CN117504670A - Processing proportioning equipment of organic polymer bromide - Google Patents

Abstract

The invention discloses processing proportioning equipment for organic polymer bromide, which belongs to the technical field of polymer bromide, wherein a plurality of groups of discharge ports are formed in the bottom of a mixing ring groove, an extrusion structure is movably installed on the discharge ports, the stirring structure comprises a mounting plate, a rotating shaft is rotatably arranged in the middle of the mounting plate, a plurality of groups of planetary gears are rotatably arranged at the bottom of the mounting plate, a stirring fan is arranged at the bottom of each planetary gear, and the stirring fan and the extrusion structure are mutually matched to carry out blanking on raw materials in the mixing ring groove; the tipping bucket is matched with the blanking frame to carry out intermittent quantitative blanking; the upper beating structure is used for vibrating and beating the side face of the storage box, and the lower beating structure and the vibrating block are matched with each other to vibrate and beat the inner wall of the mixing ring groove. According to the invention, the upper storage box and the lower mixing ring groove can be beaten simultaneously during stirring operation, so that particles are prevented from being adhered to the inner wall, and the raw materials in the storage box can be precisely and intermittently discharged under the ingenious matching of the tipping bucket and the discharging frame.

Description

Processing proportioning equipment of organic polymer bromide

Technical Field

The invention relates to the technical field of polymer bromides, in particular to processing proportioning equipment of an organic polymer bromide.

Background

Brominated polymers are a plasticizer and are also one of the commonly used flame retardants. The main component of the catalyst is bromide, the bromide can react chemically, releasing a large amount of halogen element. As a plasticizer, it can improve the processability of the material, improve the flexibility and ductility of the material and improve the performance of the product. And as a flame retardant, the brominated polymer is subjected to decomposition reaction in a high-temperature environment to release bromide, and the bromide and fuel are contacted and then quickly subjected to chemical reaction to form inert halide and carbon, so that the flame retardant effect is achieved. Meanwhile, the brominated polymer also has excellent physical and mechanical properties, can improve the toughness and durability of products, and is widely applied to the fields of electronics, buildings, automobiles, toys and the like.

The patent application with the publication number of CN116351330A discloses an automatic feeding system of a bromine reduction reaction tank, a liquid inlet detection assembly comprises an inverted T-shaped pipe, a support is sleeved at the outer end of the bottom of the side wall of the reaction tank, a PH value sensor module and a chloride ion sensor module are inserted in a jack of the support, a circulating liquid pump is connected with the inverted T-shaped pipe and a shunt pipe, a shunt joint is arranged on the shunt pipe, a jet mixer comprises a main straight pipe and a side joint which are connected with the shunt joint, two ends of the top of the tee joint connected with the liquid distribution pipe are respectively provided with an acid liquid supply valve module and a chlorine supply valve module, the connecting pipe is connected between the liquid distribution pipe and the side joint, an output joint of the peripheral wall of the output pipe is connected with the top end of the main straight pipe, an output pipe port is connected with the top end of the side wall of the reaction tank, and a central control module controls the acid liquid supply valve module and the chlorine supply valve module according to PH value and chloride ion information; solves the problem that the bromine reaction tank charging device is difficult to realize accurate quantitative charging.

However, the above disclosed raw material proportioning device has low proportioning efficiency, and the raw materials cannot be sufficiently stirred and mixed before the reaction, and the inner wall is easy to adhere to the raw materials after long-time use, thereby affecting the subsequent reaction. Therefore, in view of the above-mentioned current situation, there is an urgent need to develop a processing proportioning device for organic polymer bromide, so as to overcome the shortcomings in the current practical application.

Disclosure of Invention

The invention aims at: in order to solve the problems that the existing raw material proportioning device is low in proportioning efficiency, raw materials cannot be fully stirred and mixed before reaction, raw materials are easy to adhere to the inner wall after long-time use, subsequent reaction is affected, and the like, the processing proportioning equipment for the organic polymer bromide is provided.

In order to achieve the above purpose, the technical scheme of the invention is as follows: the processing proportioning equipment of the organic polymer bromide comprises a mixing ring groove, a stirring structure and a discharging structure, wherein a plurality of groups of discharge holes are formed in the bottom of the mixing ring groove, an extrusion structure is movably mounted on the discharge holes, a plurality of vibration blocks are arranged on the inner wall of the mixing ring groove, a plurality of groups of discharging holes are formed in the side face of the mixing ring groove, and a plurality of groups of vertically arranged supporting rods are fixed on the side face of the mixing ring groove; the stirring structure comprises a mounting plate, the mounting plate is arranged at the top of the supporting rod, a rotating shaft is rotatably arranged in the middle of the mounting plate, the top of the rotating shaft is connected with an upper beating structure, the bottom of the rotating shaft is connected with a lower beating structure, a plurality of groups of planetary gears are rotatably arranged at the bottom of the mounting plate, stirring fans are arranged at the bottoms of the planetary gears, and the stirring fans and the extrusion structure are mutually matched to perform blanking on raw materials in the mixing ring groove; the blanking structure comprises side plates at two sides and a slideway arranged between the side plates, wherein the side plates are arranged at the blanking opening, a blanking frame is arranged between the side plates in a sliding manner, the top of each side plate is connected with a storage box, the bottom of each storage box is provided with a discharging bin, a tipping bucket is rotatably arranged in each discharging bin, and the tipping bucket is matched with the blanking frame to perform intermittent quantitative blanking; the upper beating structure is used for vibrating and beating the side face of the storage box, and the lower beating structure is matched with the vibrating block to vibrate and beat the inner wall of the mixing ring groove.

As still further aspects of the invention: the extrusion structure comprises a mounting ring arranged at the discharge hole, a cross is arranged at the bottom of the mounting ring, a plurality of groups of first reset springs are arranged at the bottom of the cross, an extrusion block is connected to the top of each first reset spring, and the extrusion block is movably arranged in the discharge hole.

As still further aspects of the invention: the upper beating structure comprises a plurality of groups of upper arms arranged at the top of the rotating shaft, a vertical plate is arranged on the side face of the upper arms, a second screw rod is movably arranged on the vertical plate, a protruding block is fixedly arranged on the outer side of the second screw rod, a second vibrating spring is arranged between the protruding block and the vertical plate, and an upper adjusting nut is movably arranged on the second screw rod.

As still further aspects of the invention: the lower beating structure comprises a plurality of groups of lower arms arranged at the bottom of the rotating shaft, a fixed plate is arranged on the side face of the lower arms, a first screw rod is movably arranged on the fixed plate, a vibrating plate is fixedly arranged on the outer side of the first screw rod, a first vibrating spring is arranged between the vibrating plate and the fixed plate, and a lower adjusting nut is further movably arranged on the first screw rod.

As still further aspects of the invention: the bottom of mounting panel still installs the driving gear, driving gear fixed mounting is in the pivot, the bottom of mounting panel still fixed mounting has the ring gear, planetary gear rotates and sets up between ring gear and the driving gear.

As still further aspects of the invention: a T-shaped groove is formed in the bottom of the mounting plate, and a T-shaped block matched with the T-shaped groove is arranged at the top of the planetary gear; the top of mounting panel is provided with turns over and mixes the motor, turn over and mix the motor through first belt with the pivot is connected.

As still further aspects of the invention: the two sides of the side plate are provided with grooves, the two sides of the blanking frame are fixedly connected with sliding rods, the sliding rods are arranged in the grooves in a sliding manner, the inner walls of the grooves are also provided with second reset springs, and the second reset springs are connected with the sliding rods; the two sides of the tipping bucket are provided with rotating shafts, the side plates are provided with blanking motors, the blanking motors are connected with the rotating shafts through second belts, and the output shafts of the blanking motors are fixedly connected with swinging rods matched with the sliding rods.

As still further aspects of the invention: the inner side of the side plate is provided with a sliding rail, two sides of the blanking frame are provided with sliding blocks matched with the sliding rail, and transverse plates matched with the blanking frame are fixedly arranged between the side plates on two sides.

As still further aspects of the invention: and a plurality of groups of connecting frames connected with the storage box are also arranged on the mounting plate.

As still further aspects of the invention: the bottom of mixing ring groove is provided with a plurality of bases, the bottom of discharge gate is connected with the discharging pipe, extrusion structure installs in the discharging pipe.

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

1. according to the invention, multiple raw materials can be simultaneously proportioned through the design of the multiple groups of blanking structures, so that the raw material treatment efficiency of the production of the organic polymer bromide is greatly improved, and the multiple raw materials can be fully stirred through the design of the mixing ring groove and the planetary gear, wherein the stirring fan rotates while revolving relative to the driving gear, so that the stirring effect of the raw materials is greatly improved. And the mixed raw materials can be intermittently discharged through the cooperation of the stirring fan and the extrusion structure, so that the working efficiency is further improved, and the labor cost is reduced.

2. According to the invention, the upper beating structure and the lower beating structure are designed on the mounting plate, and the upper storage box and the lower mixing ring groove can be beaten simultaneously during stirring operation, so that particles are prevented from being adhered to the inner wall, and blocking is caused after the device is used for a long time, and the working efficiency is greatly improved. And the beating force of the lug and the vibrating plate can be adjusted according to actual demands by mutually matching the upper adjusting nut and the lower adjusting nut, so that the proportioning efficiency and the proportioning capacity are further improved. Under the ingenious matching of the tipping bucket and the blanking frame, the raw materials in the storage box can be precisely and intermittently blanked.

Drawings

The invention is further explained below with reference to the drawings and examples:

FIG. 1 is a front view of a three-dimensional structure of the present invention;

FIG. 2 is a top view of a hybrid ring groove of the present invention;

FIG. 3 is a cross-sectional view of a hybrid ring groove in the present invention;

FIG. 4 is a perspective view of the extrusion structure of the present invention;

FIG. 5 is a bottom view of the flip structure of the present invention;

FIG. 6 is an enlarged view of the structure of FIG. 5A in accordance with the present invention;

FIG. 7 is an enlarged view of the structure of FIG. 5B in accordance with the present invention;

FIG. 8 is a cross-sectional view of the tumble structure of the present invention;

FIG. 9 is a perspective view of a blanking structure in the present invention;

FIG. 10 is a side view of the blanking structure of the present invention;

fig. 11 is a cross-sectional view of a blanking structure in the present invention.

Reference numerals illustrate:

1. a mixing ring groove; 101. a discharge port; 102. an extrusion structure; 103. a vibrating block; 104. a feed opening; 105. a base; 106. a support rod; 107. a discharge pipe; 108. a mounting ring; 109. a cross; 110. a first return spring; 111. extruding a block; 2. turning over the stirring structure; 201. a mounting plate; 202. a rotating shaft; 203. a stirring motor; 204. a first belt; 205. an upper tapping structure; 206. a lower striking structure; 207. a lower arm; 208. a fixing plate; 209. a first screw; 210. a vibration plate; 211. a first vibration spring; 212. a lower adjustment nut; 213. an upper arm; 214. a riser; 215. a second screw; 216. a bump; 217. a second vibration spring; 218. an upper adjusting nut; 219. a drive gear; 220. a gear ring; 221. a planetary gear; 222. a stirring fan; 223. a T-shaped groove; 224. a T-shaped block; 225. a connecting frame; 3. a blanking structure; 301. a side plate; 302. a slideway; 303. a slide rail; 304. a blanking frame; 305. a slide block; 306. a cross plate; 307. slotting; 308. a slide bar; 309. a second return spring; 310. a blanking motor; 311. a swinging rod; 312. a second belt; 313. a dump box; 314. a rotation shaft; 315. a storage bin; 316. and discharging the material from the material bin.

Detailed Description

The technical solutions of the present invention will be clearly and completely described below with reference to fig. 1 to 11, and it is obvious that the described embodiments are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

The invention provides processing proportioning equipment of organic polymer bromide by improving, as shown in fig. 1-11, the equipment comprises a mixing ring groove 1, a stirring structure 2 and a blanking structure 3, wherein a plurality of groups of discharge holes 101 are formed in the bottom of the mixing ring groove 1, an extrusion structure 102 is movably mounted on the discharge holes 101, a plurality of vibration blocks 103 are arranged on the inner wall of the mixing ring groove 1, a plurality of groups of blanking holes 104 are formed in the side surface of the mixing ring groove 1, and a plurality of groups of support rods 106 which are vertically arranged are fixed on the side surface of the mixing ring groove 1; the stirring structure 2 comprises a mounting plate 201, the mounting plate 201 is arranged at the top of the supporting rod 106, a rotating shaft 202 is rotatably arranged in the middle of the mounting plate 201, an upper beating structure 205 is connected to the top of the rotating shaft 202, a lower beating structure 206 is connected to the bottom of the rotating shaft 202, a plurality of groups of planetary gears 221 are rotatably arranged at the bottom of the mounting plate 201, a stirring fan 222 is arranged at the bottom of the planetary gears 221, and the stirring fan 222 and the extrusion structure 102 are mutually matched to perform blanking on raw materials in the mixing ring groove 1; the blanking structure 3 comprises side plates 301 on two sides and a slideway 302 positioned between the side plates 301, the side plates 301 are arranged at the blanking opening 104, a blanking frame 304 is slidably arranged between the side plates 301, the top of the side plates 301 is connected with a storage box 315, the bottom of the storage box 315 is provided with a discharge bin 316, a tipping bucket 313 is rotationally arranged in the discharge bin 316, and the tipping bucket 313 is matched with the blanking frame 304 for intermittent quantitative blanking; the upper beating structure 205 is used for performing vibration beating on the side surface of the storage tank 315, and the lower beating structure 206 and the vibration block 103 are matched with each other to perform vibration beating on the inner wall of the mixing ring groove 1.

In this embodiment: the processing proportioning equipment of the organic polymer bromide is mainly divided into three parts: mixing ring groove 1, turn over mix structure 2 and unloading structure 3. When the device is used, various raw materials are firstly placed in the material storage box 315 respectively, then the blanking motor 310 is started, and the rotating speed of each blanking motor 310 is controlled according to the preset raw material proportion. When the discharging motor 310 is turned on, the skip 313 rotates in the discharging bin 316 under the cooperation of the second belt 312 and the rotation shaft 314. When the skip 313 rotates counterclockwise, the swing lever 311 also rotates counterclockwise. When the dump box 313 is filled with material and unloaded into the drop box 304, the swing lever 311 toggles the slide bar 308 to the right, at which point the slide bar 308 slides along the slot 307, at which point the drop box 304 leaves the cross plate 306 and the material in the drop box 304 falls into the chute 302. When the swing rod 311 is separated from the slide rod 308, the blanking frame 304 is restored to the original position under the action of the second return spring 309. After each raw material falls into the mixing ring groove 1, the stirring fan 222 rotates by itself while revolving around the driving gear 219 by the stirring motor 203. When the rotating shaft 202 rotates, the upper beating structure 205 performs vibration beating on the side surface of the storage tank 315, and the lower beating structure 206 and the vibration block 103 cooperate with each other to perform vibration beating on the inner wall of the mixing ring groove 1. When the stirring fan 222 rotates, the extrusion block 111 moves downward, and the mixed raw materials fall into the discharge pipe 107 from the gap between the discharge port 101 and the extrusion block 111 and the middle of the cross 109.

Referring to fig. 2-4, the extruding structure 102 includes a mounting ring 108 installed at the discharge port 101, a cross 109 is provided at the bottom of the mounting ring 108, a plurality of groups of first return springs 110 are installed at the bottom of the cross 109, an extruding block 111 is connected to the top of the first return springs 110, and the extruding block 111 is movably disposed in the discharge port 101.

In this embodiment: in order to intermittently block the discharge port 101 and thus realize intermittent discharging, an extrusion structure 102 is installed at the bottom of the discharge port 101. When the stirring fan 222 presses the pressing block 111 downward, the pressing block 111 moves downward at this time, and the mixed raw materials fall into the discharge pipe 107 from the gap between the discharge port 101 and the pressing block 111 and the middle of the cross 109. When the stirring fan 222 is separated from the extrusion block 111, the extrusion block 111 is restored to its original position by the first return spring 110.

Referring to fig. 5-7, the upper striking structure 205 includes a plurality of groups of upper arms 213 disposed at the top of the rotating shaft 202, a vertical plate 214 disposed on a side surface of the upper arms 213, a second screw 215 movably disposed on the vertical plate 214, a bump 216 fixedly disposed on an outer side of the second screw 215, a second vibration spring 217 disposed between the bump 216 and the vertical plate 214, and an upper adjusting nut 218 movably disposed on the second screw 215.

In this embodiment: in order to cyclically tap the top bin 315, a lug 216 is movably provided on the upper arm 213. In order to adjust the elastic potential energy of the second vibration spring 217 according to actual requirements, thereby further adjusting the striking force of the bump 216, an upper adjusting nut 218 is further provided on the second screw 215.

Referring to fig. 5-7, the lower beating structure 206 includes a plurality of groups of lower arms 207 disposed at the bottom of the rotating shaft 202, a fixing plate 208 disposed on a side surface of the lower arms 207, a first screw 209 movably disposed on the fixing plate 208, a vibrating plate 210 fixedly disposed on an outer side of the first screw 209, a first vibrating spring 211 disposed between the vibrating plate 210 and the fixing plate 208, and a lower adjusting nut 212 movably disposed on the first screw 209.

In this embodiment: in order to circularly tap the mixing ring groove 1 at the bottom, a vibration plate 210 is movably provided on the lower arm 207. In order to adjust the elastic potential energy of the first vibration spring 211 according to actual requirements, thereby further adjusting the striking force of the vibration plate 210, a lower adjusting nut 212 is further disposed on the first screw 209.

Referring to fig. 5 to 8, a driving gear 219 is further installed at the bottom of the mounting plate 201, the driving gear 219 is fixedly installed on the rotating shaft 202, a gear ring 220 is further fixedly installed at the bottom of the mounting plate 201, and planetary gears 221 are rotatably disposed between the gear ring 220 and the driving gear 219.

In this embodiment: in order to enhance the stirring effect of the raw materials in the mixing ring groove 1, a planetary structure is designed on the mounting plate 201, and the planetary gear 221 itself rotates when revolving around the driving gear 219.

Referring to fig. 5 to 8, a T-shaped groove 223 is formed in the bottom of the mounting plate 201, and a T-shaped block 224 matched with the T-shaped groove 223 is formed on the top of the planetary gear 221; the top of mounting panel 201 is provided with turns over and mixes motor 203, turns over and mixes motor 203 and is connected with pivot 202 through first belt 204.

In this embodiment: in order to improve stability when the planetary gear 221 rotates, a T-shaped block 224 is provided on the top of the planetary gear 221 to be engaged with the T-shaped groove 223. In order to drive the rotation shaft 202 to rotate, thereby further driving the upper and lower tapping structures 205 and 206, a tumble motor 203 is provided on top of the mounting plate 201.

Referring to fig. 9-11, slots 307 are formed in two sides of the side plate 301, sliding rods 308 are fixedly connected to two sides of the blanking frame 304, the sliding rods 308 are slidably arranged in the slots 307, second reset springs 309 are further arranged on the inner walls of the slots 307, and the second reset springs 309 are connected with the sliding rods 308; the two sides of the tipping bucket 313 are provided with rotating shafts 314, the side plates 301 are provided with blanking motors 310, the blanking motors 310 are connected with the rotating shafts 314 through second belts 312, and the output shafts of the blanking motors 310 are fixedly connected with swinging rods 311 matched with the sliding rods 308.

In this embodiment: in order to intermittently discharge the raw material in the storage tank 315, a discharge motor 310 is mounted on the side plate 301. When the discharging motor 310 is turned on, the skip 313 rotates in the discharging bin 316 under the cooperation of the second belt 312 and the rotation shaft 314. When the skip 313 rotates counterclockwise, the swing lever 311 also rotates counterclockwise. When the dump box 313 is filled with material and unloaded into the drop box 304, the swing lever 311 toggles the slide bar 308 to the right, at which point the slide bar 308 slides along the slot 307, at which point the drop box 304 leaves the cross plate 306 and the material in the drop box 304 falls into the chute 302. When the swing rod 311 is separated from the slide rod 308, the blanking frame 304 is restored to the original position under the action of the second return spring 309.

Referring to fig. 9-11, a sliding rail 303 is provided on the inner side of a side plate 301, sliding blocks 305 matched with the sliding rail 303 are provided on two sides of a blanking frame 304, and a transverse plate 306 matched with the blanking frame 304 is fixedly provided between the side plates 301 on two sides.

In this embodiment: the bottom of the blanking frame 304 can be shielded by the design of the cross plate 306, so that raw materials are prevented from sliding off from the bottom. When the sliding blocks 305 on both sides of the blanking frame 304 slide along the sliding rails 303 on the side plates 301, at this time, the blanking frame 304 leaves the cross plate 306, and the raw materials in the blanking frame 304 fall into the sliding rails 302 and further enter into the mixing ring groove 1.

Referring to fig. 1 and 8, the mounting plate 201 is further provided with a plurality of sets of connection frames 225 connected to a storage tank 315.

In this embodiment: in order to further improve the stability of the storage tank 315, a plurality of sets of connection frames 225 connected to the storage tank 315 are further provided on the mounting plate 201.

Referring to fig. 2-3, a plurality of bases 105 are arranged at the bottom of the mixing ring groove 1, a discharging pipe 107 is connected to the bottom of the discharging hole 101, and an extrusion structure 102 is installed in the discharging pipe 107.

In this embodiment: in order to transfer the mixed raw materials to the next reaction equipment, the extrusion structure 102 is installed in the discharge pipe 107, and the raw materials are introduced into the discharge pipe 107 from the discharge port 101 with the stirring fan 222 being engaged with the extrusion structure 102.

The working principle of the invention is as follows: when the device is used, various raw materials are firstly placed in the material storage box 315 respectively, then the blanking motor 310 is started, and the rotating speed of each blanking motor 310 is controlled according to the preset raw material proportion. When the discharging motor 310 is turned on, the skip 313 rotates in the discharging bin 316 under the cooperation of the second belt 312 and the rotation shaft 314. When the skip 313 rotates counterclockwise, the swing lever 311 also rotates counterclockwise. When the dump box 313 is filled with material and unloaded into the drop box 304, the swing lever 311 toggles the slide bar 308 to the right, at which point the slide bar 308 slides along the slot 307, at which point the drop box 304 leaves the cross plate 306 and the material in the drop box 304 falls into the chute 302. When the swing rod 311 is separated from the slide rod 308, the blanking frame 304 is restored to the original position under the action of the second return spring 309. After each raw material falls into the mixing ring groove 1, the stirring fan 222 rotates by itself while revolving around the driving gear 219 by the stirring motor 203. When the rotating shaft 202 rotates, the upper beating structure 205 performs vibration beating on the side surface of the storage tank 315, and the lower beating structure 206 and the vibration block 103 cooperate with each other to perform vibration beating on the inner wall of the mixing ring groove 1. When the stirring fan 222 rotates, the extrusion block 111 moves downward, and the mixed raw materials fall into the discharge pipe 107 from the gap between the discharge port 101 and the extrusion block 111 and the middle of the cross 109. The top of extrusion piece 111 is the fillet structure, and the raw materials can slide to the below of extrusion piece 111. And the first reset spring 110 is positioned at the bottom of the extrusion block 111, so that raw materials can not scatter on the first reset spring 110 when freely falling, and the raw materials after accurate proportioning can be fed into the discharge pipe 107 step by step for a plurality of times under the action of the stirring fan 222.

According to the invention, a plurality of raw materials can be simultaneously proportioned through the design of the plurality of groups of blanking structures 3, so that the raw material treatment efficiency of the production of the organic polymer bromide is greatly improved, and the plurality of raw materials can be fully stirred through the design of the mixing ring groove 1 and the planetary gear 221, wherein the stirring fan 222 rotates while revolving relative to the driving gear 219, so that the stirring effect of the raw materials is greatly improved. And the mixed raw materials can be intermittently discharged through the cooperation of the stirring fan 222 and the extrusion structure 102, so that the working efficiency is further improved and the labor cost is reduced. The upper beating structure 205 and the lower beating structure 206 are designed on the mounting plate 201, and the upper material storage box 315 and the lower mixing ring groove 1 can be beaten simultaneously during stirring operation, so that particles are prevented from being adhered to the inner wall, and blockage is avoided after long-time use, and the working efficiency is greatly improved. And the beating force of the lug 216 and the vibrating plate 210 can be adjusted according to actual requirements by mutually matching the upper adjusting nut 218 and the lower adjusting nut 212, so that the proportioning efficiency and the proportioning capability are further improved. With the smart cooperation of the skip 313 and the blanking frame 304, accurate and intermittent blanking of the raw material in the storage bin 315 can be performed.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (10)

1. The utility model provides a processing proportioning equipment of organic polymer bromide, includes mixing ring groove (1), turns over and mixes structure (2) and unloading structure (3), its characterized in that: a plurality of groups of discharge holes (101) are formed in the bottom of the mixing ring groove (1), an extrusion structure (102) is movably mounted on the discharge holes (101), a plurality of vibration blocks (103) are arranged on the inner wall of the mixing ring groove (1), a plurality of groups of discharge holes (104) are formed in the side face of the mixing ring groove (1), and a plurality of groups of support rods (106) which are vertically arranged are fixed on the side face of the mixing ring groove (1);

the stirring structure (2) comprises a mounting plate (201), wherein the mounting plate (201) is arranged at the top of the supporting rod (106), a rotating shaft (202) is rotatably arranged in the middle of the mounting plate (201), an upper beating structure (205) is connected to the top of the rotating shaft (202), a lower beating structure (206) is connected to the bottom of the rotating shaft (202), a plurality of groups of planetary gears (221) are rotatably arranged at the bottom of the mounting plate (201), stirring fans (222) are arranged at the bottom of the planetary gears (221), and the stirring fans (222) are mutually matched with the extrusion structure (102) to feed raw materials in the mixing ring groove (1);

the blanking structure (3) comprises side plates (301) on two sides and a slideway (302) arranged between the side plates (301), the side plates (301) are arranged at the blanking opening (104), a blanking frame (304) is slidably arranged between the side plates (301), the top of each side plate (301) is connected with a storage box (315), the bottom of each storage box (315) is provided with a discharging bin (316), a tipping bucket (313) is rotationally arranged in each discharging bin (316), and the tipping bucket (313) is matched with the blanking frame (304) to perform intermittent quantitative blanking; the upper beating structure (205) is used for vibrating and beating the side face of the storage box (315), and the lower beating structure (206) and the vibrating block (103) are matched with each other to perform vibrating and beating on the inner wall of the mixing ring groove (1).

2. The processing proportioning device for organic polymer bromide according to claim 1, wherein: the extrusion structure (102) comprises a mounting ring (108) arranged at the discharge hole (101), a cross (109) is arranged at the bottom of the mounting ring (108), a plurality of groups of first reset springs (110) are arranged at the bottom of the cross (109), an extrusion block (111) is connected to the top of each first reset spring (110), and the extrusion block (111) is movably arranged in the discharge hole (101).

3. The processing proportioning device for organic polymer bromide according to claim 1, wherein: the upper beating structure (205) comprises a plurality of groups of upper arms (213) arranged at the top of the rotating shaft (202), vertical plates (214) are arranged on the side faces of the upper arms (213), second screw rods (215) are movably arranged on the vertical plates (214), protruding blocks (216) are fixedly arranged on the outer sides of the second screw rods (215), second vibrating springs (217) are arranged between the protruding blocks (216) and the vertical plates (214), and upper adjusting nuts (218) are movably arranged on the second screw rods (215).

4. The processing proportioning device for organic polymer bromide according to claim 1, wherein: the lower beating structure (206) is in including setting up multiunit lower arm (207) of pivot (202) bottom, the side of lower arm (207) is provided with fixed plate (208), the activity is provided with first screw rod (209) on fixed plate (208), the outside of first screw rod (209) is fixed to be provided with vibrations board (210), vibrations board (210) with be provided with first vibrations spring (211) between fixed plate (208), still the activity is provided with down adjusting nut (212) on first screw rod (209).

5. The processing proportioning device for organic polymer bromide according to claim 1, wherein: the bottom of mounting panel (201) is still installed driving gear (219), driving gear (219) fixed mounting is in on pivot (202), the bottom of mounting panel (201) is still fixed mounting has ring gear (220), planetary gear (221) rotation sets up between ring gear (220) and driving gear (219).

6. The processing proportioning device for organic polymer bromide according to claim 1, wherein: a T-shaped groove (223) is formed in the bottom of the mounting plate (201), and a T-shaped block (224) matched with the T-shaped groove (223) is arranged at the top of the planetary gear (221); the top of mounting panel (201) is provided with turns over and mixes motor (203), turn over and mix motor (203) through first belt (204) with pivot (202) are connected.

7. The processing proportioning device for organic polymer bromide according to claim 1, wherein: the automatic feeding device is characterized in that grooves (307) are formed in two sides of the side plate (301), sliding rods (308) are fixedly connected to two sides of the blanking frame (304), the sliding rods (308) are arranged in the grooves (307) in a sliding mode, second reset springs (309) are further arranged on the inner walls of the grooves (307), and the second reset springs (309) are connected with the sliding rods (308); the two sides of the tipping bucket (313) are provided with rotating shafts (314), the side plates (301) are provided with blanking motors (310), the blanking motors (310) are connected with the rotating shafts (314) through second belts (312), and the output shafts of the blanking motors (310) are fixedly connected with swinging rods (311) matched with the sliding rods (308).

8. The process proportioning device for organic polymer bromide according to claim 7, wherein: slide rail (303) have been seted up to the inboard of curb plate (301), the both sides of unloading frame (304) be provided with slide rail (303) complex slider (305), both sides fixedly between curb plate (301) be provided with unloading frame (304) complex diaphragm (306).

9. The processing proportioning device for organic polymer bromide according to claim 1, wherein: and a plurality of groups of connecting frames (225) connected with the storage box (315) are also arranged on the mounting plate (201).

10. The processing proportioning device for organic polymer bromide according to claim 1, wherein: the bottom of mixing ring groove (1) is provided with a plurality of bases (105), the bottom of discharge gate (101) is connected with discharging pipe (107), extrusion structure (102) are installed in discharging pipe (107).