CN211030809U - Granule material quick cooling screening plant of insulating material - Google Patents
Granule material quick cooling screening plant of insulating material Download PDFInfo
- Publication number
- CN211030809U CN211030809U CN201921578494.6U CN201921578494U CN211030809U CN 211030809 U CN211030809 U CN 211030809U CN 201921578494 U CN201921578494 U CN 201921578494U CN 211030809 U CN211030809 U CN 211030809U
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- conveying
- screening
- assembly
- conveying belt
- cooling
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Abstract
The utility model provides a rapid cooling and screening device for insulating material granules, which comprises a device shell, wherein a feeding component, a conveying component, a cooling component and a screening component are arranged in the device shell; the conveying assembly comprises two conveying rollers, a conveying belt is tensioned and fixed between the two conveying rollers, the conveying rollers are rotatably fixed in the device shell, one conveying roller is connected with an output shaft of a servo motor, and the servo motor drives the conveying belt to move; the cooling assembly comprises two side baffle plates which are respectively fixed on two sides of the conveying belt, a plurality of air outlet pipes are uniformly distributed on the side baffle plates, and the air outlet pipes are used for blowing cold air to the conveying belt; the utility model discloses guarantee screening and cooling effect, improved work efficiency.
Description
Technical Field
The utility model relates to a screening plant, especially a granule material quick cooling screening plant of insulating material.
Background
The vibrating screen utilizes the vibration of a vibrating motor as a vibration source to throw up materials on the screen and simultaneously move forwards in a straight line, the materials uniformly enter a feeding hole of the screening machine from the feeding machine, and oversize materials and undersize materials with various specifications are generated through multiple layers of screen meshes and are respectively discharged from respective outlets.
The insulating material is particles prepared by taking polyvinyl chloride as base resin, adding plasticizers such as a stabilizer, dioctyl phthalate, diisodecyl phthalate, dioctyl terephthalate, trioctyl trimellitate and the like, inorganic fillers such as calcium carbonate and the like, additives such as an auxiliary agent, a lubricant and the like, and mixing, kneading and extruding the materials.
The granulation of the insulating material adopts air cooling and hot cutting, and the phenomenon of uneven grain state can be generated in the production process, for example, the grain length is not consistent, so that the finished product material needs to be screened.
Current cooling shale shaker, inside washing is inconvenient after having worked, and when cable material glued together and formed the caking moreover, relies on inside current structure can't effectively shake the caking and scatter, has reduced the screening and the cooling effect of material.
SUMMERY OF THE UTILITY MODEL
The utility model is directed to the above problem to a granule material quick cooling screening plant of insulating material has been proposed, has guaranteed screening and cooling effect, has improved work efficiency.
The specific technical scheme is as follows:
the utility model provides a granule material quick cooling screening plant of insulating material, includes the device casing, is equipped with feeding subassembly, transport module, cooling module and screening subassembly in the device casing.
Further, the conveying assembly comprises two conveying rollers, a conveying belt is fixed between the two conveying rollers in a tensioning mode, the conveying rollers are rotatably fixed in the device shell, one conveying roller is connected with an output shaft of the servo motor, and the servo motor drives the conveying belt to move.
Furthermore, the cooling assembly comprises two side baffles which are respectively fixed at two sides of the conveying belt, a plurality of air outlet pipes are uniformly distributed on the side baffles, and the air outlet pipes are used for blowing cold air to the conveying belt.
Further, the screening assembly comprises a screening assembly shell, a first cavity with an opening at the top is arranged in the screening assembly shell, a screen is arranged in the first cavity, and a vibration motor is arranged at the bottom of the first cavity;
be equipped with first transfer board and second transfer board on the lateral wall of first cavity, first transfer board is located the top of second transfer board, and flushes mutually with the screen cloth, and the second transfer board flushes with the bottom of first cavity.
Further, the conveying assembly is arranged in the device shell, one end of the screening assembly is arranged below the conveying assembly, and the other end of the screening assembly penetrates through the device shell to be arranged outside.
Further, the feeding assembly comprises a feeding pipe, the feeding pipe is obliquely fixed at the top of the device shell, and the outlet end of the feeding pipe is arranged above the conveying belt;
the end face of the feeding pipe is of a rectangular structure, a first guide plate group and a second guide plate group are arranged on the pipe wall of the feeding pipe, the first guide plate group comprises a plurality of first guide plates which are obliquely arranged, the second guide plate group comprises a plurality of second guide plates which are obliquely arranged, the first guide plate group and the second guide plate group are respectively fixed on two inner side walls of the feeding pipe, which are oppositely arranged, and the first guide plates and the second guide plates are arranged in a staggered mode.
Furthermore, the feeding pipe and the screening assembly are respectively arranged at two ends of the conveying assembly, and the conveying assembly drives the materials falling onto the conveying assembly to move from the feeding pipe to the screening assembly.
Further, the top of conveying component still is equipped with scrapes the material subassembly, scrapes the material subassembly and includes first scraper blade and second scraper blade, and the vertical setting of first scraper blade and second scraper blade is between two side shields, and first scraper blade is close the inlet pipe, and the second scraper blade is close screening assembly, and the distance between first scraper blade and the conveyor belt is greater than the distance between second scraper blade and the conveyor belt.
Further, the outlet duct is arranged between the first scraper and the second scraper.
Further, the utility model discloses a theory of operation does:
1) adding granules from a feeding pipe, and primarily dispersing the granules through a first guide plate and a second guide plate;
2) the granular materials after the preliminary dispersion fall onto the conveying belt and move along with the conveying belt;
3) in the moving process, the particles enter the cooling assembly through the first scraper, and the cold air with the temperature of less than 20 ℃ is blown out of the particle materials on the conveying belt by the air outlet pipe to cool the particle materials;
4) the cooled particles are leveled by a second scraper blade and fall onto a screening component;
5) the screening component is used for carrying out vibration screening on the granular materials, the granular materials with the grain diameters smaller than the screen mesh diameter fall into the first chamber and are moved out by the second transfer plate, and unqualified granular materials with the grain diameters larger than the screen mesh diameter are moved out from the first transfer plate.
The utility model has the advantages that:
the utility model ensures the screening and cooling effect and improves the working efficiency;
the utility model discloses strike the dispersion to the material earlier in the inlet pipe, the material after the dispersion can cool off at conveyor belt's removal in-process, has improved efficiency, has reduced the energy consumption, has guaranteed the continuation of operation.
Drawings
Fig. 1 is a sectional view of the present invention;
FIG. 2 is a top view of a screen assembly;
fig. 3 is a top view of the transport assembly.
Reference numerals:
the device comprises a device shell 1, a feeding assembly 2, a conveying assembly 3, a cooling assembly 4 and a screening assembly 5;
a feeding pipe 101, a first guide plate 102 and a second guide plate 103;
a conveying roller 301, a conveying belt 302, a first scraper 303, and a second scraper 304;
a side baffle 401 and an outlet pipe 402;
Detailed Description
For making the technical scheme of the utility model clear more clearly and definitely, it is right to combine the drawing below the utility model discloses further describe, any is right the utility model discloses technical scheme's technical characteristic carries out the scheme that equivalent replacement and conventional reasoning reachs and all falls into the utility model discloses protection scope.
As shown in the figure, the rapid cooling and screening device for the insulating material particles comprises a device shell 1, wherein a feeding assembly 2, a conveying assembly 3, a cooling assembly 4 and a screening assembly 5 are arranged in the device shell.
Further, the conveying assembly comprises two conveying rollers 301, a conveying belt 302 is tensioned and fixed between the two conveying rollers, the conveying rollers are rotatably fixed in the device shell, one conveying roller is connected with an output shaft of a servo motor, and the servo motor drives the conveying belt to move.
Further, the cooling assembly comprises two side baffles 401, the two side baffles are respectively fixed on two sides of the conveying belt, a plurality of air outlet pipes 402 are uniformly distributed on the side baffles, and the air outlet pipes are used for blowing cold air to the conveying belt.
Further, the screen assembly comprises a screen assembly housing 501, a first chamber 502 with an open top is arranged in the screen assembly housing, a screen 503 is arranged in the first chamber, and a vibration motor 504 is arranged at the bottom of the first chamber;
the side wall of the first chamber is provided with a first transfer plate 505 and a second transfer plate 506, the first transfer plate is positioned above the second transfer plate and is flush with the screen, and the second transfer plate is flush with the bottom of the first chamber.
Further, the conveying assembly is arranged in the device shell, one end of the screening assembly is arranged below the conveying assembly, and the other end of the screening assembly penetrates through the device shell to be arranged outside.
Further, the feeding assembly comprises a feeding pipe 101, the feeding pipe is obliquely fixed at the top of the device shell, and the outlet end of the feeding pipe is arranged above the conveying belt;
the end face of the feeding pipe is of a rectangular structure, a first guide plate group and a second guide plate group are arranged on the pipe wall of the feeding pipe, the first guide plate group comprises a plurality of first guide plates 102 which are obliquely arranged, the second guide plate group comprises a plurality of second guide plates 103 which are obliquely arranged, the first guide plate group and the second guide plate group are respectively fixed on two inner side walls of the feeding pipe, which are oppositely arranged, and the first guide plates and the second guide plates are arranged in a staggered mode.
Furthermore, the feeding pipe and the screening assembly are respectively arranged at two ends of the conveying assembly, and the conveying assembly drives the materials falling onto the conveying assembly to move from the feeding pipe to the screening assembly.
Further, the top of conveying component still is equipped with scrapes the material subassembly, scrapes the material subassembly and includes first scraper blade 303 and second scraper blade 304, and the vertical setting of first scraper blade and second scraper blade is between two side shields, and first scraper blade is close the inlet pipe, and the second scraper blade is close screening components, and the distance between first scraper blade and the conveyor belt is greater than the distance between second scraper blade and the conveyor belt.
Further, the outlet duct is arranged between the first scraper and the second scraper.
Further, the utility model discloses a theory of operation does:
1) adding granules from a feeding pipe, and primarily dispersing the granules through a first guide plate and a second guide plate;
2) the granular materials after the preliminary dispersion fall onto the conveying belt and move along with the conveying belt;
3) in the moving process, the particles enter the cooling assembly through the first scraper, and the cold air with the temperature of less than 20 ℃ is blown out of the particle materials on the conveying belt by the air outlet pipe to cool the particle materials;
4) the cooled particles are leveled by a second scraper blade and fall onto a screening component;
5) the screening component is used for carrying out vibration screening on the granular materials, the granular materials with the grain diameters smaller than the screen mesh diameter fall into the first chamber and are moved out by the second transfer plate, and unqualified granular materials with the grain diameters larger than the screen mesh diameter are moved out from the first transfer plate.
The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any changes or substitutions that can be easily conceived by those skilled in the art within the technical scope of the present invention should be covered by the present invention.
Claims (5)
1. A rapid cooling and screening device for insulating granular materials is characterized by comprising a device shell, wherein a feeding assembly, a conveying assembly, a cooling assembly and a screening assembly are arranged in the device shell;
the conveying assembly comprises two conveying rollers, a conveying belt is tensioned and fixed between the two conveying rollers, the conveying rollers are rotatably fixed in the device shell, one conveying roller is connected with an output shaft of a servo motor, and the servo motor drives the conveying belt to move;
the cooling assembly comprises two side baffle plates which are respectively fixed on two sides of the conveying belt, a plurality of air outlet pipes are uniformly distributed on the side baffle plates, and the air outlet pipes are used for blowing cold air to the conveying belt;
the screening assembly comprises a screening assembly shell, a first cavity with an opening at the top is arranged in the screening assembly shell, a screen is arranged in the first cavity, and a vibration motor is arranged at the bottom of the first cavity;
a first transfer plate and a second transfer plate are arranged on the side wall of the first chamber, the first transfer plate is positioned above the second transfer plate and is flush with the screen, and the second transfer plate is flush with the bottom of the first chamber;
the conveying assembly is arranged in the device shell, one end of the screening assembly is arranged below the conveying assembly, and the other end of the screening assembly penetrates through the device shell to be arranged outside.
2. A rapid cooling screening apparatus for particulate material in insulation according to claim 1 wherein the feed assembly includes a feed tube which is angularly fixed to the top of the apparatus housing, the outlet end of the feed tube being disposed above the conveyor belt;
the end face of the feeding pipe is of a rectangular structure, a first guide plate group and a second guide plate group are arranged on the pipe wall of the feeding pipe, the first guide plate group comprises a plurality of first guide plates which are obliquely arranged, the second guide plate group comprises a plurality of second guide plates which are obliquely arranged, the first guide plate group and the second guide plate group are respectively fixed on two inner side walls of the feeding pipe, which are oppositely arranged, and the first guide plates and the second guide plates are arranged in a staggered mode.
3. A rapid cooling screening apparatus for particulate material in insulating material according to claim 2 wherein the feed tube and the screening elements are located at opposite ends of the conveyor assembly, the conveyor assembly moving material falling thereon from the feed tube to the screening elements.
4. A device for rapidly cooling and screening insulating material particles as claimed in claim 3, wherein a scraping component is further arranged above the conveying component, the scraping component comprises a first scraping plate and a second scraping plate, the first scraping plate and the second scraping plate are vertically arranged between the two side baffle plates, the first scraping plate is close to the feeding pipe, the second scraping plate is close to the screening component, and the distance between the first scraping plate and the conveying belt is larger than the distance between the second scraping plate and the conveying belt.
5. A screen apparatus for the rapid cooling of particulate material from an insulating material as claimed in claim 4 wherein the air outlet is located between the first scraper and the second scraper.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN201921578494.6U CN211030809U (en) | 2019-09-20 | 2019-09-20 | Granule material quick cooling screening plant of insulating material |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN201921578494.6U CN211030809U (en) | 2019-09-20 | 2019-09-20 | Granule material quick cooling screening plant of insulating material |
Publications (1)
Publication Number | Publication Date |
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CN211030809U true CN211030809U (en) | 2020-07-17 |
Family
ID=71563243
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
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CN201921578494.6U Expired - Fee Related CN211030809U (en) | 2019-09-20 | 2019-09-20 | Granule material quick cooling screening plant of insulating material |
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CN (1) | CN211030809U (en) |
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN113752412A (en) * | 2021-08-20 | 2021-12-07 | 江西瑞溢新材料科技有限公司 | Cooling device for shaping plastic particles |
-
2019
- 2019-09-20 CN CN201921578494.6U patent/CN211030809U/en not_active Expired - Fee Related
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN113752412A (en) * | 2021-08-20 | 2021-12-07 | 江西瑞溢新材料科技有限公司 | Cooling device for shaping plastic particles |
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GR01 | Patent grant | ||
GR01 | Patent grant | ||
CF01 | Termination of patent right due to non-payment of annual fee |
Granted publication date: 20200717 Termination date: 20210920 |
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CF01 | Termination of patent right due to non-payment of annual fee |