing cap 20, and the super hydrophilic material of nanometer is sprayed with the conical through-hole 301 of column plug 30 Out, during injection, the super hydrophilic material of nanometer with impeller 305 is freely rotated contacts to force that impeller 305 is freely rotated It is freely rotated, impeller 305 is freely rotated and rotates that straight-bar 306 is driven to be stirred the super hydrophilic material of nanometer in container, And mixed organization 303 is also stirred the super hydrophilic material of nanometer after grid type.

The super hydrophilic material of the nanometer includes following components and parts by weight content:

20-26 parts of sodium hydroxide

0.5-0.9 parts of dehydrated alcohol

1-3 parts of ethyl acetate

10-15 parts of carbon nanotube

0.1-0.3 parts of methyl orange.

Prioritization scheme, the present embodiment its be stirred according to following parts by weight:

23 parts of sodium hydroxide

0.7 part of dehydrated alcohol

2 parts of ethyl acetate

12 parts of carbon nanotube

0.2 part of methyl orange.

When solidification temperature is 180 DEG C, this nanometer of its contact angle of super hydrophilic material is 152 °, can satisfy daily building Requirement.

Embodiment two

The super hydrophilic material of nanometer includes following components and parts by weight content:

21 parts of sodium hydroxide

0.6 part of dehydrated alcohol

1 part of ethyl acetate

15 parts of carbon nanotube

0.15 part of methyl orange.

Embodiment three

The super hydrophilic material of nanometer includes following components and parts by weight content:

26 parts of sodium hydroxide

0.9 part of dehydrated alcohol

3 parts of ethyl acetate

15 parts of carbon nanotube

0.3 part of methyl orange.

Example IV

The super hydrophilic material of nanometer includes following components and parts by weight content:

20 parts of sodium hydroxide

0.8 part of dehydrated alcohol

1.7 parts of ethyl acetate

10 parts of carbon nanotube

0.1 part of methyl orange.

The specific embodiments described herein are merely examples of the spirit of the present invention.The utility model institute Belonging to those skilled in the art can make various modifications or additions to the described embodiments or using similar Mode substitute, but without departing from the spirit of the present application or beyond the scope of the appended claims.

Claims (9)

1. the plugging mechanism of nanometer super hydrophilic material storage means, is arranged in inside the open end of container, mechanism includes and appearance The closing cap of device open end outer wall thread connection, which is characterized in that mechanism further includes column plug, in the axial direction of column plug Small inner-diameter end of the center equipped with conical through-hole and conical through-hole outwardly, is equipped with annulus part, In on the inner end end face of column plug The inner face of annulus part is equipped with mixed organization after the grid type of structure in a ring, and across the arch in annulus part inner end Piece, arch piece are equipped at the top of the arc of arch piece and impeller are freely rotated, the every of impeller is being freely rotated to arching upward inside container It is connected separately with straight-bar on piece blade and straight-bar stretches to inside container, the straight-bar is parallel to each other, and divides on every straight-bar It is not arranged at least one movable sleeving that can be moved axially along straight-bar, is respectively equipped with evagination gear at the both ends of every straight-bar Point, movable sleeving are located between two outer convex retaining points and move between two outer convex retaining points.

2. the plugging mechanism of the super hydrophilic material storage means of nanometer according to claim 1, which is characterized in that the shifting Dynamic set inner wall is equipped with several inner convex ribs for moving along set and being axially arranged.

3. the plugging mechanism of the super hydrophilic material storage means of nanometer according to claim 1, which is characterized in that the shifting Dynamic set both ends outer wall is equipped with circular arc chamfering.

4. the plugging mechanism of the super hydrophilic material storage means of nanometer according to claim 1, which is characterized in that the net Mixed organization includes interior blended sliver after several C-shapeds being circumferentially distributed after format, and is located at interior blended sliver outside after the C-shaped Several C-shapeds after outer blended sliver, outer blended sliver quantity is equal and inside and outside dislocation after interior blended sliver quantity and C-shaped after the C-shaped Distribution.

5. the plugging mechanism of the super hydrophilic material storage means of nanometer according to claim 1, which is characterized in that the arch Positioning through hole is equipped at the top of shape piece arc, the axial line of positioning through hole and the axial line of conical through-hole are overlapped, and impeller is freely rotated Center is connected with shaft, and shaft is mounted in positioning through hole and shaft and positioning through hole are rotatablely connected.

6. the plugging mechanism of the super hydrophilic material storage means of nanometer according to claim 5, which is characterized in that described turns Axis outer end extends on the outside of the outer end of positioning through hole, is equipped with tool mating groove in the outer end of shaft.

7. the plugging mechanism of the super hydrophilic material storage means of nanometer according to claim 1, which is characterized in that the column Shape plug outer end is equipped with outside extended flange, and the outer diameter of flange is less than container open end outer diameter and flange sticks on container opening On end face.

8. the plugging mechanism of the super hydrophilic material storage means of nanometer according to claim 7, which is characterized in that described turns over Side outer end face is equipped with several ring annular grooves.

9. the storage device of nanometer super hydrophilic material, including the upper end of container and container opening, its radial direction of container is squeezed power When radial deformation can occur, which is characterized in that be equipped with plugging mechanism in the open end of container, which includes and container The closing cap of open end outer wall thread connection, mechanism further includes column plug, is equipped with taper in the axial centre of column plug The small inner-diameter end of through-hole and conical through-hole outwardly, is equipped with annulus part, in the inner end of annulus part on the inner end end face of column plug Face is equipped with mixed organization after the grid type of structure in a ring, and across the arch piece in annulus part inner end, and arch piece is to appearance It arches upward inside device, is equipped at the top of the arc of arch piece and impeller is freely rotated, on every blade for be freely rotated impeller respectively It is connected with straight-bar and straight-bar stretches to inside container, the straight-bar is parallel to each other, and is arranged with respectively at least on every straight-bar One movable sleeving that can be moved axially along straight-bar, is respectively equipped with outer convex retaining point at the both ends of every straight-bar, movable sleeving is located at It is moved between two outer convex retaining points and between two outer convex retaining points.