CN219252247U - Halogen adding device - Google Patents

Abstract

The utility model provides a halogen mixing device. The brine mixing device comprises: the box body comprises a containing cavity surrounded by side walls and a first water drain hole formed in the side walls, and the first water drain hole is communicated with the containing cavity; one end of the liquid inlet component is communicated with the accommodating cavity, and the other end of the liquid inlet component is communicated with a raw material storage device to be mixed with halogen; the filter plates are positioned in the accommodating cavity and connected or lapped with the side walls, and a plurality of through holes which are arranged at intervals are formed in the filter plates; the blockage removing assembly comprises a blockage removing piece positioned in the accommodating cavity, and relative movement is arranged between the blockage removing piece and the filter plate so as to prevent crystals generated after halogen mixing from blocking the through holes. The technical scheme of the utility model provides the brine mixing device which can prevent crystals from blocking the filtering holes in the brine mixing process, so that the production efficiency is improved.

Description

Halogen adding device

Technical Field

The utility model relates to the technical field of potassium chloride production, in particular to a halogen adding device.

Background

In the process of potassium chloride production, the conditioned first brine (potassium chloride, sodium chloride, carnallite co-saturation) and the second brine (magnesium chloride, sodium chloride, carnallite co-saturation) are required to be mixed to obtain the required brine, and carnallite and a small amount of sodium chloride crystals are separated out together in the process.

The existing brine mixing device is used for mixing first brine and second brine, filtering is carried out by utilizing a filter plate, mixed brine is discharged through a filtering hole in the filter plate, carnallite with larger particles and a small amount of sodium chloride crystals are left on the filter plate, so that the mixed brine and the crystals are separated, after a period of time, the filtering hole can be blocked due to the fact that a large amount of crystals are left above the filter plate, the mixed brine cannot be discharged through the filtering hole, the filter plate is required to be cleaned frequently by workers, and production efficiency is reduced.

Disclosure of Invention

The utility model mainly aims to provide a brine mixing device, which solves the problems that in the prior art, crystals generated by brine mixing are easy to block drain holes, so that brine and crystals are difficult to separate, and the production efficiency is reduced.

In order to achieve the above object, the present utility model provides a halogen adding device comprising: the box body comprises a containing cavity surrounded by side walls and a first water drain hole formed in the side walls, and the first water drain hole is communicated with the containing cavity; one end of the liquid inlet component is communicated with the accommodating cavity, and the other end of the liquid inlet component is communicated with a raw material storage device to be mixed with halogen; the filter plates are positioned in the accommodating cavity and connected or lapped with the side walls, and a plurality of through holes which are arranged at intervals are formed in the filter plates; the blockage removing assembly comprises a blockage removing piece positioned in the accommodating cavity, and relative movement is arranged between the blockage removing piece and the filter plate so as to prevent crystals generated after halogen mixing from blocking the through holes.

Further, clear stifled piece includes the mounting panel and sets up a plurality of stands on the mounting panel, and the mounting panel is located the below of filter, and a plurality of stands and a plurality of through-holes one-to-one set up to filter and clear stifled subassembly can follow vertical direction relative movement, so that the stand has the first position that is located outside the through-hole and stretches into the second position of through-hole.

Further, the block-cleaning assembly further comprises a lifting piece connected with the mounting plate, and the lifting piece can drive the mounting plate to move in the vertical direction relative to the filter plate.

Further, the lifting piece is an operating rod, the filter plate is provided with an avoidance through hole for the operating rod to pass through, and the first end of the operating rod passes through the avoidance through hole and is connected with the mounting plate; or the lifting piece is a driving motor positioned outside the box body.

Further, a second end of the operating lever is provided with a grip handle.

Further, the holding handle is an arc-shaped plate, and the arc-shaped plate defines a holding space.

Further, clear stifled subassembly still includes the baffle of being connected and becoming the contained angle with the mounting panel, and the baffle extends along the circumference border of mounting panel, has still seted up the second wash port on the baffle.

Further, the feed liquor subassembly includes first conveyer pipe and second conveyer pipe, and first conveyer pipe extends along the partial circumference lateral wall of box, and first conveyer pipe is used for carrying first steamed raw materials of mixing to holding the intracavity, and the second conveyer pipe is used for carrying the second steamed raw materials of mixing to holding the intracavity, all is equipped with out the liquid hole on first conveyer pipe and the second conveyer pipe, and a plurality of liquid holes are along the length direction interval setting of first conveyer pipe and second conveyer pipe.

Further, the liquid inlet assembly further comprises a first liquid inlet pipe communicated with the first conveying pipe and a second liquid inlet pipe communicated with the second conveying pipe, and the second conveying pipe extends along part of the circumferential side wall of the box body.

Further, the brine mixing device also comprises a plurality of scrapers which are arranged in one-to-one correspondence with the plurality of through holes, and the scrapers are arranged on the lower surface of the filter plate so as to scrape crystals on the outer surface of the upright post; and/or, the brine mixing device further comprises a drain pipe communicated with the first drain hole and a control valve arranged at the drain pipe, and the control valve is used for controlling the on-off of the drain pipe.

By applying the technical scheme of the utility model, the mixed brine can be discharged into the box body through the through holes on the filter plate and then discharged through the first water discharge holes on the side wall of the box body, and crystals generated by brine mixing cannot pass through the through holes on the filter plate due to the larger outer diameter, so that the crystals can be left on the filter plate, and the effect of separating the brine from the crystals is realized; meanwhile, under the action of external force, the blocking removing piece moves relative to the filter plate, and the blocking removing piece can push crystals blocking the through holes to other positions on the filter plate, so that the problem that brine is difficult to discharge due to the fact that the through holes are blocked by the crystals can be avoided, the provided brine mixing device does not need to take out the filter plate frequently to clean the crystals, and the brine mixing device is convenient to use and improves production efficiency.

Drawings

The accompanying drawings, which are included to provide a further understanding of the utility model and are incorporated in and constitute a part of this specification, illustrate embodiments of the utility model and together with the description serve to explain the utility model. In the drawings:

FIG. 1 shows a schematic structural view of an embodiment of a brine mixing device according to the present utility model;

FIG. 2 shows a cross-sectional view of the brine mixing device of FIG. 1;

FIG. 3 shows an enlarged view of the brine mixing apparatus of FIG. 2 at A; and

fig. 4 shows an enlarged view of the brine mixing device of fig. 2 at B.

Wherein the above figures include the following reference numerals:

1. a case; 11. a first liquid inlet pipe; 111. a receiving chamber; 12. a first delivery tube; 14. a second liquid inlet pipe; 15. a second delivery tube; 16. a first drain hole; 161. a drain pipe; 17. a control valve; 19. a liquid outlet hole; 2. a support; 3. a filter plate; 31. a through hole; 4. avoiding the through hole; 5. an operation lever; 51. an arc-shaped plate; 511. a holding space; 6. a mounting plate; 61. a baffle; 7. a column; 9. a scraper.

Detailed Description

It should be noted that, in the case of no conflict, the embodiments and features in the embodiments may be combined with each other. The utility model will be described in detail below with reference to the drawings in connection with embodiments.

As shown in fig. 1 and 2, an embodiment of the present utility model provides a halogen blending apparatus. The brine mixing device comprises: the device comprises a box body 1, a liquid inlet assembly, a filter plate 3 and a blockage removal assembly, wherein the box body 1 comprises a containing cavity 111 surrounded by side walls and a first drain hole 16 formed in the side walls, and the first drain hole 16 is communicated with the containing cavity 111; one end of the liquid inlet component is communicated with the accommodating cavity 111, and the other end of the liquid inlet component is communicated with a raw material storage device to be mixed with halogen; the filter plate 3 is positioned in the accommodating cavity 111 and connected or lapped with the side wall, and a plurality of through holes 31 which are arranged at intervals are formed in the filter plate 3; the blockage removing assembly comprises a blockage removing part positioned in the accommodating cavity 111, and relative movement is arranged between the blockage removing part and the filter plate 3 so as to prevent crystals generated after halogen mixing from blocking the through holes 31.

Through the arrangement, the liquid inlet component conveys the raw materials to be mixed, namely the first brine and the second brine, into the accommodating cavity 111, the raw materials to be mixed can be mixed in the accommodating cavity 111, part of crystals, namely carnallite and a small amount of sodium chloride, can be separated out in the process, the mixed brine can be discharged into the box body 1 through the through hole 31 on the filter plate 3, and then can be discharged through the first water outlet hole 16 on the side wall of the box body, and the crystals generated by mixing the brine cannot pass through the through hole 31 on the filter plate 3 due to the fact that the outer diameter is larger, so that the crystals can be left on the filter plate 3, and the effect of separating the brine from the crystals is achieved; meanwhile, in the brine mixing process, under the action of external force, the blocking removing piece moves relative to the filter plate 3, and the blocking removing piece can push crystals blocking the through holes 31 to other positions on the filter plate 3, so that the problem that brine is difficult to discharge due to the fact that the through holes 31 are blocked by the crystals can be avoided, the brine mixing device does not need to take out the filter plate 3 frequently to clean the crystals, and the brine mixing device is convenient to use and improves production efficiency.

As shown in fig. 2, in the embodiment of the present utility model, the blocking remover includes a mounting plate 6 and a plurality of columns 7 disposed on the mounting plate 6, the mounting plate 6 is located below the filter plate 3, the plurality of columns 7 are disposed in one-to-one correspondence with the plurality of through holes 31, and the filter plate 3 and the blocking remover assembly can relatively move in a vertical direction so that the columns 7 have a first position located outside the through holes 31 and a second position extending into the through holes 31.

In the above technical scheme, clear stifled subassembly still includes the lifter of being connected with mounting panel 6, and like this, the lifter drives mounting panel 6 along vertical direction reciprocates, and mounting panel 6 can drive stand 7 and switch between first position and second position.

Through the arrangement, in the process of switching the upright post 7 from the first position to the second position, namely, in the process of upward movement of the upright post 7, one end of the upright post 7 penetrates through the through hole 31 and can push crystals blocked at the through hole 31 to other positions on the filter plate 3, so that the problem that brine cannot be smoothly discharged from the through hole 31 due to blocking of the through hole 31 by the crystals is solved.

In an alternative embodiment of the present utility model, the blocking removing member may be a sliding plate provided on the filter plate 3, the sliding plate extending in the width direction of the case 1, and manually moving the sliding plate in the length direction of the case 1, the crystal on the upper surface of the filter plate 3 can be pushed to one side of the filter plate 3, so that the blocking of the through hole 31 by the crystal can be avoided.

Of course, in one embodiment of the utility model, the lifting member may also be in driving connection with the filter plate 3 to bring the filter plate 3 in a vertical direction with respect to the mounting plate 6.

As shown in fig. 2, in the embodiment of the present utility model, the lifting member is an operation rod 5, the filter plate 3 is provided with a avoidance through hole 4 through which the operation rod 5 passes, and a first end of the operation rod 5 passes through the avoidance through hole 4 and is connected with the mounting plate 6.

In the above technical solution, the operating lever 5 is a rectangular plate, so that the mounting plate 6 and the upright post 7 can be driven to move along the vertical direction by manually lifting or moving the operating lever 5 upwards or downwards.

Alternatively, the operating lever 5 may be a circular lever.

Of course, in one embodiment of the utility model, the lifting member is a drive motor located outside the housing 1.

As shown in fig. 1 and 2, in the embodiment of the present utility model, the second end of the operation lever 5 is provided with a grip handle.

In the above technical solution, the grip handle is an arc plate 51, and the arc plate 51 defines the grip space 511. The device is convenient to hold.

Alternatively, the grip handle may be a rectangular frame or a spherical protrusion.

As shown in fig. 2, in the embodiment of the present utility model, the blocking removing assembly further includes a baffle 61 connected to the mounting plate 6 and forming an included angle, the baffle 61 extends along a circumferential edge of the mounting plate 6, and a second drain hole is further formed in the baffle 61.

In the above technical solution, the baffle 61 is vertically disposed with the mounting plate 6 to form a containing cavity with a certain space, so that the mixed brine is discharged from the through hole 31, reaches the containing cavity, is discharged into the tank 1 through the second drain hole, and is discharged through the first drain hole 16, thus avoiding the problem that the brine in the tank 1 is difficult to discharge due to the fact that the brine falls from different directions on the mounting plate 6; meanwhile, part of fine crystals can be provided in the process of flowing out of the through hole 31, and by arranging the baffle 61, after the brine flows out of the second drain hole, part of crystals can be left on the mounting plate 6, so that the effect of conveniently collecting the crystals is realized, and the problem that the crystals are difficult to collect due to the fact that the crystals flow to the bottom wall of the box body 1 along with the brine can be avoided.

It should be noted that the upper surface of the mounting plate 6 may be provided as an inclined surface to facilitate smooth flow of the brine to the position where the second drain hole is located.

As shown in fig. 2, in the embodiment of the present utility model, the brine mixing device further includes a support member 2 disposed in the receiving chamber 111 and connected to the inner wall of the case 1, and the filter plate 3 is overlapped on the support member 2.

In the above technical scheme, support piece 2 is annular backup pad, and filter 3 overlap joint is on support piece 2, like this, accomplishes to mix the back of steamed, upwards promotes action bars 5, and action bars 5 can drive mounting panel 6 and filter 3 synchronous upward movement to take out back clearance crystal with mounting panel 6 and filter 3 from holding the intracavity 111, set up like this, be convenient for operate.

Of course, in the embodiment of the utility model not shown in the drawings, the supporting members 2 may also be supporting protrusions provided at intervals along the circumferential direction of the case 1.

As shown in fig. 1, 2 and 4, in the embodiment of the present utility model, the liquid inlet assembly includes a first conveying pipe 12 and a second conveying pipe 15, the first conveying pipe 12 extends along a part of the circumferential side wall of the box 1, the first conveying pipe 12 is used for conveying the first halogen-blended raw material into the accommodating cavity 111, the second conveying pipe 15 is used for conveying the second halogen-blended raw material into the accommodating cavity 111, liquid outlet holes 19 are formed in each of the first conveying pipe 12 and the second conveying pipe 15, and a plurality of liquid outlet holes 19 are arranged at intervals along the length direction of the first conveying pipe 12 and the second conveying pipe 15.

In the above technical scheme, through the arrangement, the first halogen-blended raw material sequentially enters the accommodating cavity 111 through the first conveying pipe 12 and the liquid outlet hole 19, and the second halogen-blended raw material sequentially enters the accommodating cavity 111 through the second conveying pipe 15 and the liquid outlet hole 19, so that the first halogen-blended raw material and the second halogen-blended raw material can be fully crystallized in the first conveying pipe 12 and the second conveying pipe 15 respectively; meanwhile, the first conveying pipe 12 and the second conveying pipe 15 are both positioned at the upper part of the inner wall of the box body 1, so that the first halogen-mixed raw material and the second halogen-mixed raw material can be fully mixed and crystallized in the air after flowing out from the liquid outlet 19, and the problem of poor halogen-mixed effect caused by direct discharge of the first halogen-mixed raw material and the second halogen-mixed raw material in the form of brine due to insufficient crystallization can be avoided.

As shown in fig. 1 and 2, in the embodiment of the present utility model, the liquid inlet assembly further includes a first liquid inlet pipe 11 communicating with the first conveying pipe 12, and a second liquid inlet pipe 14 communicating with the second conveying pipe 15, the second conveying pipe 15 extending along a part of the circumferential side wall of the tank body 1.

In the above arrangement, the first liquid inlet pipe 11 is perpendicular to the first conveying pipe 12, and the second liquid inlet pipe 14 is perpendicular to the second conveying pipe 15, so that the first halogen-mixed raw material sequentially passes through the first liquid inlet pipe 11 and the first conveying pipe 12 and then is discharged to the accommodating cavity 111, and the second halogen-mixed raw material sequentially passes through the second liquid inlet pipe 14 and the second conveying pipe 15 and then is discharged to the accommodating cavity 111, and the arrangement is convenient for adding raw materials into the accommodating cavity 111.

As shown in fig. 2 and 3, in the embodiment of the present utility model, the brine mixing apparatus further includes a plurality of scrapers 9 provided in one-to-one correspondence with the plurality of through holes 31, the scrapers 9 being provided on the lower surface of the filter plate 3 to scrape crystals off the outer surface of the stand column 7.

In the above technical scheme, the scraper 9 is disposed along the circumference of the through hole 31 and extends along the central axis of the through hole 31, so that when the upright post 7 moves in the vertical direction, the scraper 9 can scrape the crystals on the outer surface of the upright post 7, thereby avoiding the problem that brine is difficult to discharge due to the adhesion of the crystals on the outer surface of the upright post 7.

As shown in fig. 2, in the embodiment of the present utility model, the brine mixing device further includes a drain pipe 161 communicating with the first drain hole 16, and a control valve 17 provided at the drain pipe 161, the control valve 17 being used to control the on-off of the drain pipe 161.

With the above arrangement, the user can open or close the control valve 17 according to the actual use requirement, thereby discharging brine or stopping discharging brine.

From the above description, it can be seen that the above embodiments of the present utility model achieve the following technical effects: the brine raw materials are fully mixed and crystallized in the air after entering the accommodating cavity through the liquid inlet component, the mixed brine can be discharged into the box body through the through holes on the filter plate and then sequentially discharged through the second water discharge holes on the baffle plate and the first water discharge holes on the side wall of the box body, and crystals generated by brine mixing cannot pass through the through holes on the filter plate due to the fact that the outer diameter is larger, so that the crystals can be left on the filter plate, and the effect of separating the brine from the crystals is achieved; meanwhile, in the brine mixing process, the operating rod is lifted upwards, the operating rod drives the mounting plate and the stand column to move relative to the filter plate, the stand column can push crystals blocking the through holes to other positions on the filter plate, so that the problem that brine is difficult to discharge due to the fact that the through holes are blocked by the crystals can be avoided, and the brine mixing device does not need to take out the filter plate frequently to clean the crystals, so that the brine mixing device is convenient to use.

The above is only a preferred embodiment of the present utility model, and is not intended to limit the present utility model, but various modifications and variations can be made to the present utility model by those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present utility model should be included in the protection scope of the present utility model.

Claims (10)

1. A brine mixing device, comprising:

the box body (1) comprises a containing cavity (111) surrounded by side walls and a first water discharge hole (16) formed in the side walls, wherein the first water discharge hole (16) is communicated with the containing cavity (111);

one end of the liquid inlet component is communicated with the accommodating cavity (111), and the other end of the liquid inlet component is communicated with a raw material storage device to be mixed with halogen;

the filter plate (3) is positioned in the accommodating cavity (111) and connected with or overlapped with the side wall, and a plurality of through holes (31) which are arranged at intervals are formed in the filter plate (3);

the blockage removing assembly comprises a blockage removing piece positioned in the accommodating cavity (111), and relative movement is arranged between the blockage removing piece and the filter plate (3) so as to prevent crystals generated after halogen mixing from blocking the through hole (31).

2. The brine mixing device according to claim 1, wherein the blocking removing member comprises a mounting plate (6) and a plurality of stand columns (7) arranged on the mounting plate (6), the mounting plate (6) is positioned below the filter plate (3), the stand columns (7) are arranged in one-to-one correspondence with the through holes (31), and the filter plate (3) and the blocking removing assembly can move relatively in the vertical direction, so that the stand columns (7) are provided with a first position positioned outside the through holes (31) and a second position extending into the through holes (31).

3. The brine mixing device according to claim 2, wherein the block-cleaning assembly further comprises a lifting member connected with the mounting plate (6), and the lifting member can drive the mounting plate (6) to move in a vertical direction relative to the filter plate (3).

4. A brine mixing device according to claim 3, wherein the lifting member is an operating rod (5), the filter plate (3) is provided with an avoidance through hole (4) for the operating rod (5) to pass through, and a first end of the operating rod (5) passes through the avoidance through hole (4) and is connected with the mounting plate (6); or the lifting piece is a driving motor positioned outside the box body (1).

5. The brine mixing device according to claim 4, wherein the second end of the operating lever (5) is provided with a gripping handle.

6. The brine mixing device according to claim 5, wherein the grip handle is an arcuate plate (51), the arcuate plate (51) defining a grip space (511).

7. The brine mixing device according to any one of claims 2 to 6, wherein the block-removal assembly further comprises a baffle (61) connected with the mounting plate (6) and forming an included angle, the baffle (61) extends along the circumferential edge of the mounting plate (6), and a second drain hole is further formed in the baffle (61).

8. The brine mixing device according to any one of claims 1 to 6, wherein the liquid inlet assembly comprises a first conveying pipe (12) and a second conveying pipe (15), the first conveying pipe (12) extends along part of the circumferential side wall of the box body (1), the first conveying pipe (12) is used for conveying first brine mixing raw materials into the containing cavity (111), the second conveying pipe (15) is used for conveying second brine mixing raw materials into the containing cavity (111), liquid outlet holes (19) are formed in the first conveying pipe (12) and the second conveying pipe (15), and a plurality of liquid outlet holes (19) are formed in the first conveying pipe (12) and the second conveying pipe (15) at intervals in the length direction.

9. The brine mixing device according to claim 8, wherein the liquid inlet assembly further comprises a first liquid inlet pipe (11) in communication with the first conveying pipe (12), and a second liquid inlet pipe (14) in communication with the second conveying pipe (15), the second conveying pipe (15) extending along a part of the circumferential side wall of the tank (1).

10. The brine mixing device according to any one of claims 2 to 6, further comprising a plurality of scrapers (9) provided in one-to-one correspondence with the plurality of through holes (31), the scrapers (9) being provided on the lower surface of the filter plate (3) to scrape crystals on the outer surface of the column (7); and/or the number of the groups of groups,

the brine mixing device further comprises a drain pipe (161) communicated with the first drain hole (16) and a control valve (17) arranged at the drain pipe (161), and the control valve (17) is used for controlling the on-off of the drain pipe (161).

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