CN219902995U - Polymer material preparation facilities - Google Patents

Abstract

The utility model relates to the technical field of polymer material preparation, in particular to a polymer material preparation device, which comprises: the cooling cylinder is provided with a water collecting barrel at the bottom; the discharging structure is arranged at the bottom of the cooling cylinder and is used for discharging cooled materials; the baffle structure is arranged in the cooling cylinder, and the discharging structure is communicated with the cooling cylinder through the baffle structure; through setting up the row material structure, can utilize material and coolant liquid to lead when discharging under the effect of row material structure to drive the drive impeller and make the pivot rotatory, and under drive mechanism, connecting axle and helical blade's effect, will drop the inside material of row material shell and pass through the discharge pipe and discharge, the inside that the apopore got into the connection shell can be passed to the coolant liquid, and with its inside recycle of water collection bucket of leading back under the effect of drain pipe, effectively reduced the problem that a large amount of coolant liquids of in-process of current equipment discharge material run off.

Description

Polymer material preparation facilities

Technical Field

The utility model relates to the technical field of polymer material preparation, in particular to a polymer material preparation device.

Background

The polymer material is also called as a polymer material, and is a material formed by taking a polymer compound as a matrix and adding other additives, wherein the polymer material is divided into rubber, fiber, plastic, a polymer adhesive, a polymer coating, a polymer matrix composite material and the like according to characteristics, and the plastic is one of the most widely used materials at present;

through searching, chinese patent discloses a polymer material preparation device (publication No. CN 217802665U), and this patent technology discharges the material through the discharge hopper after cooling the material, but there is still coolant liquid in the cooling cylinder in the discharge process, and a large amount of coolant liquid is discharged along with the material to cause a large amount of loss of coolant liquid, has increased use cost, and consequently, the person skilled in the art provides a polymer material preparation device to solve the problem that the above-mentioned background art presented.

Disclosure of Invention

The utility model aims to solve the problems and provide a high polymer material preparation device which solves the problem that a large amount of cooling liquid is lost in the material discharging process.

The utility model realizes the aim through the following technical scheme, and a high polymer material preparation device comprises: the cooling cylinder is provided with a water collecting barrel at the bottom; the discharging structure is arranged at the bottom of the cooling cylinder and is used for discharging cooled materials; the baffle structure, the baffle structure sets up in the inside of cooling cylinder, the row material structure is linked together with the cooling cylinder through the baffle structure, the baffle structure is used for reducing the loss of coolant liquid in the cooling process.

Preferably, the discharging structure comprises a connecting box arranged at the bottom of the cooling cylinder, an installation shell is fixedly connected to the inner wall of the connecting box, a guide plate is fixedly connected to the inner wall of the installation shell, a connecting shell is fixedly connected to the bottom of the installation shell, a drain pipe is communicated with one side of the connecting shell, the other end of the drain pipe penetrates through the connecting box and is communicated with the water collecting barrel, and a collecting cavity is formed between the inner side of the connecting shell and the bottom of the connecting box.

Preferably, the inner bottom wall of the installation shell is communicated with a discharge shell, the discharge shell is positioned in the collecting cavity, uniformly distributed drain holes are formed in the surface of the discharge shell, one end of the discharge shell is communicated with a discharge pipe, and the other end of the discharge pipe penetrates through the connecting box.

Preferably, the inner wall rotation of installation shell is connected with the pivot that is located the deflector below, the fixed surface of pivot is connected with evenly distributed's drive blade, the one end of pivot runs through installation shell and junction box in proper order and fixedly connected with drive mechanism, the inside of arranging the material shell is provided with the connecting axle, the one end of connecting axle extends to the inside of discharge pipe, the other end of connecting axle runs through row material shell and junction box in proper order and with drive mechanism's other end fixed connection, the fixed surface of connecting axle is connected with helical blade.

Preferably, the baffle structure is including the embedding install in the connecting block of cooling cylinder inner wall, the lower extreme of connecting block runs through out the cooling cylinder and with the top fixed connection of connecting box, the inner wall sliding connection of connecting block has the baffle body, sealed gasbag is installed to the top edge embedding of baffle body, sealed gasbag's bottom intercommunication has the pipe.

Preferably, the inside of baffle body has offered the gas storage chamber that is two in quantity, the inner wall sliding connection in gas storage chamber has the stripper plate, one side fixedly connected with connecting rod of stripper plate, the other end of connecting rod runs through out the baffle body and with the inboard fixed connection of connecting block, the surface cover of connecting rod is equipped with the spring, it has inert gas to fill between opposite side and the gas storage chamber of stripper plate, the other end of pipe is linked together with adjacent the gas storage chamber.

Preferably, one side of the baffle body far away from the connecting block is rotationally connected with a threaded rod, the other end of the threaded rod penetrates through the cooling cylinder, and the threaded rod is in threaded connection with the inner wall of the cooling cylinder.

The beneficial effects of the utility model are as follows:

by arranging the discharging structure, the material and the cooling liquid can be guided when being discharged under the action of the discharging structure, so that the driving blade is driven to rotate the rotating shaft, materials falling into the discharging shell are discharged through the discharging pipe under the action of the transmission mechanism, the connecting shaft and the spiral blade, the cooling liquid can pass through the discharging hole to enter the inside of the connecting shell, and the cooling liquid is guided back to the inside of the water collecting barrel for recycling under the action of the discharging pipe, so that the problem of loss of a large amount of cooling liquid in the material discharging process of the existing equipment is effectively solved;

through setting up baffle structure, can fill the gap between baffle and the connecting block through the sealed gasbag of swell when closing the baffle body to improved sealed effect, reduced the loss to the material cooling in-process coolant liquid.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a schematic diagram showing the connection of the discharge structure and the baffle structure of the present utility model;

FIG. 3 is a schematic view of a baffle structure according to the present utility model;

FIG. 4 is a schematic view of a discharging structure according to the present utility model;

fig. 5 is a schematic diagram of the connection of the connecting shaft and the transmission mechanism according to the present utility model.

In the figure: 1. a cooling cylinder; 101. a water collecting barrel; 2. a discharging structure; 201. a connection box; 202. a mounting shell; 203. a guide plate; 204. a connection housing; 205. a discharge shell; 206. a drain hole; 207. a discharge pipe; 208. a rotating shaft; 209. driving the blade; 210. a transmission mechanism; 211. a connecting shaft; 212. a helical blade; 213. a drain pipe; 3. a baffle structure; 301. a connecting block; 302. a baffle body; 303. a threaded rod; 304. sealing the air bag; 305. a connecting rod; 306. a spring; 307. an extrusion plate; 308. a catheter.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

The specific implementation method comprises the following steps: as shown in fig. 1 to 5, a polymer material preparing apparatus includes: the cooling cylinder 1, the bottom of the cooling cylinder 1 is provided with a water collecting barrel 101; the discharging structure 2 is arranged at the bottom of the cooling cylinder 1, and the discharging structure 2 is used for discharging cooled materials; baffle structure 3, baffle structure 3 set up in the inside of cooling cylinder 1, and the row material structure 2 is linked together with cooling cylinder 1 through baffle structure 3, and baffle structure 3 is arranged in reducing the loss of cooling liquid in the cooling process.

As shown in fig. 1-5, the discharging structure 2 comprises a connecting box 201 arranged at the bottom of the cooling cylinder 1, an inner wall of the connecting box 201 is fixedly connected with a mounting shell 202, the inner wall of the mounting shell 202 is fixedly connected with a guide plate 203, the bottom of the mounting shell 202 is fixedly connected with a connecting shell 204, one side of the connecting shell 204 is communicated with a drain pipe 213, the other end of the drain pipe 213 penetrates through the connecting box 201 and is communicated with the water collecting barrel 101, a collecting cavity is formed between the inner side of the connecting shell 204 and the bottom of the connecting box 201, the inner bottom wall of the mounting shell 202 is communicated with a discharging shell 205, the discharging shell 205 is positioned in the collecting cavity, a uniformly distributed drain hole 206 is formed in the surface of the discharging shell 205, one end of the discharging shell 205 is communicated with a discharge pipe 207, the other end of the discharging tube 207 penetrates through the connecting box 201, the inner wall of the mounting shell 202 is rotationally connected with a rotating shaft 208 positioned below the guide plate 203, the surface of the rotating shaft 208 is fixedly connected with uniformly distributed driving blade plates, one end of the rotating shaft 208 sequentially penetrates through the mounting shell 202 and the connecting box 201 and the connecting box 101 and is fixedly connected with a transmission mechanism 210 (the transmission mechanism 210 is a transmission wheel 205 in the prior art is a transmission part, which is a transmission shaft 211 is connected with one end of the transmission shaft 211 which is sequentially connected with the other end of the transmission shaft 211 in a rotating part of the transmission shaft 211 in a rotating manner and is connected with the other end of the transmission shaft 211 in the transmission shaft through the transmission shaft which is connected with the other end of the transmission shaft 211 in turn in the transmission part of the transmission shaft;

in-process coolant and material of discharging can be led into the inside of installation shell 202 through baffle structure 3, in this process can be under the effect of deflector 203 to material and coolant are led, thereby the coolant and the material after the guide can promote the rotation of drive impeller 209, and then can drive the synchronous rotation of pivot 208, and can drive connecting axle 211 and drive helical blade 212 rotation under the effect of drive mechanism 210, in-process material and coolant can be led into the inside of discharge shell 205, the coolant can be discharged into the inside of connection shell 204 through water discharge hole 206 and be led into the inside of catchment bucket 101 under the effect of drain pipe 213 and recycle, the loss of coolant has been reduced, avoid the in-process of current structure discharge can take away most coolant, the use cost has been increased, simultaneously can be with the material discharge through discharge shell 205 and discharge pipe 207 under the effect of helical blade 212.

As shown in fig. 1-5, the baffle structure 3 comprises a connecting block 301 embedded and installed on the inner wall of the cooling cylinder 1, the lower end of the connecting block 301 penetrates through the cooling cylinder 1 and is fixedly connected with the top of the connecting box 201, the inner wall of the connecting block 301 is slidably connected with a baffle body 302, the top edge of the baffle body 302 is embedded and installed with a sealing air bag 304, the bottom of the sealing air bag 304 is communicated with a conduit 308, two gas storage cavities are formed in the baffle body 302, the inner wall of the gas storage cavity is slidably connected with a squeezing plate 307, one side of the squeezing plate 307 is fixedly connected with a connecting rod 305, the other end of the connecting rod 305 penetrates through the baffle body 302 and is fixedly connected with the inner side of the connecting block 301, a spring 306 is sleeved on the surface of the connecting rod 305, inert gas is filled between the other side of the squeezing plate 307 and the gas storage cavities, the other end of the conduit 308 is communicated with the adjacent gas storage cavities, one side of the baffle body 302 away from the connecting block 301 is rotatably connected with a threaded rod 303, the other end of the threaded rod 303 penetrates through the cooling cylinder 1, and the threaded rod 303 is in threaded connection with the inner wall of the cooling cylinder 1;

can drive baffle body 302 through rotatory threaded rod 303 and keep away from connecting block 301 to make the inside material of cooling cylinder 1 and coolant liquid pass through the inboard discharge of connecting block 301, can drive baffle body 302 through reverse rotation threaded rod 303 and reset, thereby baffle body 302 can shelter from the inboard of connecting block 301, in this process connecting rod 305 can drive the inside inert gas of stripper plate 307 extrusion gas storage chamber, thereby inert gas can pour into the inside of sealed gasbag 304 through pipe 308, and then bulge sealed gasbag 304 fills the inboard junction of baffle body 302 and connecting block 301, the sealed effect has been improved, the condition that coolant liquid lost in the use has been reduced.

When the cooling device is used, the baffle body 302 can be driven to be far away from the connecting block 301 through the rotating threaded rod 303, so that materials and cooling liquid in the cooling cylinder 1 are led into the installation shell 202 through the inner side of the connecting block 301, the materials and the cooling liquid can be led under the action of the guide plate 203, the led cooling liquid and materials can push the driving blade 209 to enable the rotating shaft 208 to rotate, the connecting shaft 211 can be driven to drive the spiral blade 212 to rotate under the action of the transmission mechanism 210, in the process, the materials and the cooling liquid can be led into the inner side of the discharge shell 205, the cooling liquid can be discharged into the connecting shell 204 through the drain hole 206 and led into the water collecting barrel 101 for recycling under the action of the drain pipe 213, the loss of the cooling liquid is reduced, meanwhile, the materials can be discharged through the discharge shell 205 and the drain pipe 207 under the action of the spiral blade 212, the baffle body 302 can be driven to reset through the reverse rotating threaded rod 209 after the use, the inner side of the baffle body 302 can be blocked, the inner side of the baffle body 301 is filled with the air bag 302 under the action of the baffle structure 3, the cooling effect of the sealing connection of the air bag 301 is improved, and the cooling effect of the connecting block structure is improved.

Furthermore, it should be understood that although the present disclosure describes embodiments, not every embodiment is provided with a separate embodiment, and that this description is provided for clarity only, and that the disclosure is not limited to the embodiments described in detail below, and that the embodiments described in the examples may be combined as appropriate to form other embodiments that will be apparent to those skilled in the art.

Claims (7)

1. The utility model provides a macromolecular material preparation facilities which characterized in that includes:

the cooling device comprises a cooling cylinder (1), wherein a water collecting barrel (101) is arranged at the bottom of the cooling cylinder (1);

the discharging structure (2) is arranged at the bottom of the cooling cylinder (1), and the discharging structure (2) is used for discharging cooled materials;

the baffle structure (3), baffle structure (3) set up in the inside of cooling cylinder (1), discharge structure (2) are linked together with cooling cylinder (1) through baffle structure (3), baffle structure (3) are used for reducing the loss of coolant liquid in the cooling process.

2. The polymer material preparing apparatus according to claim 1, wherein: the discharging structure (2) comprises a connecting box (201) arranged at the bottom of the cooling cylinder (1), an installation shell (202) is fixedly connected to the inner wall of the connecting box (201), a guide plate (203) is fixedly connected to the inner wall of the installation shell (202), a connecting shell (204) is fixedly connected to the bottom of the installation shell (202), a drain pipe (213) is communicated with one side of the connecting shell (204), the other end of the drain pipe (213) penetrates through the connecting box (201) and is communicated with the water collecting barrel (101), and a collecting cavity is formed between the inner side of the connecting shell (204) and the bottom of the connecting box (201).

3. The polymer material preparing apparatus according to claim 2, wherein: the inner bottom wall of installation shell (202) communicates there is discharge shell (205), discharge shell (205) are located the inside of collecting the chamber, and the surface of discharge shell (205) has seted up evenly distributed's wash port (206), the one end intercommunication of discharge shell (205) has discharge pipe (207), the other end of discharge pipe (207) runs through out junction box (201).

4. A polymeric material preparing apparatus according to claim 3, wherein: the inner wall rotation of installation shell (202) is connected with pivot (208) that are located deflector (203) below, the fixed surface of pivot (208) is connected with evenly distributed's drive blade (209), the one end of pivot (208) runs through installation shell (202) and junction box (201) in proper order and fixedly connected with drive mechanism (210), the inside of arranging material shell (205) is provided with connecting axle (211), the one end of connecting axle (211) extends to the inside of discharge pipe (207), the other end of connecting axle (211) runs through in proper order and arranges material shell (205) and junction box (201) and with other end fixed connection of drive mechanism (210), the fixed surface of connecting axle (211) is connected with helical blade (212).

5. The polymer material preparing apparatus according to claim 2, wherein: baffle structure (3) are including embedding install in connecting block (301) of cooling cylinder (1) inner wall, the lower extreme of connecting block (301) runs through out cooling cylinder (1) and with the top fixed connection of connecting box (201), the inner wall sliding connection of connecting block (301) has baffle body (302), sealed gasbag (304) are installed in the top edge embedding of baffle body (302), the bottom intercommunication of sealed gasbag (304) has pipe (308).

6. The polymer material preparing apparatus according to claim 5, wherein: the inside of baffle body (302) has offered the gas storage chamber that is two in quantity, the inner wall sliding connection in gas storage chamber has stripper plate (307), one side fixedly connected with connecting rod (305) of stripper plate (307), the other end of connecting rod (305) runs through out baffle body (302) and with the inboard fixed connection of connecting block (301), the surface cover of connecting rod (305) is equipped with spring (306), it has inert gas to fill between opposite side and the gas storage chamber of stripper plate (307), the other end of pipe (308) is linked together with adjacent the gas storage chamber.

7. The polymer material preparing apparatus according to claim 6, wherein: one side of baffle body (302) keeping away from connecting block (301) rotates and is connected with threaded rod (303), the other end of threaded rod (303) runs through out cooling cylinder (1), the inner wall threaded connection of threaded rod (303) and cooling cylinder (1).