CN118183977B

CN118183977B - Antimony-lead alloy processing wastewater treatment device

Info

Publication number: CN118183977B
Application number: CN202410380085.4A
Authority: CN
Inventors: 唐磊; 田智
Original assignee: Shiny Materials Science & Technology Inc
Current assignee: Shiny Materials Science & Technology Inc
Priority date: 2024-03-30
Filing date: 2024-03-30
Publication date: 2025-03-07
Anticipated expiration: 2044-03-30
Also published as: CN118183977A

Abstract

The invention belongs to the technical field of antimony-lead alloy processing, in particular to an antimony-lead alloy processing wastewater treatment device, which comprises a fixed frame, wherein the upper surface of the fixed frame is fixedly connected with a supporting table, the upper surface of the supporting table is fixedly connected with a feeding cylinder, one end of the feeding cylinder is fixedly connected with a feeding frame, the inside of the feeding cylinder is rotationally connected with a screw rod, the other end of the feeding cylinder is fixedly connected with a discharging pipe, one end of the discharging pipe is fixedly connected with a treatment cylinder, the lower surface of the treatment cylinder is fixedly connected with one end of the fixed frame, the inside of the treatment cylinder is rotationally connected with a first rotating rod, the circumference of the first rotating rod is fixedly connected with a plurality of fixing plates, and a water inlet frame is fixedly connected between every two adjacent fixing plates, so that the equivalent arsenic and antimony removing agent can be added into equivalent wastewater, and the accuracy of chemical reaction is ensured.

Description

Antimony-lead alloy processing wastewater treatment device

Technical Field

The invention belongs to the technical field of antimony-lead alloy processing, and particularly relates to a wastewater treatment device for antimony-lead alloy processing.

Background

The processing process of the antimony-lead alloy generally comprises the steps of alloy preparation, casting, heat treatment, cutting, polishing, surface treatment and the like, in the link of surface treatment, acid washing, electroplating or other chemical treatment is required to improve the appearance of the alloy or enhance the corrosion resistance of the alloy, a cleaning agent or a solvent is used in the pretreatment steps, after the cleaning, the liquid containing impurities, greasy dirt or chemical residues can form wastewater, heavy metal ions contained in the wastewater mainly comprise antimony ions and lead ions, and the heavy metal ions are directly discharged into the environment without treatment and can cause great harm to the environment.

One patent application with publication number CN105858958B discloses a method for treating mine wastewater containing arsenic and antimony, which comprises the steps of adding an arsenic and antimony removing agent into the wastewater, adding an oxidant A, controlling the pH value to be 6-9, enabling arsenic and antimony pollutants in the wastewater to react with the arsenic and antimony removing agent, and enabling the generated indissolvable compounds to enter water treatment slag.

In the prior art, the wastewater is collected in a wastewater tank, and then a large amount of arsenic and antimony removing agent is added to react with the wastewater, so that the wastewater treatment efficiency is affected, the amount of the arsenic and antimony removing agent is calculated again according to the collected wastewater amount, and a certain time is required to be consumed in the process, so that the wastewater treatment efficiency is reduced, and when the arsenic and antimony removing agent is agglomerated to generate a block shape, the contact area with the wastewater is reduced, so that the problem of insufficient antimony and lead treatment in the wastewater is caused.

Therefore, the invention provides a device for treating wastewater from processing antimony-lead alloy.

Disclosure of Invention

In order to overcome the deficiencies of the prior art, at least one technical problem presented in the background art is solved.

The technical scheme includes that the antimony-lead alloy processing wastewater treatment device comprises a fixing frame, wherein a supporting table is fixedly connected to the upper surface of the fixing frame, a feeding cylinder is fixedly connected to the upper surface of the supporting table, a feeding frame is fixedly connected to one end of the feeding cylinder, a screw is rotatably connected to the inside of the feeding cylinder, a discharging pipe is fixedly connected to the other end of the feeding cylinder, a treatment cylinder is fixedly connected to one end of the discharging pipe, the lower surface of the treatment cylinder is fixedly connected with one end of the fixing frame, a first rotating rod is rotatably connected to the inside of the treatment cylinder, a plurality of fixing plates are fixedly connected to the circumference of the first rotating rod, a water inlet frame is fixedly connected between every two adjacent fixing plates, openings are formed in the upper surface of the water inlet frame, a second rotating rod is rotatably connected to the inside of the water inlet frame, a plurality of stirring plates are fixedly connected to the surface of the second rotating rod, tooth sockets are formed in one end of the stirring plate, tooth sockets are fixedly connected to the inner lower surface of the water inlet frame, tooth sockets are fixedly connected to the inner lower surface of the water inlet frame, and the tooth sockets are fixedly connected to the water inlet pipe are fixedly meshed with the upper surface of the treatment cylinder.

Preferably, the upper surface fixedly connected with motor of mount, the output of motor and the one end of first bull stick are all fixedly connected with band pulley, two pass through belt transmission connection between the band pulley.

Preferably, the other output end of the motor is fixedly connected with a sixth bevel gear, one end of the screw is fixedly connected with a transmission rod, one end of the transmission rod is fixedly connected with a fifth bevel gear, and the fifth bevel gear and the sixth bevel gear are meshed with each other.

Preferably, the bottom of the feeding frame and the connecting end of the charging barrel are obliquely arranged, the discharging pipe is obliquely arranged, and one end of the discharging pipe is attached to the inner wall of the treatment barrel.

Preferably, the fixed plate is attached to the inner wall of the treatment cylinder, the inner wall of the water inlet frame is circular, and one end of the stirring plate is attached to the inner wall of the water inlet frame.

Preferably, the both ends of a processing section of thick bamboo are all fixedly connected with support frame, two fixedly connected with first dead lever between the support frame, the both ends of first dead lever are all fixedly connected with first bevel gear, the inside rotation of a water inlet frame is connected with fourth bevel gear, and fourth bevel gear and first bevel gear intermeshing.

Preferably, each of the two ends of the second rotating rod is fixedly connected with a second bevel gear, a first connecting rod is fixedly connected to the inside of the fourth bevel gear, the first connecting rod is rotationally connected with the inside of the water inlet frame, a third bevel gear is fixedly connected to one end of the first connecting rod, and the third bevel gear and the second bevel gear are meshed with each other.

Preferably, the inside symmetry slip of second bull stick is provided with the second connecting rod, the equal fixedly connected with of surface of second connecting rod is a plurality of first pinion rack, the equal and surface sliding connection of stirring board of first pinion rack, the fixed surface of stirring board is connected a plurality of second pinion rack, second pinion rack and first pinion rack intermeshing, the inside of stirring board is provided with a plurality of filtration pore.

Preferably, one end of the second connecting rod is rotationally connected with a connecting rod, the other end of the connecting rod is rotationally connected with a driven gear, a rotating rod is fixedly connected inside the driven gear, the surface of the rotating rod is rotationally connected with the inner part of the second rotating rod, and a spring is fixedly connected between the surface of the second connecting rod and the inner wall of the second rotating rod.

Preferably, the inside fixedly connected with second dead lever of frame that intakes, the both ends of second dead lever all fixedly connected with fixed gear, fixed gear and driven gear intermeshing.

The beneficial effects of the invention are as follows:

1. according to the antimony-lead alloy processing wastewater treatment device, the baffle and the water inlet frame are arranged, the first rotating rod drives the baffle to rotate, when the baffle drives the water inlet frame to rotate to the material discharging pipe, the material discharging pipe conveys the equivalent arsenic-removing antimonic agent into the water inlet frame, the material discharging pipe drives the water inlet frame to rotate to the water inlet pipe along with the baffle, and the wastewater enters the water inlet frame through the opening in an equivalent manner, so that the equivalent arsenic-removing antimonic agent can be added into the equivalent wastewater, the accuracy of chemical reaction is ensured, and the metering and mixing operation processes are simple and convenient, so that the treatment efficiency is improved.

2. According to the antimony-lead alloy processing wastewater treatment device, the stirring plates and the tooth blocks are arranged, the second rotating rods drive the stirring plates to rotate, the stirring plates stir the arsenic-removing antimonial agent and wastewater in the water inlet frame, so that the reaction efficiency of the arsenic-removing antimonial agent and the wastewater is improved, meanwhile, when the arsenic-removing antimonial agent is agglomerated into larger blocks, the large blocks are settled at the bottom of the water inlet frame due to gravity, and at the moment, the stirring plates push the large blocks of the arsenic-removing antimonial agent to move to the tooth blocks through the tooth grooves, the tooth grooves are meshed with the tooth blocks, and the large blocks of the arsenic-removing antimonial agent can be crushed into small blocks, so that the reaction dissolution speed of the arsenic-removing antimonial agent and the wastewater is accelerated.

3. According to the wastewater treatment device for processing the antimony-lead alloy, the first toothed plate, the second toothed plate and the filtering holes are arranged, when the stirring plate rotates, the sizes of the aggregated blocks of the arsenic-removing antimonic agent are different, so that different heights in wastewater can exist, the stirring plate rotates, the wastewater passes through the filtering holes, the block-shaped arsenic-removing antimonic agent can be attached to the filtering holes, the first toothed plate is driven to slide, the first toothed plate pushes the block-shaped arsenic-removing antimonic agent at the filtering holes to be meshed with the second toothed plate, and therefore the arsenic-removing antimonic agent floating in the wastewater can be crushed, the reaction rate between the arsenic-removing antimonic agent and the wastewater can be quickened, and the reaction efficiency is improved.

Drawings

The invention is further described below with reference to the accompanying drawings.

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a cross-sectional view of the internal structure of the feed cylinder and the treatment cylinder of the present invention;

FIG. 3 is a schematic view of the structure of the treatment canister and the water inlet frame of the present invention;

FIG. 4 is a schematic view of the overall structure of the water inlet frame of the present invention;

FIG. 5 is a sectional view showing the construction of the water inlet frame of the present invention;

FIG. 6 is a structural cross-sectional view of the water inlet frame of the present invention from another perspective;

FIG. 7 is a schematic view of the structure of the stirring plate of the present invention;

FIG. 8 is an enlarged view of a portion of FIG. 7A in accordance with the present invention;

In the figure, 1, a fixed frame, 11, a supporting table, 2, a processing cylinder, 21, a first rotating rod, 22, a fixed plate, 23, a first fixed rod, 24, a first bevel gear, 25, a water inlet pipe, 26, a water outlet pipe, 27, a supporting frame, 3, a water inlet frame, 31, an opening, 32, a second rotating rod, 33, a second bevel gear, 34, a first connecting rod, 35, a third bevel gear, 36, a fourth bevel gear, 37, a stirring plate, 371, a tooth socket, 372, a first toothed plate, 373, a second toothed plate, 374, a filtering hole, 375, a second connecting rod, 376, a rotating rod, 377, a spring, 378, a driven gear, 379, a connecting rod, 38, a toothed block, 39, a fixed gear, 310, a second fixed rod, 4, a charging cylinder, 41, a charging frame, 42, a discharging pipe, 43, a screw, 44, a transmission rod, 45, a fifth bevel gear, 5, a motor, 51, a belt pulley, 52 and a sixth bevel gear are arranged.

Detailed Description

The invention is further described in connection with the following detailed description in order to make the technical means, the creation characteristics, the achievement of the purpose and the effect of the invention easy to understand.

Example 1

As shown in fig. 1 to 4 and 6, the device for treating wastewater from processing antimony-lead alloy according to the embodiment of the invention comprises a fixing frame 1, wherein the upper surface of the fixing frame 1 is fixedly connected with a supporting table 11, the upper surface of the supporting table 11 is fixedly connected with a feeding cylinder 4, one end of the feeding cylinder 4 is fixedly connected with a feeding frame 41, the inside of the feeding cylinder 4 is rotatably connected with a screw 43, the other end of the feeding cylinder 4 is fixedly connected with a discharge pipe 42, one end of the discharge pipe 42 is fixedly connected with a processing cylinder 2, the lower surface of the processing cylinder 2 is fixedly connected with one end of the fixing frame 1, the inside of the processing cylinder 2 is rotatably connected with a first rotating rod 21, the circumferential surface of the first rotating rod 21 is fixedly connected with a plurality of fixing plates 22, a water inlet frame 3 is fixedly connected between adjacent fixing plates 22, the upper surface of the water inlet frame 3 is provided with an opening 31, the inside of the feeding frame 3 is rotatably connected with a second rotating rod 32, the surface of the second rotating rod 32 is fixedly connected with a plurality of stirring plates 37, one end of each stirring plate 37 is fixedly connected with a tooth socket 371, one end of each stirring plate 37 is fixedly connected with a water inlet pipe 38, and the surface of each tooth socket is fixedly connected with a water inlet pipe 38, and the water inlet pipe is fixedly connected with one end of water inlet pipe 38.

Specifically, in the prior art, after filtering the waste water with antimony and lead to remove larger impurities in the waste water, collecting the waste water with antimony and lead in a waste water tank, and then adding an arsenic and antimony removing agent and an oxidizing agent into the waste water tank to enable the antimony and lead in the waste water to undergo a chemical reaction to generate a precipitate, and finally pumping the precipitate out for safe disposal;

The above operation process firstly collects the wastewater in a wastewater tank, then adds a large amount of arsenic-antimony removing agent to react with the wastewater, which may require a long time, thus affecting the wastewater treatment efficiency, and the amount of the arsenic-antimony removing agent is calculated again according to the collected wastewater amount, which requires a certain time, thus causing the problem of reduced wastewater treatment efficiency, and when the arsenic-antimony removing agent is agglomerated to generate a block, the contact area with the wastewater is reduced, thus causing the problem of insufficient antimony-lead treatment in the wastewater;

When the device is used, the first rotating rod 21 is driven to rotate, the first rotating rod 21 drives the fixed plate 22 to rotate, the fixed plate 22 drives the water inlet frame 3 to synchronously rotate, at the moment, the driving screw 43 rotates, the arsenic-removing antimonial agent is fed into the feed cylinder 4 through the feed frame 41, the screw 43 feeds the arsenic-removing antimonial agent into the discharge pipe 42, when the opening 31 of the water inlet frame 3 moves to the position of the discharge pipe 42, the arsenic-removing antimonial agent in the discharge pipe 42 slides into the water inlet frame 3 through the opening 31, then the water inlet frame 3 continuously rotates, the opening 31 is attached to the inner wall of the treatment cylinder 2, thus the outer wall of the water inlet frame 3 seals the discharge pipe 42 to stop adding the arsenic-removing antimonial agent until the subsequent opening 31 reaches the position of the discharge pipe 42 to repeatedly add the arsenic-removing antimonial agent, and as the water inlet frame 3 rotates to the position of the water inlet pipe 25, the wastewater with large impurities removed is discharged into the treatment cylinder 2 through the water inlet pipe 25, the waste water enters the water inlet frame 3 through the opening 31, then the water inlet frame 3 rotates, the water inlet pipe 25 is closed through the outer wall of the water inlet frame 3 to stop water inlet, and the subsequent opening 31 is known to reach the water inlet operation, so in the process, the time between the opening 31 of each water inlet frame 3 passing through the discharge pipe 42 and the water inlet pipe 25 is the same, and therefore, the amount of the waste water and the arsenic-antimony removing agent entering the water inlet frame 3 through the opening 31 is fixed, the equal amount of the arsenic-antimony removing agent and the waste water can be added into the water inlet frame 3, simultaneously, the second rotating rod 32 drives the stirring plate 37 to rotate, the stirring plate 37 can stir the waste water in the water inlet frame, the arsenic-antimony removing agent and the waste water can accelerate reaction, when the arsenic-antimony removing agent is agglomerated into a large block shape, the block-shaped arsenic-antimony removing agent is settled at the bottom of the water inlet frame 3, at this time, the tooth grooves 371 at one end of the stirring plate 37 push the block-shaped arsenic-antimony removing agent to move to the tooth blocks 38, the tooth grooves 371 are meshed with the tooth blocks 38, the block-shaped arsenic-antimony removing agent can be crushed into small blocks, the arsenic-antimony removing agent is scattered in the wastewater to perform reaction operation, the wastewater completely reacted in the water inlet frame 3 moves to the drain pipe 26, the opening 31 corresponds to the drain pipe 26, and the wastewater completely reacted can be discharged;

The device can ensure that the equivalent arsenic-antimony removing agent is added into the equivalent wastewater, so that the waiting time of the reaction is reduced, the wastewater treatment efficiency is improved, and meanwhile, the large arsenic-antimony removing agent can be crushed into small blocks, so that the reaction dissolution speed of the arsenic-antimony removing agent and the wastewater is accelerated.

As shown in fig. 1, the upper surface of the fixing frame 1 is fixedly connected with a motor 5, the output end of the motor 5 and one end of the first rotating rod 21 are fixedly connected with belt wheels 51, and the two belt wheels 51 are connected through belt transmission.

Specifically, when the motor 5 is turned on, the output end of the motor 5 drives the belt pulley 51 to rotate, and the belt pulley 51 can drive the belt pulley 51 at one end of the first rotating rod 21 to synchronously rotate through belt transmission, so that the first rotating rod 21 can be driven to drive the fixing plate 22 to synchronously rotate.

As shown in fig. 2, the other output end of the motor 5 is fixedly connected with a sixth bevel gear 52, one end of the screw 43 is fixedly connected with a transmission rod 44, one end of the transmission rod 44 is fixedly connected with a fifth bevel gear 45, and the fifth bevel gear 45 and the sixth bevel gear 52 are meshed with each other.

Specifically, when the motor 5 is turned on, the other output end of the motor 5 drives the sixth bevel gear 52 to rotate, and the sixth bevel gear 52 is meshed with the fifth bevel gear 45, so that the fifth bevel gear 45 drives the transmission rod 44 to rotate, the transmission rod 44 drives the screw 43 to synchronously rotate, and the screw 43 can drive the arsenic-antimony removing agent to be fed into the discharge pipe 42.

As shown in fig. 2, the bottom end of the feeding frame 41 and the connecting end of the feed cylinder 4 are arranged in an inclined manner, the discharge pipe 42 is arranged in an inclined manner, and one end of the discharge pipe 42 is attached to the inner wall of the treatment cylinder 2.

Specifically, the arsenic-antimonial agent in the interior of the feed frame 41 can be rapidly slid into the interior of the cartridge 4 and fed into the discharge pipe 42 by the screw 43, and finally slid from the discharge pipe 42 into the interior of the treatment cartridge 2 by gravity.

As shown in fig. 3, the fixing plate 22 is attached to the inner wall of the treatment cylinder 2, the inner wall of the water inlet frame 3 is circular, and one end of the stirring plate 37 is attached to the inner wall of the water inlet frame 3.

Specifically, the fixing plate 22 can divide the treatment cylinder 2 into a plurality of areas, each area can enter equivalent wastewater, then equivalent arsenic-antimony removing agents are added, the equivalent wastewater and the arsenic-antimony removing agents can react, and when the stirring plate 37 rotates, the stirring plate can drive the blocky arsenic-antimony removing agents attached to the inner wall of the water inlet frame 3 to rotate.

As shown in fig. 4 and fig. 5, two ends of the treatment drum 2 are fixedly connected with supporting frames 27, a first fixing rod 23 is fixedly connected between two supporting frames 27, two ends of the first fixing rod 23 are fixedly connected with a first bevel gear 24, the inside of the water inlet frame 3 is rotatably connected with a fourth bevel gear 36, the fourth bevel gear 36 and the first bevel gear 24 are meshed with each other, two ends of each second rotating rod 32 are fixedly connected with a second bevel gear 33, a first connecting rod 34 is fixedly connected to the inside of the fourth bevel gear 36, the first connecting rod 34 is rotatably connected with the inside of the water inlet frame 3, one end of the first connecting rod 34 is fixedly connected with a third bevel gear 35, and the third bevel gear 35 and the second bevel gear 33 are meshed with each other.

Specifically, when the first rotating rod 21 rotates, the first rotating rod 21 drives the fixing plate 22 to rotate, the fixing plate 22 drives the water inlet frame 3 to rotate, the water inlet frame 3 drives the fourth bevel gear 36 to rotate, and because the first bevel gear 24 is fixed between the two supporting frames 27 through the first fixing rod 23, when the fourth bevel gear 36 rotates around the first bevel gear 24, the fourth bevel gear 36 is meshed with the first bevel gear 24, so that the fourth bevel gear 36 can rotate, the fourth bevel gear 36 drives the first connecting rod 34 to rotate, the first connecting rod 34 drives the third bevel gear 35 to rotate, the third bevel gear 35 and the second bevel gear 33 rotate, the second bevel gear 33 drives the second rotating rod 32 to rotate, and the second rotating rod 32 can drive the stirring plate 37 to synchronously rotate.

Example two

As shown in fig. 6 and 8, in a first comparative example, a second connecting rod 375 is symmetrically and slidably disposed in the second rotating rod 32, a plurality of first toothed plates 372 are fixedly connected to the surface of the second connecting rod 375, the first toothed plates 372 are slidably connected to the surface of the stirring plate 37, a plurality of second toothed plates 373 are fixedly connected to the surface of the stirring plate 37, the second toothed plates 373 and the first toothed plates 372 are engaged with each other, and a plurality of filtering holes 374 are disposed in the stirring plate 37;

One end of the second connecting rod 375 is rotatably connected with a connecting rod 379, the other end of the connecting rod 379 is rotatably connected with a driven gear 378, a rotating rod 376 is fixedly connected inside the driven gear 378, the surface of the rotating rod 376 is rotatably connected with the inside of the second rotating rod 32, and a spring 377 is fixedly connected between the surface of the second connecting rod 375 and the inner wall of the second rotating rod 32;

The inside fixedly connected with second dead lever 310 of frame 3 intakes, the both ends of second dead lever 310 all fixedly connected with fixed gear 39, fixed gear 39 and driven gear 378 intermesh.

Specifically, after the arsenic-antimony removing agent is mixed with the wastewater, the small-block arsenic-antimony removing agent which is partially polymerized does not have sedimentation reaction, so that the small-block arsenic-antimony removing agent can be positioned in different depths in the wastewater, the contact area between the small-block arsenic-antimony removing agent and the wastewater is reduced, and the diffusion and collision of reactants are limited, so that the reaction speed is reduced;

Therefore, in order to solve the above problem, when the second rotating rod 32 drives the stirring plate 37 to rotate, the waste water can pass through the filtering holes 374, the arsenic-antimony removing agent floating in different depths can be filtered by the filtering holes 374, meanwhile, the second rotating rod 32 drives the driven gear 378 to rotate, the driven gear 378 is meshed with the fixed gear 39, so that the driven gear 378 rotates, the driven gear 378 drives the connecting rod 379 to rotate, the connecting rod 379 rotates and drives the second connecting rod 375 to slide reciprocally through the spring 377, the second connecting rod 375 drives the first toothed plate 372 to slide on the stirring plate 37, the first toothed plate 372 pushes the blocky arsenic-antimony removing agent at the filtering holes 374 to move to the second toothed plate 373, and the first toothed plate 372 and the second toothed plate 373 are meshed, so that the arsenic-antimony removing agent can be crushed, and the blocky arsenic-antimony removing agent can be decomposed;

The device can crush the blocky arsenic-antimony removing agents floating in the wastewater at different heights, so that the reaction rate between the arsenic-antimony removing agents and the wastewater is quickened, the reaction efficiency is improved, meanwhile, the first toothed plate 372 moves back and forth, the filtering holes 374 can be cleaned, and the flowing efficiency of the wastewater is improved, so that the wastewater is quickened to be mixed with the arsenic-antimony removing agents.

The working principle is that the motor 5 is opened, the output end of the motor 5 drives the belt pulley 51 to rotate, the belt pulley 51 can drive the belt pulley 51 at one end of the first rotating rod 21 to synchronously rotate through belt transmission, the first rotating rod 21 can be driven to drive the first rotating rod 21, the first rotating rod 21 drives the fixed plate 22 to rotate, the fixed plate 22 drives the water inlet frame 3 to synchronously rotate, the other output end of the motor 5 drives the sixth bevel gear 52 to rotate while the motor 5 is opened, the sixth bevel gear 52 is meshed with the fifth bevel gear 45, the fifth bevel gear 45 drives the transmission rod 44 to rotate, the transmission rod 44 drives the screw 43 to synchronously rotate, the arsenic and antimony removing agent is fed into the feed cylinder 4 through the feed frame 41, the screw 43 feeds the arsenic and antimony removing agent into the discharge pipe 42, when the opening 31 of the water inlet frame 3 moves to the position of the discharge pipe 42, the arsenic and antimony removing agent in the discharge pipe 42 slides into the water inlet frame 3 through the opening 31, then the water inlet frame 3 rotates and seals the discharging pipe 42, along with the rotation of the water inlet frame 3 to the water inlet pipe 25, the waste water with large impurities removed is discharged into the treatment cylinder 2 through the water inlet pipe 25, the waste water enters the water inlet frame 3 through the opening 31, the arsenic removal antimonide and the waste water are added into the water inlet frame 3 in equal quantity, the water inlet frame 3 rotates, the water inlet frame 3 drives the fourth bevel gear 36 to rotate, the first bevel gear 24 is fixed between the two supporting frames 27 through the first fixing rod 23, therefore, when the fourth bevel gear 36 rotates around the first bevel gear 24, the fourth bevel gear 36 is meshed with the first bevel gear 24, the fourth bevel gear 36 can rotate, the fourth bevel gear 36 drives the first connecting rod 34 to rotate, the first connecting rod 34 drives the third bevel gear 35 to rotate, the third bevel gear 35 and the second bevel gear 33 rotate, the second bevel gear 33 drives the second rotating rod 32 to rotate, the second bull stick 32 can drive stirring board 37 synchronous rotation, stirring board 37 can stir the operation to inside waste water, make dearsenification antimonic agent and waste water can accelerate the reaction, when dearsenification antimonic agent takes place to agglomerate and form great cubic, cubic dearsenification antimonic agent subsides in water inlet frame 3 bottom, tooth groove 371 of stirring board 37 one end promotes cubic dearsenification antimonic agent and moves to tooth piece 38 department this moment, tooth groove 371 and tooth piece 38 meshing, can smash into the fritter to cubic dearsenification antimonic agent, make dearsenification antimonic agent scatter in waste water and carry out the reaction operation, when second bull stick 32 drive stirring board 37 rotates, waste water can be passed through in the filtration pore 374, float the dearsenification antimonic agent in different depths can be filtered by the filtration pore 374, simultaneously, driven gear 378 rotates, driven gear 378 and fixed gear 39 meshing, make driven gear 378 take place to rotate, driven gear 379 drives connecting rod 379 and rotates and drives second connecting rod 375 through spring 377, second connecting rod 375 reciprocal slip, can drive first tooth plate 372 on stirring board 37, make dearsenification antimonic agent and waste water take place to complete reaction, the reaction at the place in the mouth of the filter pore 374, can be carried out the reaction at the complete, the inside waste water can be broken down by the filter pore 374, and can be made to take place, and the reaction at the inside waste water is completely, and the filter hole 372 is broken down, and the reaction takes place, and can be completely broken down.

The foregoing has shown and described the basic principles, principal features and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present invention, and various changes and modifications may be made without departing from the spirit and scope of the invention, which is defined in the appended claims. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims

1. The antimony lead alloy processing wastewater treatment device is characterized by comprising a fixing frame (1), wherein the upper surface of the fixing frame (1) is fixedly connected with a supporting table (11), the upper surface of the supporting table (11) is fixedly connected with a feeding cylinder (4), one end of the feeding cylinder (4) is fixedly connected with a feeding frame (41), the inside of the feeding cylinder (4) is rotationally connected with a screw (43), the other end of the feeding cylinder (4) is fixedly connected with a discharging pipe (42), one end of the discharging pipe (42) is fixedly connected with a treatment cylinder (2), the lower surface of the treatment cylinder (2) is fixedly connected with one end of the fixing frame (1), the inside of the treatment cylinder (2) is rotationally connected with a first rotating rod (21), the circumference surface of the first rotating rod (21) is fixedly connected with a plurality of fixed plates (22), a water inlet frame (3) is fixedly connected between adjacent fixed plates (22), the upper surface of the water inlet frame (3) is provided with an opening (31), the inside of the water inlet frame (3) is rotationally connected with a second tooth groove (32), one end of the second rotating rod (32) is fixedly connected with a plurality of stirring plates (37) and the inner stirring plates (37) are fixedly connected with one end of the stirring plates (37), and tooth piece (38) and tooth's socket (371) intermesh, the upper surface fixedly connected with inlet tube (25) of handling section of thick bamboo (2), the lower surface fixedly connected with drain pipe (26) of handling section of thick bamboo (2).

2. The antimony-lead alloy processing wastewater treatment device according to claim 1, wherein a motor (5) is fixedly connected to the upper surface of the fixing frame (1), a belt wheel (51) is fixedly connected to the output end of the motor (5) and one end of the first rotating rod (21), and the two belt wheels (51) are connected through belt transmission.

3. The antimony-lead alloy processing wastewater treatment device according to claim 2, wherein the other output end of the motor (5) is fixedly connected with a sixth bevel gear (52), one end of the screw (43) is fixedly connected with a transmission rod (44), one end of the transmission rod (44) is fixedly connected with a fifth bevel gear (45), and the fifth bevel gear (45) and the sixth bevel gear (52) are meshed with each other.

4. The antimony-lead alloy processing wastewater treatment device according to claim 3, wherein the bottom end of the feeding frame (41) and the connecting end of the charging barrel (4) are obliquely arranged, the discharging pipe (42) is obliquely arranged, and one end of the discharging pipe (42) is attached to the inner wall of the processing barrel (2).

5. The antimony-lead alloy processing wastewater treatment device according to claim 4, wherein the fixing plate (22) is attached to the inner wall of the processing cylinder (2), the inner wall of the water inlet frame (3) is circular, and one end of the stirring plate (37) is attached to the inner wall of the water inlet frame (3).

6. The antimony lead alloy processing wastewater treatment device according to claim 5, wherein two ends of the processing barrel (2) are fixedly connected with supporting frames (27), a first fixing rod (23) is fixedly connected between the two supporting frames (27), two ends of the first fixing rod (23) are fixedly connected with a first bevel gear (24), a fourth bevel gear (36) is rotatably connected in the water inlet frame (3), and the fourth bevel gear (36) and the first bevel gear (24) are meshed with each other.

7. The antimony lead alloy processing wastewater treatment device according to claim 6, wherein two ends of each second rotating rod (32) are fixedly connected with second bevel gears (33), the inside of each fourth bevel gear (36) is fixedly connected with a first connecting rod (34), the first connecting rods (34) are rotatably connected with the inside of the water inlet frame (3), one ends of the first connecting rods (34) are fixedly connected with third bevel gears (35), and the third bevel gears (35) and the second bevel gears (33) are meshed with each other.

8. The antimony lead alloy processing wastewater treatment device according to claim 7, wherein second connecting rods (375) are symmetrically arranged in the second rotating rods (32) in a sliding mode, a plurality of first toothed plates (372) are fixedly connected to the surfaces of the second connecting rods (375), the first toothed plates (372) are fixedly connected with the surfaces of stirring plates (37) in a sliding mode, a plurality of second toothed plates (373) are fixedly connected to the surfaces of the stirring plates (37), the second toothed plates (373) are meshed with the first toothed plates (372), and a plurality of filtering holes (374) are formed in the stirring plates (37).

9. The antimony lead alloy processing wastewater treatment device according to claim 8, wherein one end of the second connecting rod (375) is rotationally connected with a connecting rod (379), the other end of the connecting rod (379) is rotationally connected with a driven gear (378), a rotating rod (376) is fixedly connected inside the driven gear (378), the surface of the rotating rod (376) is rotationally connected with the inside of the second rotating rod (32), and a spring (377) is fixedly connected between the surface of the second connecting rod (375) and the inner wall of the second rotating rod (32).

10. The antimony lead alloy processing wastewater treatment device according to claim 9, wherein a second fixing rod (310) is fixedly connected to the inside of the water inlet frame (3), fixing gears (39) are fixedly connected to two ends of the second fixing rod (310), and the fixing gears (39) and driven gears (378) are meshed with each other.