CN114699937A - Waste water recovery treatment equipment is used in insecticide production - Google Patents

Abstract

The invention discloses a wastewater recovery treatment device for insecticide production, which belongs to the technical field of insecticide production and comprises a treatment box, wherein a water inlet pipe is fixedly communicated with the treatment box, the water inlet pipe is fixedly connected with a feed pipe, and a first feed plate, a second feed plate and a third feed plate are sequentially arranged in the feed pipe from top to bottom; the first feeding plate is connected with the feeding pipe in a sliding mode in the left-right direction; the first feeding plate is fixedly connected with a first spring for resetting the first feeding plate; the second feeding plate is rotatably connected with the feeding pipe; the third feeding plate is fixedly connected with a sliding rod, and the sliding rod is connected with the feeding pipe in a sliding mode in the vertical direction; the bottom of the third feeding plate is fixedly connected with a second spring; the bottom end of the second spring is fixedly connected with the water inlet pipe; the third feeding plate is fixedly connected with a one-way valve; the invention can make the waste water treatment better when producing the insecticide.

Description

Waste water recovery treatment equipment is used in insecticide production

Technical Field

The invention relates to the technical field of pesticide production, in particular to a wastewater recovery treatment device for pesticide production.

Background

The insect agent is an agent for killing pests, such as beetles, flies, grubs, noseworms, springtails and nearly ten thousand other pests, and the use of the insect agent successively goes through several stages: natural pesticides and inorganic compounds were first discovered, but they were single acting, large in dose, and short in duration; organic chlorine, organic phosphorus, carbamate and other organic synthetic pesticides are characterized by high efficiency and high residue or low residue, wherein a plurality of varieties have high acute toxicity to mammals, and a large amount of waste water is often generated in the production process of the pesticides, and needs to be purified before being discharged.

Various medicaments are generally required to be used when the waste water generated in pesticide production is treated, but the medicaments are generally manually added after the waste water is filled in a treatment tank when in use, the mixing speed of the medicaments and the waste water is slow, and the manual addition is difficult to control, so that the waste water treatment is incomplete.

Based on the above, the invention designs a wastewater recovery and treatment device for pesticide production, so as to solve the problems.

Disclosure of Invention

The invention aims to provide a device for recycling and treating wastewater for pesticide production, which solves the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme: the waste water recovery and treatment equipment for pesticide production comprises a treatment box, wherein a water inlet pipe is fixedly communicated with the treatment box, the water inlet pipe is fixedly connected with a feed pipe, and a first feeding plate, a second feeding plate and a third feeding plate are sequentially arranged in the feed pipe from top to bottom; the first feeding plate is connected with the feeding pipe in a sliding mode in the left-right direction; the first feeding plate is fixedly connected with a first spring for resetting the first feeding plate; the second feeding plate is rotatably connected with the feeding pipe; the third feeding plate is fixedly connected with a sliding rod, and the sliding rod is connected with the feeding pipe in a sliding mode in the vertical direction; the bottom of the third feeding plate is fixedly connected with a second spring; the bottom end of the second spring is fixedly connected with the water inlet pipe; the third feeding plate is fixedly connected with a one-way valve; a discharge port is formed in the bottom of the right side wall of the feeding pipe, and a water inlet positioned on the left side of the discharge port is formed in the left side wall of the feeding pipe; the water inlet pipe is provided with a driving assembly.

As a further scheme of the invention, the driving assembly comprises a turbine, a first push rod, a limiting block and a first sliding groove; the turbine is rotatably connected to the inside of the water inlet pipe, a rotating shaft of the turbine extends to the outer side of the top of the water inlet pipe and is fixedly connected with a first gear, the first gear is meshed with a second gear, the second gear is rotatably connected with the top of the water inlet pipe, a rotating shaft of the second gear is fixedly connected with a third gear, and the third gear is meshed with a first rack rod; a first wedge block for driving the first rack rod to move backwards and disengage from being meshed with the third gear is arranged on the left side of the first rack rod; the first rack rod is fixedly connected with an L-shaped block, a push plate for driving the L-shaped block to move forwards is arranged on the rear side of the L-shaped block, the push plate is connected with the water inlet pipe in a sliding mode in the front-rear direction, an eighth spring for resetting the push plate is fixedly connected to the push plate, and a third traction rope is fixedly connected to the push plate; the bottom end of the third traction rope penetrates through the front walls of the water inlet pipe and the feed pipe to extend into the feed pipe and is fixedly connected with a pressing plate; the pressing plate is connected with the feeding pipe in a sliding manner; the first rack rod is connected with a first sliding plate in a sliding manner, the first sliding plate is connected with the water inlet pipe in a sliding manner in the left-right direction, and a third spring for resetting the first sliding plate is fixedly connected to the first sliding plate; a first traction rope is fixedly connected to the first sliding plate, and the top end of the first traction rope is fixedly connected with the sliding rod; the first push rod is connected with the first feeding plate, a second push rod for driving the first push rod to move leftwards is arranged on the right side of the first push rod, and the second push rod is fixedly connected with the first sliding plate; the first gear is also meshed with a fourth gear which is rotationally connected with the water inlet pipe, and the fourth gear is meshed with a second rack rod; a second wedge block for driving the second rack rod to move backwards is arranged on the left side of the second rack rod; the second rack rod is connected with a first sliding block in a sliding mode in the left-right direction, the first sliding block is connected with the water inlet pipe in a sliding mode in the front-back direction, a second traction rope is fixedly connected onto the first sliding block, the right end of the second traction rope is fixedly connected with a second sliding block, and the second sliding block is connected with the water inlet pipe in a sliding mode in the left-right direction; a first push block for driving the second slide block to move rightwards is arranged on the side edge of the second slide block; the first push block is connected with a sliding sleeve in a sliding manner, and the sliding sleeve is fixedly connected with the first sliding plate; a ninth spring for resetting the first push block is fixedly connected in the sliding sleeve; a third wedge block for driving the first push block to move forwards is arranged on the right side of the first push block; the right side wall of the second rack rod is connected with a third rack rod in a sliding manner in the front-back direction, and the third rack rod is connected with the feeding pipe in a sliding manner; a fifth gear is meshed with the third rack rod and is fixedly connected with a rotating shaft of the second feeding plate; a fourth spring for resetting the third rack bar is fixedly connected to the third rack bar; the limiting block is connected with the feeding pipe and the water inlet pipe in a sliding manner; the limiting block is positioned above the discharge hole and the water inlet; the rear end of the limiting block extends to the outer side of the rear side wall of the water inlet pipe, and a fifth spring for resetting the limiting block is fixedly connected to the limiting block; the side edge of the limiting block is provided with a fourth wedge-shaped block for driving the limiting block to move towards the rear side, and the fourth wedge-shaped block is connected with the water inlet pipe in a sliding manner; the first sliding chute is arranged at the top of the water inlet pipe, and the shape of the first sliding chute is a parallelogram; sliding connection has the traveller in the first spout, traveller fixedly connected with telescopic link, the front end and the third rack bar fixed connection of telescopic link.

As a further scheme of the invention, the left inner wall and the right inner wall of the feeding pipe are both fixedly connected with sealing blocks matched with the second feeding plate.

As a further aspect of the present invention, the first push rod is connected with the first feeding plate in a sliding manner in the left-right direction; the top of first delivery sheet is provided with and is used for spacing having fixed subassembly to first push rod.

As a further scheme of the invention, the fixing assembly comprises a threaded pressing rod, the bottom end of the threaded pressing rod is in contact with the top of the first push rod, the threaded pressing rod is in threaded connection with the first feeding plate, and the top of the threaded pressing rod is fixedly connected with the screwing block.

As a further scheme of the invention, a torsion spring for resetting the second feeding plate is sleeved on the rotating shaft of the second feeding plate.

As a further scheme of the invention, a sixth spring is fixedly connected to the second sliding block, and the right end of the sixth spring is fixedly connected with the water inlet pipe.

As a further scheme of the invention, a seventh spring is fixedly connected to the side wall of the fourth wedge-shaped block; and the left end of the seventh spring is fixedly connected with the water inlet pipe.

Compared with the prior art, the invention has the beneficial effects that:

1. according to the invention, through the arrangement of the water inlet pipe, the feed pipe, the first feed plate, the second feed plate, the third feed plate and the driving assembly, the turbine can be driven to rotate by wastewater entering the water inlet pipe, when a certain amount of wastewater enters the water inlet pipe, a certain amount of medicament can automatically drop in the first feed pipe, so that the addition of the medicament can be ensured to be more accurate, and the medicament can be ensured to be mixed with wastewater more quickly because the feeding position of the medicament is positioned in the water inlet pipe; when the first feeding plate is opened, the second feeding plate is always in a closed state; when the second feeding plate is opened, the first feeding plate is always in a closed state, and when the second feeding plate is opened, the third feeding plate can discharge the wastewater in the closed space completely, so that the wastewater can not enter an area above the second feeding plate; can guarantee that the region between first delivery sheet and the second delivery sheet keeps dry state forever, can guarantee when using powdered medicament, moist state can not appear in the medicament, can make the medicament can fuse with waste water better.

Drawings

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

FIG. 2 is a drawing; the invention is a schematic diagram of the connection relationship and the position relationship of a feeding pipe, a first feeding plate, a second feeding plate and a third feeding plate;

FIG. 3 is a schematic sectional view of a water inlet pipe and the structure thereon according to the present invention;

FIG. 4 is a schematic view of the water inlet pipe and its upper structure (from back to front view);

FIG. 5 is an enlarged view of a portion A of FIG. 4;

FIG. 6 is a schematic view of a limiting block and a related structure thereof.

In the drawings, the components represented by the respective reference numerals are listed below:

the device comprises a treatment box 1, a water inlet pipe 2, a feed pipe 3, a first feed plate 4, a second feed plate 5, a third feed plate 6, a first spring 7, a sliding rod 8, a second spring 9, a discharge port 11, a water inlet 12, a turbine 13, a first push rod 14, a limiting block 15, a first chute 16, a first gear 17, a second gear 18, a third gear 19, a first rack rod 20, a first wedge-shaped block 21, a first sliding plate 22, a third spring 23, a first traction rope 24, a second push rod 25, a fourth gear 26, a second rack rod 27, a second wedge-shaped block 28, an L-shaped block 29, a first sliding block 30, a second traction rope 31, a second sliding block 32, a first push block 33, a third wedge-shaped block 34, a third rack rod 35, a fifth gear 36, a fourth spring 37, a fifth spring 38, a fourth wedge-shaped block 39, a sliding column 40, a telescopic rod 41, a threaded pressing rod 43, a torsion spring 44, a torsion spring 45, a sealing rod, A sixth spring 46, a seventh spring 47, a push plate 48, an eighth spring 49, a third pull rope 50, a pressure plate 51, a sliding sleeve 52 and a ninth spring 53.

Detailed Description

Referring to fig. 1-6, the present invention provides a technical solution: the waste water recycling and treating equipment for pesticide production comprises a treating box 1, wherein a water inlet pipe 2 is fixedly communicated with the treating box 1, the water inlet pipe 2 is fixedly connected with a feeding pipe 3, and a first feeding plate 4, a second feeding plate 5 and a third feeding plate 6 are sequentially arranged in the feeding pipe 3 from top to bottom; the first feeding plate 4 is connected with the feeding pipe 3 in a sliding manner in the left-right direction; a first spring 7 for resetting the first feeding plate 4 is fixedly connected to the first feeding plate; the second feeding plate 5 is rotatably connected with the feeding pipe 3; the third feeding plate 6 is fixedly connected with a sliding rod 8, and the sliding rod 8 is connected with the feeding pipe 3 in a sliding mode in the vertical direction; the bottom of the third feeding plate 6 is fixedly connected with a second spring 9; the bottom end of the second spring 9 is fixedly connected with the water inlet pipe 2; the third feeding plate 6 is fixedly connected with a one-way valve 10; a discharge port 11 is formed in the bottom of the right side wall of the feeding pipe 3, and a water inlet 12 positioned on the left side of the discharge port 11 is formed in the left side wall of the feeding pipe 3; the water inlet pipe 2 is provided with a driving assembly.

The driving assembly comprises a turbine 13, a first push rod 14, a limiting block 15 and a first sliding groove 16; the turbine 13 is rotatably connected inside the water inlet pipe 2, a rotating shaft of the turbine 13 extends to the outer side of the top of the water inlet pipe 2 and is fixedly connected with a first gear 17, the first gear 17 is meshed with a second gear 18, the second gear 18 is rotatably connected with the top of the water inlet pipe 2, a rotating shaft of the second gear 18 is fixedly connected with a third gear 19, and the third gear 19 is meshed with a first rack rod 20; a first wedge block 21 for driving the first rack bar 20 to move backwards and disengage from the third gear 19 is arranged on the left side of the first rack bar; the first rack bar 20 is fixedly connected with an L-shaped block 29, a push plate 48 for driving the L-shaped block 29 to move forwards is arranged on the rear side of the L-shaped block 29, the push plate 48 is connected with the water inlet pipe 2 in a sliding manner in the front and rear directions, an eighth spring 49 for resetting the push plate 48 is fixedly connected with the push plate 48, and a third traction rope 50 is fixedly connected with the push plate 48; the bottom end of the third traction rope 50 penetrates through the front walls of the water inlet pipe 2 and the feed pipe 3 to extend into the feed pipe 3 and is fixedly connected with a pressing plate 51; the pressing plate 51 is connected with the feeding pipe 3 in a sliding way; the first rack bar 20 is connected with a first sliding plate 22 in a sliding manner, the first sliding plate 22 is connected with the water inlet pipe 2 in a sliding manner in the left-right direction, and a third spring 23 for resetting the first sliding plate 22 is fixedly connected to the first sliding plate 22; a first traction rope 24 is fixedly connected to the first sliding plate 22, and the top end of the first traction rope 24 is fixedly connected with the sliding rod 8; the first push rod 14 is connected with the first feeding plate 4, a second push rod 25 for driving the first push rod 14 to move leftwards is arranged on the right side of the first push rod 14, and the second push rod 25 is fixedly connected with the first sliding plate 22; the first gear 17 is also meshed with a fourth gear 26, the fourth gear 26 is rotatably connected with the water inlet pipe 2, and the fourth gear 26 is meshed with a second rack rod 27; a second wedge block 28 for driving the second rack rod 27 to move backwards is arranged at the left side of the second rack rod; the second rack bar 27 is connected with a first sliding block 30 in a left-right sliding manner, the first sliding block 30 is connected with the water inlet pipe 2 in a front-back sliding manner, a second traction rope 31 is fixedly connected to the first sliding block 30, a second sliding block 32 is fixedly connected to the right end of the second traction rope 31, and the second sliding block 32 is connected with the water inlet pipe 2 in a left-right sliding manner; a first push block 33 for driving the second slide block 32 to move rightwards is arranged on the side edge of the second slide block; the first pushing block 33 is slidably connected with a sliding sleeve 52, and the sliding sleeve 52 is fixedly connected with the first sliding plate 22; a ninth spring 53 for resetting the first pushing block 33 is fixedly connected in the sliding sleeve 52; a third wedge block 34 for driving the first push block 33 to move forwards is arranged at the right side of the first push block 33; a third rack bar 35 is connected to the right side wall of the second rack bar 27 in a sliding manner in the front-rear direction, and the third rack bar 35 is connected with the feeding pipe 3 in a sliding manner; a fifth gear 36 is meshed with the third rack bar 35, and the fifth gear 36 is fixedly connected with a rotating shaft of the second feeding plate 5; a fourth spring 37 for resetting the third rack bar 35 is fixedly connected to the third rack bar; the limiting block 15 is connected with the feeding pipe 3 and the water inlet pipe 2 in a sliding manner; the limiting block 15 is positioned above the discharge port 11 and the water inlet 12; the rear end of the limiting block 15 extends to the outer side of the rear side wall of the water inlet pipe 2, and a fifth spring 38 for resetting the limiting block 15 is fixedly connected to the limiting block 15; a fourth wedge-shaped block 39 used for driving the limiting block 15 to move towards the rear side is arranged on the side edge of the limiting block, and the fourth wedge-shaped block 39 is connected with the water inlet pipe 2 in a sliding mode; the first chute 16 is arranged at the top of the water inlet pipe 2, and the shape of the first chute 16 is a parallelogram; sliding connection has traveller 40 in the first spout 16, traveller 40 fixedly connected with telescopic link 41, the front end and the third rack bar 35 fixed connection of telescopic link 41.

When the scheme is put into practical use; the water inlet pipe 2 is connected to a wastewater inlet pipe, so that wastewater flows into the treatment box 1 through the water inlet pipe 2; when wastewater flows through the water inlet pipe 2, the turbine 13 can be driven to rotate, the turbine 13 can drive the first gear 17 to rotate, the first gear 17 can drive the second gear 18 to rotate, the second gear 18 can drive the third gear 19 to rotate, the third gear 19 can drive the first rack rod 20 to move leftwards, and the first rack rod 20 can drive the first sliding plate 22 to synchronously move leftwards; the first sliding plate 22 drives the second push rod 25 to move leftwards together, when the second push rod 25 moves to be in contact with the first push rod 14, the second push rod 25 drives the first push rod 14 to move leftwards, the first push rod 14 drives the first feeding plate 4 to synchronously move leftwards, and at the moment, the medicament above the first feeding plate 4 falls onto the second feeding plate 5; the first sliding plate 22 also drives the bottom end of the first traction rope 24 to move leftwards together and stretches the third spring 23; the top end of the first traction rope 24 drives the sliding rod 8 and the third feeding plate 6 to move upwards; when the third feeding plate 6 moves upwards to a position above the discharge port 11 and the water inlet 12, a closed space is formed among the feeding pipe 3, the second feeding plate 5 and the third feeding plate 6, and at the moment, the closed space is filled with wastewater; because the second feeding plate 5 can only rotate downwards and cannot rotate upwards, when the third feeding plate 6 moves upwards continuously, the second feeding plate 5 can push the wastewater in the closed space to flow out of the one-way valve 10 into the water inlet pipe 2, when the third feeding plate 6 moves upwards to be in contact with the inclined plane at the bottom of the limiting block 15, the third feeding plate 6 moves upwards continuously to drive the limiting block 15 to move backwards, and when the third feeding plate 6 moves above the limiting block 15, the limiting block 15 moves forwards to return to the initial position under the action of the elastic force of the fifth spring 38; when the third feeding plate 6 moves upwards to be attached to the second feeding plate 5, the waste in the closed space completely flows out; at this time, the first rack bar 20 moves leftwards to a position contacting with the inclined surface of the first wedge 21, the first wedge 21 drives the first rack bar 20 to move backwards a small distance relatively, the first rack bar 20 is disengaged from the third gear 19, and then the first rack bar 20 and the first sliding plate 22 move rightwards under the elastic force of the third spring 23; the first sliding plate 22 drives one end of the first traction rope 24 to move rightwards together, the third feeding plate 6 moves downwards under the action of the elastic force of the second spring 9, after the third feeding plate 6 moves downwards to be in contact with the top surface of the limiting block 15, the limiting block 15 can limit the third feeding plate 6, and the third feeding plate 6 cannot move downwards continuously for a while; after the first sliding plate 22 drives the second push rod 25 to move rightwards, the first feeding plate 4 moves rightwards under the action of the elastic force of the first spring 7 to close the feeding pipe 3 again; when the first sliding plate 22 drives the first pushing block 33 to move rightwards to contact with the side wall of the second sliding block 32, the first pushing block 33 drives the second sliding block 32 to move rightwards, the second sliding block 32 drives the first sliding block 30 to move forwards through the second traction rope 31, the first sliding block 30 drives the second rack rod 27 to move forwards for a short distance, and at the moment, the second rack rod 27 is meshed with the fourth gear 26; when the first pushing block 33 moves rightwards to contact with the third wedge block 34, the third wedge block 34 drives the first pushing block 33 to slide in the sliding sleeve 52 out of contact with the second sliding block 32; the fourth gear 26 can drive the second rack rod 27 to move leftwards, the second rack rod 27 can drive the third rack rod 35 to synchronously move rightwards, the third rack rod 35 can drive the fifth gear 36 to rotate, the fifth gear 36 can drive the second feeding plate 5 to turn downwards, the medicament on the second feeding plate 5 can fall onto the third feeding plate 6, and after the second rack rod 27 moves rightwards to be in contact with the inclined surface of the second wedge 28, the second wedge 28 can act on the second rack rod 27 to move backwards, so that the second rack rod 27 is disengaged from the fourth gear 26; then the third rack bar 35 and the second rack bar 27 are moved rightward by the elastic force of the fourth spring 37; when the third rack bar 35 moves rightwards, the telescopic rod 41 drives the sliding column 40 to slide in the first sliding chute 16, when the second rack bar 27 is disengaged from the fourth gear 26, the spool 40 slides into the rear horizontal groove of the first chute 16, then, in the process that the third rack bar 35 moves rightwards and returns to the initial position, the sliding column 40 is driven to move rightwards in the horizontal groove at the rear side of the first sliding groove 16, at the moment, the telescopic rod 41 drives the fourth wedge-shaped block 39 to move leftwards synchronously, the fourth wedge-shaped block 39 drives the limiting block 15 to move backwards, when the third rack bar 35 moves rightwards to the initial position, the second feeding plate 5 is closed again, the limiting block 15 cancels the limiting of the third feeding plate 6, the third feeding plate 6 will then move downwards under the spring force of the second spring 9 back to the initial position shown in figure 2, the agent on the third feeding plate 6 will then be melted by the waste water and carried into the treatment tank 1; when the third feeding plate 6 moves to the initial position, the L-shaped block 29 is driven to move forward by the pressing plate 51, the third traction rope 50 and the pushing plate 48, and the first rack bar 20 is driven by the L-shaped block 29 to move forward to a position meshed with the third gear 19; then repeating the working process; according to the invention, through the arrangement of the water inlet pipe 2, the feed pipe 3, the first feed plate 4, the second feed plate 5, the third feed plate 6 and the driving assembly, the turbine 13 can be driven to rotate by wastewater entering the water inlet pipe 2, when a certain amount of wastewater enters the water inlet pipe 2, a certain amount of medicament can automatically fall into the feed pipe 3, the addition amount of the medicament can be ensured to be more accurate, and the medicament can be ensured to be mixed with wastewater more quickly when the medicament is put into the water inlet pipe; when the first feeding plate 4 is opened, the second feeding plate 5 is always in a closed state; when the second feeding plate 5 is opened, the first feeding plate 4 is always in a closed state, and when the second feeding plate 5 is opened, the third feeding plate 6 can discharge the wastewater in the closed space completely, so that the wastewater can not enter an area above the second feeding plate 5; can guarantee that the regional dry state of keeping forever between first pay-off board 4 and the second pay-off board 5, can guarantee when using powdered medicament, moist state can not appear in the medicament, can make the medicament can fuse with waste water better.

As a further scheme of the invention, the left inner wall and the right inner wall of the feeding pipe 3 are both fixedly connected with sealing blocks 42 matched with the second feeding plate 5; in operation, the sealing block 42 can be arranged to keep the second feeding plate 5 in a better sealing state.

As a further aspect of the present invention, the first push rod 14 is connected with the first feeding plate 4 in a sliding manner in the left-right direction; the top of the first feeding plate 4 is provided with a fixing component for limiting the first push rod 14; the fixing assembly comprises a thread pressing rod 43, the bottom end of the thread pressing rod 43 is in contact with the top of the first push rod 14, the thread pressing rod is in threaded connection with the first feeding plate 4, and the top of the thread pressing rod 43 is fixedly connected with a screwing block 44; when the device works, the opening size of the first feeding plate 4 can be adjusted by setting the distance between the first push rod 14 and the second push rod 25, and the dosage of the medicament can be controlled; meanwhile, the first push rod 14 and the first feeding plate 4 can be relatively fixed by rotating the threaded pressing rod 43 through the screwing block 44.

As a further scheme of the invention, a torsion spring 45 for resetting the second feeding plate 5 is sleeved on a rotating shaft of the second feeding plate; during operation, the second feeding plate 5 can be kept sealed better through the arrangement of the torsion spring 45.

As a further scheme of the present invention, a sixth spring 46 is fixedly connected to the second slider 32, and a right end of the sixth spring 46 is fixedly connected to the water inlet pipe 2; in operation, the second slider 32 can be better reset by the sixth spring 46.

As a further aspect of the present invention, a seventh spring 47 is fixedly connected to a side wall of the fourth wedge block 39; the left end of the seventh spring 47 is fixedly connected with the water inlet pipe 2; in operation, the fourth wedge 39 can be reset better by the seventh spring 47.

Claims (8)

1. The utility model provides a waste water recovery treatment facility is used in insecticide production, is including handling case (1), it has inlet tube (2), its characterized in that to handle fixed intercommunication on case (1): the water inlet pipe (2) is fixedly connected with a feed pipe (3), and a first feeding plate (4), a second feeding plate (5) and a third feeding plate (6) are sequentially arranged in the feed pipe (3) from top to bottom; the first feeding plate (4) is connected with the feeding pipe (3) in a sliding mode in the left-right direction; a first spring (7) for resetting the first feeding plate (4) is fixedly connected to the first feeding plate; the second feeding plate (5) is rotationally connected with the feeding pipe (3); the third feeding plate (6) is fixedly connected with a sliding rod (8), and the sliding rod (8) is in sliding connection with the feeding pipe (3) in the vertical direction; the bottom of the third feeding plate (6) is fixedly connected with a second spring (9); the bottom end of the second spring (9) is fixedly connected with the water inlet pipe (2); the third feeding plate (6) is fixedly connected with a one-way valve (10); a discharge hole (11) is formed in the bottom of the right side wall of the feeding pipe (3), and a water inlet (12) located on the left side of the discharge hole (11) is formed in the left side wall of the feeding pipe (3); the water inlet pipe (2) is provided with a driving assembly.

2. The wastewater recycling device for pesticide production according to claim 1, characterized in that: the driving assembly comprises a turbine (13), a first push rod (14), a limiting block (15) and a first sliding groove (16); the water inlet pipe is characterized in that the turbine (13) is rotatably connected inside the water inlet pipe (2), a rotating shaft of the turbine (13) extends to the outer side of the top of the water inlet pipe (2) and is fixedly connected with a first gear (17), a second gear (18) is meshed with the first gear (17), the second gear (18) is rotatably connected with the top of the water inlet pipe (2), a third gear (19) is fixedly connected to a rotating shaft of the second gear (18), and a first rack rod (20) is meshed with the third gear (19); a first wedge block (21) for driving the first rack rod (20) to move backwards to be disengaged from the third gear (19) is arranged on the left side of the first rack rod; the first rack rod (20) is fixedly connected with an L-shaped block (29), a push plate (48) used for driving the L-shaped block (29) to move forwards is arranged on the rear side of the L-shaped block (29), the push plate (48) is connected with the water inlet pipe (2) in a sliding mode in the front-rear direction, an eighth spring (49) used for resetting the push plate (48) is fixedly connected with the push plate (48), and a third traction rope (50) is fixedly connected with the push plate (48); the bottom end of the third traction rope (50) penetrates through the front walls of the water inlet pipe (2) and the feed pipe (3) to extend into the feed pipe (3) and is fixedly connected with a pressing plate (51); the pressing plate (51) is connected with the feeding pipe (3) in a sliding way; the first rack rod (20) is connected with a first sliding plate (22) in a sliding mode, the first sliding plate (22) is connected with the water inlet pipe (2) in a sliding mode in the left-right direction, and a third spring (23) used for resetting the first sliding plate (22) is fixedly connected to the first sliding plate (22); a first traction rope (24) is fixedly connected to the first sliding plate (22), and the top end of the first traction rope (24) is fixedly connected with the sliding rod (8); the first push rod (14) is connected with the first feeding plate (4), a second push rod (25) used for driving the first push rod (14) to move leftwards is arranged on the right side of the first push rod (14), and the second push rod (25) is fixedly connected with the first sliding plate (22); the first gear (17) is also meshed with a fourth gear (26), the fourth gear (26) is rotatably connected with the water inlet pipe (2), and the fourth gear (26) is meshed with a second rack rod (27); a second wedge block (28) for driving the second rack rod (27) to move backwards is arranged on the left side of the second rack rod; the second rack rod (27) is connected with a first sliding block (30) in a left-right sliding mode, the first sliding block (30) is connected with the water inlet pipe (2) in a front-rear sliding mode, a second traction rope (31) is fixedly connected to the first sliding block (30), the right end of the second traction rope (31) is fixedly connected with a second sliding block (32), and the second sliding block (32) is connected with the water inlet pipe (2) in a left-right sliding mode; a first push block (33) for driving the second sliding block (32) to move rightwards is arranged on the side edge of the second sliding block; the first push block (33) is connected with a sliding sleeve (52) in a sliding manner, and the sliding sleeve (52) is fixedly connected with the first sliding plate (22); a ninth spring (53) for resetting the first push block (33) is fixedly connected in the sliding sleeve (52); a third wedge block (34) for driving the first push block (33) to move forwards is arranged on the right side of the first push block; the right side wall of the second rack rod (27) is connected with a third rack rod (35) in a sliding mode in the front-rear direction, and the third rack rod (35) is connected with the feeding pipe (3) in a sliding mode; a fifth gear (36) is meshed with the third rack rod (35), and the fifth gear (36) is fixedly connected with a rotating shaft of the second feeding plate (5); a fourth spring (37) for resetting the third rack bar (35) is fixedly connected to the third rack bar; the limiting block (15) is connected with the feeding pipe (3) and the water inlet pipe (2) in a sliding manner; the limiting block (15) is positioned above the discharge hole (11) and the water inlet (12); the rear end of the limiting block (15) extends to the outer side of the rear side wall of the water inlet pipe (2), and a fifth spring (38) for resetting the limiting block (15) is fixedly connected to the limiting block (15); a fourth wedge-shaped block (39) used for driving the limiting block (15) to move towards the rear side is arranged on the side edge of the limiting block, and the fourth wedge-shaped block (39) is connected with the water inlet pipe (2) in a sliding mode; the first sliding chute (16) is formed in the top of the water inlet pipe (2), and the shape of the first sliding chute (16) is a parallelogram; sliding connection has traveller (40) in first spout (16), traveller (40) fixedly connected with telescopic link (41), the front end and third rack bar (35) fixed connection of telescopic link (41).

3. The wastewater recycling device for pesticide production according to claim 1, characterized in that: the inner wall all fixedly connected with on the left and right sides of inlet pipe (3) with the sealed block (42) of second delivery sheet (5) adaptation.

4. The apparatus for recovering and treating wastewater from pesticide production as set forth in claim 2, wherein: the first push rod (14) is connected with the first feeding plate (4) in a sliding mode in the left-right direction; the top of the first feeding plate (4) is provided with a fixing component for limiting the first push rod (14).

5. The wastewater recycling device for pesticide production according to claim 4, characterized in that: the fixing assembly comprises a thread pressing rod (43), the bottom end of the thread pressing rod (43) is in contact with the top of the first push rod (14), the thread pressing rod is in threaded connection with the first feeding plate (4), and the top of the thread pressing rod (43) is fixedly connected with a screwing block (44).

6. The wastewater recycling device for pesticide production according to claim 1, characterized in that: and a torsion spring (45) for resetting the second feeding plate (5) is sleeved on the rotating shaft of the second feeding plate.

7. The wastewater recycling device for pesticide production according to claim 2, characterized in that: and a sixth spring (46) is fixedly connected to the second sliding block (32), and the right end of the sixth spring (46) is fixedly connected with the water inlet pipe (2).

8. The wastewater recycling device for pesticide production according to claim 2, characterized in that: a seventh spring (47) is fixedly connected to the side wall of the fourth wedge block (39); the left end of the seventh spring (47) is fixedly connected with the water inlet pipe (2).

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