CN115178131A

CN115178131A - Mixing arrangement is used in potassium peroxydisulfate composite powder production

Info

Publication number: CN115178131A
Application number: CN202210897211.4A
Authority: CN
Inventors: 陈黄实
Original assignee: Zhongkebaike Tianjin Biopharmaceutical Co ltd
Current assignee: Zhongkebaike Tianjin Biopharmaceutical Co ltd
Priority date: 2022-07-28
Filing date: 2022-07-28
Publication date: 2022-10-14

Abstract

The utility model provides a mixing arrangement is used in potassium peroxydisulfate composite powder production, the first gear of every second connecting rod one end respectively with the meshing transmission of sixth ring gear, the baffle is established respectively to every second connecting rod other end, establish first solid fixed ring on the support frame, the slide bar is connected with the center pin one end of rotating the installation in the backup pad, first inner skleeve and second inner skleeve bottom are provided with respectively and are located the inside rabbling mechanism of urceolus down. According to the invention, materials are added into the material inlet, enter the upper material storage barrel, are stirred to flow into the first through hole of the lower material storage barrel, other materials are continuously added into the material inlet, are stored in other first through holes of the lower material storage barrel, after the baffle is opened, the materials are fully and uniformly stirred after passing through the separation plate, after the lower baffle disc is opened and is stirred by the stirring rod, the potassium hydrogen persulfate composite material flows out from the bottom of the discharge hole of the lower outer barrel, so that various materials can be fully and uniformly mixed, and the stirring efficiency is improved.

Description

Mixing arrangement is used in potassium peroxydisulfate compound powder production

Technical Field

The invention belongs to the technical field of potassium hydrogen persulfate preparation equipment, and particularly relates to a mixing device for producing potassium hydrogen persulfate composite powder.

Background

Potassium hydrogen sulfate is an inorganic peroxide, also called potassium peroxymonosulfate, and is combined with potassium hydrogen sulfate and potassium sulfate to form a tri-salt, so that the potassium peroxymonosulfate is called potassium monopersulfate composite salt, can provide super-strong and effective non-oxychlorination potential and microbial efficiency, is widely applied to the fields of industrial production and disinfection, and has the characteristics of good storage stability, safe and convenient use and the like.

Potassium hydrogen persulfate generally is according to the mixture of sulfuric acid and sulphuric acid and potassium carbonate according to certain proportion carry out the reaction and prepare, need stir in the preparation process in order to ensure that the reaction carries out completely, among the current device, only rely on the motor to drive the stirring rake and mix the stirring, and stirring efficiency is low, and the mixing uniformity is poor, difficult misce bene.

Disclosure of Invention

The technical problem to be solved by the invention is to overcome the defects of the prior art and provide a mixing device for producing potassium hydrogen persulfate composite powder, which is uniform in mixing and high in stirring efficiency.

The technical scheme for solving the technical problems is as follows: an upper outer cylinder is arranged at the upper end of the lower outer cylinder, second connecting rods are uniformly and rotatably connected to the circumferential direction of the side wall of the upper outer cylinder, a first gear at one end of each second connecting rod is respectively in meshing transmission with a sixth gear ring at the bottom of a second fixing ring, a fifth gear ring at the upper part of the second fixing ring is in meshing transmission with a second gear connected with an output shaft of a stepping motor, the other end of each second connecting rod is respectively provided with a baffle plate, a support plate is arranged inside the second fixing ring, a first fixing ring in sliding connection with a slide bar is arranged on a support frame on the support plate, the slide bar is connected with one end of a central shaft rotatably arranged on the support plate, a first inner sleeve is clamped on the outer circumference of the central shaft, a second inner sleeve is arranged on the outer circumference of the first inner sleeve, and a stirring mechanism positioned inside the lower outer cylinder is respectively arranged at the bottoms of the first inner sleeve and the second inner sleeve; the outer circumference of the second inner sleeve is provided with a third inner sleeve, a feeding port communicated with the upper storage barrel is arranged on the supporting plate, a driving lever for pushing materials in the upper storage barrel to a first through hole in the lower storage barrel is arranged on the outer circumference of the third inner sleeve, the plurality of baffles are arranged at the outlet end of the first through hole, one end of the third inner sleeve is provided with a second gear ring connected with the adjusting mechanism, the other end of the third inner sleeve is provided with a separating plate, and the separating plate is positioned below the baffles and above the stirring mechanism.

Further, the stirring mechanism is: first inner skleeve one end is provided with first ring gear, the outer circumferencial direction of the other end evenly is provided with the puddler, and second inner skleeve one end is provided with the third ring gear, and the outer circumferencial direction of the other end evenly is provided with the stirring frame, and first ring gear and third ring gear are connected with adjustment mechanism respectively.

Furthermore, a clamping groove which is clamped with the stirring rod in the vertical direction is processed on the outer circumference of the second inner sleeve.

Further, the rotation direction of the first gear ring is opposite to the rotation direction of the third gear ring.

Furthermore, center pin bottom and inserted bar one end joint, the inserted bar other end passes through spring and head rod internal connection, the tooth of the outer circumference of inserted bar and the outer circumference of head rod tooth meshing, the outer circumference of inserted bar is provided with the lower fender dish that is located puddler and agitator below.

Furthermore, the outer circumference of the first connecting rod is provided with a stirring blade, and the stirring blade is positioned at an inner outlet of the lower outer barrel.

Furthermore, the outer circumference of the upper end of the upper storage cylinder is provided with a fourth gear ring connected with the adjusting mechanism, and a second through hole communicated with the first through hole in the lower storage cylinder is processed on the bottom plate of the upper storage cylinder.

Furthermore, the inner circumference of the first fixing ring is provided with an upper slide rail and a lower slide rail which are respectively connected with the slide bar in a sliding manner, the upper slide rail is positioned above the lower slide rail, and the side wall of the first fixing ring is provided with an inserting block which is communicated with the upper slide rail and the lower slide rail.

Further, the adjusting mechanism is: an output shaft of the motor on the supporting plate is in transmission connection with a third inner sleeve through a first belt, a second gear ring on the outer circumference of the third inner sleeve is in meshing transmission with a fourth gear, a fifth connecting shaft on the supporting frame is provided with a first helical gear, the fourth gear is provided with a second helical gear in meshing transmission with the first helical gear, the second helical gear is provided with a third connecting shaft and a fourth connecting shaft, two ends of the third connecting shaft and the fourth connecting shaft are in threaded connection, the fifth connecting shaft is in transmission connection with a sixth connecting shaft through a fourth belt, and one end of the sixth connecting shaft is provided with a third gear in meshing transmission with the first gear ring and the third gear ring respectively; the threaded connection part of the third connecting shaft and the fourth connecting shaft is in transmission connection with a second connecting shaft on the second incomplete gear through a third belt, the second connecting shaft is in transmission connection with a first connecting shaft on the first incomplete gear and a seventh connecting shaft on the third incomplete gear through the second belt, and the first incomplete gear, the second incomplete gear and the third incomplete gear are in meshing transmission with a fourth gear ring respectively.

According to the invention, materials are added into the material inlet, enter the upper storage barrel, are stirred to flow into the first through hole of the lower storage barrel, other materials are continuously added into the material inlet, are stored in other first through holes of the lower storage barrel, after the baffle is opened, the materials are fully and uniformly stirred after passing through the separation plate, after the lower baffle disc is opened and is stirred by the stirring rod, the potassium hydrogen persulfate composite material flows out from the bottom of the discharge hole of the lower outer barrel, so that various materials can be fully and uniformly mixed, and the stirring efficiency is improved.

Drawings

FIG. 1 is a schematic structural view of an embodiment of a mixing apparatus for producing potassium hydrogen persulfate composite powder according to the present invention.

Fig. 2 is a schematic view of the internal structure of fig. 1.

Fig. 3 is a schematic structural view of fig. 1 with the upper outer cylinder 7 and the lower outer cylinder 8 removed.

FIG. 4 is a schematic view of the structure of lower cartridge 14 and upper cartridge 24.

Fig. 5 is a schematic view of the structure of fig. 4 from another angle.

FIG. 6 is a schematic view of the lower cartridge 14 of FIG. 4.

Figure 7 is a schematic view of the third inner sleeve 16, separating plate 17.

FIG. 8 is a schematic view of the upper cartridge 24 of FIG. 4.

Fig. 9 is a bottom view of fig. 8.

Fig. 10 is a schematic structural view of the first fixing ring 5 in fig. 1.

Fig. 11 is a schematic view of the structure of fig. 10 from another angle.

Fig. 12 is a schematic view of the connection structure of the first inner sleeve 10, the second inner sleeve 11, the stirring rod 18 and the stirring rack 30.

Figure 13 is a schematic view of the first inner sleeve 10 and the stirring rod 18 of figure 12.

Figure 14 is a schematic view of the second inner sleeve 11 and the agitator frame 30 of figure 12.

Fig. 15 is a schematic structural view of the plunger 20 of fig. 3.

Fig. 16 is a schematic structural view of the insertion rod 20 and the stirring blade 23 in fig. 3.

Fig. 17 is a schematic structural view of the upper outer cylinder 7 and the support plate 38.

Fig. 18 is a schematic structural view of the second fixing ring 27.

Fig. 19 is a schematic structural view of the adjustment mechanism 1 in fig. 1.

Fig. 20 is a schematic view of the structure of fig. 19 from another angle.

Reference numerals are as follows: 1. an adjustment mechanism; 101. a motor; 102. a first belt; 103. a second belt; 104. a first incomplete gear; 105. a first connecting shaft; 106. a third gear; 107. a first helical gear; 108. a second helical gear; 109. a fourth gear; 110. a third belt; 111. a second incomplete gear;

112. a second connecting shaft; 113. a third connecting shaft; 114. a fourth connecting shaft; 115. a fifth connecting shaft;

116. a fourth belt; 117. a sixth connecting shaft; 118. a third incomplete gear; 119. a seventh connecting shaft; 2. a support frame; 3. a slide bar; 4. a central shaft; 5. a first retaining ring; 6. a feeding port; 7. an outer barrel is arranged; 8. a lower outer cylinder; 9. a first ring gear; 10. a first inner sleeve; 11. a second inner sleeve; 13. a first through hole; 14. a lower storage barrel; 15. a baffle plate; 16. a third inner sleeve; 17. a separation plate; 18. a stirring rod; 19. a lower baffle disc; 20. inserting a rod; 21. a first connecting rod; 22. a spring; 23. a stirring blade; 24. an upper storage cylinder; 25. a second ring gear; 26. a third ring gear; 27. a second retaining ring; 28. a first gear; 29. a second connecting rod; 30. a stirring frame; 31. a deflector rod; 32. a fourth ring gear; 33. a second through hole; 34. inserting a block; 35. an upper slide rail; 36. a lower slide rail; 37. a card slot; 38. a support plate; 39. a fifth ring gear; 40. a sixth ring gear; 41. a second gear.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

The mixing device for producing the oxone complex powder in this embodiment is formed by connecting an adjusting mechanism 1, a support frame 2, a slide bar 3, a central shaft 4, a first fixing ring 5, a feeding port 6, an upper outer cylinder 7, a lower outer cylinder 8, a first gear ring 9, a first inner sleeve 10, a second inner sleeve 11, a first through hole 13, a lower storage cylinder 14, a baffle 15, a third inner sleeve 16, a separating plate 17, a stirring rod 18, a lower baffle disc 19, an inserted rod 20, a first connecting rod 21, a spring 22, a stirring blade 23, an upper storage cylinder 24, a second gear ring 25, a third gear ring 26, a second fixing ring 27, a first gear 28, a second connecting rod 29, a stirring frame 30, a driving rod 31, a fourth gear ring 32, a second through hole 33, an inserted block 34, an upper slide rail 35, a lower slide rail 36, a clamping groove 37, a support plate 38, a fifth gear ring 39, a sixth gear ring 40, and a second gear 41.

As shown in fig. 1 to 9 and 17 to 18, an upper outer cylinder 7 is fixedly mounted at the upper end of a lower outer cylinder 8, second connecting rods 29 are uniformly and rotatably connected to the side wall of the upper outer cylinder 7 in the circumferential direction, a first gear 28 at one end of each second connecting rod 29 is respectively in meshing transmission with a sixth gear ring 40 at the bottom of a second fixing ring 27, an output shaft of a stepping motor is connected with a second gear 41, a fifth gear ring 39 at the upper part of the second fixing ring 27 is in meshing transmission with the second gear 41, a baffle 15 is respectively and fixedly connected to the other end of each second connecting rod 29, a supporting plate 38 is fixedly mounted inside the second fixing ring 27, a first fixing ring 5 slidably connected with a slide bar 3 is fixedly mounted on a supporting frame 2 on the supporting plate 38, the slide bar 3 is connected with one end of a central shaft 4 rotatably mounted on the supporting plate 38, a first inner sleeve 10 is clamped on the outer circumference of the central shaft 4, a second inner sleeve 11 is mounted on the outer circumference of the first inner sleeve 10, and a stirring mechanism located inside the lower outer cylinder 8 is respectively mounted at the bottoms of the first inner sleeve 10 and the second inner sleeve 11.

A third inner sleeve 16 is mounted on the outer circumference of the second inner sleeve 11, a feeding port 6 communicated with the upper storage barrel 24 is mounted on the supporting plate 38, a shifting lever 31 for pushing the material in the upper storage barrel 24 to the first through hole 13 in the lower storage barrel 14 is mounted on the outer circumference of the third inner sleeve 16, the plurality of baffles 15 are located at the outlet end of the first through hole 13, a second gear ring 25 connected with the adjusting mechanism 1 is fixedly mounted at one end of the third inner sleeve 16, a separating plate 17 is fixedly mounted at the other end of the third inner sleeve 16, and the separating plate 17 is located below the baffles 15 and above the stirring mechanism. A fourth gear ring 32 connected with the adjusting mechanism 1 is installed on the outer circumference of the upper end of the upper storage cylinder 24, and a second through hole 33 communicated with the first through hole 13 in the lower storage cylinder 14 is processed on the bottom plate of the upper storage cylinder 24.

As shown in fig. 10 to 11, an upper slide rail 35 and a lower slide rail 36 respectively connected to the slide bar 3 are formed on the inner circumference of the first fixing ring 5, the upper slide rail 35 is located above the lower slide rail 36, and an insertion block 34 is movably mounted on the side wall of the first fixing ring 5, wherein the upper slide rail 35 is communicated with the lower slide rail 36.

As shown in fig. 12 to 14, the stirring mechanism is: first inner skleeve 10 one end fixed mounting has first ring gear 9, and the even fixed mounting of first inner skleeve 10 other end outer circumferencial direction has

puddler

18, and 11 one end fixed mounting of second inner skleeve has third ring gear 26, and the even fixed mounting of 11 other ends outer circumferencial direction has a stirring frame 30, and first ring gear 9 and third ring gear 26 are connected with adjustment mechanism 1 respectively, and the outer circumference of 11 second inner skleeves is processed there is the draw-in groove 37 with puddler 18 in the vertical direction joint. The direction of rotation of the first ring gear 9 is opposite to the direction of rotation of the third ring gear 26.

As shown in fig. 15 to 16, the bottom of the central shaft 4 is engaged with one end of the insert rod 20, the other end of the insert rod 20 is connected to the inside of the first connecting rod 21 through the spring 22, the teeth on the outer circumference of the insert rod 20 are engaged with the teeth on the outer circumference of the first connecting rod 21, and the outer circumference of the insert rod 20 is provided with the lower stop disc 19 located below the stirring rod 18 and the stirring rack 30. The outer circumference of the first connecting rod 21 is fixedly provided with a stirring blade 23, and the stirring blade 23 is positioned at the inner outlet of the lower outer cylinder 8.

As shown in fig. 19 to 20, the adjusting mechanism 1 is formed by coupling a motor 101, a first belt 102, a second belt 103, a first incomplete gear 104, a first connecting shaft 105, a third gear 106, a first helical gear 107, a second helical gear 108, a fourth gear 109, a third belt 110, a second incomplete gear 111, a second connecting shaft 112, a third connecting shaft 113, a fourth connecting shaft 114, a fifth connecting shaft 115, a fourth belt 116, a sixth connecting shaft 117, a third incomplete gear 118 and a seventh connecting shaft 119, and the adjusting mechanism 1 is: the supporting plate 38 is fixedly provided with a motor 101, an output shaft of the motor 101 is in transmission connection with the third inner sleeve 16 through a first belt 102, a second gear ring 25 on the outer circumference of the third inner sleeve 16 is in meshing transmission with a fourth gear 109, a fifth connecting shaft 115 on the supporting frame 2 is fixedly provided with a first helical gear 107, the fourth gear 109 is fixedly provided with a second helical gear 108 in meshing transmission with the first helical gear 107, the second helical gear 108 is fixedly provided with a third connecting shaft 113 and a fourth connecting shaft 114, and the third connecting shaft 113 is in threaded connection with two ends of the fourth connecting shaft 114. The fifth connecting shaft 115 is in transmission connection with a sixth connecting shaft 117 through a fourth belt 116, and one end of the sixth connecting shaft 117 is fixedly provided with a third gear 106 which is in meshing transmission with the first gear ring 9 and the third gear ring 26 respectively. The threaded connection between the third connecting shaft 113 and the fourth connecting shaft 114 is in transmission connection with a second connecting shaft 112 on the second incomplete gear 111 through a third belt 110, the second connecting shaft 112 is in transmission connection with a seventh connecting shaft 119 on the first connecting shaft 105 and the third incomplete gear 118 on the first incomplete gear 104 respectively through a second belt 103, and the first incomplete gear 104, the second incomplete gear 111 and the third incomplete gear 118 are in meshing transmission with the fourth gear ring 32 respectively.

The working principle of the embodiment is as follows: (1) feeding: the first material is added into the feeding port 6, the material enters the upper storage barrel 24, the motor 101 is started, the output shaft of the motor 101 drives the third inner sleeve 16 to rotate through the first belt 102, the third inner sleeve 16 drives the second gear ring 25 to rotate, the second gear ring 25 drives the fourth gear 109 to rotate, the fourth gear 109 drives the second helical gear 108 to rotate, the second helical gear 108 drives the third connecting shaft 113 and the fourth connecting shaft 114 which are in threaded connection at two ends to rotate, the rotating speed of the second connecting shaft 112 is adjusted by changing the width of the third belt 110 at the joint of the third connecting shaft 113 and the fourth connecting shaft 114, the second connecting shaft 112 drives the first connecting shaft 105 and the seventh connecting shaft 119 to rotate through the second belt 103, the second connecting shaft 112 drives the second incomplete gear 111, the first connecting shaft 105 drives the first incomplete gear 104, the seventh connecting shaft 119 drives the third incomplete gear 118 to mesh with the fourth gear ring 32 of the upper storage barrel 24 respectively to drive the upper storage barrel 24 to rotate, the storage material 31 on the third inner sleeve 16 rotates the material, the material in the upper toggle barrel 24 flows into the through hole 33 of the second inner sleeve, the material flows into the through hole 13 of the second storage barrel, and other materials are stored in the outlet end 13 of the first storage barrel 13, and the first material storage barrel 13, and the other materials are blocked in the first through hole 13.

(2) Stirring and mixing: the output shaft of step motor drives second gear 41 and rotates, second gear 41 drives the solid fixed ring of second 27 rotation with the meshing transmission of fifth ring gear 39, the sixth ring gear 40 on the solid fixed ring of second 27 respectively with the first gear 28 meshing transmission that the circumference distributes, the solid fixed ring of second 27 drives second connecting rod 29 through first gear 28 and rotates, second connecting rod 29 drives baffle 15 motion, baffle 15 is opened, each material in all first through-holes 13 of lower storage cylinder 14 flows out, various materials are behind pivoted separation plate 17, flow to rabbling mechanism.

The second bevel gear 108 drives the fifth connecting shaft 115 to rotate through the first bevel gear 107, the fifth connecting shaft 115 drives the sixth connecting shaft 117 to rotate through the fourth belt 116, the sixth connecting shaft 117 drives the first gear ring 9 and the third gear ring 26 to rotate, the rotating direction of the first gear ring 9 is opposite to that of the third gear ring 26, the first gear ring 9 drives the first inner sleeve 10 to rotate, the first inner sleeve 10 drives the stirring rod 18 to rotate, the third gear ring 26 drives the second inner sleeve 11 to rotate, the second inner sleeve 11 drives the stirring frame 30 to rotate, the rotating directions of the stirring frame 30 and the stirring rod 18 are opposite, and the stirring frame 30 and the stirring rod 18 respectively stir materials and uniformly stir the materials.

The insert block 34 is manually shifted, the upper slide rail 35 is communicated with the lower slide rail 36, the slide bar 3 is rotated, the slide bar 3 is moved to the lower slide rail 36 and is in sliding connection with the lower slide rail 36, the slide bar 3 drives the central shaft 4 to move downwards in the vertical direction, the central shaft 4 drives the first gear ring 9 to move downwards in the vertical direction, the stirring rod 18 on the outer circumference of the first inner sleeve 10 is clamped with the clamping groove 37 on the outer circumference of the second inner sleeve 11, and when the motor 101 stops moving, the stirring frame 30 and the stirring rod 18 can also achieve the purpose of stirring materials.

(3) After the stirring, the central shaft 4 drives the inserted bar 20 to move downwards in the vertical direction, the teeth on the inserted bar 20 are meshed with the teeth on the first connecting rod 21 for transmission, the central shaft 4 drives the lower baffle disc 19 to move downwards in the vertical direction, the stirred material flows out, the central shaft 4 is rotated, the central shaft 4 can be rotated by the stirring blades 23, and the potassium hydrogen persulfate composite material which is uniformly stirred flows out from the bottom of the discharge hole of the lower outer cylinder 8.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the scope of the present invention.

Claims

1. The utility model provides a mixing arrangement is used in potassium peroxydisulfate composite powder production which characterized in that: an upper outer cylinder (7) is arranged at the upper end of a lower outer cylinder (8), second connecting rods (29) are uniformly and rotatably connected to the circumferential direction of the side wall of the upper outer cylinder (7), a first gear (28) at one end of each second connecting rod (29) is respectively in meshing transmission with a sixth gear ring (40) at the bottom of a second fixing ring (27), a fifth gear ring (39) at the upper part of each second fixing ring (27) is in meshing transmission with a second gear (41) connected with an output shaft of a stepping motor, a baffle (15) is respectively arranged at the other end of each second connecting rod (29), a supporting plate (38) is arranged inside the second fixing ring (27), a first fixing ring (5) in sliding connection with a sliding rod (3) is arranged on a supporting frame (2) on the supporting plate (38), the sliding rod (3) is connected with one end of a central shaft (4) rotatably installed on the supporting plate (38), a first inner sleeve (10) is clamped on the outer circumference of the central shaft (4), a second inner sleeve (11) is arranged on the outer circumference of the first inner sleeve (10), and a stirring mechanism positioned inside the lower outer cylinder (8) is respectively arranged at the bottoms of the first inner sleeve (10) and the second inner sleeve (11);

the outer circumference of the second inner sleeve (11) is provided with a third inner sleeve (16), a material inlet (6) communicated with the upper material storage barrel (24) is formed in the supporting plate (38), a deflector rod (31) for pushing materials in the upper material storage barrel (24) to a first through hole (13) in the lower material storage barrel (14) is arranged on the outer circumference of the third inner sleeve (16), the plurality of baffles (15) are located at the outlet end of the first through hole (13), one end of the third inner sleeve (16) is provided with a second gear ring (25) connected with the adjusting mechanism (1), the other end of the third inner sleeve (16) is provided with a separating plate (17), and the separating plate (17) is located below the baffles (15) and above the stirring mechanism.

2. The mixing device for producing oxone complex powder according to claim 1, wherein the stirring mechanism is: one end of the first inner sleeve (10) is provided with a first gear ring (9), the outer circumference direction of the other end is uniformly provided with stirring rods (18), one end of the second inner sleeve (11) is provided with a third gear ring (26), the outer circumference direction of the other end is uniformly provided with a stirring frame (30), and the first gear ring (9) and the third gear ring (26) are respectively connected with the adjusting mechanism (1).

3. The mixing device for producing oxone composite powder according to claim 2, wherein the outer circumference of the second inner sleeve (11) is formed with a slot (37) which is vertically engaged with the stirring rod (18).

4. The mixing device for producing oxone complex powder according to claim 2, wherein: the rotating direction of the first gear ring (9) is opposite to that of the third gear ring (26).

5. The mixing device for producing oxone complex powder according to claim 1, wherein: the bottom of the central shaft (4) is clamped with one end of an insert rod (20), the other end of the insert rod (20) is connected with the inner part of a first connecting rod (21) through a spring (22), teeth on the outer circumference of the insert rod (20) are meshed with teeth on the outer circumference of the first connecting rod (21), and a lower blocking disc (19) positioned below the stirring rod (18) and the stirring frame (30) is arranged on the outer circumference of the insert rod (20).

6. The mixing device for producing oxone complex powder according to claim 5, wherein: and the outer circumference of the first connecting rod (21) is provided with a stirring blade (23), and the stirring blade (23) is positioned at the inner outlet of the lower outer cylinder (8).

7. The mixing device for producing oxone complex powder according to claim 1, wherein: the outer circumference of the upper end of the upper storage cylinder (24) is provided with a fourth gear ring (32) connected with the adjusting mechanism (1), and a second through hole (33) communicated with the first through hole (13) in the lower storage cylinder (14) is processed on the bottom plate of the upper storage cylinder (24).

8. The mixing device for producing oxone complex powder according to claim 1, wherein: the inner circumference of the first fixing ring (5) is provided with an upper sliding rail (35) and a lower sliding rail (36) which are respectively connected with the sliding rod (3) in a sliding manner, the upper sliding rail (35) is positioned above the lower sliding rail (36), and the side wall of the first fixing ring (5) is provided with an inserting block (34) which is communicated with the upper sliding rail (35) and the lower sliding rail (36).

9. The mixing device for producing oxone complex powder according to claim 1, wherein the adjusting mechanism (1) is: an output shaft of a motor (101) on a support plate (38) is in transmission connection with a third inner sleeve (16) through a first belt (102), a second gear ring (25) on the outer circumference of the third inner sleeve (16) is in meshing transmission with a fourth gear (109), a fifth connecting shaft (115) on a support frame (2) is provided with a first helical gear (107), the fourth gear (109) is provided with a second helical gear (108) in meshing transmission with the first helical gear (107), the second helical gear (108) is provided with a third connecting shaft (113) and a fourth connecting shaft (114) which are in threaded connection with two ends, the fifth connecting shaft (115) is in transmission connection with a sixth connecting shaft (117) through a fourth belt (116), and one end of the sixth connecting shaft (117) is provided with a third gear (106) which is in meshing transmission with the first gear ring (9) and the third gear ring (26) respectively;

the threaded connection position of the third connecting shaft (113) and the fourth connecting shaft (114) is in transmission connection with a second connecting shaft (112) on a second incomplete gear (111) through a third belt (110), the second connecting shaft (112) is in transmission connection with a first connecting shaft (105) on a first incomplete gear (104) and a seventh connecting shaft (119) on a third incomplete gear (118) through a second belt (103), and the first incomplete gear (104), the second incomplete gear (111) and the third incomplete gear (118) are in meshing transmission with a fourth gear ring (32) respectively.