CN112546950A

CN112546950A - Multiple solution mixing device for realizing negative ion separation

Info

Publication number: CN112546950A
Application number: CN202011372622.9A
Authority: CN
Inventors: 袁里
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-11-30
Filing date: 2020-11-30
Publication date: 2021-03-26

Abstract

The invention discloses a multi-solution mixing device for realizing negative ion separation, which comprises a rotating cavity and a plurality of liquid inlet pipes, wherein the liquid inlet pipes are circumferentially arranged at the bottom of the rotating cavity and are fixedly connected with the rotating cavity through liquid inlet holes formed in the bottom of the rotating cavity, a liquid outlet hole is formed in the top of the rotating cavity, a liquid discharge pipe is arranged in the liquid outlet hole, a second rotating rod is arranged in each liquid inlet pipe, and a first liquid inlet spiral blade, a second liquid inlet spiral blade and a third liquid inlet spiral blade are coaxially arranged in each liquid inlet pipe. The invention adopts the mode that the liquid spraying head is opened to enable the solution to rush into the liquid inlet pipe with the first liquid inlet spiral blade, and the solution impacts the first liquid inlet spiral blade, so that the first liquid inlet spiral blade is driven to rotate, the first meshing gear at the end part of the second rotating rod on the first liquid inlet spiral blade is driven to rotate together, and the first meshing gear drives the second meshing gear which is meshed with each other to rotate in a meshing way.

Description

Multiple solution mixing device for realizing negative ion separation

Technical Field

The invention relates to the technical field of anion separation, in particular to a multi-solution mixing device for realizing anion separation.

Background

At present, some free ions need to be separated in some experimental devices, but the proportion required by the reaction is sometimes difficult to be grasped, and usually, the problems of large quantity and small quantity exist in the adding reaction process, which is extremely easy to generate waste in an industrial system, but in some chemical reaction operations with low profit, some high-precision detection instruments often have the problem of being over-applied, so that the cost in the test process can be increased, and the production of the product and the separation of the required free ions are not facilitated.

Therefore, a multi-solution mixing device for realizing negative ion separation is designed.

Disclosure of Invention

The invention aims to provide a multi-solution mixing device for realizing negative ion separation, which aims to solve the problems that the proportion required by a chemical reaction is difficult to grasp sometimes, and the addition reaction process usually has a large amount and a small amount.

In order to achieve the purpose, the invention adopts the following technical scheme:

a multiple solution mixing device for realizing negative ion separation comprises a rotating cavity and a plurality of liquid inlet pipes, wherein the liquid inlet pipes are circumferentially arranged at the bottom of the rotating cavity and are fixedly connected with the rotating cavity through liquid inlet holes formed at the bottom of the rotating cavity, a liquid outlet hole is formed at the top of the rotating cavity, a liquid discharge pipe is arranged in the liquid outlet hole, a second rotating rod is arranged in each liquid inlet pipe, a plurality of first liquid inlet spiral leaves, a second liquid inlet spiral leaves and a third liquid inlet spiral leaves are coaxially arranged in each liquid inlet pipe respectively, the first liquid inlet spiral leaves, the second liquid inlet spiral leaves and the third liquid inlet spiral leaves are coaxially arranged with the second rotating rod respectively, a second meshing gear is arranged in the rotating cavity, the second meshing gear is horizontally arranged, a plurality of first meshing gears are circumferentially arranged around the second meshing gear, and the first meshing gear is fixedly connected with the end part of the second rotating rod, the last coaxial first transfer pole that is provided with of second meshing gear, be provided with the flowing back spiral leaf on the first transfer pole lateral wall, flowing back spiral leaf and the coaxial setting of fluid-discharge tube, be provided with the slope filter screen on the fluid-discharge tube inside wall, slope filter screen below is provided with holds the sediment pipe, it is provided with the rubber buffer to hold the sediment pipe slag notch.

Preferably, a plurality of the liquid inlet pipes are arranged at the bottom of the rotating cavity in an angle.

Preferably, the first liquid inlet spiral blade, the second liquid inlet spiral blade and the third liquid inlet spiral blade have the same height and diameter and different screw pitches.

Preferably, the second meshing gear is in meshed transmission with a plurality of first meshing gears arranged in a circumferential mode.

Preferably, the flowing back helical blade is the same with first feed liquor helical blade, second feed liquor helical blade and third feed liquor helical blade compare diameter, and the pitch is different, and the pitch of flowing back helical blade all is greater than the pitch of first feed liquor helical blade, second feed liquor helical blade and third feed liquor helical blade.

Preferably, the first rotating rod is arranged on the inner side wall of the liquid discharge pipe through an external load bracket.

The invention has the beneficial effects that:

1. the invention adopts the mode that the liquid spraying head is opened to enable the solution to rush into the liquid inlet pipe with the first liquid inlet spiral blade, and the solution impacts the first liquid inlet spiral blade, so that the first liquid inlet spiral blade is driven to rotate, the first meshing gear at the end part of the second rotating rod on the first liquid inlet spiral blade is driven to rotate together, and the first meshing gear drives the second meshing gear which is meshed with each other to rotate in a meshing way.

2. According to the invention, the first liquid inlet spiral blade, the second liquid inlet spiral blade and the third liquid inlet spiral blade are different in screw pitch and number of turns, so that when the second rotating rod rotates for one turn, the amount of solution entering the rotating cavity by the corresponding solution brought by the first liquid inlet spiral blade, the second liquid inlet spiral blade and the third liquid inlet spiral blade is different, and thus the first liquid inlet spiral blade, the second liquid inlet spiral blade and the third liquid inlet spiral blade with different screw pitches can be selected for regulating and controlling the amount of the solution to be mixed.

Drawings

FIG. 1 is a schematic structural diagram of a multi-solution mixing device for achieving negative ion separation according to the present invention;

FIG. 2 is a front view of a multiple solution mixing device for achieving negative ion separation according to the present invention;

FIG. 3 is a side view of an upper and lower equiangular shaft of a multi-solution mixing device for realizing negative ion separation according to the present invention;

fig. 4 is a partial exploded view of a multi-solution mixing device for realizing negative ion separation according to the present invention.

In the figure: 1 rotation chamber, 2 fluid-discharge tubes, 3 feed liquor pipes, 4 first dwang, 5 second dwang, 6 flowing back spiral leaf, 7 first feed liquor spiral leaf, 8 second feed liquor spiral leaf, 9 third feed liquor spiral leaf, 10 first meshing gear, 11 second meshing gear, 12 slope filter screens, 13 hold the sediment pipe.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention.

Referring to fig. 1-4, a multiple solution mixing arrangement for realizing anion separation, including rotating chamber 1 and a plurality of feed liquor pipe 3, a plurality of feed liquor pipe 3 are circumference setting and rotate chamber 1 bottom, and feed liquor pipe 3 through rotate the feed liquor hole that 1 bottom of chamber was seted up with rotate chamber 1 fixed connection, a plurality of feed liquor pipe 3 each other be 120 degrees arrange in rotating chamber 1 bottom, set up the rubber tube in corresponding feed liquor pipe 3 respectively, then pass through threaded connection with one of them feed liquor pipe 3 bottom, other container that hold and wait to mix the solution is placed to other feed liquor pipe 3 bottoms, then open the hydrojet, let solution rush into the feed liquor pipe 3 that has first feed liquor spiral leaf 7.

The top of the rotating cavity 1 is provided with a liquid outlet hole, a liquid discharge pipe 2 is arranged in the liquid outlet hole, second rotating rods 5 are arranged in the liquid inlet pipes 3, a first liquid inlet spiral blade 7, a second liquid inlet spiral blade 8 and a third liquid inlet spiral blade 9 are coaxially arranged in the liquid inlet pipes 3 respectively, the first liquid inlet spiral blade 7, the second liquid inlet spiral blade 8 and the third liquid inlet spiral blade 9 have the same height and diameter and different screw pitches, because the first liquid inlet spiral blade 7, the second liquid inlet spiral blade 8 and the third liquid inlet spiral blade 9 have different screw pitches and turns, the first liquid inlet spiral blade 7, the second liquid inlet spiral blade 8 and the third liquid inlet spiral blade 9 bring corresponding solutions into the rotating cavity 1 with different solution amounts when the second rotating rod 5 rotates for one turn, therefore, the regulation and control of the first liquid inlet spiral blade 7, the second liquid inlet spiral blade 8 and the third liquid inlet spiral blade 9 with different screw pitches can be realized according to different amounts of the solution to be mixed.

The first liquid inlet spiral blade 7, the second liquid inlet spiral blade 8 and the third liquid inlet spiral blade 9 are respectively arranged coaxially with the second rotating rod 5, a second meshing gear 11 is arranged in the rotating cavity 1, the second meshing gear 11 is horizontally arranged, a plurality of first meshing gears 10 are circumferentially arranged around the second meshing gear 11, the first meshing gears 10 are fixedly connected with the end part of the second rotating rod 5, the second meshing gear 11 is in meshed transmission with the plurality of first meshing gears 10 which are circumferentially arranged, a solution impacts the first liquid inlet spiral blade 7, the first liquid inlet spiral blade 7 is driven to rotate, the first meshing gears 10 at the end part of the second rotating rod 5 on the first liquid inlet spiral blade 7 are driven to rotate together, the first meshing gears 10 can drive the second meshing gears 11 which are meshed with each other to rotate, then, the second meshing gears 11 rotate, the other two first meshing gears 10 around the second meshing gears 11 can be driven to rotate, like other two first meshing gear 10 can take the second dwang 5 of below to rotate, and the second feed liquor spiral leaf 8 and the third feed liquor spiral leaf 9 that set up on the second dwang 5 lateral wall of other two also can rotate, and then can take and hold the container solution suction that remains mixed solution and in the feed liquor pipe 3, accomplish the mixture to solution.

The second meshing gear 11 is coaxially provided with a first rotating rod 4, and the first rotating rod 4 is arranged on the inner side wall of the liquid discharge pipe 2 through an outer load support to provide support for the rotation of the first rotating rod 4.

Be provided with flowing back helical blade 6 on the 4 lateral walls of first transfer line, flowing back helical blade 6 sets up with the drainpipe 2 is coaxial, flowing back helical blade 6 and first feed liquor helical blade 7, second feed liquor helical blade 8 is the same with third feed liquor helical blade 9 compares the diameter, the pitch is different, and the pitch of flowing back helical blade 6 all is greater than first feed liquor helical blade 7, the pitch of second feed liquor helical blade 8 and third feed liquor helical blade 9, because rotate the interior solution gathering of chamber 1, in addition the rotation of second meshing gear 11 drives the rotation of first transfer line 4, finally to the rotation of flowing back helical blade 6, it needs to explain, the pitch ratio first feed liquor helical blade 7 of flowing back helical blade 6, second feed liquor helical blade 8 and third feed liquor helical blade 9 are all big, can guarantee that can be timely will rotate the intracavity 1 interior solution discharge.

Be provided with slope filter screen 12 on the 2 inside walls of fluid-discharge tube, slope filter screen 12 below is provided with holds slag pipe 13, it is provided with the rubber buffer to hold slag pipe 13 slag notch, there are mixed solution and corresponding deposit in rotating chamber 1, when the mixed solution is upwards lifted by flowing back spiral leaf 6, the obstruction of slope filter screen 12 has been met, set up the slag pipe 13 that holds that has the rubber buffer on the fluid-discharge tube 2 lateral wall of slope filter screen 12 bottom, that, contain the sediment material in the solution and can enter into in holding slag pipe 13, and the solution can pass slope filter screen 12 and continue to rise along fluid-discharge tube 2.

Wherein the setting of slope filter screen 12 is for containing the sediment in the solution that will draw from the bottom from top and can not complete cover in conventional flat filter screen 12 bottom, leads to the jam of filter screen, and the advantage of slope setting will produce the difference in height, can not lead to the sediment to plug up the filter screen under the impact, in order to play better filter effect.

The working principle of the invention is as follows: firstly, two to three kinds of solutions to be mixed are selected, then the rubber pipes are respectively arranged in the corresponding liquid inlet pipes 3, then one of the liquid spraying heads is connected to the bottom of one of the liquid inlet pipes 3 through threads, other containers containing the solutions to be mixed are placed at the bottoms of the other liquid inlet pipes 3, then the liquid spraying heads are opened, the solutions are flushed into the liquid inlet pipes 3 with the first liquid inlet spiral blades 7, the first liquid inlet spiral blades 7 are driven to rotate due to the fact that the solutions impact the first liquid inlet spiral blades 7, then the first meshing gears 10 at the end parts of the second rotating rods 5 on the first liquid inlet spiral blades 7 are driven to rotate together, and the first meshing gears 10 are driven to mesh and rotate with the second meshing gears 11 which are meshed with each other.

Then, the rotation of the second meshing gear 11 can drive the other two first meshing gears 10 around the second meshing gear 11 to rotate, and like this, the other two first meshing gears 10 can drive the second rotating rod 5 below to rotate, and the second liquid inlet spiral blade 8 and the third liquid inlet spiral blade 9 arranged on the outer side walls of the other two second rotating rods 5 can also rotate, and then the container solution containing the solution to be mixed can be driven to be pumped into the liquid inlet pipe 3.

It should be noted that, because the three first engaging gears 10 around the second engaging gear 11 have the same rotation speed, the three first engaging gears 10 will drive the respective first liquid feeding spiral blade 7, second liquid feeding spiral blade 8 and third liquid feeding spiral blade 9 to rotate, except that the first liquid feeding spiral blade 7 is used for self-feeding liquid, the liquid feeding pipes 3 in the other two second liquid feeding spiral blades 8 and third liquid feeding spiral blades 9 are used for sucking up the solution, and because the screw pitches and the number of turns on the first liquid feeding spiral blade 7, the second liquid feeding spiral blade 8 and the third liquid feeding spiral blade 9 are different, the solution amount of the corresponding solution in the rotating cavity 1 is also different when the second rotating rod 5 rotates for each turn, so that the selection of the first liquid feeding spiral blade 7, the second liquid feeding spiral blade 8 and the third liquid feeding spiral blade 9 with different screw pitches can be completed for different amounts of the solution to be mixed, The second liquid inlet spiral blade 8 and the third liquid inlet spiral blade 9 are regulated and controlled.

Then, because the solution in the rotating cavity 1 is gathered, and the rotation of the second meshing gear 11 drives the rotation of the first rotating rod 4, finally the drainage spiral blade 6 is rotated, it should be noted that the screw pitch of the drainage spiral blade 6 is larger than that of the first liquid inlet spiral blade 7, the second liquid inlet spiral blade 8 and the third liquid inlet spiral blade 9, so that the solution in the rotating cavity 1 can be discharged timely.

It should be noted that the mixed solution and the corresponding precipitate are in the rotary chamber 1, and when the mixed solution is lifted upwards by the drainage spiral blade 6, the mixed solution is blocked by the inclined filter screen 12, and the slag storage tube 13 with a rubber plug is arranged on the side wall of the drainage tube 2 at the bottom of the inclined filter screen 12, so that the precipitate contained in the solution enters the slag storage tube 13, and the solution passes through the inclined filter screen 12 and continues to rise along the drainage tube 2.

It should be noted that the inclined filter screen 12 is arranged to cover the bottom of the conventional flat filter screen 12 with the sediment in the solution drawn from the bottom, which will not completely cover the bottom of the flat filter screen 12, resulting in the blockage of the filter screen.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims

1. The utility model provides a realize multiple solution mixing arrangement of anion separation, includes and rotates chamber (1) and a plurality of feed liquor pipe (3), its characterized in that, a plurality of feed liquor pipe (3) are the circumference setting and rotate chamber (1) bottom, and feed liquor pipe (3) through rotating the feed liquor hole that chamber (1) bottom was seted up and rotating chamber (1) fixed connection, it has seted up out the liquid hole to rotate chamber (1) top, and is provided with fluid-discharge tube (2) in the liquid hole, all be provided with second dwang (5) in feed liquor pipe (3), a plurality of respectively coaxial first feed liquor spiral leaf (7), second feed liquor spiral leaf (8) and third feed liquor spiral leaf (9) are provided with in feed liquor pipe (3), first feed liquor spiral leaf (7), second feed liquor spiral leaf (8) and third feed liquor spiral leaf (9) respectively with second dwang (5) coaxial setting, be provided with second meshing gear (11) in rotation chamber (1), second meshing gear (11) level is placed, and second meshing gear (11) be the circumference all around and be provided with a plurality of first meshing gear (10), and first meshing gear (10) and second dwang (5) tip fixed connection, the coaxial first dwang (4) that is provided with on second meshing gear (11), be provided with flowing back spiral leaf (6) on first dwang (4) lateral wall, flowing back spiral leaf (6) and fluid-discharge tube (2) coaxial setting, be provided with slope filter screen (12) on fluid-discharge tube (2) inside wall, slope filter screen (12) below is provided with holds slag pipe (13), it is provided with the rubber buffer to hold slag pipe (13) slag notch.

2. The device for mixing multiple solutions to realize negative ion separation according to claim 1, wherein the multiple liquid inlet pipes (3) are arranged at the bottom of the rotating chamber (1) at an angle of 120 degrees from each other.

3. The device for mixing multiple solutions to realize negative ion separation according to claim 1, wherein the first liquid inlet spiral blade (7), the second liquid inlet spiral blade (8) and the third liquid inlet spiral blade (9) have the same height and diameter and different screw pitches.

4. The multiple solution mixing device for realizing negative ion separation according to claim 1, wherein the second meshing gear (11) is in meshed transmission with a plurality of first meshing gears (10) arranged in a circle.

5. The multi-solution mixing device for realizing negative ion separation according to claim 1, wherein the drainage spiral blade (6) has the same diameter and different screw pitches compared with the first liquid inlet spiral blade (7), the second liquid inlet spiral blade (8) and the third liquid inlet spiral blade (9), and the screw pitches of the drainage spiral blade (6) are all larger than the screw pitches of the first liquid inlet spiral blade (7), the second liquid inlet spiral blade (8) and the third liquid inlet spiral blade (9).

6. The multi-solution mixing device for realizing negative ion separation according to claim 1, wherein the first rotating rod (4) is arranged on the inner side wall of the liquid discharge pipe (2) through an external load support.