CN115611390A

CN115611390A - Utilize chemical coagulation method to handle auxiliary assembly of industrial waste water

Info

Publication number: CN115611390A
Application number: CN202211343293.4A
Authority: CN
Inventors: 于涛
Original assignee: Weifang Hongtu Environmental Protection Equipment Co ltd
Current assignee: Weifang Hongtu Environmental Protection Equipment Co ltd
Priority date: 2022-10-31
Filing date: 2022-10-31
Publication date: 2023-01-17

Abstract

The invention relates to auxiliary equipment for treating industrial wastewater by using a chemical coagulation method, which comprises a bottom plate (101) and a mixing barrel (103), wherein one end of a water inlet pipe (105) is arranged at an inlet above the mixing barrel (103), and the bottom of the mixing barrel (103) is connected and communicated with one end of a water outlet pipe (106); a first disk (307) disposed within the mixing tub (103), the first disk (307) enabling mixing agitation of wastewater and chemical reagents; the mixing mechanism (300) is installed on the support (102), the mixing mechanism (300) drives a rotating mechanism through a motor (201) to realize the up-and-down swing of the first disc (307) in the mixing barrel (103), and the mixing of the chemical reagent and the wastewater is completed.

Description

Utilize chemical coagulation method to handle auxiliary assembly of industrial waste water

Technical Field

The invention relates to the field of wastewater treatment, in particular to auxiliary equipment for treating industrial wastewater by a chemical coagulation method.

Background

The chemical coagulation method is to add chemical agent into waste water to make fine suspended particles and colloidal particles aggregate into coarser particles for precipitation, so as to separate water from waste water and purify waste water.

In addition, industrial wastewater contains a large amount of heavy metal ions such as copper, chromium, lead and the like, and part of chloride ions and hydrogen ions, so that the harmful ions in the wastewater are treated before sewage discharge, and a chemical method for treating the harmful ions generally comprises the steps of putting a chemical reagent into a wastewater tank, realizing the precipitation of ions and the discharge of gas in the wastewater, and then realizing the separation of precipitates and water, thereby realizing the treatment of the wastewater. However, in the dissolving and reacting processes of the chemical reagent, the treatment efficiency is generally affected by the standing reaction, and the traditional chemical reagent feeding mode is uniform pouring, the chemical reagent dissolving mode is easy to cause non-uniformity of chemical reagent dissolving in the sewage, and the reaction speed is also greatly affected due to the very slow dissolving and diffusing speed.

In addition, in the treatment process of the precipitate, how to quickly and effectively realize the separation of the precipitate and water is always an industrial problem, and the treatment speed of industrial wastewater is directly influenced.

Therefore, aiming at the technical problems, the invention designs the auxiliary equipment for treating the industrial wastewater, which can fully realize the full reaction of the industrial wastewater and the chemical reagent and realize the separation of the precipitate and the wastewater at the highest speed.

Disclosure of Invention

The invention aims to solve the technical problem of providing auxiliary equipment for treating industrial wastewater, which can fully realize the full reaction of the industrial wastewater and a chemical reagent and realize the separation of precipitates and wastewater at the highest speed.

The invention relates to an auxiliary device for treating industrial wastewater by using a chemical coagulation method, which comprises

A base plate to which one ends of a plurality of brackets are fixed;

the mixing barrel is fixed on the bottom plate, one end of a water inlet pipe is arranged at an inlet above the mixing barrel, the water inlet pipe is fixedly connected with the support, and the bottom of the mixing barrel is connected and communicated with one end of a water outlet pipe;

a first disk disposed within the mixing tub, the first disk capable of achieving mixing agitation of wastewater and chemical reagents;

and the mixing mechanism is arranged on the support and drives the rotating mechanism to realize the up-and-down swing of the first disc in the mixing barrel through a motor so as to complete the mixing of the chemical reagent and the wastewater.

The invention relates to an auxiliary device for treating industrial wastewater by using a chemical coagulation method, wherein

The mixing mechanism comprises a motor, an output shaft, a first gear, a second gear, a first rotating shaft, a first crank, a first sleeve, a first rotating shaft, a first C-shaped block, a guide plate, a third gear, a first bevel gear and a rotating plate;

the support is fixedly connected with the motor, an output shaft of the motor is coaxially fixed with the first gear, the first gear is meshed with the second gear, the second gear is coaxially fixed with the first rotating shaft, the first rotating shaft is installed on the support through a bearing, one end of the first rotating shaft is fixedly connected with one end of the first crank, the other end of the first crank is fixedly connected with the first sleeve, one end of the first rotating shaft rotating along the first sleeve is arranged in the first sleeve, the first disc is installed in the middle of the first rotating shaft through a bearing, one side of the outer circumferential surface of the first disc is hinged with the middle of the first C-shaped block, the guide plate moving along the first C-shaped block is arranged in the first C-shaped block, and the guide plate is fixedly connected with the side face of the mixing barrel;

the other end of the first rotating shaft is coaxially fixed with the third gear, the third gear is meshed with the first bevel gear, the first bevel gear is fixedly connected with the bottom of the mixing barrel, and a plurality of rotating plates are fixed on the outer circumferential surface of the middle of the first rotating shaft along the circumferential direction of the outer circumferential surface.

The first rotating shaft also drives a feeding mechanism, and the feeding mechanism comprises a first circular ring, a first arc-shaped plate, a second circular ring, a first through hole, a second C-shaped block, a second through hole, a first pipeline and a concrete box;

the upper side of the first rotating shaft is provided with the first circular ring through a bearing, the outer circumferential surface of the first circular ring is fixedly connected with one end of the first arc-shaped plate, the other end of the first arc-shaped plate is fixedly connected with the outer circumferential surface of the second circular ring, and the second circular ring is arranged on the lower side of the first rotating shaft through a bearing;

the middle part of first arc has been seted up first through-hole, first arc configuration is in and move along it in the second C shape piece, the surface of first arc with the sealed overlap joint in bottom of second C shape piece internal surface, the middle part of second C shape piece has been seted up the second through-hole, the second through-hole with first through-hole can align each other and communicate, the second through-hole with the one end intercommunication of first pipeline, the one end of first pipeline is passed through the bearing and is installed the middle part of second C shape piece, the other end of first pipeline with the bottom fixed connection and the intercommunication of concrete box, the concrete box with the side fixed connection of mixing drum.

The first rotating shaft also drives a feeding mechanism, and the feeding mechanism comprises a first circular ring, a first arc-shaped plate, a second circular ring, a second C-shaped block, a first pipeline, a concrete box, an eighth rotating shaft, a fifth crank and a third arc-shaped plate;

the first arc-shaped plate is arranged in the second C-shaped block and moves along the second C-shaped block, the middle of the second C-shaped block is fixedly connected with one end of an eighth rotating shaft, the other end of the eighth rotating shaft is installed on the side wall of the mixing barrel through a bearing, the middle of the eighth rotating shaft is fixedly connected with one end of a fifth crank, the other end of the fifth crank is fixedly connected with a third arc-shaped plate, the outer surface of the third arc-shaped plate can be in sealing lap joint with one end of a first pipeline, the other end of the first pipeline is fixedly connected and communicated with the bottom of a concrete box, and the concrete box is fixedly connected with the first pipeline.

The invention relates to auxiliary equipment for treating industrial wastewater by using a chemical coagulation method, wherein the intersection point of a first rotating shaft and a first disc is positioned on the extension line of the center of the first rotating shaft.

The invention relates to auxiliary equipment for treating industrial wastewater by using a chemical coagulation method, wherein a hinge direction of a first C-shaped block and a first disc passes through the axis of the first disc.

The invention relates to auxiliary equipment for treating industrial wastewater by using a chemical coagulation method, wherein two structural bodies consisting of a first C-shaped block and a guide plate can be symmetrically distributed at the left and right of the center of a mixing barrel.

The invention relates to auxiliary equipment for treating industrial wastewater by using a chemical coagulation method, wherein a first bevel gear is coaxially arranged with a first rotating shaft.

The invention relates to auxiliary equipment for treating industrial wastewater by using a chemical coagulation method, wherein the section of a guide plate which is arranged on one side of a first C-shaped block and moves is arc-shaped, and the center of the arc coincides with the intersection point of a first rotating shaft and a first disc.

The auxiliary equipment for treating industrial wastewater by using the chemical coagulation method is different from the prior art in that the auxiliary equipment can fully realize the full reaction of the industrial wastewater and a chemical reagent and realize the separation of precipitates and the wastewater at the highest speed.

The auxiliary equipment for treating industrial wastewater by using a chemical coagulation method of the invention is further explained by combining the attached drawings.

Drawings

FIG. 1 is a front view of an auxiliary apparatus for treating industrial wastewater by a chemical coagulation method;

FIG. 2 is an isometric view from a first perspective of an auxiliary apparatus for treating industrial wastewater using chemical coagulation of FIG. 1;

FIG. 3 is a side view of FIG. 1;

FIG. 4 isbase:Sub>A cross-sectional view taken along line A-A of FIG. 1;

FIG. 5 is a cross-sectional view taken along line B-B of FIG. 3;

FIG. 6 is a partial cross-sectional view of FIG. 1;

FIG. 7 is a cross-sectional view taken along line C-C of FIG. 1;

FIG. 8 is an isometric view of FIG. 1 from a second perspective;

fig. 9 is a partial sectional view of fig. 1.

Detailed Description

As shown in FIGS. 1 to 7, an auxiliary apparatus for treating industrial wastewater by chemical coagulation according to the present invention comprises

A base plate 101 on which one ends of a plurality of brackets 102 are fixed;

the mixing barrel 103 is fixed on the bottom plate 101, one end of a water inlet pipe 105 is arranged at an inlet above the mixing barrel 103, the water inlet pipe 105 is fixedly connected with the bracket 102, and the bottom of the mixing barrel 103 is connected and communicated with one end of a water outlet pipe 106;

a first disk 307 disposed inside the mixing tub 103, the first disk 307 enabling mixing agitation of wastewater and chemical agents;

and the mixing mechanism 300 is installed on the bracket 102, and the mixing mechanism 300 drives a rotating mechanism through a motor 201 to realize the up-and-down swinging of the first disc 307 in the mixing barrel 103, so that the mixing of the chemical reagent and the wastewater is completed.

According to the invention, the motor 201 drives each position of the first disc 307 to swing up and down in the mixing barrel 103 through the output shaft 202, so that the first disc 307 fully stirs and mixes the industrial wastewater and the added chemical reagent in the mixing barrel 103 in the swinging process, the chemical reagent fully reacts with ions in the industrial wastewater, gas or precipitate is formed, and the separation of harmful ions and water is realized.

Wherein the number of the racks 102 can be 3, 4, 5, 6, 7, 8, 9, or more.

Wherein, the water inlet pipe 105 is fixedly connected and communicated with the waste water drainage pipeline, thereby facilitating the sewage to be discharged into the mixing barrel 103.

Wherein, the bottom of the mixing barrel 103 is fixedly connected and communicated with one end of the water outlet pipe 106.

The power module of the motor 201 comprises a battery, an electric control module and a wireless communication module, wherein the battery is fixedly connected with the bottom plate 101, and the wireless communication module is wirelessly connected with a user terminal.

According to the invention, through the wireless communication module, a user can smoothly control the rotating speed and the rotating direction of the motor 201, so that the control of the swinging direction and the swinging speed of the first disc 307 is realized.

The rotating mechanism comprises a first gear 301, a second gear 302, a first rotating shaft 303, a first crank 304, a first sleeve 305, a first rotating shaft 306, a first C-shaped block 308, a guide plate 309, a third gear 310, a first bevel gear 311 and a rotating plate 312.

As a further explanation of the present invention, the mixing mechanism 300 includes a motor 201, an output shaft 202, a first gear 301, a second gear 302, a first rotating shaft 303, a first crank 304, a first sleeve 305, a first rotating shaft 306, a first C-block 308, a guide plate 309, a third gear 310, a first bevel gear 311, a rotating plate 312;

the bracket 102 is fixedly connected with the motor 201, the output shaft 202 of the motor 201 is coaxially fixed with the first gear 301, the first gear 301 is engaged with the second gear 302, the second gear 302 is coaxially fixed with the first rotating shaft 303, the first rotating shaft 303 is mounted on the bracket 102 through a bearing, one end of the first rotating shaft 303 is fixedly connected with one end of the first crank 304, the other end of the first crank 304 is fixedly connected with the first sleeve 305, one end of the first rotating shaft 306 rotating along the first sleeve 305 is arranged in the first sleeve 305, the first disc 307 is mounted in the middle of the first rotating shaft 306 through a bearing, one side of the outer circumferential surface of the first disc 307 is hinged with the middle of the first C-shaped block 308, the guide plate 309 moving along the first C-shaped block 308 is arranged in the first C-shaped block 308, and the guide plate 309 is fixedly connected with the side of the mixing barrel 103;

the other end of the first rotating shaft 306 is coaxially fixed with the third gear 310, the third gear 310 is engaged with the first bevel gear 311, the first bevel gear 311 is fixedly connected with the bottom of the mixing barrel 103, and a plurality of rotating plates 312 are fixed on the outer circumferential surface of the middle part of the first rotating shaft 306 along the circumferential direction.

The motor 201 of the present invention drives each orientation of the first disk 307 to swing up and down along the guide plate 309 through the output shaft 202, thereby realizing the mixing of the wastewater and the chemical reagent at each position of the mixing barrel 103, and the first rotating shaft 306 drives the rotating plate 312 to rotate during the process of the up-and-down swing of the first disk 307, thereby further mixing the chemical reagent and the wastewater during the rotation of the rotating plate 312, and thus realizing the full reaction of the wastewater and the chemical reagent.

The motor 201 drives the first gear 301 to rotate synchronously through the output shaft 202, the first gear 301 further drives the second gear 302, the first rotating shaft 303, the first crank 304 and the first sleeve 305 to rotate along the axis of the first rotating shaft 303, the first rotating shaft 306 is further driven to rotate around the axis of the first rotating shaft 303 in the process that the first sleeve 305 rotates along the center of the first rotating shaft 303, the orientation of each position of the first disk 307 is constantly changed due to the perpendicular relationship between the first disk 307 and the first rotating shaft 306, and finally the first disk 307 swings, and in addition, due to the meshing of the third gear 310 and the first bevel gear 311, the first rotating shaft 306 can rotate in the process of revolution, the rotating plate 312 is further driven to rotate around the axis of the first rotating shaft 306, and thus the chemical reagent and the wastewater are fully mixed.

Another deformation of the first rotating shaft 306 with the first disk 307 mounted on the middle portion thereof through a bearing may be that an annular slot is formed in the middle portion of the first rotating shaft 306, and the first disk 307 is coaxially formed with a through hole, and the through hole is disposed in the slot and rotates along the slot.

Wherein the number of the rotating plates 312 can be 3, 4, 5, 6, 7, 8, 9 or more.

As a further explanation of the present invention, the first rotating shaft 306 further drives a feeding mechanism 400, and the feeding mechanism 400 includes a first circular ring 401, a first arc-shaped plate 402, a second circular ring 403, a first through hole 404, a second C-shaped block 405, a second through hole 406, a first pipe 407, and a concrete box 408;

the first circular ring 401 is mounted on the upper side of the first rotating shaft 306 through a bearing, the outer circumferential surface of the first circular ring 401 is fixedly connected with one end of the first arc-shaped plate 402, the other end of the first arc-shaped plate 402 is fixedly connected with the outer circumferential surface of the second circular ring 403, and the second circular ring 403 is mounted on the lower side of the first rotating shaft 306 through a bearing;

the middle of the first arc-shaped plate 402 is provided with a first through hole 404, the first arc-shaped plate 402 is arranged in the second C-shaped block 405 and moves along the second C-shaped block, the outer surface of the first arc-shaped plate 402 is in sealed lap joint with the bottom of the inner surface of the second C-shaped block 405, the middle of the second C-shaped block 405 is provided with a second through hole 406, the second through hole 406 and the first through hole 404 can be aligned and communicated with each other, the second through hole 406 is communicated with one end of the first pipeline 407, one end of the first pipeline 407 is mounted in the middle of the second C-shaped block 405 through a bearing, the other end of the first pipeline 407 is fixedly connected and communicated with the bottom of the concrete box 408, and the concrete box 408 is fixedly connected with the side surface of the mixing barrel 103.

In the process that the first rotating shaft 306 rotates along the axis of the first rotating shaft 303, the first arc-shaped plate 402 and the second C-shaped block 405 are further driven to slide relatively, and finally, the chemical reagent in the concrete box 408 intermittently enters the mixing barrel 103 through the first pipeline 407, so that the chemical reagent and the wastewater are mixed more uniformly.

Wherein, the rotation of the first rotating shaft 306 along the axis of the first rotating shaft 303 changes the distance between the upper end and the lower end of the first rotating shaft 306 and the second C-shaped block 405, when the distance between the upper end of the first rotating shaft 306 and the second C-shaped block 405 is larger, the first arc-shaped plate 402 slides upwards relative to the second C-shaped block 405, otherwise, the first arc-shaped plate 402 slides downwards relative to the second C-shaped block 405, and when the first through hole 404 and the second through hole 406 are aligned with each other during the relative sliding of the first arc-shaped plate 402 and the second C-shaped block 405, the chemical reagent in the concrete box 408 can smoothly enter the mixing barrel 103 through the first pipeline 407, the second through hole 406 and the first through hole 404, whereas when the first through hole 404 and the second through hole 406 are not aligned, the chemical reagent in the concrete box 408 cannot enter the mixing barrel 103, thereby realizing the intermittent addition of the chemical reagent in the mixing barrel 103.

Wherein the first arc plate 402 has an arc profile, and the center of the arc is located at the intersection of the first rotating shaft 306 and the first disc 307.

The side of the first arc-shaped plate 402 is provided with a dovetail-shaped sliding block, and the side of the second C-shaped block 405 is provided with a dovetail-shaped guide rail, so that the first arc-shaped plate 402 is always configured in the second C-shaped block 405 and moves along the second C-shaped block.

As a further explanation of the present invention, the first rotating shaft 306 also drives a feeding mechanism 400, and the feeding mechanism 400 includes a first circular ring 401, a first arc-shaped plate 402, a second circular ring 403, a second C-shaped block 405, a first pipe 407, a concrete box 408, an eighth rotating shaft 409, a fifth crank 410, and a third arc-shaped plate 411;

the first arc-shaped plate 402 is arranged in the second C-shaped block 405 and moves along the second C-shaped block, the middle of the second C-shaped block 405 is fixedly connected with one end of an eighth rotating shaft 409, the other end of the eighth rotating shaft 409 is mounted on the side wall of the mixing barrel 103 through a bearing, the middle of the eighth rotating shaft 409 is fixedly connected with one end of a fifth crank 410, the other end of the fifth crank 410 is fixedly connected with a third arc-shaped plate 411, the outer surface of the third arc-shaped plate 411 can be in sealing lap joint with one end of a first pipeline 407, the other end of the first pipeline 407 is fixedly connected and communicated with the bottom of the concrete box 408, and the concrete box 408 is fixedly connected with the concrete box 408.

As a further explanation of the invention, the intersection of the first spindle 306 and the first disc 307 is located on an extension of the center of the first spindle 303.

As a further explanation of the present invention, the hinge direction of the first C-block 308 and the first disc 317 passes through the axis of the first disc 307.

As a further explanation of the present invention, the structural body composed of the first C-shaped blocks 308 and the guide plates 309 can be symmetrically distributed in two about the center of the mixing tub 103.

The present invention further defines the position of the first disk 307 to ensure the above-mentioned action of the first disk 307.

As a further explanation of the present invention, the first bevel gear 311 is disposed coaxially with the first rotating shaft 303.

The present invention ensures that the third gear 310 is always engaged with the first bevel gear 311.

As a further explanation of the present invention, the guide plate 309 is configured such that a cross-sectional shape of a side moving in the first C-block 308 is an arc, and a center of the arc coincides with an intersection of the first rotating shaft 306 and the first disk 307.

As a further explanation of the present invention, the bottom of the mixing barrel 103 is connected and communicated with one end of the water outlet pipe 106 through a centrifugal filtering mechanism 500, the centrifugal filtering mechanism 500 comprises a first gear ring 501, a filter cartridge 502, a filtering hole 503, a third ring 504, a first annular groove 505, a second pipeline 506, and a first collecting barrel 507;

the first gear 301 is engaged with the first gear ring 501, the first gear ring 501 is coaxially fixed with one end of the filter cartridge 502, the side surface of the filter cartridge 502 is uniformly provided with a plurality of filter holes 503 along the circumferential direction thereof, the bottom of the filter cartridge 502 is rotatably and hermetically connected with one end of the second pipeline 506, the other end of the second pipeline 506 is fixedly connected and communicated with the bottom of the mixing barrel 103, the outer surface of the filter cartridge 502 is coaxially fixed with the third ring 504, the third ring 504 is arranged in the first annular groove 505 and rotates along the first annular groove, the first annular groove 505 is fixedly connected with the inner surface of the first collecting barrel 507, the first collecting barrel 507 is fixedly connected with the bracket 102, and the bottom of the first collecting barrel 507 is fixedly connected and communicated with one end of the water outlet pipe 106.

According to the invention, after the wastewater in the mixing barrel 103 is mixed with the chemical reagent, the wastewater is conveyed into the filter cylinder 502 through the second pipeline 506, and the centrifugal separation of the sediment and the water in the wastewater is realized through the rotation of the filter cylinder 502, so that the separation speed of the wastewater and the sediment is increased.

The motor 201 drives the first gear 301 to rotate synchronously through the output shaft 202, the engagement between the first gear 301 and the first gear 501 drives the first gear 501 and the filter cartridge 502 to rotate along the center of the filter cartridge 502, so that in the rotation process of the filter cartridge 502, the waste water in the filter cartridge 502 can be separated from the sediment through the filter holes 503 under the centrifugal action, and the filtered water can enter the first collection barrel 507 and be discharged through the water outlet pipe 106.

Wherein, a person skilled in the art can control the rotation speed of the filter cartridge 502 by adjusting the gear ratio of the first gear 301 and the first gear ring 501.

The bottom of the filter cartridge 502 is in driving sealing connection with one end of the second pipeline 506 through a bearing and a sealing ring, the bottom of the filter cartridge 502 is coaxially provided with a through hole, and the inner surface of the through hole is in rotatable sealing connection with the outer surface of one end of the second pipeline 506, so that the fully mixed wastewater and chemical reagent in the mixing barrel 103 can enter the filter cartridge 502 through the second pipeline 506.

As a further explanation of the present invention, the motor 201 further drives a cleaning mechanism 600, and the cleaning mechanism 600 includes a fourth gear 601, a second rotating shaft 602, a fifth gear 603, a sixth gear 604, a first square shaft 605, a first square hole 606, a first roller 607, a first guide groove 608, a second guide groove 609, a first guide block 610, a third rotating shaft 611, a second annular groove 612, a fourth annular ring 613, a first connecting rod 614, a third through hole 615, a first guide rod 616, a second collecting barrel 619, a first scraper 620;

the first gear 301 is engaged with the fourth gear 601, the fourth gear 601 is coaxially fixed with one end of the second rotating shaft 602, the second rotating shaft 602 is mounted on the bracket 102 through a bearing, the other end of the second rotating shaft 602 is coaxially fixed with the fifth gear 603, the fifth gear 603 is engaged with the sixth gear 604, the sixth gear 604 is coaxially fixed with the first square shaft 605, one end of the first square shaft 605 is mounted on the bottom plate 101 through a bearing, and the other end of the first square shaft 605 is mounted on the bracket 102 through a bearing;

the first square shaft 605 is disposed in and moves along the first square hole 606, the first square hole 606 is coaxially disposed on the first roller 607, the outer circumferential surface of the first roller 607 is provided with the first screw-shaped guide groove 608 along the circumferential direction thereof, the outer circumferential surface of the first roller 607 is further provided with the second screw-shaped guide groove 609 along the circumferential direction thereof, two ends of the first guide groove 608 and the second guide groove 609 are respectively connected and communicated, the first guide block 610 moving along the first guide groove 608 and the second guide groove 609 is disposed in the first guide groove 608 and the second guide groove 609, the first guide block 610 is mounted at one end of the third rotating shaft 611 through a bearing, and the other end of the third rotating shaft 611 is fixedly connected with the bracket 102;

the second annular groove 612 is annularly formed in the outer circumferential surface of the first roller 607, the fourth annular groove 613 which rotates along the second annular groove 612 is arranged in the second annular groove 612, the fourth annular groove 613 is fixedly connected with one end of the first connecting rod 614, the first connecting rod 614 is provided with the third through hole 615, the first guide rod 616 which moves along the third through hole 615 is arranged in the third through hole 615, one end of the first guide rod 616 is fixedly connected with the bottom plate 101, the other end of the first guide rod 616 is fixedly connected with the bracket 102, the other end of the first connecting rod 614 is fixedly connected with the first scraper 620, the outer circumferential surface of the first scraper 620 is overlapped with the inner circumferential surface of the filter cartridge 502, the inner circumferential surface of the first scraper 620 is overlapped with the outer circumferential surface of the second collecting barrel 619, and the second collecting barrel 619 is fixedly connected with the bracket 102.

According to the invention, the motor 201 drives the first roller 607 to move up and down through the output shaft 202, and simultaneously drives the first scraper 620 to scrape the inner surface of the filter cylinder 502, so that the filter hole 503 is prevented from being blocked by sediment between the filter cylinder 502 and the second collection barrel 619, and the separation speed of the sediment is increased, and in addition, the first scraper 620 moves up and down to push the sediment attached to the inner surface of the filter cylinder 502 to the inlet at the upper end of the second collection barrel 619, so that part of the sediment is collected in the second collection barrel 619.

The motor 201 drives the first gear 301 to rotate through the output shaft 202, and further drives the fourth gear 601, the second rotating shaft 602, the fifth gear 603, the sixth gear 604 and the first square shaft 605 to rotate synchronously through the first gear 301, the first square shaft 605 and the first square hole 606 are arranged to further drive the first roller 607 to rotate, during the rotation of the first roller 607, due to the arrangement of the first guide groove 608, the second guide groove 609 and the first guide block 610, the first roller 607 is further driven to move up and down, and the second annular groove 612, the fourth annular ring 613 and the first link 614 are used to drive the first scraper 620 to move up and down.

The upper end of the second collecting barrel 619 is fixedly connected with one end of a plurality of second connecting rods 617, the other end of the second connecting rods 617 is fixedly connected with one end of a third connecting rod 618, the other end of the third connecting rod 618 is fixedly connected with the bracket 102, and at least three groups of structures formed by the second connecting rods 617 and the third connecting rod 618 are distributed in a central symmetry manner about the axis of the second collecting barrel 619.

The first guide groove 608 has a left-hand thread profile, the second guide groove 609 has a right-hand thread profile, and the thread angles of the two are the same, preferably 35 degrees.

The first guide groove 608 and the second guide groove 609 are communicated with each other at their middle portions in a crossing manner.

The first guide block 610 has a football-shaped or shuttle-shaped profile, so that the above-mentioned operation can be smoothly performed.

The length of the first guide block 610 is greater than the widths of the first guide groove 608 and the second guide groove 609, so that the first guide block 610 is ensured to be configured in the process of moving in the first guide groove 608 or the second guide groove 609, and the direction is only changed when the first guide block reaches the highest point or the lowest point.

The cross-sectional shape of the first square shaft 605 is square, and the cross-sectional shape of the first square hole 606 is square matched with the cross-sectional shape of the first square shaft 605, so that the first square shaft 605 can drive the first roller 607 to rotate synchronously, and the first roller 607 can move up and down along the length direction of the first square shaft 605.

Wherein the second collection tub 619 is configured coaxially with the filter cartridge 502.

The above-mentioned embodiments are merely illustrative of the preferred embodiments of the present invention, and do not limit the scope of the present invention, and various modifications and improvements of the technical solution of the present invention by those skilled in the art should fall within the protection scope defined by the claims of the present invention without departing from the spirit of the present invention.

Claims

1. The utility model provides an utilize auxiliary assembly of chemical coagulation method processing industrial waste water which characterized in that: comprises a bottom plate (101) on which one end of a plurality of brackets (102) is fixed;

the mixing barrel (103) is fixed on the bottom plate (101), one end of a water inlet pipe (105) is arranged at an inlet above the mixing barrel (103), the water inlet pipe (105) is fixedly connected with the support (102), and the bottom of the mixing barrel (103) is connected and communicated with one end of a water outlet pipe (106);

a first disk (307) disposed within the mixing tub (103), the first disk (307) enabling mixing agitation of wastewater and chemical reagents;

the mixing mechanism (300) is installed on the support (102), the mixing mechanism (300) drives a rotating mechanism through a motor (201) to realize the up-and-down swing of the first disc (307) in the mixing barrel (103), and the mixing of the chemical reagent and the wastewater is completed.

2. The auxiliary equipment for treating industrial wastewater by using the chemical coagulation method according to claim 1, wherein the auxiliary equipment comprises:

the mixing mechanism (300) comprises a motor (201), an output shaft (202), a first gear (301), a second gear (302), a first rotating shaft (303), a first crank (304), a first sleeve (305), a first rotating shaft (306), a first C-shaped block (308), a guide plate (309), a third gear (310), a first bevel gear (311) and a rotating plate (312);

the bracket (102) is fixedly connected with the motor (201), an output shaft (202) of the motor (201) is coaxially fixed with the first gear (301), the first gear (301) is engaged with the second gear (302), the second gear (302) is coaxially fixed with the first rotating shaft (303), the first rotating shaft (303) is mounted on the bracket (102) through a bearing, one end of the first rotating shaft (303) is fixedly connected with one end of the first crank (304), the other end of the first crank (304) is fixedly connected with the first sleeve (305), one end of the first rotating shaft (306) rotating along the first sleeve (305) is arranged in the first sleeve (305), the first disc (307) is mounted in the middle of the first rotating shaft (306) through a bearing, one side of the outer circumferential surface of the first disc (307) is hinged with the middle of the first C-shaped block (308), the guide plate (309) moving along the first C-shaped block (308) is arranged in the first C-shaped block (308), and the guide plate (309) is fixedly connected with the side surface of the mixing barrel (103);

the other end of the first rotating shaft (306) is coaxially fixed with the third gear (310), the third gear (310) is meshed with the first bevel gear (311), the first bevel gear (311) is fixedly connected with the bottom of the mixing barrel (103), and a plurality of rotating plates (312) are fixed on the outer circumferential surface of the middle part of the first rotating shaft (306) along the circumferential direction.

3. The auxiliary equipment for treating industrial wastewater by using the chemical coagulation method as claimed in claim 2, wherein:

the first rotating shaft (306) is also driven by a feeding mechanism (400), and the feeding mechanism (400) comprises a first circular ring (401), a first arc-shaped plate (402), a second circular ring (403), a first through hole (404), a second C-shaped block (405), a second through hole (406), a first pipeline (407) and a concrete box (408);

the upper side of the first rotating shaft (306) is provided with the first circular ring (401) through a bearing, the outer circumferential surface of the first circular ring (401) is fixedly connected with one end of the first arc-shaped plate (402), the other end of the first arc-shaped plate (402) is fixedly connected with the outer circumferential surface of the second circular ring (403), and the second circular ring (403) is arranged on the lower side of the first rotating shaft (306) through a bearing;

the middle of the first arc-shaped plate (402) is provided with the first through hole (404), the first arc-shaped plate (402) is arranged in the second C-shaped block (405) and moves along the second C-shaped block, the outer surface of the first arc-shaped plate (402) is in sealing lap joint with the bottom of the inner surface of the second C-shaped block (405), the middle of the second C-shaped block (405) is provided with the second through hole (406), the second through hole (406) and the first through hole (404) can be aligned and communicated with each other, the second through hole (406) is communicated with one end of the first pipeline (407), one end of the first pipeline (407) is mounted in the middle of the second C-shaped block (405) through a bearing, the other end of the first pipeline (407) is fixedly connected and communicated with the bottom of the concrete box (408), and the concrete box (408) is fixedly connected with the side face of the mixing barrel (103).

4. The auxiliary equipment for treating industrial wastewater by using the chemical coagulation method according to claim 2, wherein the auxiliary equipment comprises:

the first rotating shaft (306) is also driven by a feeding mechanism (400), and the feeding mechanism (400) comprises a first circular ring (401), a first arc-shaped plate (402), a second circular ring (403), a second C-shaped block (405), a first pipeline (407), a concrete box (408), an eighth rotating shaft (409), a fifth crank (410) and a third arc-shaped plate (411);

the first arc-shaped plate (402) is arranged in the second C-shaped block (405) and moves along the second C-shaped block, the middle of the second C-shaped block (405) is fixedly connected with one end of an eighth rotating shaft (409), the other end of the eighth rotating shaft (409) is installed on the side wall of the mixing barrel (103) through a bearing, the middle of the eighth rotating shaft (409) is fixedly connected with one end of a fifth crank (410), the other end of the fifth crank (410) is fixedly connected with the third arc-shaped plate (411), the outer surface of the third arc-shaped plate (411) can be in sealed lap joint with one end of the first pipeline (407), the other end of the first pipeline (407) is fixedly connected and communicated with the bottom of the concrete box (408), and the concrete box (408) is fixedly connected with the concrete box.

5. The auxiliary equipment for treating industrial wastewater by using the chemical coagulation method according to claim 3, wherein the auxiliary equipment comprises: the intersection of the first shaft (306) and the first disc (307) is located on an extension of the center of the first shaft (303).

6. The auxiliary equipment for treating industrial wastewater by using the chemical coagulation method as claimed in claim 5, wherein: the hinge direction of the first C-shaped block (308) and the first disc (317) passes through the axle center of the first disc (307).

7. The auxiliary equipment for treating industrial wastewater by using the chemical coagulation method according to claim 6, wherein the auxiliary equipment comprises: the structure body formed by the first C-shaped block (308) and the guide plate (309) can be distributed in two in a left-right symmetrical mode about the center of the mixing barrel (103).

8. The auxiliary equipment for treating industrial wastewater by using the chemical coagulation method according to claim 7, wherein the auxiliary equipment comprises: the first bevel gear (311) is arranged coaxially with the first rotation shaft (303).

9. The auxiliary equipment for treating industrial wastewater by using the chemical coagulation method according to claim 8, wherein the auxiliary equipment comprises: the cross section of the guide plate (309) on the side which is configured to move in the first C-shaped block (308) is arc-shaped, and the center of the arc is coincident with the intersection point of the first rotating shaft (306) and the first disc (307).