CN114471240A - Application of aluminum magnesium silicate suspension injection in pesticide - Google Patents

Abstract

The invention discloses an application of an aluminum magnesium silicate suspension injection agent on pesticides, which comprises a stirring barrel, a machine cover, a stirring barrel mechanism, a plurality of groups of stirring rod assemblies and a driving assembly, wherein the machine cover is arranged on a top port of the stirring barrel in parallel; and the cover is provided with a linkage mechanism, and the linkage mechanism is used for enabling a plurality of groups of stirring rod assemblies which keep rotating at a constant speed to fluctuate along the vertical direction. The aluminum magnesium silicate suspension injection agent provided by the invention is applied to pesticides, and is driven by a driving assembly to rotate in opposite directions by utilizing a mixing drum mechanism and a plurality of groups of mixing rod assemblies so as to realize mixing and enable liquid to form two torrents, so that the plurality of groups of mixing rod assemblies are enabled to show up-and-down change on the path, a central vortex can generate a suction effect in sequence, and nutrient substances in the stratum are wrapped to the upper liquid level.

Description

Application of aluminum magnesium silicate suspension injection in pesticide

Technical Field

The invention relates to an application of an aluminum magnesium silicate suspension injection in pesticides.

Background

The particles of the dispersed phase in the pesticide suspending agent are very small, and a relatively large phase interface and interface energy exist between the dispersed phase and a dispersing medium, so that the pesticide suspending agent is a thermodynamically unstable system between a colloid system and a crude dispersion system. The particles will self-assemble, thereby reducing the interfacial area and the interfacial energy, so that the whole suspension system is destroyed, and a proper dispersant is added, such as the anionic surfactant of sodium dibutylnaphthalenesulfonate, formaldehyde condensate (NNO) of alkyl naphthalenesulfonate, etc.; nonionic surfactants such as aryl phenol polyoxyethylene ether and dodecyl polyvinyl ether phosphate; and macromolecular dispersants such as lignates, which are generally capable of inhibiting irreversible flocculation for ionic surfactants; due to repulsive forces generated by the electric double layer formed at the particle/solution interface; nonionic surfactants and macromolecular dispersants, which are adsorbed onto the surface of the bulk drug particles and form a denser adsorption layer with/steric hindrance 0 interactions that repel the particles from each other; in addition, some polyelectrolytes adsorb on the original drug particles, so that repulsion forces of both steric hindrance 0 and electrostatic interaction exist between the particles. The deflocculation effect of the dispersant in the suspending agent is closely related to the adsorption amount of the dispersant on the raw drug particles, the thickness of an adsorption layer, the stability of adsorption and the like. In some cases, the use of anionic surfactants in combination with nonionic surfactants can alter the thickness of the adsorbent layer, thereby improving the physical stability of the suspension. In order to maintain the physical stability of the pesticide suspending agent, the austenite (Ostwald) aging caused by different solubilities of large crystals and small crystals in the suspending agent is controlled to grow crystals, so that the particle sedimentation is intensified, and the generation of swelling precipitates is promoted. The crystal growth can also be inhibited by selecting a proper dispersing assistant to adsorb the dispersing assistant on the surface of the original drug particles. Therefore, the aluminum magnesium silicate suspension injection can reduce the precipitation or degradation reaction in the pesticide when being applied to agriculture. The specific preparation process comprises mixing, coarse grinding, sanding, sieving, detecting and obtaining the finished product. The raw materials comprise raw pesticide, wetting agent, dispersing agent, defoaming agent, antifreeze agent, magnesium aluminum silicate, thickening agent and water. The raw pesticide is pesticide (weeding, killing insects, sterilizing, etc.).

In the mixing step, the components are required to be put into a stirring container in proportion for mixing and stirring. The stirring modes of the traditional stirring equipment are different in the forms of the spiral blades, but the basic principle is that the spiral blades are driven by a motor to keep rotating at a high speed, or the circuit board rotates forwards and backwards at a preset time to fully and uniformly stir liquid, the stirring mode can only be that a liquid level generates a torrent, and then the spiral blades are enabled to break up the torrent by a reversing motor to uniformly stir. However, the stirring mode has great damage to the motor, and the mode of disturbing the torrent has certain limitation, so that the stirring can be ensured to be relatively uniform.

Disclosure of Invention

The invention aims to provide an application of an aluminum magnesium silicate suspension injection on pesticides, wherein stirred liquid can form two independent directional vortexes in a convection mode, and the liquid is more uniformly slowed by utilizing a mode of two eddy rotational convection.

In order to achieve the above purpose, the invention provides the following technical scheme: the application of the aluminum magnesium silicate suspension injection agent to pesticides comprises a stirring barrel, a machine cover, a stirring barrel mechanism, a plurality of groups of stirring rod assemblies and a driving assembly, wherein the machine cover is arranged on a port at the top of the stirring barrel in parallel; and the cover is provided with a linkage mechanism, and the linkage mechanism is used for enabling a plurality of groups of stirring rod assemblies which keep rotating at a constant speed to fluctuate along the vertical direction.

Preferably, the cover is provided with:

a three-phase asynchronous motor;

and the transmission mechanism enables the output end of the three-phase asynchronous motor to be coupled and connected with the driving assembly.

Preferably, a tenon rod column is arranged at the center of the bottom of the inner side of the stirring barrel, a boring hole is formed in the top of the tenon rod column, and the driving assembly is assembled in the through hole;

the stirring rod assemblies are distributed in a circumferential array mode relative to the tenon rod columns, and are positioned on the inner side of the stirring drum mechanism;

the mixing drum mechanism is fixed in the mixing drum through tenon rod columns.

Preferably, the mixing drum mechanism comprises a sleeve with a drum body part arranged at the center of the bottom of the inner side of the drum body part, and the sleeve is axially and rotatably arranged on the tenon rod column;

the outer wall of barrel portion has been seted up and has been the rectangular hole that the circumference array distributes, and the inner wall of the relative both sides of rectangular hole is provided with respectively:

a first stirring plate extending between the barrel part and the stirring barrel;

a second agitating plate extending between the barrel portion and the agitating bar assembly;

a plurality of groups of flow guide holes are formed in the side walls of the first stirring plate and the second stirring plate;

preferably, a predetermined space is maintained between the cylindrical body and the inner bottom of the stirring barrel, and the bottom of the cylindrical body is provided with a helical blade located in the space.

Preferably, the stirring rod assembly comprises a connecting portion and a trapezoidal stirring rod, a guide slide rod and a limiting rod are symmetrically arranged on the outer wall of one side of the connecting portion, one end of the trapezoidal stirring rod is arranged on the side wall of the connecting portion, and the outer wall of one side of the limiting rod is connected with the outer wall of one side of the trapezoidal stirring rod.

Preferably, the driving assembly comprises a rotating shaft and a holder arranged on the outer wall of the rotating shaft, the rotating shaft is axially and rotatably arranged in the boring hole, the holder is located at the top of the tenon rod column, the outer wall of the holder is provided with an alignment groove inserted into the positioning rod on the stirring rod assembly, the holder is provided with a guide sliding groove distributed close to the rotating shaft, and the guide sliding rod on the stirring rod assembly is located in the guide sliding groove.

Preferably, the driving assembly further comprises a diagonal gear, a notch is formed in the outer wall of the tenon rod column, the diagonal gear is axially and rotatably arranged in the notch, the diagonal gear is respectively meshed with a tooth opening formed in the outer wall of the rotating shaft and a tooth opening formed in the inner wall of the sleeve, and a trapezoidal stirring rod on the stirring rod assembly keeps a preset distance from the outer wall of the sleeve.

Preferably, the linkage mechanism comprises a curved rod and an orbital ring which are arranged at the top of the connecting part, the orbital ring is formed by arranging an upper half part and a lower half part in parallel, and an irregular slide rail groove is formed at the interval between the upper half part and the lower half part;

the outer wall of the cover facing one side of the stirring barrel is provided with an annular depressed part, the track ring is arranged in the depressed part, and one end of the curved rod extends into the depressed part and is in sliding fit with the slide rail groove.

Preferably, the transmission mechanism comprises a worm gear and worm rod piece, a big fluted disc and a small fluted disc, the output end of the three-phase asynchronous motor is connected with a worm on the worm gear and worm rod piece, the big fluted disc is coaxial with a worm wheel on the worm gear and worm rod piece, the big fluted disc is meshed with the small fluted disc, and the small fluted disc is used for driving the rotating shaft to rotate.

In the technical scheme, the application of the aluminum magnesium silicate suspension injection agent provided by the invention in pesticides has the following beneficial effects: set up the churn mechanism and the multiunit stirring rod subassembly of inside and outside distribution in the agitator in the scheme, it orders about by drive assembly, churn mechanism and multiunit stirring rod subassembly direction of rotation are reciprocal, form the convection current vortex according to this, receive link gear when multiunit stirring rod subassembly is rotatory and order about, each stirring rod subassembly can be along vertical direction motion, consequently make multiunit stirring rod subassembly present the state of height fluctuation at rotatory in-process, upwards extract lower floor's liquid according to this, the inboard vortex that is formed by multiunit stirring rod subassembly of remitting, and two strand marginal portion liquid take place alternately in order to realize the purpose of stirring. Compared with the traditional stirring mode, the load of the motor is greatly reduced, and the stirring drum mechanism and the multiple groups of stirring rod assemblies are driven by component force to perform two different actions.

Drawings

In order to more clearly illustrate the embodiments of the present application or technical solutions in the prior art, the drawings required in the embodiments will be briefly described below, it is obvious that the drawings in the following description are only some embodiments described in the present invention, and other drawings can be obtained by those skilled in the art according to these drawings.

FIG. 1 is a schematic overall structure diagram provided in an embodiment of the present invention;

FIG. 2 is a schematic structural diagram of a linkage mechanism according to an embodiment of the present invention;

FIG. 3 is a schematic structural diagram of a linkage mechanism and orbital ring according to an embodiment of the invention;

FIG. 4 is a schematic structural diagram of a mixing drum mechanism according to an embodiment of the present invention;

FIG. 5 is a schematic structural diagram of a driving assembly according to an embodiment of the present invention;

FIG. 6 is a schematic structural view of a stirring rod assembly provided in an embodiment of the present invention;

FIG. 7 is a schematic structural diagram of an orbital ring according to an embodiment of the invention;

fig. 8 is a schematic structural view of the inside of the cover according to the embodiment of the present invention;

FIG. 9 is a schematic structural diagram of a twill gear according to an embodiment of the present invention;

fig. 10 is a schematic cross-sectional view of a sleeve according to an embodiment of the present invention.

Description of reference numerals:

1. a stirring barrel; 11. a tenon post; 2. a machine cover; 4. a mixing drum mechanism; 41. a barrel portion; 411. a rectangular hole; 42. a sleeve; 43. a first stirring plate; 44. a second stirring plate; 45. a flow guide hole; 5. a stirring rod assembly; 51. a connecting portion; 52. a trapezoidal stirring rod; 53. a guide slide bar; 54. a limiting rod; 6. a drive assembly; 61. a rotating shaft; 62. a holder; 621. a positioning groove; 622. a guide chute; 63. a twill gear; 7. A linkage mechanism; 71. a curved bar; 72. an orbital ring; 721. an upper half part; 722. a lower half; 8. a three-phase asynchronous motor; 9. a transmission mechanism; 91. a worm gear rod; 92. a big fluted disc; 93. a small fluted disc.

Detailed Description

In order to make the technical solutions of the present invention better understood, those skilled in the art will now describe the present invention in further detail with reference to the accompanying drawings.

As shown in fig. 1-10, an application of an aluminum magnesium silicate suspension injection agent for pesticides includes a mixing tank 1, a cover 2 disposed on a top port in parallel, a mixing tank mechanism 4, a plurality of mixing rod assemblies 5, and a driving assembly 6, wherein the driving assembly 6 is used for driving the mixing tank mechanism 4 and the mixing rod assemblies 5 to rotate in opposite directions; the cover 2 is provided with a linkage mechanism 7, and the linkage mechanism 7 is used for enabling the multiple groups of stirring rod assemblies 5 which keep rotating at a constant speed to fluctuate along the vertical direction.

Specifically, the churn mechanism 4, the multiunit puddler subassembly 5 in the scheme are the spiral stirring rake, and this both sides screw exists and is driven by drive assembly 6 and drive to keep opposite direction rotatory to realize that the stirring makes liquid form two torrents, be close to the agitator 1 central point put and be close to agitator 1 inner wall position promptly. And the driving component 6 in the above scheme makes the rotation direction of the final output power of the driving component reciprocal by using the gear stirring barrel 1 to transmit. Further, its main effect of the link gear 7 that provides in the scheme is in the rotatory route process of multiunit puddler subassembly 5, makes multiunit puddler subassembly 5 present the change of fluctuation on this route, makes the effect that central vortex can produce the suction in proper order, wraps up the nutrient substance in stratum to upper liquid level.

Set up the churn mechanism 4 and the multiunit stirring rod subassembly 5 of inside and outside distribution in the agitator 1 in the scheme, it orders about by drive assembly 6, churn mechanism 4 and the reciprocal of 5 direction of rotation of multiunit stirring rod subassembly, form the convection current vortex according to this, receive link gear 7 when multiunit stirring rod subassembly 5 is rotatory and order about, each stirring rod subassembly 5 can move along vertical direction, consequently make multiunit stirring rod subassembly 5 present the state of height fluctuation at rotatory in-process, upwards extract lower floor's liquid according to this, in the inboard vortex that is formed by multiunit stirring rod subassembly 5 of influx, and two strand marginal portion liquid take place alternately. Compared with the traditional stirring mode, the load on the motor is greatly reduced, and the stirring cylinder mechanism 4 and the multiple groups of stirring rod assemblies 5 are driven by component force to take two different actions.

Further, as can be seen from fig. 1, 3 and 7, the above solution further includes a three-phase asynchronous motor 8 and a transmission mechanism 9 respectively disposed inside the cover 2, and the transmission mechanism 9 is similar to a medium. The power output by the three-phase asynchronous motor 8 is transmitted to the driving assembly 6 through the transmission mechanism 9, so that the mutual reverse rotation of the mixing drum mechanism 4 and the multiple groups of mixing rod assemblies 5 in the scheme is driven.

As a preferred embodiment provided by the present invention, as can be seen from fig. 4, 5, 6, 7, 8 and 9, the driving assembly 6 includes a rotating shaft 61 and a pan/tilt head 62 disposed on an outer wall of the rotating shaft 61. In the embodiment, the cradle head 6 is located in the middle of the rotating shaft 61, and one end of the rotating shaft 61 is inserted into the boring hole at the top of the tenon rod column 11 at the center of the bottom inside the stirring barrel 1, and the other end is inserted into the inside of the top cover 2. The multiple groups of stirring rod assemblies 5 are distributed in a circumferential array relative to the holder 6, and the holder 6 is in sliding fit, so that the rotating directions of the stirring rod assemblies 5 are consistent with the rotating direction of the holder 6; and the one end that pivot 61 is located the boring is provided with the tooth mouth (fig. 5), and twill gear 63 then assembles the breach department that sets up at tenon post 11 outer wall and is connected with the tooth mouth of pivot 61 meshing, because two then be twill connection, and according to the characteristic of twill gear, twill gear 63 is reciprocal with the direction of rotation of pivot 61, and twill gear 63 then is used for ordering about churn mechanism 4 rotatory, consequently makes this churn mechanism 4 present in the opposite rotation mode of churn subassembly 5.

Further, the stirring rod assembly 5 in the above-mentioned scheme includes the connecting portion 51 and the trapezoidal stirring rod 52, and what has the multi-group geometric shape skeleton on the trapezoidal stirring rod 52 to increase the stirring force in the stirring process. And the trapezoidal shaped stirring rod 52 is integrated with the connection portion 51. As can be seen from fig. 5, the connecting portion 51 is symmetrically provided with the slide guiding rod 53 and the limiting rod 54, and the holder 62 is correspondingly provided with a slide guiding slot 622 distributed near the rotating shaft 61 and an alignment slot 621 located on the side wall. The limiting rod 54 is attached to the outer wall of the trapezoidal stirring rod 52 on the side without the geometric framework, and after the alignment groove 621 is inserted into the limiting rod 54, the guide slide rod 53 is inserted into the guide slide groove 622 to form a line of two points so as to lock the line. Avoiding the occurrence of oscillations thereof on the head 62.

And the outer wall of the trapezoidal stirring rod 52 on the side without the geometric framework is kept at a preset distance from the outer wall of the tenon rod column 11 under the influence of the limiting rod 54.

As a further embodiment of the present invention, as can be seen from fig. 4 and 9, the agitating barrel mechanism 4 includes a sleeve 42 having a barrel 41 disposed at the center of the inner bottom of the barrel 41, and in order to increase the agitating force of the liquid, a rectangular hole 411 is formed in the outer wall of the barrel 41, and a first agitating plate 43 and a second agitating plate 44 protruding to both sides are disposed on the inner walls of the two opposite sides of the rectangular hole 411, respectively, and during the rotation of the barrel 41, the liquid on both sides of the first agitating plate 43 and the second agitating plate 44 is blocked by the first agitating plate 43 and the second agitating plate 44, and convection occurs toward the center, that is, the rectangular hole 411, so as to form convection mixing of the outer vortex. And the side walls of the first stirring plate 43 and the second stirring plate 44 are provided with a plurality of groups of flow guide holes 45, which play a role in scattering convection and then forming turbulent flow, so that the liquid level of the liquid is prevented from rising and splashing to the outside.

Furthermore, the rotation of the barrel 41 is realized by the sleeve 42, the sleeve 42 is sleeved on the outer wall of the tenon rod column 11, the inner wall of the sleeve 42 is provided with a tooth opening (fig. 9), in the scheme, a circular spur gear is additionally arranged below the twill gear 63, the circular spur gear and the twill gear 63 rotate coaxially, and the circular spur gear is meshed with the tooth opening of the sleeve 42 so as to realize transmission.

It should be noted that a predetermined distance is kept between the barrel 41 and the agitator 1, and the helical blades at the bottom of the barrel 41 face the bottom of the inside of the agitator 1, so that when the barrel 41 rotates, the helical blades flow the liquid at the bottom of the agitator 1 toward the barrel wall, so that the surge intersects with the counter-rotating directions of the agitator mechanism 4 and the sets of agitator bar assemblies 5 to form a convective vortex.

Further, the link mechanism 7 in the above-described aspect includes a curved rod 71 and an orbital ring 72 mounted on the top of the connecting portion 41. As can be seen from fig. 2 and 3, the outer wall of the cover 2 facing the mixer drum 1 is provided with an annular recess, and the orbital ring 72 is disposed on the inner wall of the recess, because the orbital ring 72 is composed of an upper half portion 721 and a lower half portion 722 which are disposed in parallel, and the gap between the two forms an irregular track groove. One end of the curved rod 71 is fixed on the top of the connecting part 51, and the other end is located in the slide rail groove. Because the slide rail groove is of a multi-curved-surface structure, when the rotating shaft 61 rotates to enable the holder 62 to drive the trapezoidal stirring rod 52 to rotate, the curved rod 71 slides along the curved surface of the slide rail groove, and after the alignment groove 621 on the connecting portion 41 is inserted into the limiting rod 54, the guide slide rod 53 is inserted into the guide slide groove 622 to form a line of two points, so that the locking is realized, and the trapezoidal stirring rod 52 is ensured not to be dragged by the curved rod 71 and to be inclined. While the change in curvature causes each trapezoidal stirring rod 52 to exhibit a different height drop change.

According to the illustration of fig. 7, since the output force of the output end of the three-phase asynchronous motor 8 in this embodiment is decomposed by the driving assembly 6 and transmitted to the mixing drum mechanism 4 and the plurality of sets of mixing rod assemblies 5 to reverse the rotation direction thereof, a convection vortex is formed. This increases the load on the operation of the three-phase asynchronous motor 8. In order to meet the technical requirements of the embodiment, the output force of the three-phase asynchronous motor 8 is transmitted to the driving assembly 6 through the transmission mechanism 9, the specific structure of the three-phase asynchronous motor comprises a worm gear rod 91, a large fluted disc 92 and a small fluted disc 93, the output end of the three-phase asynchronous motor 8 is connected with a worm on the worm gear rod 91, the large fluted disc 92 is coaxial with a worm gear on the worm gear rod 91, the large fluted disc 92 is meshed with the small fluted disc 93, and the small fluted disc 93 is used for driving the rotating shaft 61 to rotate. Therefore, the mechanical characteristics of the worm gear 91 are utilized to match the gear ratio of the gear, so as to reduce the problem of the operation load of the three-phase asynchronous motor 8. The sleeve 42 is sleeved on the outer wall of the tenon rod column 11, the inner wall of the sleeve 42 is provided with a tooth opening (figure 9), in the scheme, a circular straight gear is additionally arranged below the twill gear 63, the circular straight gear and the twill gear 63 rotate coaxially, and the circular straight gear is meshed with the tooth opening of the sleeve 42 so as to realize transmission

The working principle is as follows:

when the three-phase asynchronous motor 8 drives the rotating shaft 61 to rotate so that the holder 62 drives the trapezoidal stirring rod 52 to rotate, the curved rod 71 slides along the curved surface of the slide rail groove, and after the alignment groove 621 on the connecting part 41 is inserted into the limiting rod 54, the guide slide rod 53 is inserted into the guide slide groove 622 to form a line of two points, so that the trapezoidal stirring rod 52 is locked, and the trapezoidal stirring rod 52 is ensured not to be dragged by the curved rod 71 to incline. Simultaneously, because twill gear 63 then assembles the breach department of seting up at tenon pole post 11 outer wall and the tooth mouth of pivot 61 carries out the meshing and is connected, because two then are the twill and connect, and according to the characteristic of twill gear, the direction of rotation reciprocal of twill gear 63 and pivot 61, and twill gear 63 then is used for ordering about churn mechanism 4 rotatory. And the circular spur gear is additionally arranged below the twill gear 63, the circular spur gear and the twill gear 63 rotate coaxially, and the circular spur gear is meshed with the tooth mouth of the sleeve 42, so that transmission is realized.

While certain exemplary embodiments of the present invention have been described above by way of illustration only, it will be apparent to those of ordinary skill in the art that the described embodiments may be modified in various different ways without departing from the spirit and scope of the invention. Accordingly, the drawings and description are illustrative in nature and should not be construed as limiting the scope of the invention.

Claims (10)

1. The application of the aluminum magnesium silicate suspension injection agent on pesticides comprises a stirring barrel (1) and a cover (2) which is arranged on the top port of the stirring barrel (1) in parallel, and is characterized by further comprising a stirring barrel mechanism (4), a plurality of groups of stirring rod assemblies (5) and a driving assembly (6), wherein the driving assembly (6) is used for driving the stirring barrel mechanism (4) and the stirring rod assemblies (5) to rotate in the opposite directions; the machine cover (2) is provided with a linkage mechanism (7), and the linkage mechanism (7) is used for keeping a plurality of groups of stirring rod assemblies (5) rotating at a constant speed to fluctuate along the vertical direction.

2. The use of a magnesium aluminum silicate suspension injection formulation as claimed in claim 1, wherein said cover (2) is provided with:

a three-phase asynchronous motor (8);

the transmission mechanism (9) enables the output end of the three-phase asynchronous motor (8) to be coupled with the driving component (6).

3. The application of the aluminum magnesium silicate suspension injection agent on pesticides as claimed in claim 1, wherein a tenon rod column (11) is arranged at the center of the bottom of the inner side of the stirring barrel (1), a boring hole is formed in the top of the tenon rod column (11), and the driving assembly (6) is assembled in the through hole;

the multiple groups of stirring rod assemblies (5) are distributed in a circumferential array mode relative to the tenon rod columns (11), and the multiple groups of stirring rod assemblies (5) are located on the inner side of the stirring drum mechanism (4);

the mixing drum mechanism (4) is fixed in the mixing drum (1) through a tenon rod column (11).

4. The application of the aluminum magnesium silicate suspension injection agent on the pesticide as claimed in claim 3, wherein the mixing drum mechanism (4) comprises a sleeve (42) which is arranged at the center of the bottom of the inner side of the barrel body (41) and the sleeve (42) is axially and rotatably arranged on the tenon rod column (11);

rectangular hole (411) that are the circumference array and distribute are seted up to the outer wall of barrel portion (41), and the inner wall of the relative both sides of rectangular hole (411) is provided with respectively:

a first agitating plate (43) extending between the barrel part (41) and the agitating barrel (1);

a second agitating plate (44) extending between the barrel portion (41) and the agitating bar assembly (5);

and a plurality of groups of flow guide holes (45) are formed in the side walls of the first stirring plate (43) and the second stirring plate (44).

5. The application of the aluminum magnesium silicate suspension injection agent on the pesticide as claimed in claim 4, characterized in that a predetermined space is kept between the barrel body (41) and the bottom of the inner side of the stirring barrel (1), and the bottom of the barrel body (41) is provided with a spiral blade positioned in the space.

6. The application of the aluminum magnesium silicate suspension injection agent on pesticide as claimed in claim 3, wherein the stirring rod assembly (5) comprises a connecting part (51) and a trapezoidal stirring rod (52), the outer wall of one side of the connecting part (51) is symmetrically provided with a guide slide rod (53) and a limiting rod (54), one end of the trapezoidal stirring rod (52) is arranged on the side wall of the connecting part (51), and the outer wall of one side of the limiting rod (54) is connected with the outer wall of one side of the trapezoidal stirring rod (52).

7. The application of the aluminum magnesium silicate suspension injection agent on pesticides as claimed in claim 3, wherein the driving assembly (6) comprises a rotating shaft (61) and a holder (62) arranged on the outer wall of the rotating shaft (61), the rotating shaft (61) is axially and rotatably arranged in the boring hole, the holder (62) is located at the top of the tenon rod column (11), an aligning groove (621) inserted into the positioning rod (54) on the stirring rod assembly (5) is formed in the outer wall of the holder (62), a guide chute (622) distributed close to the rotating shaft (61) is formed in the holder (62), and the guide slide rod (53) on the stirring rod assembly (5) is located in the guide chute (622).

8. The application of the aluminum magnesium silicate suspension injection agent on pesticides as claimed in claim 7, wherein the driving assembly (6) further comprises a diagonal gear (63), the outer wall of the tenon rod column (11) is provided with a notch, the diagonal gear (63) is axially and rotatably arranged in the notch, the diagonal gear (63) is respectively meshed with a tooth opening formed in the outer wall of the rotating shaft (61) and a tooth opening formed in the inner wall of the sleeve (42), and a trapezoidal stirring rod (52) on the stirring rod assembly (5) keeps a predetermined distance from the outer wall of the sleeve (42).

9. The application of the aluminum magnesium silicate suspension injection on pesticides as claimed in claim 1, wherein the linkage mechanism (7) comprises a curved rod (71) and an orbital ring (72) which are arranged at the top of the connecting part (41), the orbital ring (72) is formed by an upper half part (721) and a lower half part (722) which are arranged in parallel, and an irregular sliding rail groove is formed between the upper half part and the lower half part;

the outer wall of the cover (2) facing one side of the stirring barrel (1) is provided with an annular depressed part, the track ring (72) is arranged in the depressed part, and one end of the curved rod (71) extends into the depressed part and is in sliding fit with the slide rail groove.

10. The application of the aluminum magnesium silicate suspension injection agent on pesticide as claimed in claim 2, wherein the transmission mechanism (9) comprises a worm and worm rod member (91), a large toothed disc (92) and a small toothed disc (93), the output end of the three-phase asynchronous motor (8) is connected with a worm on the worm and worm rod member (91), the large toothed disc (92) is coaxial with a worm wheel on the worm and worm rod member (91), the large toothed disc (92) is meshed with the small toothed disc (93), and the small toothed disc (93) is used for driving the rotating shaft (61) to rotate.

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