CN117125842A - Device for treating industrial wastewater by utilizing microbial remediation technology - Google Patents

Abstract

The invention discloses a device for treating industrial wastewater by utilizing a microbial remediation technology, which comprises an industrial wastewater pipe assembly, wherein a self-driven inner shaft arm assembly is rotatably arranged in the industrial wastewater pipe assembly, a reversing shaft arm assembly is rotatably arranged at the top of the industrial wastewater pipe assembly, a microbial liquid suction cylinder assembly is fixedly arranged at the middle end position of the top of the industrial wastewater pipe assembly, a piston arm assembly is arranged between the reversing shaft arm assembly and the microbial liquid suction cylinder assembly, a reciprocating bacterial liquid suction liquid conveying structure is formed between the piston arm assembly and the microbial liquid suction cylinder assembly, a power reversing driving structure is formed between the self-driven inner shaft arm assembly and the piston arm assembly by the reversing shaft arm assembly, and the self-driven inner shaft arm assembly forms a self-driven leaf shaft structure in the industrial wastewater pipe assembly.

Description

Device for treating industrial wastewater by utilizing microbial remediation technology

Technical Field

The invention belongs to the technical field of industrial wastewater treatment, and particularly relates to a device for treating industrial wastewater by utilizing a microbial remediation technology.

Background

With the rapid development of industry, wastewater pollution is increasingly serious. In order to protect the environment, it is necessary to properly treat industrial wastewater. The industrial waste water treating microbial process is to utilize the metabolism of microbe to convert, degrade and absorb pollutant in waste water to purify water. The treatment method has the advantages of good treatment effect, low cost, simple and convenient operation and the like, and is widely applied to industrial wastewater treatment.

The prior art has the following problems: when industrial wastewater is treated by microorganisms, the cultured microbial bacteria liquid is added into an industrial wastewater bin, the addition amount of the microbial bacteria liquid is determined according to the treatment amount of the industrial wastewater, and when the treatment amount of the industrial wastewater is large, the microbial bacteria liquid is required to be added according to the treatment amount of the industrial wastewater, the existing arrangement is that the industrial wastewater is added firstly and then the microbial bacteria liquid is added according to the amount, and meanwhile stirring is carried out after the addition, the procedure is simple, but the operation is complicated, or the existing adding device is only partially realized by adopting a controllable mode, so that the use and maintenance cost is high, and the problem is continuously solved.

Disclosure of Invention

To solve the problems set forth in the background art. The invention provides a device for treating industrial wastewater by utilizing a microbial remediation technology, which has the characteristics of convenience and reliability.

In order to achieve the above purpose, the invention provides the following technical scheme: the utility model provides an utilize device of microorganism restoration technique processing industrial waste water, includes industrial waste water pipe assembly, the inside rotation of industrial waste water pipe assembly is provided with the interior armshaft subassembly of self-driven, and industrial waste water pipe assembly top rotates and is provided with the switching-over armshaft subassembly, the middle-end position at industrial waste water pipe assembly top is fixed to be provided with microorganism fungus liquid drawing liquid section of thick bamboo subassembly, be provided with the piston arm subassembly between switching-over armshaft subassembly and the microorganism fungus liquid drawing liquid section of thick bamboo subassembly, form reciprocating type fungus liquid drainage formula liquid feeding structure between piston arm subassembly and the microorganism fungus liquid drawing liquid section of thick bamboo subassembly, the switching-over armshaft subassembly forms power switching-over drive structure between interior armshaft subassembly of self-driven and piston arm subassembly, the interior armshaft subassembly of self-driven is at the inside leaf axle structure of industrial waste water pipe assembly, a set of switching-over armshaft subassembly, piston arm subassembly, microorganism fungus liquid drawing liquid section of thick bamboo subassembly and self-driven interior armshaft subassembly form a complete self-adjusting formula liquid feeding unit to industry waste water degradation processing storehouse.

In a preferred scheme of the device for treating industrial wastewater by utilizing a microbial remediation technology, the industrial wastewater water supply pipe assembly comprises an industrial wastewater water supply end pipe, wherein a water inlet side pipe and a water outlet straight pipe are respectively and fixedly arranged at one side and the rear end of the industrial wastewater water supply end pipe, a through hole and a supporting and fixing seat are formed in the top of the industrial wastewater water supply end pipe, a seat with a ring groove and an arc-shaped protection plate are arranged on the periphery of the supporting and fixing seat, a guide vertical sliding rod is arranged on the inner wall of the arc-shaped protection plate, and an inner wall fixing table is fixedly arranged inside the water outlet straight pipe through an inner wall supporting rod;

the reversing shaft arm assembly comprises a reversing guide rail seat table, a reversing shaft lever is fixedly arranged at the bottom of the reversing guide rail seat table, an elliptical guide rail chute is formed in the outer wall of the reversing guide rail seat table, a reversing shaft bevel gear is fixedly arranged at the bottom of the reversing shaft lever, and a reset spring is sleeved outside the reversing guide rail seat table;

the piston arm assembly comprises a piston arm ball seat, a ball slide seat groove and a guide vertical slide groove are respectively formed in the inner wall and the outer wall of the piston arm ball seat, a reversing guide rail convex slide bar is fixedly arranged on the inner wall of the ball slide seat, a piston arm slide bar is fixedly arranged on the outer wall of the piston arm ball seat, a bacterial liquid extracting piston is fixedly arranged at the far end of the piston arm slide bar, and a piston pushing spring is sleeved on a rod body at the far end of the piston arm slide bar;

the microbial liquid extracting cylinder assembly comprises a microbial liquid extracting cylinder, wherein a microbial liquid inlet pipe and a microbial liquid outlet pipe are respectively fixedly arranged at one side and the bottom end of the bottom of the microbial liquid extracting cylinder, a first one-way valve and a second one-way valve are respectively arranged on the microbial liquid inlet pipe and the microbial liquid outlet pipe, and a perforated top table is fixedly arranged at the top of the microbial liquid extracting cylinder through an L-shaped top plate;

the self-driven inner shaft arm assembly comprises a self-driven inner shaft arm rod, a self-driven arm rod bevel gear and a driving wing blade are fixedly arranged at the front end of the self-driven inner shaft arm rod, and a short stirring sheet and a long stirring sheet are fixedly arranged at the rear end of the self-driven inner shaft arm rod.

In a device preferred scheme of utilizing microorganism restoration technique to handle industrial waste water, the switching-over arm axostylus axostyle rotates with the support fixed seat platform through the bearing frame to be connected, switching-over shaft bevel gear is located out the water straight tube, reset spring and switching-over guide rail seat platform are located out the water straight tube outside, from driving interior shaft armed lever through the bearing frame with the fixed bench rotation of inner wall be connected, from driving armed lever bevel gear is located the fixed bench front end of inner wall, short stirring piece and long stirring piece are located the fixed bench rear end of inner wall, from driving armed lever bevel gear and switching-over shaft bevel gear meshing.

In a device preferred scheme for treating industrial wastewater by utilizing a microbial remediation technology, a piston arm ball seat is sleeved outside a reversing guide rail seat table through a ball sliding seat groove, the piston arm ball seat slides up and down outside the reversing guide rail seat table, a reversing guide rail convex sliding rod on the inner wall of the ball sliding seat groove slides in an elliptical guide rail sliding groove in a guiding manner, a guiding vertical sliding rod slides in a guiding vertical sliding groove in a linear manner in a limiting manner, the top of a reset spring is abutted against the bottom end surface of the piston arm ball seat, and the bottom of the reset spring is abutted against a ring-shaped groove with a ring groove seat table.

In a device preferred scheme for treating industrial wastewater by utilizing a microbial remediation technology, the bottom of a bacterial liquid outlet pipe is fixedly arranged at a through hole, the bottom of the bacterial liquid outlet pipe stretches into a straight water outlet pipe, the bottom of the bacterial liquid outlet pipe is arranged at the front ends of a short stirring piece and a long stirring piece, and a plurality of bacterial liquid inlet pipes are communicated with an external bacterial liquid containing cylinder through hoses.

In the preferred scheme of the device for treating industrial wastewater by utilizing the microbial remediation technology, the bacterial liquid extracting piston moves linearly and reciprocally in the microbial bacterial liquid extracting cylinder, a piston arm sliding rod on the bacterial liquid extracting piston and the perforated top table run through and slide, and two ends of the piston pushing spring respectively prop against the perforated top table and the bacterial liquid extracting piston.

In a preferred scheme of the device for treating industrial wastewater by utilizing the microbial remediation technology, the driving fin rotates in the industrial wastewater delivery end pipe, the water inlet side pipe and the water outlet straight pipe form an L-shaped industrial wastewater delivery pipe structure on the industrial wastewater delivery end pipe, the water inlet side pipe is lower than the water outlet straight pipe in position, the water inlet side pipe is opposite to the driving fin, and the far end of the water inlet side pipe is communicated with an external industrial wastewater pressurizing water delivery pump.

In a preferred scheme of the device for treating industrial wastewater by utilizing a microbial remediation technology, a piston type bacterial liquid pumping structure is formed between the piston arm assembly and the microbial bacterial liquid pumping cylinder assembly, the high-pressure industrial wastewater at the water inlet side pipe forms a structure for driving the self-driven inner shaft arm assembly to rotate, and the rotation speed of the self-driven inner shaft arm assembly is related to the water delivery pressure and the water delivery quantity at the water inlet side pipe.

Compared with the prior art, the invention has the beneficial effects that: the invention discloses a self-adjusting type liquid feeding unit, which comprises a group of reversing shaft arm components, a piston arm component, a microbial liquid pumping cylinder component and a self-driving inner shaft arm component, wherein a set of complete self-adjusting type liquid feeding units for feeding industrial wastewater and microbial liquid into an industrial wastewater degradation treatment bin are formed on an industrial wastewater water feeding pipe component, namely, by the self-adjusting type structure, when the industrial wastewater is fed into the industrial wastewater degradation treatment bin through the self-adjusting type liquid feeding unit, synchronous feeding of microbial liquid is simultaneously carried out, meanwhile, water feeding pressure is high, the water feeding quantity of the microbial liquid is high, meanwhile, self-adjustment is realized, meanwhile, the bacterial liquid feeding of the self-adjusting type liquid feeding unit does not need external power driving, the feeding and the feeding quantity of the microbial liquid can be self-adjusted through the water pressure of the industrial wastewater, the far end of a water inlet side pipe is communicated with an external industrial wastewater pressurization water feeding pump, when the industrial wastewater is fed into the industrial wastewater degradation treatment bin through the self-adjusting type liquid feeding device, the self-driving inner shaft arm component is rotationally arranged, the self-driving inner shaft arm component is simultaneously, the self-driving inner shaft arm component is rotationally impacted by the industrial high pressure on a driving blade wing, the self-driving shaft arm component is simultaneously slides on a reversing seat, a reversing seat is arranged on an inner shaft seat, a guide rail, a reversing seat is arranged on the inner shaft seat, and a reversing seat is in a reversing seat, and a guide groove is matched with an outer shaft, and a rotary seat is arranged on the inner shaft, and a reversing seat, and a rotary seat is in the piston, and the position is in the position on the position of the inner guide groove, and a rotary seat, and the type is provided on the type, and is provided with a rotary seat, and a type. When the reversing guide rail seat table rotates, the elliptic guide rail chute drives the piston arm ball seat to reciprocate up and down outside the reversing guide rail seat table through the reversing guide rail convex slide rod, at the moment, the bacterial liquid pumping piston can perform pumping action of up and down action in the microbial liquid pumping cylinder, at the moment, the bacterial liquid inlet pipes are communicated with the bacterial liquid containing cylinder outside through hoses, the bacterial liquid inlet pipes and the bacterial liquid outlet pipes are respectively provided with a first check valve and a second check valve, when the bacterial liquid pumping piston performs upward action in the microbial liquid pumping cylinder, the microbial liquid pumping cylinder component can form pumping action of bacterial liquid, when the bacterial liquid pumping piston performs downward action in the microbial liquid pumping cylinder, the microbial liquid pumping cylinder component can form discharging action of bacterial liquid, at the moment, the bacterial liquid can be smoothly discharged into the water outlet straight pipe, the bottom of the bacterial liquid outlet pipe is arranged at the front ends of the short stirring sheet and the long stirring sheet, after bacterial liquid is discharged into the water outlet straight pipe, the rotation of the self-driven inner shaft arm assembly can drive the short stirring sheet and the long stirring sheet to rotate at the moment, so that the rapid mixing of the microbial bacterial liquid and the industrial wastewater is realized, the subsequent stirring and mixing of the microbial bacterial liquid and the industrial wastewater are not needed, the process is omitted, meanwhile, when the water pressure of the industrial wastewater fed through the water inlet side pipe is larger, the rotation speed of the self-driven inner shaft arm assembly is faster, the frequency of the up-down motion of the piston arm assembly is faster, the times of the pumping in the microbial bacterial liquid pumping cylinder assembly is larger, the feeding amount of the microbial bacterial liquid is increased, namely, when the water pressure of the industrial wastewater is larger, the feeding amount of the microbial bacterial liquid is larger in unit time at the moment, thereby realizing self-adaptive synchronous liquid feeding between industrial wastewater and microbial liquid.

Drawings

FIG. 1 is a perspective view of the invention in use;

FIG. 2 is a perspective view of the invention;

FIG. 3 is a cross-sectional view of the invention;

FIG. 4 is an exploded view of the invention;

FIG. 5 is a perspective view of an inventive industrial wastewater feed tube assembly;

FIG. 6 is a cross-sectional view of an inventive industrial wastewater feed tube assembly;

FIG. 7 is a perspective view of the reversing shaft arm assembly, the piston arm assembly and the microbial liquid cartridge assembly of the present invention;

FIG. 8 is a perspective view of the reversing lever arm assembly of the present invention;

FIG. 9 is a perspective view of the piston arm assembly of the present invention;

FIG. 10 is a perspective view of an inventive microbial liquid cartridge assembly;

FIG. 11 is a perspective view of the self-driving inner axle arm assembly of the present invention;

in the figure: 100. an industrial wastewater feed pipe assembly; 101. industrial waste water delivering end pipe; 102. a water inlet side pipe; 103. a straight water outlet pipe; 104. seat with ring groove; 105. a support fixing seat; 106. arc-shaped protection plates; 107. guiding the vertical sliding rod; 108. a through hole; 109. an inner wall strut; 110. an inner wall fixing table; 200. a reversing shaft arm assembly; 201. a reversing guide rail seat; 202. an elliptical guide rail chute; 203. a reversing arm shaft lever; 204. a reversing shaft bevel gear; 205. a return spring; 300. a piston arm assembly; 301. a piston arm ball seat; 302. guiding vertical sliding grooves; 303. convex slide bar of reversing guide rail; 304. a ball slide groove; 305. a piston arm slide bar; 306. a bacterial liquid pumping piston; 307. a piston pushing spring; 400. a microbial liquid extracting cylinder assembly; 401. a microorganism bacterium liquid extracting cylinder; 402. an L-shaped top plate; 403. a top platform with holes; 404. a bacterial liquid outlet pipe; 405. a second one-way valve; 406. a bacterial liquid inlet pipe; 407. a first one-way valve; 500. a self-driving inner axle arm assembly; 501. self-driving inner shaft arm lever; 502. a self-driven arm lever bevel gear; 503. driving the wing leaves; 504. short stirring sheets; 505. long stirring sheets; 600. and an industrial wastewater degradation treatment bin.

Detailed Description

The following description of the technical solutions in the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is apparent that the described embodiments are only some embodiments of the present invention, not all embodiments. All other embodiments, based on the embodiments of the invention, which would be apparent to one of ordinary skill in the art without making any inventive effort are intended to be within the scope of the invention.

Referring to fig. 1-11, the present invention provides a device for treating industrial wastewater by using a microbial remediation technology, which includes an industrial wastewater pipe assembly 100, a self-driven inner shaft arm assembly 500 rotatably disposed inside the industrial wastewater pipe assembly 100, a reversing shaft arm assembly 200 rotatably disposed at the top of the industrial wastewater pipe assembly 100, a microbial liquid suction tube assembly 400 fixedly disposed at a middle end of the top of the industrial wastewater pipe assembly 100, a piston arm assembly 300 disposed between the reversing shaft arm assembly 200 and the microbial liquid suction tube assembly 400, a reciprocating type bacteria liquid suction type liquid feeding structure formed between the piston arm assembly 300 and the microbial liquid suction tube assembly 400, a power reversing driving structure formed between the reversing shaft arm assembly 200 and the piston arm assembly 300, a self-driven leaf shaft structure formed inside the industrial wastewater pipe assembly 100 by the self-driven inner shaft arm assembly 500, and a set of reversing shaft arm assembly 200, a piston arm assembly 300, a microbial liquid suction tube assembly 400 and the self-driven inner shaft arm assembly 500 forming a complete set of self-regulating unit for degrading industrial wastewater in a complete cabin.

In a preferred embodiment, referring to fig. 5 to 8, an industrial wastewater pipe assembly 100 includes an industrial wastewater pipe 101, a water inlet side pipe 102 and a water outlet straight pipe 103 are fixedly arranged at one side and the rear end of the industrial wastewater pipe 101, a through hole 108 and a supporting and fixing seat base 105 are arranged at the top of the industrial wastewater pipe 101, a seat base 104 with a ring groove and an arc protection plate 106 are arranged at the periphery of the supporting and fixing seat base 105, a guide vertical sliding rod 107 is arranged on the inner wall of the arc protection plate 106, and an inner wall fixing seat 110 is fixedly arranged inside the water outlet straight pipe 103 through an inner wall supporting rod 109;

the reversing shaft arm assembly 200 comprises a reversing guide rail seat 201, a reversing arm shaft lever 203 is fixedly arranged at the bottom of the reversing guide rail seat 201, an elliptical guide rail chute 202 is formed in the outer wall of the reversing guide rail seat 201, a reversing shaft bevel gear 204 is fixedly arranged at the bottom of the reversing arm shaft lever 203, and a reset spring 205 is sleeved outside the reversing guide rail seat 201;

the self-driving inner shaft arm assembly 500 comprises a self-driving inner shaft arm 501, a self-driving arm bevel gear 502 and a driving wing 503 are fixedly arranged at the front end of the self-driving inner shaft arm 501, and a short stirring blade 504 and a long stirring blade 505 are fixedly arranged at the rear end of the self-driving inner shaft arm 501.

In this embodiment, the reversing arm shaft 203 is rotatably connected to the support fixing base 105 through a bearing housing, the reversing shaft bevel gear 204 is located inside the straight water pipe 103, and the return spring 205 and the reversing guide base 201 are located outside the straight water pipe 103.

Next, please refer to fig. 11.

The self-driving inner shaft arm 501 is rotatably connected with the inner wall fixing table 110 through a bearing seat, the self-driving arm bevel gear 502 is positioned at the front end of the inner wall fixing table 110, the short stirring blade 504 and the long stirring blade 505 are positioned at the rear end of the inner wall fixing table 110, the self-driving arm bevel gear 502 and the reversing shaft bevel gear 204 are meshed, the driving wing 503 rotates in the industrial wastewater delivery end pipe 101, the water inlet side pipe 102 and the water outlet straight pipe 103 form an L-shaped industrial wastewater delivery pipeline structure on the industrial wastewater delivery end pipe 101, the water inlet side pipe 102 is lower than the position of the water outlet straight pipe 103, the water inlet side pipe 102 is opposite to the driving wing 503, and the far end of the water inlet side pipe 102 is communicated with an external industrial wastewater pressurizing delivery pump.

In this embodiment, the impact force of the industrial wastewater is converted into the rotational force of the self-driving inner arm assembly 500 by the cooperation of the above-described structure, and the self-rotation of the reversing arm assembly 200 is achieved by the cooperation of the self-driving inner arm assembly 500 and the reversing arm assembly 200.

In a preferred embodiment, referring to fig. 7 and 9, the piston arm assembly 300 includes a piston arm ball seat 301, a ball sliding seat 304 and a guiding vertical sliding groove 302 are respectively formed in the inner wall and the outer wall of the piston arm ball seat 301, a reversing guide rail convex sliding rod 303 is fixedly arranged on the inner wall of the ball sliding seat 304, a piston arm sliding rod 305 is fixedly arranged on the outer wall of the piston arm ball seat 301, a bacterial liquid pumping piston 306 is fixedly arranged at the distal end of the piston arm sliding rod 305, and a piston pushing spring 307 is sleeved on the distal rod body of the piston arm sliding rod 305.

In this embodiment, the piston arm ball seat 301 is sleeved outside the reversing guide rail seat 201 through the ball sliding seat groove 304, the piston arm ball seat 301 slides up and down outside the reversing guide rail seat 201, the reversing guide rail convex sliding rod 303 on the inner wall of the ball sliding seat groove 304 slides in the elliptical guide rail sliding groove 202 in a guiding manner, the guiding vertical sliding rod 107 slides in the guiding vertical sliding groove 302 in a linear limiting manner, the top of the reset spring 205 is abutted against the bottom end surface of the piston arm ball seat 301, and the bottom of the reset spring 205 is abutted against the annular groove of the annular groove seat 104.

The rotational force generated from the inner shaft-arm assembly 500 is converted into the pumping action of the piston-arm assembly 300 to reciprocate up and down by the cooperation of the reversing shaft-arm assembly 200 and the piston-arm ball seat 301.

Still further, referring to fig. 9 and 10, the microbial liquid and liquid extracting tube assembly 400 includes a microbial liquid and liquid extracting tube 401, a liquid inlet tube 406 and a liquid outlet tube 404 are respectively and fixedly arranged at one side and bottom end of the bottom of the microbial liquid and liquid extracting tube 401, a first check valve 407 and a second check valve 405 are respectively arranged on the liquid inlet tube 406 and the liquid outlet tube 404, and a perforated top table 403 is fixedly arranged at the top of the microbial liquid and liquid extracting tube 401 through an L-shaped top plate 402.

The bottom of the bacterial liquid outlet pipe 404 is fixedly arranged at the through hole 108, the bottom of the bacterial liquid outlet pipe 404 stretches into the water outlet straight pipe 103, the bottom of the bacterial liquid outlet pipe 404 is arranged at the front ends of the short stirring piece 504 and the long stirring piece 505, the bacterial liquid inlet pipes 406 are communicated with an external bacterial liquid containing cylinder through hoses, the bacterial liquid drawing piston 306 linearly reciprocates in the microbial liquid drawing cylinder 401, the piston arm sliding rod 305 on the bacterial liquid drawing piston 306 and the perforated top table 403 run through and slide, and two ends of the piston pushing spring 307 respectively abut against the perforated top table 403 and the bacterial liquid drawing piston 306.

In this embodiment, the up-and-down reciprocating pumping and draining actions of the piston arm assembly 300 are used for pumping and draining the microbial liquid inside the microbial liquid pumping cylinder assembly 400.

In a preferred embodiment, please refer to fig. 3, 5 and 8, 9 and 10.

In this embodiment, the outside cover of reversing guide seat 201 is equipped with reset spring 205, reset spring 205's top is contradicted on piston arm ball seat 301 bottom end face, and reset spring 205's bottom is contradicted in the annular recess of taking annular seat 104, through reset spring 205's top, guarantee the complex reliability and the hugging nature between piston arm ball seat 301 and the reversing guide seat 201 inner structure, avoid the cooperation unreliable that the slippage leads to, the cover is equipped with piston pushing spring 307 on the piston arm slide bar 305 distal end body simultaneously, piston pushing spring 307's both ends are contradicted respectively on foraminiferous top platform 403 and bacterial liquid pull piston 306, through the effect of piston pushing spring 307, realize bacterial liquid pull piston 306 at microbial liquid pull cylinder 401 the steadiness of activity from top to bottom, simultaneously when carrying out the discharge of microbial bacterial liquid, guarantee the smoothness of bacterial liquid pull piston 306 to bacterial liquid press discharge.

The working principle of the invention is as follows: the invention discloses a group of steering shaft arm components 200, piston arm components 300, microbial bacteria liquid pumping cylinder components 400 and self-driven inner shaft arm components 500 form a complete set of self-adjusting liquid feeding units for feeding industrial wastewater and bacteria liquid into an industrial wastewater degradation treatment bin 600 on an industrial wastewater feeding pipe component 100, namely, through the self-adjusting structure, when industrial wastewater is fed into the industrial wastewater degradation treatment bin 600 through the invention, synchronous feeding of microbial bacteria liquid is simultaneously carried out, meanwhile, water feeding pressure is high, water feeding quantity of the industrial wastewater is high, meanwhile, the feeding quantity of the microbial bacteria liquid is also high, self-adjusting is realized, meanwhile, the bacterial liquid feeding is driven by external power, the water pressure of the industrial wastewater can be carried out, the working principle is as follows, the distal end of a water feeding side pipe 102 is communicated with an external industrial wastewater pressurizing water feeding pump, when the industrial wastewater is fed into the industrial wastewater degradation treatment bin 600 through the invention, the industrial wastewater feeding pipe component 100 is internally rotated and provided with the self-driven inner shaft arm components 500, the high-pressure pair of driving bevel blade wings are simultaneously fed, the inner shaft arm components are rotatably driven by the self-driving bevel arm components 500, the inner shaft components are rotatably arranged on a reversing seat arm shaft seat component and a rotary seat, a rotary seat type bevel shaft sleeve component is rotatably arranged on an inner shaft sleeve component 201, a reversing shaft seat is provided with a rotary seat, a sliding seat is provided with a guide rail, a groove is provided on an outer shaft seat, a guide rail is provided with a groove, a guide rail is provided, a groove is provided, and a guide seat is provided, and a sleeve is provided, and a sleeve, a sleeve is provided, and has a sleeve, and has is provided. Meanwhile, the guide vertical sliding rod 107 slides in the guide vertical sliding groove 302 in a linear limit manner, through the cooperation of the structure, when the reversing guide seat 201 rotates, the elliptical guide sliding groove 202 drives the piston arm ball seat 301 to reciprocate up and down outside the reversing guide seat 201 through the reversing guide convex sliding rod 303, at the moment, the bacterial liquid pumping piston 306 performs pumping action of up and down in the microbial liquid pumping cylinder 401, at the moment, the bacterial liquid inlet pipes 406 are communicated with an external bacterial liquid containing cylinder through hoses, the bacterial liquid inlet pipes 406 and the bacterial liquid outlet pipes 404 are respectively provided with a first check valve 407 and a second check valve 405, when the bacterial liquid pumping piston 306 performs upward action in the microbial liquid pumping cylinder 401, the microbial liquid pumping cylinder assembly 400 can form pumping action of bacterial liquid, when the bacterial liquid pumping piston 306 performs downward action in the microbial liquid pumping cylinder 401, the microbial liquid can be smoothly discharged into the straight water pipe 103 after being discharged into the straight water pipe 103, the bottom of the microbial liquid outlet pipe 404 is arranged at the front ends of the short stirring piece 504 and the long stirring piece 505, the rotation of the self-driven inner shaft arm assembly 500 can drive the short stirring piece 504 and the long stirring piece 505 to rotate after the microbial liquid is discharged into the straight water pipe 103, the rapid mixing of the microbial liquid and the industrial wastewater is realized, the subsequent stirring and mixing of the microbial liquid and the industrial wastewater are not needed, the process is omitted, the rotation speed of the self-driven inner shaft arm assembly 500 is higher when the water pressure of the industrial wastewater fed through the water inlet side pipe 102 is higher, the frequency of the up-down motion of the piston arm assembly 300 is higher, the number of times of pumping and discharging in the microbial liquid pumping barrel assembly 400 is higher, the feeding amount of the microbial liquid is increased, when the water pressure of the industrial wastewater is larger, the water quantity fed in unit time is larger, and the microbial liquid quantity fed in unit time is larger, so that the self-adaptive synchronous liquid feeding between the industrial wastewater and the microbial liquid is realized.

Although embodiments of the invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (8)

1. An apparatus for treating industrial wastewater by utilizing a microbial remediation technology, comprising an industrial wastewater feed pipe assembly (100), characterized in that: the industrial wastewater pipe assembly (100) is internally provided with a self-driven inner shaft arm assembly (500) in a rotating manner, the top of the industrial wastewater pipe assembly (100) is provided with a reversing shaft arm assembly (200) in a rotating manner, the middle end of the top of the industrial wastewater pipe assembly (100) is fixedly provided with a microbial liquid pumping cylinder assembly (400), a piston arm assembly (300) is arranged between the reversing shaft arm assembly (200) and the microbial liquid pumping cylinder assembly (400), a reciprocating bacterial liquid pumping liquid conveying structure is formed between the piston arm assembly (300) and the microbial liquid pumping cylinder assembly (400), the reversing shaft arm assembly (200) forms a power reversing driving structure between the self-driven inner shaft arm assembly (500) and the piston arm assembly (300), the self-driven inner shaft arm assembly (500) forms a self-driven leaf shaft structure inside the industrial wastewater pipe assembly (100), and a group of reversing shaft arm assembly (200), the piston arm assembly (300), the microbial liquid pumping cylinder assembly (400) and the self-driven inner shaft arm assembly (500) form a self-regulating wastewater treatment complete wastewater treatment unit on the industrial wastewater pipe assembly (100).

2. An apparatus for treating industrial wastewater using a microbial remediation technology according to claim 1, wherein: the industrial wastewater delivery pipe assembly (100) comprises an industrial wastewater delivery end pipe (101), a water inlet side pipe (102) and a water outlet straight pipe (103) are respectively and fixedly arranged at one side and the rear end of the industrial wastewater delivery end pipe (101), a through hole (108) and a supporting and fixing seat table (105) are arranged at the top of the industrial wastewater delivery end pipe (101), a ring groove seat table (104) and an arc protection plate (106) are arranged at the periphery of the supporting and fixing seat table (105), a guide vertical sliding rod (107) is arranged on the inner wall of the arc protection plate (106), and an inner wall fixing table (110) is fixedly arranged inside the water outlet straight pipe (103) through an inner wall supporting rod (109);

the reversing shaft arm assembly (200) comprises a reversing guide rail seat table (201), a reversing arm shaft lever (203) is fixedly arranged at the bottom of the reversing guide rail seat table (201), an elliptical guide rail sliding groove (202) is formed in the outer wall of the reversing guide rail seat table (201), a reversing shaft bevel gear (204) is fixedly arranged at the bottom of the reversing arm shaft lever (203), and a reset spring (205) is sleeved outside the reversing guide rail seat table (201);

the piston arm assembly (300) comprises a piston arm ball seat (301), a ball sliding seat groove (304) and a guide vertical sliding groove (302) are respectively formed in the piston arm ball seat (301) and on the outer wall of the piston arm ball seat, a reversing guide rail convex sliding rod (303) is fixedly arranged on the inner wall of the ball sliding seat groove (304), a piston arm sliding rod (305) is fixedly arranged on the outer wall of the piston arm ball seat (301), a bacterial liquid drawing piston (306) is fixedly arranged at the far end of the piston arm sliding rod (305), and a piston pushing spring (307) is sleeved on the far end rod body of the piston arm sliding rod (305);

the microbial liquid and bacterial liquid extracting cylinder assembly (400) comprises a microbial liquid and bacterial liquid extracting cylinder (401), a bacterial liquid inlet pipe (406) and a bacterial liquid outlet pipe (404) are respectively fixedly arranged at one side and the bottom end of the bottom of the microbial liquid and bacterial liquid extracting cylinder (401), a first one-way valve (407) and a second one-way valve (405) are respectively arranged on the bacterial liquid inlet pipe (406) and the bacterial liquid outlet pipe (404), and a perforated top table (403) is fixedly arranged at the top of the microbial liquid and bacterial liquid extracting cylinder (401) through an L-shaped top plate (402);

the self-driving inner shaft arm assembly (500) comprises a self-driving inner shaft arm rod (501), a self-driving arm rod bevel gear (502) and driving wing blades (503) are fixedly arranged at the front end of the self-driving inner shaft arm rod (501), and a short stirring blade (504) and a long stirring blade (505) are fixedly arranged at the rear end of the self-driving inner shaft arm rod (501).

3. An apparatus for treating industrial wastewater using a microbial remediation technology according to claim 2, wherein: the reversing arm shaft lever (203) is rotationally connected with the supporting and fixing seat table (105) through a bearing seat, the reversing shaft bevel gear (204) is positioned in the water outlet straight pipe (103), the reset spring (205) and the reversing guide rail seat table (201) are positioned outside the water outlet straight pipe (103), the self-driven inner shaft arm lever (501) is rotationally connected with the inner wall fixing table (110) through the bearing seat, the self-driven arm lever bevel gear (502) is positioned at the front end of the inner wall fixing table (110), the short stirring piece (504) and the long stirring piece (505) are positioned at the rear end of the inner wall fixing table (110), and the self-driven arm lever bevel gear (502) and the reversing shaft bevel gear (204) are meshed.

4. An apparatus for treating industrial wastewater using a microbial remediation technology according to claim 2, wherein: the piston arm ball seat (301) is sleeved outside the reversing guide rail seat table (201) through the ball sliding seat groove (304), the piston arm ball seat (301) slides up and down outside the reversing guide rail seat table (201), the reversing guide rail convex sliding rod (303) on the inner wall of the ball sliding seat groove (304) slides in the elliptical guide rail sliding groove (202) in a guiding mode, the guiding vertical sliding rod (107) slides in the guiding vertical sliding groove (302) in a linear limiting mode, the top of the reset spring (205) is abutted to the bottom end face of the piston arm ball seat (301), and the bottom of the reset spring (205) is abutted to the annular groove of the annular groove seat table (104).

5. An apparatus for treating industrial wastewater using a microbial remediation technology according to claim 2, wherein: the utility model discloses a fungus liquid drain pipe, including fungus liquid drain pipe (404), fungus liquid drain pipe (404) bottom is fixed to be set up in through-hole (108), and in fungus liquid drain pipe (404) bottom stretches into play water straight tube (103), the bottom of fungus liquid drain pipe (404) sets up in the front end of short stirring piece (504) and long stirring piece (505), a plurality of fungus liquid feed liquor pipe (406) are held a section of thick bamboo intercommunication through hose and outside fungus liquid.

6. An apparatus for treating industrial wastewater using a microbial remediation technology according to claim 2, wherein: the bacterial liquid drawing piston (306) moves linearly and reciprocally in the microbial liquid drawing cylinder (401), a piston arm sliding rod (305) on the bacterial liquid drawing piston (306) and the perforated top table (403) penetrate and slide, and two ends of the piston pushing spring (307) respectively prop against the perforated top table (403) and the bacterial liquid drawing piston (306).

7. An apparatus for treating industrial wastewater using a microbial remediation technology according to claim 2, wherein: the driving fin blade (503) rotates in the industrial wastewater delivery end pipe (101), the water inlet side pipe (102) and the water outlet straight pipe (103) form an L-shaped industrial wastewater delivery pipe structure on the industrial wastewater delivery end pipe (101), the position of the water inlet side pipe (102) is lower than that of the water outlet straight pipe (103), the water inlet side pipe (102) is opposite to the driving fin blade (503), and the far end of the water inlet side pipe (102) is communicated with an external industrial wastewater pressurizing water delivery pump.

8. An apparatus for treating industrial wastewater using a microbial remediation technology according to claim 2, wherein: a piston type bacterial liquid pumping and draining structure is formed between the piston arm assembly (300) and the microbial bacterial liquid pumping and draining cylinder assembly (400), high-pressure industrial wastewater at the water inlet side pipe (102) forms a structure for driving the self-driving inner shaft arm assembly (500) to rotate, and the rotation speed of the self-driving inner shaft arm assembly (500) is related to water delivery pressure and water delivery quantity at the water inlet side pipe (102).