CN113713743B - Salt mud processing apparatus of chlor-alkali industry - Google Patents

Abstract

The invention relates to the technical field of chemical treatment equipment, in particular to a salt mud treatment device for chlor-alkali industry. The invention aims to provide a salt mud treatment device for the chlor-alkali industry, which avoids resource waste caused by in-situ burying of salt mud and prevents environmental pollution caused by in-situ burying of salt mud. The technical scheme is as follows: a salt mud treatment device in the chlor-alkali industry comprises a bottom plate, a first supporting leg, a reaction shell and the like; four first supporting legs are installed at the left part of the upper surface of the bottom plate, and a reaction shell is arranged between the upper parts of the four first supporting legs. According to the invention, the salt mud is subjected to multiple reactions through the operation of the reaction mechanism to form magnesium hydroxide particles, the magnesium hydroxide particles are sent into the collection mechanism to be atomized, so that the magnesium hydroxide particles form magnesium hydroxide powder, meanwhile, the collection mechanism is used for carrying out adsorption collection on the magnesium hydroxide powder, and air is discharged to finish the collection of the magnesium hydroxide powder, so that the resource waste caused by the on-site burying of the salt mud is avoided, and the environmental pollution caused by the on-site burying of the salt mud is also prevented.

Description

Salt mud processing apparatus of chlor-alkali industry

Technical Field

The invention relates to the technical field of chemical treatment equipment, in particular to a salt mud treatment device for chlor-alkali industry.

Background

The magnesium hydroxide is an inorganic white amorphous powder or a colorless hexagonal column crystal, is dissolved in dilute acid and ammonium salt solution, is almost insoluble in water, and the part dissolved in water is completely ionized, and the aqueous solution is alkalescent. Heating to 350 deg.C to lose water to produce magnesium oxide and magnesium hydroxide, and can be used for preparing sugar and magnesium oxide.

The existing salt mud is usually buried on site, but the buried salt mud easily causes hardening and alkalization of land, is not beneficial to the growth of crops in the land and can cause environmental pollution, and because a large amount of magnesium hydroxide exists in the salt mud and gradually replaces aluminum chloride to be used as an analytical reagent and in the pharmaceutical industry, huge resource waste can be caused by the fact that the salt mud is buried on site.

Aiming at the defects of the prior art, a salt mud treatment device for the chlor-alkali industry is developed, which can avoid resource waste caused by on-site burying of salt mud and prevent environmental pollution caused by on-site burying of salt mud.

Disclosure of Invention

The invention aims to overcome the defects that the land hardening and alkalization are caused by the in-situ burying of the salt mud, the environment pollution is caused, and the huge resource waste is caused by the in-situ burying of the salt mud due to the existence of a large amount of magnesium hydroxide in the salt mud.

The technical scheme is as follows: the utility model provides a chlor-alkali industry salt mud processing apparatus, is including bottom plate, first landing leg, reaction shell, outlet duct, reaction mechanism and collection mechanism, and four first landing legs are installed to the left part of bottom plate upper surface, are provided with the reaction shell between the upper portion of four first landing legs, and the outlet duct has been inlayed at the top of reaction shell, is provided with reaction mechanism between the upper surface of reaction shell and bottom plate, and the upper surface of bottom plate is provided with collects the mechanism, collects mechanism and reaction mechanism intercommunication.

As an improvement of the scheme, the reaction mechanism comprises a mounting plate, a first servo motor, a gearbox, a first rotating shaft, a collecting hopper, a first support plate, a mounting disc, a second rotating shaft, a spline shaft, a fixed disc, a sliding rod, a spline housing, a reset spring, a first swinging plate, a hinging block, a balancing weight, a second swinging plate, a pin rod, a connecting disc, a third rotating shaft, an impeller, a sliding frame, a gear ring, a pinion, a separating part, a feeding part and a mixing part, wherein the mounting plate is fixedly connected to the top of the reaction shell, the mounting plate is positioned on one side of the air outlet pipe, the side wall of the mounting plate is provided with the first servo motor, the side wall of the mounting plate is provided with the gearbox, the gearbox is positioned on the lower side of the first servo motor, the output end of the first servo motor is connected with the input end of the gearbox, the output end of the gearbox is provided with the first rotating shaft, the collecting hopper is arranged on the upper part of the inner wall of the reaction shell, the bottom in the collecting hopper is uniformly and fixedly connected with a plurality of first support plates along the circumferential direction, a mounting disc is arranged between the upper parts of the plurality of first support plates, the upper surface of the mounting disc is rotatably provided with a second rotating shaft, a spline shaft is fixedly connected between the second rotating shaft and the first rotating shaft, the middle part of the spline shaft is connected with a fixed disc, the fixed disc is uniformly and fixedly connected with a plurality of sliding rods along the circumferential direction, the upper part and the lower part between the plurality of sliding rods are both provided with a spline housing in a sliding manner, a plurality of reset springs are respectively and fixedly connected between the spline housings on the upper side and the lower side and the fixed disc, the plurality of reset springs are respectively wound on the outer sides of the plurality of sliding rods, the outer wall of the spline housing on the lower side is uniformly hinged with a plurality of first swinging plates along the circumferential direction, the upper parts of the first swinging plates are provided with chutes, the upper parts of the two walls of the first swinging plates are both rotatably provided with hinged blocks, and balancing weights are rotatably arranged between the lower parts of the two adjacent hinged blocks, the outer wall of the spline housing at the upper side is evenly hinged with a plurality of second swinging plates along the circumferential direction, the plurality of second swinging plates are respectively arranged with a plurality of first swinging plates in a sliding way, pin rods are embedded at the lower parts of the second swinging plates and are respectively connected with a plurality of sliding grooves in a sliding way, the lower part of the spline shaft is provided with a connecting disc, the connecting disc is positioned at the lower side of the spline housing at the lower side, the outer side wall of the connecting disc is provided with a plurality of third rotating shafts along the circumferential direction in an even and rotating way, a plurality of impellers are fixedly connected onto the third rotating shafts, the upper part of the inner wall of the reaction shell is provided with a sliding frame in a sliding way, the sliding frame is positioned at the upper side of the collecting hopper, the outer ends of the plurality of third rotating shafts penetrate through the sliding frame and are connected with the sliding frame in a rotating way, the outer ends of the plurality of third rotating shafts are provided with pinions, the outer side wall of the sliding frame is provided with gear rings, the gear rings are respectively meshed with a plurality of small gears, and the lower part is arranged at the lower part of the inner wall of the reaction shell, the separating component is fixedly connected with the collecting hopper, the feeding component is arranged on the upper surface of the bottom plate and is positioned on one side of the reaction shell, the feeding component is communicated with the reaction shell, the mixing component is arranged on the upper surface of the bottom plate and is positioned on one side of the reaction shell, and the mixing component is communicated with the separating component.

As the improvement of the scheme, the outer surface of the balancing weight is made of rubber, and a spherical iron block is embedded in the middle of the balancing weight.

As an improvement of the proposal, the separation part comprises a disc, a blanking hollow frame, a collecting box, a containing box, a mounting block, a hydraulic cylinder, a baffle plate, a containing hopper, a ring-shaped screen plate, a cross, a first straight gear, a ball valve, a stepping motor, a valve body, a mounting seat, a second servo motor, a second straight gear, a material conveying pipe, a first discharging pipe, a guide plate, a blanking pipe, a waste pipe, a first electromagnetic valve, a return pipe, a second electromagnetic valve, a first liquid pump, a first feeding pipe and a first water inlet pipe, the disc is arranged at the lower part of the inner wall of the reaction shell, the blanking hollow frame is embedded at the lower part of the reaction shell, the collecting box is arranged on the upper surface of a bottom plate and is positioned at one side of a first supporting leg, the collecting box is communicated with the blanking hollow frame, the containing box is arranged on the upper surface of the bottom plate and is positioned at one side of the collecting box, the mounting block is fixedly connected with the mounting block, the hydraulic cylinder is embedded on the mounting block, a baffle plate is rotatably arranged at the lower part of the blanking hollow frame, the side wall of the baffle plate is rotatably connected with the telescopic end of a hydraulic cylinder, a material containing hopper is arranged at the upper part of the blanking hollow frame, an annular mesh plate is rotatably arranged between the material containing hopper and the disc, a cross is rotatably arranged at the central position of the disc and fixedly connected with the annular mesh plate, a first straight gear is arranged at the upper part of the cross, a ball valve is arranged at the lower part of the collecting hopper, a stepping motor is arranged at the side wall of the ball valve, a valve body is arranged in a sliding manner, the output end of the stepping motor penetrates through the ball valve to be rotatably connected with the ball valve, the output end of the stepping motor is fixedly connected with the valve body, a mounting seat is arranged at the lower surface of the collecting hopper, a second servo motor is arranged in the mounting seat, a second straight gear is arranged at the output end of the second servo motor, the second straight gear is meshed with the first straight gear, and a material conveying pipe is arranged at the lower surface of the ball valve, the conveying pipeline passes disc and cross rather than sliding connection, the lateral wall of conveying pipeline has evenly inlayed the first discharging pipe of a plurality of along its circumference, hold and fight internal surface mounting and have two guide plates, reaction shell bottom central point puts and has inlayed the unloading pipe, waste pipe and back flow have been inlayed respectively to the two wall lower parts of unloading pipe, install first solenoid valve on the waste pipe, the upper portion and the reaction shell top intercommunication of back flow, the back flow lower part is provided with the second solenoid valve, the upper portion of back flow is provided with first drawing liquid pump, first drawing liquid pump and the upper portion rigid coupling of reaction shell, first inlet pipe is installed at the top of reaction shell, first inlet pipe is located one side of back flow, first inlet pipe has been inlayed on the upper portion of first inlet pipe.

As the improvement of above-mentioned scheme, the material loading part is including the second landing leg, hold the shell, conveyer pipe and second drawing liquid pump, the upper surface of bottom plate is provided with eight second landing legs, the second landing leg is located one side of first landing leg, the rigid coupling has between the upper portion of four adjacent second landing legs and holds the shell, the conveyer pipe has been inlayed at the top of holding the shell, the conveyer pipe communicates with the top of reaction shell, the second drawing liquid pump is installed on the upper portion of conveyer pipe, second drawing liquid pump and reaction shell rigid coupling.

As an improvement of the scheme, the mixing component comprises a third supporting leg, a stirring shell, a reciprocating cylinder, a second supporting plate, a containing hopper, a spiral plate, a second discharging pipe, a third liquid pump, a second water inlet pipe, a water pump, a second feed pipe and a fourth liquid pump, four third supporting legs are arranged on the upper surface of the bottom plate, the stirring shell is arranged between the upper parts of the four third supporting legs, the reciprocating cylinder is arranged at the center position of the top of the stirring shell, the telescopic end of the reciprocating cylinder penetrates through the top of the stirring shell to be in sliding connection with the top of the stirring shell, a plurality of second supporting plates are uniformly and fixedly connected with the outer side wall of the telescopic rod of the reciprocating cylinder along the circumferential direction of the outer side wall, the containing hopper is fixedly connected between the lower parts of the plurality of second supporting plates, the spiral plate is arranged on the inner wall of the stirring shell, the spiral plate is wound on the outer side of the containing hopper, the second discharging pipe is embedded at the center position of the bottom of the stirring shell, the third discharging pipe is communicated with the collecting mechanism, the third liquid pump is arranged at the lower part of the second discharging pipe, third drawing liquid pump and stirring shell rigid coupling, the second inlet tube is installed at the top of stirring shell, and the second inlet tube is located reciprocating cylinder's one side, and the upper portion of second inlet tube is provided with the suction pump, and suction pump and stirring shell rigid coupling have inlayed the second inlet pipe between stirring shell and the collecting box, and the second inlet pipe is located reciprocating cylinder's front side, and the upper portion of second inlet pipe is provided with the fourth drawing liquid pump, the upper portion rigid coupling of fourth drawing liquid pump and stirring shell.

As an improvement of the scheme, the collecting mechanism comprises a fourth supporting leg, a supporting shell, a containing bin, a sealing shell, an atomizer, an exhaust fan, a gas pipe, a heating frame, a third discharging pipe, a self-priming pump, a settling tank, a tank cover, a material conveying shell, an installation shell, a bent plate, a first air outlet pipe, a second air outlet pipe, a hollow shell and an electrostatic plate, wherein four fourth supporting legs are installed on the upper surface of a bottom plate and are positioned on one side of the third supporting leg, the supporting shell is installed between the upper parts of the four fourth supporting legs, the containing bin is embedded on the upper part of the supporting shell, the sealing shell is arranged on the top of the containing bin, the atomizer is embedded in the central position of the sealing shell, the atomizer is communicated with the second discharging pipe, the exhaust fan is installed on the top of the sealing shell, the exhaust fan is positioned on the rear side of the atomizer, the gas pipe is communicated with the atomizer, the heating frame is installed on the lower part of the inner wall of the sealing shell, the third discharging pipe is embedded in the lower part of the containing bin, be provided with the self priming pump on the third discharging pipe, the self priming pump is located the support shell lower part, the upper surface of bottom plate is provided with the setting tank, the setting tank is located one side of fourth landing leg, the lateral wall lower part rotary type of setting tank is provided with the case lid, the case lid passes through buckle mode and setting tank joint, two conveying shells have been inlayed at the top of setting tank, the conveying shell and the third discharging pipe intercommunication of one side, the lower part of conveying shell is provided with the installation shell, the installation shell inner wall is provided with a plurality of bent board, the intercommunication has first tuber pipe between two conveying shells, the second goes out the tuber pipe at the conveying shell top of opposite side installation, the second goes out the upside that the tuber pipe is located first tuber pipe, the upper portion that the second goes out the tuber pipe is provided with hollow shell, open hollow shell lateral wall lower part has a plurality of venthole, the electrostatic plate is installed to the lower part in the setting tank.

As a modification of the above, the shape of the curved plate is S-shaped.

As the improvement of the scheme, the device also comprises a groove plate, an electric push rod, a sliding block, an installation rod and a scraper, wherein the groove plate is installed on the upper part of the conveying pipeline, the electric push rod is embedded in the groove plate, a sliding groove is formed in the outer part of the groove plate, the sliding block is arranged in the sliding groove in a sliding mode, the sliding block is fixedly connected with the telescopic end of the electric push rod, the installation rod is installed on the lower surface of the sliding block, the scraper is arranged on the installation rod, and the scraper is in contact with the inner wall of the reaction shell.

The invention has the following advantages: the salt mud is subjected to multiple reactions through the operation of the reaction mechanism to form magnesium hydroxide particles, the magnesium hydroxide particles are sent into the collection mechanism to be atomized, the magnesium hydroxide particles are made to form magnesium hydroxide powder, the collection mechanism is used for carrying out adsorption collection on the magnesium hydroxide powder, air is discharged, and the collection of the magnesium hydroxide powder is completed, so that the resource waste caused by the on-site burying of the salt mud is avoided, and the environmental pollution caused by the on-site burying of the salt mud is also prevented; utilize the scraper blade to scrape the material of the adhesion on the annular otter board inner wall and get, so avoid being stained with the material on the inner wall of annular otter board, handle for salt mud next time and cause inconvenience.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

FIG. 2 is a schematic view of a first partially cut-away perspective structure of the reaction mechanism of the present invention.

FIG. 3 is a schematic partial perspective view of a first reaction mechanism of the present invention.

FIG. 4 is a schematic partial perspective view of a second reaction mechanism of the present invention.

FIG. 5 is a partially enlarged schematic perspective view of a reaction mechanism of the present invention.

Fig. 6 is an enlarged perspective view of the present invention a.

FIG. 7 is a schematic diagram of a second partially cut-away perspective structure of the reaction mechanism of the present invention.

FIG. 8 is a schematic view of a third partial perspective structure of the reaction mechanism of the present invention.

FIG. 9 is a schematic view of a fourth partial perspective structure of the reaction mechanism of the present invention.

FIG. 10 is a schematic view of a first partially split body structure of a reaction mechanism of the present invention.

FIG. 11 is a schematic view of a second partial bulk structure of a reaction mechanism of the present invention.

FIG. 12 is a perspective view of a third part of a reaction mechanism according to the present invention.

FIG. 13 is a schematic perspective view of a third partial sectional view of a reaction mechanism according to the present invention.

Fig. 14 is a perspective view of the collecting mechanism of the present invention.

Fig. 15 is a schematic view of a first partially cut-away perspective structure of the collection mechanism of the present invention.

Fig. 16 is a schematic view of a first partial body configuration of a collection mechanism of the present invention.

Fig. 17 is a second partially cut-away perspective view of the collection mechanism of the present invention.

Fig. 18 is a partially enlarged perspective view of the present invention.

Number designation in the figures: 1. a bottom plate, 2, a first supporting leg, 3, a reaction shell, 4, an air outlet pipe, 6, a reaction mechanism, 601, a mounting plate, 602, a first servo motor, 603, a gearbox, 604, a first rotating shaft, 605, a collecting hopper, 606, a first support plate, 607, a mounting plate, 608, a second rotating shaft, 609, a spline shaft, 610, a fixed plate, 611, a sliding rod, 612, a spline sleeve, 613, a return spring, 614, a first swinging plate, 615, a sliding chute, 616, a hinge block, 617, a balancing weight, 618, a second swinging plate, 619, a pin rod, 620, a connecting plate, 621, a third rotating shaft, 622, an impeller, 623, a sliding frame, 624, a gear ring, 625, a pinion, 626, a disc, 627, a blanking hollow frame, 628, a collecting box, 629, a containing box, 630, a mounting block, 631, a hydraulic cylinder, 632, a material baffle, 6321, a containing hopper, 633, a ring-shaped mesh plate, 634, a cross frame, 635 and a first straight gear, 636. ball valve, 637, stepper motor, 638, valve body, 639, mounting seat, 640, second servo motor, 641, second spur gear, 642, feed pipe, 643, first discharge pipe, 644, guide plate, 645, discharge pipe, 646, waste pipe, 647, first solenoid valve, 648, return pipe, 649, second solenoid valve, 650, first drawing pump, 651, first feed pipe, 652, first inlet pipe, 653, second leg, 654, containing shell, 655, delivery pipe, 656, second drawing pump, 657, third leg, 658, stirring shell, 659, reciprocating cylinder, 660, second support plate, 661, containing bucket, 662, spiral plate, 663, second discharge pipe, 664, third drawing pump, 665, second inlet pipe, 666, suction pump, 667, second feed pipe, 668, fourth drawing pump, 7, collection mechanism, 701, fourth, 702, support shell, leg, 703, containing bin, 704, 701, fourth leg, 703, water suction pump, suction, Sealing shell, 705, atomizer, 706, air exhauster, 707, gas-supply pipe, 708, heating frame, 709, third discharging pipe, 7091, self priming pump, 710, setting tank, 711, case lid, 712, defeated material shell, 713, installation shell, 714, bent board, 715, first play tuber pipe, 716, second play tuber pipe, 717, hollow shell, 718, electrostatic plate, 8, frid, 9, electric putter, 10, sliding tray, 11, slider, 12, installation pole, 13, scraper blade.

Detailed Description

The above-described scheme is further illustrated below with reference to specific examples. It should be understood that these examples are for illustrative purposes and are not intended to limit the scope of the present application. The conditions used in the examples may be further adjusted according to the conditions of the particular manufacturer, and the conditions not specified are generally the conditions in routine experiments.

Example 1

The utility model provides a chlor-alkali industry salt mud processing apparatus, as shown in figure 1 and figure 2, including bottom plate 1, first landing leg 2, reaction shell 3, outlet duct 4, reaction mechanism 6 and collection mechanism 7, four first landing legs 2 are installed to the left part of bottom plate 1 upper surface, be provided with reaction shell 3 between the upper portion of four first landing legs 2, outlet duct 4 has been inlayed at 3 tops of reaction shell, be provided with reaction mechanism 6 in the reaction shell 3 and between the upper surface of bottom plate 1, the upper surface of bottom plate 1 is provided with collects mechanism 7, collect mechanism 7 and reaction mechanism 6 intercommunication.

When magnesium hydroxide in the salt mud needs to be extracted, firstly, a user adds a proper amount of hydrochloric acid and sodium hydroxide into a reaction device, then, the user respectively communicates an external feeding device and an external water feeding device with the reaction mechanism 6, then, the user feeds a proper amount of salt mud into the reaction mechanism 6 through the external feeding device, simultaneously, the user feeds a proper amount of water into the reaction mechanism 6 through the external water feeding device, the weight ratio of the salt mud to the water is 1:10, the water and the salt mud are matched to form a mixture, after the reaction mechanism 6 adds a proper amount of salt mud and water, the user closes the external feeding device and the external water feeding device, then, the user adds a proper amount of hydrochloric acid into the mixture in the reaction mechanism 6, at the moment, the user starts the reaction mechanism 6 to work, the reaction mechanism 6 works to stir the mixture and the hydrochloric acid, so that the pH =2 of the mixture, and the sediment in the mixture is filtered and matched through the reaction mechanism 6, carbon dioxide generated in the mixture is discharged through an air outlet pipe 4, then a user enables a reaction mechanism 6 to pump the mixture at the lower part into the upper part, a proper amount of sodium hydroxide in the reaction mechanism 6 is added into the mixture, then the user enables the reaction mechanism 6 to stir the mixture again to enable the pH =4 of the mixture, iron hydroxide suspended matters are generated when the mixture is stirred again, the reaction mechanism 6 works to discharge the generated iron hydroxide suspended matters, then the user enables the mixture at the lower part in the reaction mechanism 6 to pump the mixture into the upper part again to add a proper amount of sodium hydroxide in the reaction mechanism 6 into the mixture, then the user enables the reaction mechanism 6 to stir the mixture again to enable the pH =12 of the mixture, a large amount of magnesium hydroxide suspended particles are generated when the mixture is stirred, the user operates the reaction mechanism 6 to collect the magnesium hydroxide suspended particles, and after the collection of the magnesium hydroxide suspended particles is completed, the user closes reaction mechanism 6 to start collection mechanism 7 to work, and collection mechanism 7 works and atomizes the magnesium hydrate suspended particles collected, so that collection mechanism 7 adsorbs the magnesium hydrate particles, and discharges gas, and after the magnesium hydrate is completely processed, the user closes collection mechanism 7, and then the user takes out the magnesium hydrate in collection mechanism 7.

Example 2

On the basis of embodiment 1, as shown in fig. 2 to 17, the reaction mechanism 6 includes a mounting plate 601, a first servo motor 602, a transmission case 603, a first rotating shaft 604, a collecting hopper 605, a first supporting plate 606, a mounting plate 607, a second rotating shaft 608, a spline shaft 609, a fixed plate 610, a sliding rod 611, a spline housing 612, a return spring 613, a first swinging plate 614, a hinge block 616, a counterweight 617, a second swinging plate 618, a pin 619, a connecting plate 620, a third rotating shaft 621, an impeller 622, a sliding frame 623, a gear ring 624, a pinion 625, a separating part, a feeding part and a mixing part, the mounting plate 601 is fixedly connected to the center position of the top of the reaction housing 3, the first servo motor 602 and the transmission case 603 are respectively arranged on the upper and lower portions of the right wall of the mounting plate 601, the lower end of the output shaft of the first servo motor 602 is connected to the upper end of the input shaft of the transmission case 603, the lower end of the output shaft 603 of the transmission case is provided with the first rotating shaft 604, the lower end of the first rotating shaft 604 penetrates through the top of the reaction shell 3 to be rotatably connected with the reaction shell, the upper part of the inner wall of the reaction shell 3 is provided with a collecting hopper 605, the bottom inside the collecting hopper 605 is uniformly and fixedly connected with three first supporting plates 606 along the circumferential direction, a mounting disc 607 is arranged between the upper parts of the three first supporting plates 606, the upper surface of the mounting disc 607 is rotatably provided with a second rotating shaft 608, a spline shaft 609 is fixedly connected between the upper end of the second rotating shaft 608 and the lower end of the first rotating shaft 604, the middle part of the spline shaft 609 is connected with a fixed disc 610, four sliding rods 611 are uniformly and fixedly connected with the fixed disc 610 along the circumferential direction, the upper part and the lower part between the four sliding rods 611 are respectively provided with a spline sleeve 612 in a sliding manner, four return springs 613 are respectively fixedly connected between the spline sleeves 612 on the upper side and the fixed disc 610, eight return springs 613 are respectively wound on the outer sides of the upper part and the lower part of the four sliding rods 611, the outer wall of the spline sleeve 612 on the lower side is uniformly hinged with four first swinging plates 614 along the circumferential direction, the upper part of the first swinging plate 614 is provided with a sliding groove 615, the upper parts of two walls of the first swinging plate 614 are respectively provided with a hinged block 616 in a rotating way, a balancing weight 617 is rotatably arranged between the lower parts of two adjacent hinged blocks 616, the outer surface of the balancing weight 617 is made of rubber, the middle part of the balancing weight 617 is embedded with a spherical iron block, the outer wall of the spline sleeve 612 at the upper side is uniformly hinged with four second swinging plates 618 along the circumferential direction thereof, the four second swinging plates 618 are respectively arranged with the four first swinging plates 614 in a sliding way, the lower parts of the second swinging plates 618 are embedded with pin rods 619, the four pin rods 619 are respectively connected with the four sliding grooves 615 in a sliding way, the lower part of the spline shaft 609 is provided with a connecting disc 620 which is positioned at the lower side of the spline sleeve 612, the outer side wall of the connecting disc 620 is provided with three third rotating shafts 621 along the circumferential direction uniformly in a rotating way, four impellers 622 are fixedly connected on the third rotating shafts 621, the upper part of the inner wall of the reaction shell 3 is provided with a sliding frame 623, the carriage 623 is located the upside of collecting the fill 605, the lower part that the carriage 623 was all passed to the outer end of three third pivot 621 is rather than rotating and being connected, pinion 625 is all installed to the outer end of three third pivot 621, ring gear 624 is installed on the lateral wall upper portion of carriage 623, ring gear 624 meshes with three pinion 625 respectively mutually, the inner wall lower part of reaction shell 3 is provided with the separation part, separation part and collection fill 605 rigid coupling, the last surface mounting of bottom plate 1 has the material loading part, the material loading part is located one side of reaction shell 3, the material loading part communicates with reaction shell 3, the upper surface of bottom plate 1 is provided with the hybrid component, the hybrid component is located one side of reaction shell 3, hybrid component and separation component intercommunication.

The separating component comprises a disc 626, a blanking hollow rack 627, a collecting box 628, a containing box 629, a mounting block 630, a hydraulic cylinder 631, a material baffle 632, a material containing hopper 6321, a ring-shaped screen plate 633, a cross 634, a first straight gear 635, a ball valve 636, a stepping motor 637, a valve body 638, a mounting seat 639, a second servo motor 640, a second straight gear 641, a material conveying pipe 642, a first material discharging pipe 643, a guide plate 644, a blanking pipe 645, a waste pipe 646, a first electromagnetic valve 647, a return pipe 648, a second electromagnetic valve 649, a first liquid pump 650, a first material feeding pipe 651 and a first water inlet pipe 652, the disc 626 is mounted at the lower part of the inner wall of the reaction shell 3, the blanking hollow rack 627 is embedded at the lower part of the reaction shell 3, the collecting box 628 is mounted on the upper surface of the bottom plate 1, the collecting box 628 is located at one side of the first supporting leg 2, the collecting box 628 is communicated with the blanking hollow rack 627, the containing box 629 is mounted on the upper surface of the bottom plate 1, the containing box 629 is positioned at one side of the collecting box 628, the bottom of the reaction shell 3 is fixedly connected with a mounting block 630, a hydraulic cylinder 631 is embedded on the mounting block 630, a baffle plate 632 is rotatably installed at the lower part of a blanking hollow frame 627, the left wall of the baffle plate 632 is rotatably connected with the right end of a telescopic rod of the hydraulic cylinder 631, a containing hopper 6321 is installed at the upper part of the blanking hollow frame 627, an annular mesh plate 633 is rotatably installed between the upper surface of the containing hopper 6321 and the lower surface of a disc 626, a cross 634 is rotatably installed at the central position of the disc 626, the cross 634 is fixedly connected with the annular mesh plate 633, a first straight gear 635 is installed at the upper part of the cross 634, a ball valve 636 is installed at the lower part of the collecting hopper 605, a stepping motor 636 is arranged at the left wall of the ball 637, a valve body 638 is slidably arranged in the ball 637, the right end of an output shaft of the stepping motor 637 penetrates through 636 to be rotatably connected with the ball 637, and the right end of the output shaft of the stepping motor 637 is fixedly connected with the valve body 638, a mounting seat 639 is mounted on the lower surface of the collecting hopper 605, the mounting seat 639 is located on one side of a ball valve 636, a second servo motor 640 is disposed in the mounting seat 639, a second spur gear 641 is mounted at the lower end of an output shaft of the second servo motor 640, the second spur gear 641 is engaged with a first spur gear 635, a material delivery pipe 642 is mounted on the lower surface of the ball valve 636, the material delivery pipe 642 penetrates through a disc 626 and a cross 634 to be slidably connected therewith, a plurality of first material discharge pipes 643 are uniformly embedded on the outer side wall of the material delivery pipe 642 along the circumferential direction, two guide plates 644 are mounted on the inner surface of the material containing hopper 6321, a material discharge pipe 645 is embedded in the center of the bottom of the reaction housing 3, the material discharge pipe 645 is located on one side of the mounting block 630, a return pipe 648 and a waste pipe 646 are respectively embedded in the lower portions of the left and right walls of the material discharge pipe 645, a first solenoid valve 647 is mounted on the waste pipe 646, the upper portion of the return pipe 648 is communicated with the top of the reaction housing 3, a second solenoid valve 649 is disposed on the lower portion of the return pipe 648, the upper portion of back flow pipe 648 is provided with first drawing liquid pump 650, and first drawing liquid pump 650 and the upper portion rigid coupling of reaction shell 3, first inlet pipe 651 is installed at the top of reaction shell 3, and first inlet pipe 651 is located one side of back flow pipe 648, and first inlet tube 652 has been inlayed on the upper portion of first inlet pipe 651.

The feeding part comprises a second supporting leg 653, a containing shell 654, a delivery pipe 655 and a second liquid pump 656, eight second supporting legs 653 are arranged on the upper surface of the bottom plate 1, the second supporting legs 653 are positioned on one side of the first supporting leg 2, the containing shells 654 are fixedly connected between the upper parts of four adjacent second supporting legs 653, the delivery pipe 655 is embedded at the top of the containing shells 654, the upper part of the delivery pipe 655 is communicated with the top of the reaction shell 3, the second liquid pump 656 is installed at the upper part of the delivery pipe 655, and the second liquid pump 656 is fixedly connected with the reaction shell 3.

The mixing component comprises a third supporting leg 657, a stirring shell 658, a reciprocating cylinder 659, a second supporting plate 660, a containing bucket 661, a spiral plate 662, a second discharging pipe 663, a third liquid pumping pump 664, a second water inlet pipe 665, a water pumping pump 666, a second feeding pipe 667 and a fourth liquid pumping pump 668, wherein four third supporting legs 657 are installed on the upper surface of the base plate 1, the stirring shell 658 is arranged between the upper parts of the four third supporting legs 657, the reciprocating cylinder 659 is installed at the center position of the top part of the stirring shell 658, the lower end of the telescopic rod of the reciprocating cylinder 659 penetrates through the top part of the stirring shell 658 and is in sliding connection with the same, three second supporting plates 660 are evenly and fixedly connected with the lower part of the telescopic rod of the reciprocating cylinder 659 along the circumferential direction of the reciprocating cylinder 659, the containing bucket 661 is fixedly connected between the lower parts of the three second supporting plates 660, the spiral plate 661 is installed on the inner wall of the stirring shell 658, the spiral plate is wound around the outer side of the containing bucket 662, the second discharging pipe 663 is embedded at the center position of the bottom part of the stirring shell 658, the lower part of second discharging pipe 663 is provided with third drawing liquid pump 664, third drawing liquid pump 664 and agitator shell 658 rigid coupling, second inlet tube 665 is installed at the top of agitator shell 658, second inlet tube 665 is located one side of reciprocating cylinder 659, the upper portion of second inlet tube 665 is provided with suction pump 666, suction pump 666 and agitator shell 658 rigid coupling, second inlet tube 667 has been inlayed between agitator shell 658 and the collecting box 628, second inlet tube 667 is located the front side of reciprocating cylinder 659, the upper portion of second inlet tube 667 is provided with fourth drawing liquid pump 668, fourth drawing liquid pump 668 and the upper portion rigid coupling of agitator shell 658.

The collecting mechanism 7 comprises a fourth supporting leg 701, a supporting shell 702, a containing bin 703, a sealing shell 704, an atomizer 705, an exhaust fan 706, an air pipe 707, a heating frame 708, a third discharging pipe 709, a self-sucking pump 7091, a settling tank 710, a tank cover 711, a material conveying shell 712, a mounting shell 713, a curved plate 714, a first air outlet pipe 715, a second air outlet pipe 716, a hollow shell 717 and an electrostatic plate 718, four fourth supporting legs 701 are mounted on the upper surface of the bottom plate 1, the fourth supporting leg 701 is positioned on one side of the third supporting leg 657, the supporting shell 702 is mounted between the upper parts of the four fourth supporting legs 701, the containing bin 703 is embedded in the upper part of the supporting shell 702, the sealing shell 704 is arranged on the top of the containing bin 703, the atomizer 705 is embedded in the central position of the sealing shell 704, the atomizer 705 is communicated with the second discharging pipe 663, the exhaust fan 706 is mounted on the top of the sealing shell 704, the exhaust fan 706 is positioned on the rear side of the atomizer 705, the air pipe 707 is communicated with the exhaust fan 706, a heating frame 708 is arranged on the lower portion of the inner wall of the sealing shell 704, a third discharging pipe 709 is embedded in the lower portion of the containing bin 703, a self-sucking pump 7091 is arranged on the third discharging pipe 709, the self-sucking pump 7091 is positioned on the lower portion of the supporting shell 702, a settling tank 710 is arranged on the upper surface of the bottom plate 1, the settling tank 710 is positioned on one side of the fourth supporting leg 701, a tank cover 711 is rotatably arranged on the lower portion of the rear wall of the settling tank 710, the tank cover 711 is clamped with the settling tank 710 in a clamping manner, material conveying shells 712 are embedded on the left portion and the right portion of the top of the settling tank 710, the material conveying shells 712 on one side are communicated with the third discharging pipe 709, a mounting shell 713 is arranged on the lower portion of the material conveying shells 712, a plurality of curved folding plates 714 are arranged on the inner wall of the mounting shell 713, the curved folding plates 714 are S-shaped, a first air outlet pipe is communicated between the material conveying shells 712 on the left side and the right side, a second air outlet pipe 716 is arranged on the top of the first air outlet pipe 715, the upper part of the second air outlet pipe 716 is provided with a hollow shell 717, the lower part of the outer side wall of the hollow shell 717 is provided with a plurality of air outlet holes, and the inner lower part of the settling tank 710 is provided with a static plate 718.

When the device is used, a user adds a proper amount of hydrochloric acid into the front containing shell 654, adds a proper amount of sodium hydroxide into the rear containing shell 654, then communicates an external feeding device with the first feeding pipe 651, communicates an external water feeding device with the first water inlet pipe 652, then feeds a proper amount of salt slurry into the first feeding pipe 651 through the external feeding device, simultaneously feeds water into the first water inlet pipe 652 through the external water feeding device, the water in the first water inlet pipe 652 flows upwards along with the water to enter the upper part of the first feeding pipe 651, the water entering the upper part of the first feeding pipe 651 is mixed with the salt slurry, the weight ratio of the salt slurry to the water is 1:10, the salt slurry and the water are mixed to form a mixture, the mixture flows forwards into the reaction shell 3, and after a proper amount of salt slurry and water are added into the reaction shell 3, the user stops feeding through the external feeding device, and stops supplying water through the external water feeding device, simultaneously, a user starts the second liquid pump 656 at the front side to work, the second liquid pump 656 at the front side works to pump hydrochloric acid in the containing shell 654 at the front side, the hydrochloric acid is added into the reaction shell 3 through the delivery pipe 655 at the front side, then the user starts the first servo motor 602 to work to provide power for the gearbox 603, the gearbox 603 then enables the first rotating shaft 604 to rotate, the first rotating shaft 604 rotates to enable the spline shaft 609 to rotate, the spline shaft 609 rotates to enable the fixed disc 610, the sliding rod 611, the spline sleeve 612, the return spring 613, the first swinging plate 614, the hinge block 616, the balancing weight 617, the second swinging plate 618 and the pin 619 to rotate, under the rotation action of the spline shaft 609, the first swinging plate 614 and the second swinging plate 618 are close to enable the spline sleeves 612 at the upper side and the lower side to be close, the return spring 613 is compressed, and at the same time, the first swinging plate 614 and the second swinging plate 618 are close to each other, the weight 617 moves outwards, the weight 617 moves outwards and rotates to generate centrifugal force, the first swing plate 614 and the second swing plate 618 are better close to each other, the spline shaft 609 rotates to rotate the connecting disc 620, the connecting disc 620 rotates to enable the pinion 625 to move circumferentially along the spline shaft 609, the pinion 625 is matched with the gear ring 624 when moving circumferentially along the spline shaft 609, the pinion 625 rotates to enable the third rotating shaft 621 to rotate, the third rotating shaft 621 rotates to enable the impeller 622, the impeller 622 rotates to be matched with the first swing plate 614 and the second swing plate 618, mixture falling downwards in the collecting hopper 605 is stirred, the mixture forms vortex-shaped flow, the mixture and hydrochloric acid are better mixed, when the hydrochloric acid and the mixture are mixed, the pH =2 of the mixture is obtained, when the mixture and the hydrochloric acid are mixed, a user closes the first servo motor 602, and the second servo motor 640 is started to rotate the second straight gear 641, the second straight gear 641 rotates to rotate the first straight gear 635, the first straight gear 635 rotates to rotate the cross 634, the cross 634 rotates to drive the annular mesh plate 633 to rotate, meanwhile, the user starts the stepping motor 637 to rotate the valve body 638 to communicate with the feed delivery pipe 642, after the valve body 638 communicates with the feed delivery pipe 642, the user closes the stepping motor 637, the mixture in the collecting hopper 605 flows downwards into the feed delivery pipe 642 through the valve body 638, the mixture in the feed delivery pipe 642 is sprayed out through the first discharge pipe 643, the sprayed mixture collides with the annular mesh plate 633, the mixture of the liquid passes through the annular mesh plate 633 and falls on the lower part of the reaction shell 3, the solid silt in the mixture falls downwards into the material containing hopper 6321, at this time, the user starts the hydraulic cylinder 631 to swing the material baffle 632 leftwards to open, the silt in the material containing hopper 6321 slides downwards into the blanking hollow rack 627 through the baffle 644, silt in the blanking hollow rack 627 slides downwards along with the silt to fall into the containing box 629, carbon dioxide generated by the mixture and hydrochloric acid is upwards discharged through the gas outlet pipe 4, after the mixture is completely filtered, a user turns off the second servo motor 640, starts the stepping motor 637 to ensure that the valve body 638 rotates and is not communicated with the material conveying pipe 642, then turns off the stepping motor 637, starts the second electromagnetic valve 649 to open the return pipe 648, starts the first liquid pump 650 to work again, the first liquid pump 650 works to pump the mixture at the lower part in the reaction shell 3 and pushes the mixture into the upper part in the reaction shell 3 through the return pipe 648, and when the mixture at the lower part in the reaction shell 3 is completely pumped into the upper part in the reaction shell 3, the user turns off the second electromagnetic valve 649 and the first liquid pump 650.

Then the user starts the second liquid pump 656 at the rear side to work, the second liquid pump 656 at the rear side works to pump the sodium hydroxide in the containing shell 654 at the rear side, and the sodium hydroxide is added into the reaction shell 3 through the delivery pipe 655 at the rear side, and then the user repeats the above operation to fully mix the mixture and the sodium hydroxide, so that the PH =4 of the mixture is ensured, at this time, the iron hydroxide suspended solids are generated in the mixture, and then the operation is repeated to separate the mixture and the iron hydroxide suspended solids, so that the iron hydroxide is discharged.

Then the user repeats the above operation to draw the mixture at the lower part in the reaction shell 3 into the upper part in the reaction shell 3 again, and starts the second liquid pump 656 at the rear side to work, the second liquid pump 656 at the rear side is operated to draw the sodium hydroxide in the holding shell 654 at the rear side and add the sodium hydroxide into the reaction shell 3 through the delivery pipe 655 at the rear side, then the user repeats the above operation to fully mix the mixture with the sodium hydroxide, so that the PH =12 of the mixture is obtained, the magnesium hydroxide suspended particles are generated in the mixture, then the above operation is repeated to separate the mixture from the magnesium hydroxide particles, the magnesium hydroxide particles enter the blanking hollow rack 627, meanwhile, the user starts the hydraulic cylinder to swing the baffle plate 632 upwards to reset, the magnesium hydroxide particles 631 in the blanking hollow rack 627 enter the collection box 628, after all the magnesium hydroxide particles in the reaction shell 3 enter the collection box 628, the user starts the first solenoid valve 647 to open the waste pipe 646, the mixture in the reaction shell 3 flows out through the blanking pipe 645 and the waste pipe 646, meanwhile, the user collects the mixture flowing out, and after the mixture in the reaction shell 3 flows out completely, the user closes the first solenoid valve 647 and closes all electric parts of the device.

Then the user connects the external water-feeding device with the second water inlet pipe 665, and starts the fourth liquid-pumping pump 668 to pump the magnesium hydroxide particles in the collection box 628 and push them into the stirring shell 658 through the second feeding pipe 667, at the same time, the user connects the external water pipe with the second water inlet pipe 665, and starts the water-pumping pump 666 to pump a proper amount of water into the stirring shell 658 through the second water inlet pipe 665, when the magnesium hydroxide particles in the collection box 628 are all pumped into the stirring shell 658, the user closes the fourth liquid-pumping pump 668, when a proper amount of water is pumped into the stirring shell 658, the user closes the water-pumping pump 666, the magnesium hydroxide particles pumped into the stirring shell 658 fall down into the bucket 661, then the user starts the reciprocating cylinder 659 to move the bucket 661 up and down through the second support plate 660, the bucket 661 moves up and down to drive the magnesium hydroxide particles to move up and down to mix with the water, so as to form magnesium hydroxide mixed water, the magnesium hydroxide mixed water flows downwards through the spiral plate 662, after the magnesium hydroxide mixed water in the stirring shell 658 is completely mixed, the user closes the reciprocating cylinder 659, and starts the third liquid drawing pump 664 to work, the third liquid drawing pump 664 draws the magnesium hydroxide mixed water in the stirring shell 658, and sends the magnesium hydroxide mixed water into the atomizer 705 through the second discharge pipe 663, meanwhile, the user starts the exhaust fan 706, the atomizer 705 and the heating rack 708 to work, the heating rack 708 works to heat the temperature in the storage bin 703, the atomizer 705 works to atomize the magnesium hydroxide mixed water in the atomizer, the exhaust fan 706 works to absorb the outside air, and sends the air into the atomizer 705 through the air pipe 707, so that the magnesium hydroxide atomized liquid is blown downwards into the storage bin 703, and at the moment, the heating rack 708 is used to heat the magnesium hydroxide atomized liquid at a high temperature, so that the magnesium hydroxide atomized liquid becomes powder.

At this time, the user starts the self-priming pump 7091 to work, the self-priming pump 7091 works to extract the magnesium hydroxide powder in the storage bin 703, and the magnesium hydroxide powder is sent into the material conveying shell 712 at one side through the third discharge pipe 709, the magnesium hydroxide powder in the material conveying shell 712 is adsorbed under the action of the electrostatic plate 718, so that the magnesium hydroxide powder falls downwards and is adsorbed on the electrostatic plate 718, air in the material conveying shell 712 at one side flows into the material conveying shell 712 at the other side through the first air outlet pipe 715, air in the material conveying shell 712 at the right side flows upwards into the hollow shell 717 through the second air outlet pipe 716, air in the hollow shell 717 flows out, a part of air in the material conveying shell 712 flows downwards into the settling box 710, air in the settling box 710 flows upwards into the mounting shell 713 along with the air, because the curved plate 713 is arranged in the mounting shell 713, and the curved plate 714 is S-shaped, the curved plate 714 is used for blocking the upwards floating magnesium hydroxide powder, avoid magnesium hydrate powder in the air directly to flow into the defeated material shell 712 of opposite side in to upwards discharge, cause magnesium hydrate powder to cause the waste, after magnesium hydrate powder is whole to be collected, the user opens and removes the buckle setting to case lid 711, opens case lid 711 afterwards, then the user takes off the magnesium hydrate powder on the static board 718, and the user resets case lid 711 afterwards and is spacing through the buckle.

Example 3

In addition to embodiment 2, as shown in fig. 8 and 18, the reactor further includes a slot plate 8, an electric push rod 9, a slide block 11, a mounting rod 12 and a scraper 13, the slot plate 8 is mounted on the upper portion of the feed delivery pipe 642, the electric push rod 9 is embedded in the slot plate 8, a slide groove 10 is opened outside the slot plate 8, the slide block 11 is slidably disposed in the slide groove 10, the slide block 11 is fixedly connected with the telescopic end of the electric push rod 9, the mounting rod 12 is mounted on the lower surface of the slide block 11, the scraper 13 is disposed on the mounting rod 12, and the scraper 13 contacts with the inner wall of the reaction shell 3.

When handling salt mud, the user starts electric putter 9 and makes slider 11 move to the outside, and slider 11 moves to the outside and makes installation pole 12 move to the outside, and installation pole 12 moves to the outside and makes scraper blade 13 and annular otter board 633's inner wall contact, and annular otter board 633 rotates and scrapes the material of the adhesion on its inner wall through scraper blade 13 and gets, avoids being stained with the material on annular otter board 633's the inner wall, handles for salt mud next time and causes the inconvenience.

The above description is only for the specific embodiments of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art can easily conceive of the changes or substitutions within the technical scope of the present invention, and all the changes or substitutions should be covered within the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.

Claims (6)

1. A salt mud treatment device in the chlor-alkali industry comprises a bottom plate (1), first support legs (2), a reaction shell (3), an air outlet pipe (4), a reaction mechanism (6) and a collection mechanism (7), and is characterized in that the left part of the upper surface of the bottom plate (1) is provided with the four first support legs (2), the reaction shell (3) is arranged between the upper parts of the four first support legs (2), the air outlet pipe (4) is embedded at the top of the reaction shell (3), the reaction mechanism (6) is arranged between the reaction shell (3) and the upper surface of the bottom plate (1), the upper surface of the bottom plate (1) is provided with the collection mechanism (7), and the collection mechanism (7) is communicated with the reaction mechanism (6);

the reaction mechanism (6) comprises a mounting plate (601), a first servo motor (602), a gearbox (603), a first rotating shaft (604), a collecting hopper (605), a first support plate (606), a mounting plate (607), a second rotating shaft (608), a spline shaft (609), a fixed plate (610), a sliding rod (611), a spline sleeve (612), a reset spring (613), a first swinging plate (614), a hinge block (616), a balancing weight (617), a second swinging plate (618), a pin rod (619), a connecting plate (620), a third rotating shaft (621), an impeller (622), a sliding frame (623), a gear ring (624), a pinion (625), a separating part, a feeding part and a mixing part, wherein the mounting plate (601) is fixedly connected to the top of the reaction shell (3), the mounting plate (601) is positioned on one side of the air outlet pipe (4), the side wall of the mounting plate (601) is provided with the first servo motor (602), the side wall of the mounting plate (601) is provided with a gearbox (603), the gearbox (603) is positioned at the lower side of a first servo motor (602), the output end of the first servo motor (602) is connected with the input end of the gearbox (603), the output end of the gearbox (603) is provided with a first rotating shaft (604), the upper part of the inner wall of the reaction shell (3) is provided with a collecting hopper (605), the bottom in the collecting hopper (605) is uniformly and fixedly connected with a plurality of first support plates (606) along the circumferential direction, a mounting disc (607) is arranged between the upper parts of the plurality of first support plates (606), the upper surface of the mounting disc (607) is rotatably provided with a second rotating shaft (608), a spline shaft (609) is fixedly connected between the second rotating shaft (608) and the first rotating shaft (604), the middle part of the spline shaft (609) is connected with a fixed disc (610), the fixed disc (610) is uniformly and fixedly connected with a plurality of sliding rods (611) along the circumferential direction, spline sleeves (612) are arranged at the upper part and the lower part between the sliding rods (611) in a sliding mode, a plurality of reset springs (613) are fixedly connected between the spline sleeves (612) at the upper side and the lower side and the fixed disc (610) respectively, the reset springs (613) are wound on the outer sides of the sliding rods (611) respectively, the outer wall of the spline sleeve (612) at the lower side is hinged with a plurality of first swinging plates (614) uniformly along the circumferential direction, a sliding groove (615) is formed in the upper part of each first swinging plate (614), hinging blocks (616) are rotatably arranged on the upper parts of the two walls of each first swinging plate (614), balancing weights (617) are rotatably arranged between the lower parts of the two adjacent hinging blocks (616), a plurality of second swinging plates (618) are uniformly hinged on the outer wall of the spline sleeve (612) at the upper side along the circumferential direction, and the second swinging plates (618) are arranged with the first swinging plates (614) in a sliding mode respectively, a pin rod (619) is embedded at the lower part of the second swinging plate (618), the pin rods (619) are respectively connected with the sliding grooves (615) in a sliding manner, a connecting disc (620) is installed at the lower part of the spline shaft (609), the connecting disc (620) is positioned at the lower side of the spline sleeve (612) at the lower side, a plurality of third rotating shafts (621) are installed on the outer side wall of the connecting disc (620) along the circumferential direction in an even and rotating manner, a plurality of impellers (622) are fixedly connected onto the third rotating shafts (621), a sliding frame (623) is arranged at the upper part of the inner wall of the reaction shell (3) in a sliding manner, the sliding frame (623) is positioned at the upper side of the collecting hopper (605), the outer ends of the third rotating shafts (621) penetrate through the sliding frame (623) to be connected with the third rotating shafts in a rotating manner, pinions (625) are installed at the outer ends of the third rotating shafts (621), a gear ring (624) is installed at the outer side wall of the sliding frame (623), the gear ring (624) is respectively meshed with the pinions (625), a separating part is arranged at the lower part of the inner wall of the reaction shell (3), the separating part is fixedly connected with the collecting hopper (605), a feeding part is arranged on the upper surface of the bottom plate (1), the feeding part is positioned at one side of the reaction shell (3), the feeding part is communicated with the reaction shell (3), a mixing part is arranged on the upper surface of the bottom plate (1), the mixing part is positioned at one side of the reaction shell (3), and the mixing part is communicated with the separating part;

the separating component comprises a disc (626), a blanking hollow frame (627), a collecting box (628), a containing box (629), a mounting block (630), a hydraulic cylinder (631), a material baffle plate (632), a material containing hopper (6321), an annular screen plate (633), a cross (634), a first straight gear (635), a ball valve (636), a stepping motor (637), a valve body (638), a mounting seat (639), a second servo motor (640), a second straight gear (641), a material conveying pipe (642), a first material discharging pipe (643), a flow guide plate (644), a blanking pipe (645), a waste pipe (646), a first electromagnetic valve (647), a return pipe (648), a second electromagnetic valve (649), a first liquid pump (650), a first material feeding pipe (651) and a first water inlet pipe (652), the disc (626) is mounted on the lower portion of the inner wall of the reaction shell (3), the blanking hollow frame (627) is embedded in the lower portion of the reaction shell (3), the upper surface of the bottom plate (1) is provided with a collecting box (628), the collecting box (628) is positioned on one side of the first supporting leg (2), the collecting box (628) is communicated with the blanking hollow frame (627), the upper surface of the bottom plate (1) is provided with a containing box (629), the containing box (629) is positioned on one side of the collecting box (628), the bottom of the reaction shell (3) is fixedly connected with a mounting block (630), a hydraulic cylinder (631) is embedded on the mounting block (630), a baffle plate (632) is rotatably installed on the lower part of the blanking hollow frame (627), the side wall of the baffle plate (632) is rotatably connected with the telescopic end of the hydraulic cylinder (631), the upper part of the blanking hollow frame (627) is provided with a containing hopper (6321), an annular mesh plate (633) is rotatably installed between the containing hopper (6321) and the disc (626), a cross (634) is rotatably installed at the center position of the disc (626), and the cross (634) is fixedly connected with the annular mesh plate (633), a first straight gear (635) is installed on the upper portion of a cross frame (634), a ball valve (636) is installed on the lower portion of a collecting hopper (605), a stepping motor (637) is arranged on the side wall of the ball valve (636), a valve body (638) is arranged in the ball valve (636) in a sliding mode, the output end of the stepping motor (637) penetrates through the ball valve (636) to be connected with the ball valve in a rotating mode, the output end of the stepping motor (637) is fixedly connected with the valve body (638), a mounting seat (639) is installed on the lower surface of the collecting hopper (605), a second servo motor (640) is arranged in the mounting seat (639), a second straight gear (641) is installed at the output end of the second servo motor (640), the second straight gear (641) is meshed with the first straight gear (635), a material conveying pipe (642) is installed on the lower surface of the ball valve (636), the material conveying pipe (642) penetrates through a disc (626) and the cross frame (634) to be connected with the cross frame in a sliding mode, a plurality of first material discharging pipes (643) are evenly embedded on the outer side wall of the material conveying pipe (642) along the circumferential direction, two guide plates (644) are installed on the inner surface of a containing hopper (661), a discharging pipe (645) is embedded in the center of the bottom of a reaction shell (3), a waste pipe (646) and a return pipe (648) are respectively embedded in the lower portions of two walls of the discharging pipe (645), a first electromagnetic valve (647) is installed on the waste pipe (646), the upper portion of the return pipe (648) is communicated with the top of the reaction shell (3), a second electromagnetic valve (649) is arranged on the lower portion of the return pipe (648), a first liquid pump (650) is arranged on the upper portion of the return pipe (648), the first liquid pump (650) is fixedly connected with the upper portion of the reaction shell (3), a first feeding pipe (651) is installed on the top of the reaction shell (3), the first feeding pipe (651) is located on one side of the return pipe (648), and a first water inlet pipe (652) is embedded in the upper portion of the first feeding pipe (651);

the collecting mechanism (7) comprises a fourth supporting leg (701), a supporting shell (702), a containing bin (703), a sealing shell (704), an atomizer (705), an exhaust fan (706), a gas pipe (707), a heating frame (708), a third discharging pipe (709), a self-sucking pump (7091), a settling tank (710), a tank cover (711), a material conveying shell (712), an installation shell (713), a bent plate (714), a first air outlet pipe (715), a second air outlet pipe (716), a hollow shell (717) and an electrostatic plate (718), four fourth supporting legs (701) are installed on the upper surface of the bottom plate (1), the fourth supporting leg (701) is located on one side of the third supporting leg (657), the supporting shell (702) is installed between the upper portions of the four fourth supporting legs (701), the containing bin (703) is embedded in the upper portion of the supporting shell (702), the sealing shell (704) is arranged at the top of the containing bin (703), the atomizer (705) is embedded in the central position of the sealing shell (704), the atomizer (705) is communicated with the second discharge pipe (663), an exhaust fan (706) is installed at the top of the sealing shell (704), the exhaust fan (706) is located at the rear side of the atomizer (705), an air conveying pipe (707) is communicated between the exhaust fan (706) and the atomizer (705), a heating frame (708) is installed at the lower part of the inner wall of the sealing shell (704), a third discharge pipe (709) is embedded at the lower part of the containing bin (703), a self-sucking pump (7091) is arranged on the third discharge pipe (709), the self-sucking pump (7091) is located at the inner lower part of the supporting shell (702), a settling box (710) is arranged on the upper surface of the bottom plate (1), the settling box (710) is located at one side of the fourth supporting leg (701), a box cover (711) is rotatably arranged at the lower part of the side wall of the settling box (710) in a clamping manner, the box cover (711) is clamped with the settling box (710), two material conveying shells (712) are embedded at the top of the settling box (710), defeated material shell (712) and third discharging pipe (709) intercommunication of one side, the lower part of defeated material shell (712) is provided with installation shell (713), installation shell (713) inner wall is provided with a plurality of bent board (714), the intercommunication has first tuber pipe (715) between two defeated material shells (712), second tuber pipe (716) are installed at defeated material shell (712) top of opposite side, second tuber pipe (716) are located the upside of first tuber pipe (715) of going out, the upper portion that second goes out tuber pipe (716) is provided with hollow shell (717), open hollow shell (717) lateral wall lower part has a plurality of venthole, electrostatic plate (718) are installed to the lower part in settling box (710).

2. The salt mud treatment device in the chlor-alkali industry as set forth in claim 1, wherein the outer surface of the balancing weight (617) is made of rubber, and the middle of the balancing weight (617) is embedded with a spherical iron block.

3. The salt slurry treatment device in the chlor-alkali industry as claimed in claim 1, wherein said feeding member comprises second legs (653), containing housings (654), delivery pipes (655) and second liquid pumps (656), eight second legs (653) are provided on the upper surface of said base plate (1), said second legs (653) are located on one side of said first legs (2), said containing housings (654) are fixedly connected between the upper portions of four adjacent second legs (653), said delivery pipes (655) are embedded on the top of said containing housings (654), said delivery pipes (655) are connected to the top of said reaction housing (3), said second liquid pumps (656) are installed on the upper portions of said delivery pipes (655), and said second liquid pumps (656) are fixedly connected to said reaction housing (3).

4. The salt mud treatment device in the chlor-alkali industry as claimed in claim 1, characterized in that the mixing means comprise a third leg (657), a stirring shell (658), a reciprocating cylinder (659), a second leg (660), a hopper (661), a spiral plate (662), a second discharge pipe (663), a third liquid pump (664), a second water inlet pipe (665), a water pump (666), a second feed pipe (667) and a fourth liquid pump (668), four third legs (657) are installed on the upper surface of the bottom plate (1), the stirring shell (658) is installed between the upper parts of the four third legs (657), the reciprocating cylinder (659) is installed in the center of the top of the stirring shell (658), the telescopic end of the reciprocating cylinder (659) passes through the top of the stirring shell (658) to be slidably connected thereto, the outer side wall of the telescopic rod of the reciprocating cylinder (659) is uniformly and fixedly connected with a plurality of second legs (660) along the circumference thereof, a containing hopper (661) is fixedly connected among the lower parts of the plurality of second support plates (660), a spiral plate (662) is installed on the inner wall of the stirring shell (658), the spiral plate (662) is wound on the outer side of the containing hopper (661), a second discharge pipe (663) is embedded in the center of the bottom of the stirring shell (658), a third liquid pump (664) is arranged on the lower part of the second discharge pipe (663), the third liquid pump (664) is fixedly connected with the stirring shell (658), a second water inlet pipe (665) is installed on the top of the stirring shell (658), the second water inlet pipe (665) is positioned on one side of the reciprocating cylinder (659), a water suction pump (666) is arranged on the upper part of the second water inlet pipe (665), the water suction pump (666) is fixedly connected with the stirring shell (658), a second feed pipe (667) is embedded between the stirring shell (658) and the collection box (628), the second feed pipe (667) is positioned on the front side of the reciprocating cylinder (659), a fourth liquid pump (668) is arranged on the upper part of the second feed pipe (667), the fourth liquid pump (668) is fixedly connected with the upper part of the stirring shell (658).

5. A plant for the treatment of salty mud for the chlor-alkali industry as in claim 1, characterized by the fact that the bent plates (714) are S-shaped.

6. The salt mud treatment device in the chlor-alkali industry as claimed in claim 1, further comprising a slot plate (8), an electric push rod (9), a slide block (11), an installation rod (12) and a scraper (13), wherein the slot plate (8) is installed on the upper portion of the feed delivery pipe (642), the electric push rod (9) is embedded in the slot plate (8), a sliding groove (10) is formed in the outer portion of the slot plate (8), the slide block (11) is slidably arranged in the sliding groove (10), the slide block (11) is fixedly connected with the telescopic end of the electric push rod (9), the installation rod (12) is installed on the lower surface of the slide block (11), the scraper (13) is arranged on the installation rod (12), and the scraper (13) is in contact with the inner wall of the reaction shell (3).

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