CN211754210U - Stirrer for reversed-phase microemulsion method - Google Patents

Abstract

The utility model discloses an agitator is used to reverse-phase microemulsion method, including first device shell, second motor, first slide bar, first linkage bar, lead screw, recess, second linkage bar and gear, the handle is installed on the top of first device shell, and evenly installs button switch in one side on handle top, the intermediate position department of the inside both sides of first device shell transversely installs the bottom plate, and the vertical fixed block of installing of intermediate position department of bottom plate top one end, the third motor is transversely installed on the top of fixed block one end, and the second linkage bar that runs through the fixed block is transversely installed to third motor output, the vertical second device shell of installing of intermediate position department of first device shell bottom, and the all vertical third device shell of installing in the bottom of the first device shell in second device shell both sides. The reverse microemulsion method uses a stirrer to control an ion wind rod through a button switch to remove the ions attached to the device, and does not cause damage to the reverse microemulsion.

Description

Stirrer for reversed-phase microemulsion method

Technical Field

The utility model relates to a stirrer technical field specifically is a stirrer for reversed-phase microemulsion method.

Background

The microemulsion is a thermodynamically stable, isotropic, transparent or translucent dispersion system formed by two immiscible liquids, and is microscopically formed by droplets of one or two liquids stabilized by a surfactant interfacial film, wherein the reverse microemulsion method is a novel method for preparing materials developed in recent years, and is a material preparation method for synthesizing particles with different sizes and shapes by searching a preparation method of one or more microemulsions so as to obtain materials related to required properties, stirring is required in the preparation process so that the reverse microemulsions are fully fused, and a stirrer used in the traditional reverse microemulsion method can basically meet the use requirements of people, but certain problems still exist, and the specific problems are as follows:

1. most of the stirrers used in the reverse microemulsion method in the market at present cannot well treat the residual reverse microemulsion on the stirred stirrer in the using process, so that the reverse microemulsion cannot be well scraped off, and the stirrer is extremely easily damaged in the scraping process;

2. most of stirrers used in the reverse-phase microemulsion method in the market at present can damage the reverse-phase microemulsion due to the electric ions carried on the device when in use, so that the reverse-phase microemulsion can not be coalesced, and the loss is caused to manufacturers;

3. most of the stirrers used in the reverse microemulsion method in the market at present can not be adjusted according to the size of a container used by a user, and meanwhile, the container for containing the reverse microemulsion is extremely easy to damage in the stirring process, and the reverse microemulsion is also polluted.

Disclosure of Invention

An object of the utility model is to provide a stirrer for reversed-phase microemulsion method to solve the problem that proposes in the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme: the utility model provides an agitator is used to opposition microemulsion method, includes first device shell, second motor, first slide bar, lead screw, recess and gear, the handle is installed on the top of first device shell, and evenly installs button switch in one side on handle top, the intermediate position department of the inside both sides of first device shell transversely installs the bottom plate, and the vertical fixed block of installing of intermediate position department of bottom plate top one end, the third motor is transversely installed on the top of fixed block one end, and the horizontal second trace that runs through the fixed block of installing of third motor output, the vertical second device shell of installing of intermediate position department of first device shell bottom, and the bottom of the first device shell of second device shell both sides is all vertically installed third device shell, the intermediate position department of the inside bottom of first device shell installs the second motor, and the second motor output end is installed through the bearing and runs through first device shell and extend to second device shell bottom The first linkage rod.

Preferably, a gear is installed at one end, far away from the fixed block, of the outer side of the second linkage rod, a first rack is transversely arranged at the top end of the gear, and first sliding rods are transversely installed inside the two ends of the first rack.

Preferably, the first sliding block penetrating through the first rack is installed on the outer side of the first sliding rod, the top end of the first sliding block is connected with the top end inside the first device shell, and a first clamping block penetrating through the first device shell is installed on one side of the first sliding block.

Preferably, the bottom of gear transversely is provided with the second rack, and the inside at second rack both ends all transversely installs the second slide bar, the second slide bar outside all installs the second slider that runs through the second rack, and the bottom of second slider all is connected with the top of bottom plate, the second rack is kept away from first fixture block one side and is installed the second fixture block that runs through the first device shell, the bottom of first fixture block and second fixture block all pastes and has anti-skidding rubber pad.

Preferably, the inside of the second device shell on both sides of the first linkage rod is vertically provided with an ion wind rod, and the bottom end of the outer side of the first linkage rod is transversely provided with a stirring blade.

Preferably, first motors are installed at the bottom ends of the inner portions of the first device shells on the two sides of the second motor, and screw rods which penetrate through the second rack and extend to the bottom end of the inner portion of the third device shell are installed at the output ends of the first motors through bearings.

Preferably, the third device shells on the two sides of the screw rod are all provided with grooves, and baffles are vertically arranged at the middle positions inside the grooves.

Preferably, the inside both ends of recess all transversely install the spring beam who runs through the baffle, and the spring beam is close to the one end of baffle and all vertically installs the card strip, the lead screw outside all is provided with the scraper blade that runs through the recess.

Compared with the prior art, the beneficial effects of the utility model are that:

1. the first motor is controlled by the button switch to drive the screw rod to rotate and drive the scraper to move, the surfaces of the second device shell and the third device shell are cleaned by the scraper in the moving thickness, so that the reversed-phase microemulsion remained on the surfaces of the devices can be well scraped off, and meanwhile, the stirrer cannot be damaged in the scraping process;

2. meanwhile, the device is provided with the button switch and the ion wind rod, and the button switch is used for controlling the ion wind rod to remove the electric ions attached to the used device, so that the electric ions carried by the device are reduced, and the reverse microemulsion is not damaged;

3. meanwhile, the device is installed, the third motor is controlled to rotate through the button switch, the gear is driven to rotate, the first rack and the second rack are driven to move in opposite directions when the gear rotates, and the first fixture block and the second fixture block are driven to move when the first rack and the second rack rotate, so that the size of the device can be adjusted according to the requirements of a user.

Drawings

FIG. 1 is a front view of the cross-sectional structure of the present invention;

FIG. 2 is a schematic right sectional view of the present invention;

FIG. 3 is an enlarged view of the portion A of FIG. 1 according to the present invention;

fig. 4 is a schematic top view of the present invention;

fig. 5 is an enlarged schematic view of a portion B in fig. 2 according to the present invention.

In the figure: 1. an anti-skid rubber pad; 2. a first clamping block; 3. a first device housing; 4. a first motor; 5. a second motor; 6. a handle; 7. a push button switch; 8. a first rack; 9. a first slider; 10. a first slide bar; 11. a second slide bar; 12. a second slider; 13. a second rack; 14. a base plate; 15. a second fixture block; 16. a squeegee; 17. an ion wind rod; 18. a second device housing; 19. a first linkage rod; 20. stirring blades; 21. a screw rod; 22. a third device housing; 23. a groove; 24. a fixed block; 25. a third motor; 26. a second linkage rod; 27. a gear; 28. clamping the strip; 29. a spring lever; 30. and a baffle plate.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-5, the present invention provides an embodiment: a stirrer for an anti-phase micro-emulsion method comprises a first device shell 3, a second motor 5, a first sliding rod 10, a screw rod 21, a groove 23 and a gear 27, wherein a handle 6 is installed at the top end of the first device shell 3, a button switch 7 is evenly installed on one side of the top end of the handle 6, a bottom plate 14 is transversely installed at the middle position of two sides in the first device shell 3, a fixing block 24 is vertically installed at the middle position of one end of the top end of the bottom plate 14, a third motor 25 is transversely installed at the top end of one end of the fixing block 24, the type of the third motor 25 can be R300-11440, and a second linkage rod 26 penetrating through the fixing block 24 is transversely installed at the output end of the third motor 25;

a gear 27 is arranged at one end of the outer side of the second linkage rod 26 far away from the fixed block 24, a first rack 8 is transversely arranged at the top end of the gear 27, and a first sliding rod 10 is transversely arranged inside each of two ends of the first rack 8, so that the device can be clamped and locked;

the outer sides of the first sliding rods 10 are respectively provided with a first sliding block 9 penetrating through the first rack 8, the top ends of the first sliding blocks 9 are connected with the top end inside the first device shell 3, and one side of each first sliding block 9 is provided with a first clamping block 2 penetrating through the first device shell 3, so that the device can be better fixed on the container placing surface when in use;

a second rack 13 is transversely arranged at the bottom end of the gear 27, a second sliding rod 11 is transversely arranged inside each of two ends of the second rack 13, a second sliding block 12 penetrating through the second rack 13 is arranged outside each second sliding rod 11, the bottom end of each second sliding block 12 is connected with the top end of the bottom plate 14, a second fixture block 15 penetrating through the first device shell 3 is arranged on one side, away from the first fixture block 2, of each second rack 13, and anti-skid rubber pads 1 are adhered to the bottom ends of the first fixture block 2 and the second fixture block 15, so that the device is more convenient to use;

a second device shell 18 is vertically installed at the middle position of the bottom end of the first device shell 3, third device shells 22 are vertically installed at the bottom ends of the first device shells 3 on two sides of the second device shell 18, a second motor 5 is installed at the middle position of the bottom end inside the first device shell 3, and the model of the second motor 5 can be 42BYGH 4818;

the first motor 4 is mounted at the bottom end inside the first device shell 3 at two sides of the second motor 5, the model of the first motor 4 can be GM12-15BY-n1, and the screw rod 21 which penetrates through the second rack 13 and extends to the bottom end inside the third device shell 22 is mounted at the output end of the first motor 4 through a bearing, so that the surface of the device can be cleaned conveniently;

grooves 23 are formed in the third device shell 22 on the two sides of the screw rod 21, and baffles 30 are vertically arranged in the middle positions of the grooves 23, so that the reverse microemulsion cannot permeate into the device due to the attachment of the device;

two ends inside the groove 23 are both transversely provided with spring rods 29 penetrating through the baffle 30, one ends of the spring rods 29, which are close to the baffle 30, are both vertically provided with clamping strips 28, and the outer side of the screw rod 21 is provided with scrapers 16 penetrating through the groove 23, so that the device is convenient to seal;

and the output end of the second motor 5 is provided with a first linkage rod 19 which penetrates through the first device shell 3 and extends to the bottom end of the second device shell 18 through a bearing;

the ion wind bars 17 are vertically arranged inside the second device shell 18 on two sides of the first linkage rod 19, the type of the ion wind bar 17 can be AS6400BF, and the bottom end of the outer side of the first linkage rod 19 is transversely provided with the stirring blades 20, so that the device can be stirred conveniently.

The working principle is as follows: when the stirrer for the reverse microemulsion method is used, the button switch 7 is used for controlling the third motor 25 to rotate, and simultaneously driving the second linkage rod 26 and the gear 27 to rotate, because the gear 27 drives the first rack 8 and the second rack 13 to move in two different directions when rotating, when the first rack 8 and the second rack 13 drive the first fixture block 2 and the second fixture block 15 to move when rotating, so that the first fixture block 2 and the second fixture block 15 clamp a container containing reverse microemulsion, when the first fixture block 2 and the second fixture block 15 are clamped, the button switch 7 is used for controlling the second motor 5 to rotate and simultaneously driving the first linkage rod 19 to rotate, when the first linkage rod 19 rotates, the stirring blade 20 is driven to stir the reverse microemulsion, and simultaneously, because the ion wind rod 17 in the second device shell 18 works, the ions carried by the device disappear and cannot cause damage to the reverse microemulsion, after the device finishes stirring the anti-phase microemulsion, the third motor 25 is controlled to rotate through the button switch 7 to drive the second linkage rod 26 and the gear 27 to rotate, then the gear 27 rotates to drive the first rack 8 and the second rack 13 to move in two opposite directions, when the first rack 8 and the second rack 13 rotate, the first fixture block 2 and the second fixture block 15 are driven to move, so that the first fixture block 2 and the second fixture block 15 loosen the container for containing the anti-phase microemulsion, the device is taken out from the container, the first motor 4 drives the screw rod 21 to rotate and simultaneously drives the scraper 16 to move to clean the surfaces of the second device shell 18 and the third device shell 22, and the above is the whole working principle of the utility model.

It is obvious to a person skilled in the art that the invention is not restricted to details of the above-described exemplary embodiments, but that it can be implemented in other specific forms without departing from the spirit or essential characteristics of the invention. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (8)

1. The utility model provides a stirrer for reverse microemulsion method, includes first device shell (3), second motor (5), first slide bar (10), lead screw (21), recess (23) and gear (27), its characterized in that: the handle (6) is installed on the top end of the first device shell (3), the button switch (7) is evenly installed on one side of the top end of the handle (6), the bottom plate (14) is transversely installed at the middle position of two sides in the first device shell (3), the fixing block (24) is vertically installed at the middle position of one end of the top end of the bottom plate (14), the third motor (25) is transversely installed at the top end of one end of the fixing block (24), the second linkage rod (26) penetrating through the fixing block (24) is transversely installed at the output end of the third motor (25), the second device shell (18) is vertically installed at the middle position of the bottom end of the first device shell (3), the third device shell (22) is vertically installed at the bottom end of the first device shell (3) on two sides of the second device shell (18), the second motor (5) is installed at the middle position of the bottom end in the first device shell (3), and the output end of the second motor (5) is provided with a first linkage rod (19) which penetrates through the first device shell (3) and extends to the bottom end of the second device shell (18) through a bearing.

2. An agitator for reverse microemulsion method according to claim 1, wherein: a gear (27) is installed at one end, far away from the fixed block (24), of the outer side of the second linkage rod (26), a first rack (8) is transversely arranged at the top end of the gear (27), and first sliding rods (10) are transversely installed inside two ends of the first rack (8).

3. An agitator for reverse microemulsion method according to claim 2, wherein: first slider (9) that run through first rack (8) are all installed in first slide bar (10) outside, and the top of first slider (9) all is connected with the inside top of first device shell (3), first fixture block (2) that run through first device shell (3) are installed to one side of first slider (9).

4. An agitator for reverse microemulsion method according to claim 2, wherein: the bottom of gear (27) transversely is provided with second rack (13), and the inside at second rack (13) both ends all transversely installs second slide bar (11), second slide bar (11) outside all installs second slider (12) that run through second rack (13), and the bottom of second slider (12) all is connected with the top of bottom plate (14), first fixture block (2) one side is kept away from in second rack (13) and second fixture block (15) that run through first device shell (3) are installed, first fixture block (2) all paste with the bottom of second fixture block (15) and have antiskid rubber pad (1).

5. An agitator for reverse microemulsion method according to claim 1, wherein: the interior of the second device shell (18) on two sides of the first linkage rod (19) is vertically provided with an ion wind rod (17), and the bottom end of the outer side of the first linkage rod (19) is transversely provided with a stirring blade (20).

6. An agitator for reverse microemulsion method according to claim 1, wherein: first motor (4) are all installed to the inside bottom of first device shell (3) in second motor (5) both sides, and first motor (4) output is installed through the bearing and is run through second rack (13) and extend to lead screw (21) of the inside bottom of third device shell (22).

7. An agitator for reverse microemulsion method according to claim 1, wherein: grooves (23) are formed in the third device shells (22) on the two sides of the screw rod (21), and baffles (30) are vertically arranged in the middle positions of the inner parts of the grooves (23).

8. A stirrer for reverse microemulsion method according to claim 7, which comprises: spring rods (29) penetrating through the baffle plates (30) are transversely installed at two ends inside the grooves (23), clamping strips (28) are vertically installed at one ends, close to the baffle plates (30), of the spring rods (29), and scraping plates (16) penetrating through the grooves (23) are arranged on the outer sides of the screw rods (21).

Images