CN215447321U

CN215447321U - Desiccator of organosilicon production

Info

Publication number: CN215447321U
Application number: CN202121433157.5U
Authority: CN
Inventors: 戴鹏; 刘胜
Original assignee: Hubei Huaxin Organosilicone New Material Co ltd
Current assignee: Hubei Huaxin Organosilicone New Material Co ltd
Priority date: 2021-06-28
Filing date: 2021-06-28
Publication date: 2022-01-07
Anticipated expiration: 2031-06-28

Abstract

The utility model discloses a dryer for organic silicon production, which comprises a supporting table, a conveying mechanism and a drying mechanism, wherein the supporting table is arranged on the top of the drying mechanism; a support table: the upper surface of the supporting platform is provided with a shell, the left side of the front surface of the shell is provided with a motor, and two sides of the lower end surface of the supporting platform are provided with guide wheels; a conveying mechanism: the conveying mechanism is arranged on the upper surface of the supporting table and is positioned in the shell; a drying mechanism: the conveying mechanism is arranged between the conveying mechanism and the shell; wherein: the control switch group is arranged at the left end of the front surface of the shell, the input end of the control switch group is electrically connected with an external power supply, and the output end of the control switch group is electrically connected with the motor; this desiccator of organosilicon production carries the material through the conveyer belt, and the high temperature through the heating pipe makes the moisture evaporation in the material again to reach dry purpose, adopt the multilayer conveying, equipment is small, is convenient for remove, can link up the last process of organosilicon production, realizes lasting feed, improves drying efficiency.

Description

Desiccator of organosilicon production

Technical Field

The utility model relates to the technical field of organic silicon drying, in particular to a dryer for organic silicon production.

Background

Organosilicon, that is, organosilicon compounds, are used not only as special materials in the aviation, advanced technology, military technology sectors, but also in various sectors of the national economy, and the application range thereof has been expanded: the mass use of organosilicon materials in building, electronics, electrical, textile, etc. is accompanied by the production of organosilicon, wherein the drying of organosilicon is an essential process.

Most of the conventional dryers adopt vacuum drying, and the moisture in the materials is gasified and extracted by vacuumizing the materials, or drying equipment is adopted to remove the moisture at high temperature.

Traditional equipment, the volume is great, and the equipment is inconvenient to be removed, and the feed that can not last is dried, and production efficiency is low, and drying effect is general, for this reason, we propose the desiccator of organosilicon production.

SUMMERY OF THE UTILITY MODEL

The utility model aims to overcome the defects in the prior art, and provides a dryer for organic silicon production, which is small in size and convenient to move, can be connected with the previous process of organic silicon production, realizes continuous feeding, and can effectively solve the problems in the background art.

In order to achieve the purpose, the utility model provides the following technical scheme: a drier for organic silicon production comprises a supporting table, a conveying mechanism and a drying mechanism;

a support table: the upper surface of the support table is provided with a shell, the left side of the front surface of the shell is provided with a motor, an output shaft of the motor is rotatably connected with the left side of the front wall of the shell through a bearing I and extends towards the inside of the shell, and four corners of the lower end surface of the support table are provided with guide wheels;

a conveying mechanism: the supporting frame is arranged on the upper surface of the supporting table, the two first transmission shafts are symmetrically and rotatably connected to the upper end inside the supporting frame through bearings, the two second transmission shafts are rotatably connected to the middle inside the supporting frame through bearings, the two third transmission shafts are rotatably connected to the lower end inside the supporting frame through bearings, and the two first transmission shafts, the two second transmission shafts and the two third transmission shafts are in transmission connection through the conveying belts;

a drying mechanism: is arranged inside the shell;

wherein: the drying device also comprises a control switch group, the control switch group is arranged at the left end of the front surface of the shell, the input end of the control switch group is electrically connected with an external power supply, the output end of the control switch group is electrically connected with the input end of a motor, the moisture in the materials on the conveying belt is evaporated through the high temperature released by the heating pipe, so that the drying purpose is achieved, the heating pipe is distributed on the front side and the rear side of the supporting frame in an incompletely symmetrical distribution mode, the temperature distribution in the device can be more uniform, the conveying belt adopts multilayer conveying, the size of the device is directly reduced, in addition, the design of the guide wheels can be more convenient to move the device, the discharge port can be directly connected with the previous step of organic silicon production, the continuous feeding can be realized, the production efficiency is accelerated, the turnover of the materials can be realized in the falling process of the materials through the multilayer conveying, and the materials can be heated more uniformly through the structure of the rake, the drying effect is better.

Further, the right-hand member of conveyer belt is the notch cuttype and distributes, and the left end of three conveyer belt is ">" type and distributes, sets up like this and can let the material successive layer convey.

Furthermore, the conveying mechanism further comprises a main transmission gear, a direction adjusting gear, a second transmission gear, a synchronous gear and a third transmission gear, the main transmission gear is arranged at the front end of the first transmission shaft, the second transmission gear is arranged at the front end of the second transmission shaft, the two direction adjusting gears are respectively connected to the front wall surface of the shell in a rotating mode through five bearings, the two direction adjusting gears are connected in a meshing mode, the direction adjusting gears are respectively connected with the main transmission gear and the second transmission gear in a meshing mode, the synchronous gear is connected to the lower end of the inner wall surface of the shell in a rotating mode through six bearings, the synchronous gear is connected with the main transmission gear in a meshing mode, the third transmission gear is arranged at the front end of the third transmission shaft and is connected with the synchronous gear in a meshing mode, and the transmission effect is achieved.

Further, transport mechanism still includes the baffle, the baffle sets up respectively in the support body middle part of support frame, and two baffles that are located on same horizontal plane are from outside to inside slope setting, and two baffles that are located on same horizontal plane and adjacent conveyer belt upper surface edge contact can effectually prevent that the material from the conveyer belt edge landing.

Further, drying mechanism includes heating pipe and fan, the heating pipe sets up respectively in the front and back both sides of support frame, and the fan sets up in the inside right-hand member of support frame, and the output of control switch group is connected to the input of heating pipe and fan electricity respectively, plays the effect of drying, and the heating pipe adopts incomplete symmetrical distribution, can make inside temperature more even.

Further, drying mechanism still includes rake and spring, the rake rotates through the bearing respectively and connects in the inside of support frame both ends about, the upper end of spring respectively with the inside plate body fixed connection of support frame, the lower extreme of spring respectively with the lower fixed surface of rake be connected, the spring can make the bottom of rake all the time with the upper surface contact of conveyer belt, the rake can harrow even material, can let the material be heated more evenly.

Further, still include the feeder hopper, the feeder hopper sets up in the upper surface left side of shell, makes things convenient for the feeding.

Further, still include electronic flexible post, electronic flexible post sets up respectively in the middle of the bottom surface of brace table, and the output of control switch group is connected to electronic flexible post's input electricity, and electronic flexible post is used for fixed equipment.

Compared with the prior art, the utility model has the beneficial effects that: the dryer for producing organic silicon has the following advantages:

1. the output shaft of the motor is controlled to rotate clockwise by the control switch group, the output shaft of the motor is fixedly connected with the first transmission shaft, so that the first transmission shaft is driven to rotate, the conveyor belt at the upper end inside the support frame is further driven to operate, meanwhile, the first transmission shaft also drives the main transmission gear to rotate, further drives the direction-adjusting gear to rotate, further drives the second transmission gear to rotate, further drives the conveyor belt at the middle inside the support frame to operate, simultaneously, the main transmission gear also drives the synchronous gear to rotate, further drives the third transmission gear to rotate, further drives the conveyor belt at the lower end inside the support frame to operate, the volume of the equipment can be effectively reduced by adopting a multi-layer conveyor belt design, the equipment is convenient to move, the multi-layer conveyor belt can realize the turnover of materials in the falling process of the materials, and then the materials are raked uniformly by the rakes, the material heating can be more uniform, the condition that the material at the bottom of the conveyer belt cannot be heated is avoided, and the material can be fully dried.

2. Control heating pipe heating through control switch group, preheat about half a minute earlier, rethread control switch group control fan operation, the circulation of the inside air current of equipment is driven to the wind that the fan blows, and the heating pipe adopts the distribution mode of incomplete symmetry to distribute in both sides around the support frame, can make the inside temperature distribution of equipment more even to it is more even to let the material be heated.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic view of the internal cross-section of the transmission mechanism of the present invention;

FIG. 3 is an enlarged schematic view of the structure at the position A of the present invention;

FIG. 4 is a schematic cross-sectional view of the present invention

FIG. 5 is an enlarged view of the structure of the present invention at B.

In the figure: 1 supporting table, 2 guide wheels, 3 electric telescopic columns, 4 shells, 5 feed hoppers, 6 motors, 7 conveying mechanisms, 701 supporting frames, 702 conveying belts, 703 first transmission shafts, 704 second transmission shafts, 705 third transmission shafts, 706 main transmission gears, 707 direction adjusting gears, 708 second transmission gears, 709 synchronizing gears, 710 third transmission gears, 711 baffles, 8 drying mechanisms, 81 heating pipes, 82 fans, 83 rakes, 84 springs and 9 control switch sets.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-5, the present embodiment provides a technical solution: a drier for organic silicon production comprises a supporting table 1, a conveying mechanism 7 and a drying mechanism 8;

support table 1: the upper surface of the support table is provided with a shell 4, the left side of the front surface of the shell 4 is provided with a motor 6, an output shaft of the motor 6 is rotatably connected with the left side of the front wall of the shell 4 through a bearing I and extends towards the inside of the shell 4, and four corners of the lower end surface of the support table 1 are provided with guide wheels 2;

the conveying mechanism 7: the conveying mechanism 7 comprises a supporting frame 701, conveying belts 702, first transmission shafts 703, second transmission shafts 704 and third transmission shafts 705, wherein the supporting frame 701 is arranged on the upper surface of a supporting table 1, the two first transmission shafts 703 are symmetrically and rotatably connected to the upper end inside the supporting frame 701 through bearings, the two second transmission shafts 704 are rotatably connected to the middle inside the supporting frame 701 through bearings, the two third transmission shafts 705 are rotatably connected to the lower end inside the supporting frame 701 through bearings in a four-way mode, the two first transmission shafts 703, the two second transmission shafts 704 and the two third transmission shafts 705 are respectively in transmission connection through the conveying belts 702, the right end of the conveying belts 702 is in ladder-shaped distribution, the left ends of the three conveying belts 702 are in '>' shaped distribution, the conveying mechanism 7 further comprises a main transmission gear 706, a direction adjusting gear 707, a second transmission gear 708, a synchronizing gear 709 and a third transmission gear 710, the main transmission gear 706 is arranged at the front end of the first transmission shafts 703, the second transmission gear 708 is arranged at the front end of the second transmission shaft 704, the two direction-adjusting gears 707 are respectively connected to the front wall surface of the shell 4 through five bearings in a rotating manner, the two direction-adjusting gears 707 are in meshing connection, the direction-adjusting gears 707 are respectively in meshing connection with the main transmission gear 706 and the second transmission gear 708, the synchronizing gear 709 is connected to the lower end of the inner wall surface of the shell 4 through six bearings in a rotating manner, the synchronizing gear 709 is in meshing connection with the main transmission gear 706, the third transmission gear 710 is arranged at the front end of the third transmission shaft 705, the third transmission gear 710 is in meshing connection with the synchronizing gear 709, the transmission mechanism 7 further comprises baffles 711, the baffles 711 are respectively arranged in the middle of the frame body of the support frame 701, the two baffles 711 on the same horizontal plane are obliquely arranged from outside to inside, the two baffles 711 on the same horizontal plane are in contact with the edge of the upper surface of the adjacent transmission belt 702, and the operation of the motor 6 is controlled by the control switch group 9, the output shaft of the motor 6 rotates clockwise, and because the output shaft of the motor 6 is fixedly connected with the first transmission shaft 703, the first transmission shaft 703 is driven to rotate, the conveyor belt 702 at the upper end inside the support frame 701 is further driven to operate, meanwhile, the first transmission shaft 703 also drives the main transmission gear 706 to rotate, the direction-adjusting gear 707 is further driven to rotate, the second transmission gear 708 is further driven to rotate, the conveyor belt 702 in the middle inside the support frame 701 is further driven to operate, meanwhile, the main transmission gear 706 also drives the synchronous gear 709 to rotate, the third transmission gear 710 is further driven to rotate, the conveyor belt 702 at the lower end inside the support frame 701 is driven to operate, multilayer transmission is adopted, the staying time of materials on the conveyor belt 702 is prolonged, and the materials can be fully dried;

and a drying mechanism 8: the drying mechanism 8 comprises a heating pipe 81 and a fan 82, the heating pipe 81 is respectively arranged at the front side and the rear side of a support frame 701, the fan 82 is arranged at the right end inside the support frame 701, the input ends of the heating pipe 81 and the fan 82 are respectively and electrically connected with the output end of a control switch group 9, the drying mechanism 8 also comprises a rake 83 and a spring 84, the rake 83 is respectively and rotatably connected with the left end and the right end inside the support frame 701 through bearings, the upper end of the spring 84 is respectively and fixedly connected with the inner plate body of the support frame 701, the lower end of the spring 84 is respectively and fixedly connected with the lower surface of the rake 83, the heating pipe 81 is controlled by the control switch group 9 to be heated, the preheating is firstly carried out for about half a minute, then the fan 82 is controlled to operate by the control switch group 9, the air blown by the fan 82 drives the circulation of the air flow inside the equipment, the rake 83 uniformly rakes the materials, and the bottom of the rake 83 can be always contacted with the upper surface of the conveyor belt 702 by the spring 84, the heating pipes are distributed on the front side and the rear side of the supporting frame in an incomplete symmetrical distribution mode, so that the internal temperature distribution is more uniform, the material is heated more uniformly, the material is raked uniformly by the rakes 83, and the material drying effect is better;

wherein: the motor is characterized by further comprising a control switch group 9, wherein the control switch group 9 is arranged at the left end of the front surface of the shell 4, the input end of the control switch group 9 is electrically connected with an external power supply, and the output end of the control switch group 9 is electrically connected with the input end of the motor 6;

wherein: the feeding hopper 5 is arranged on the left side of the upper surface of the shell 4, so that the material can be conveniently discharged;

wherein: still include electronic flexible post 3, electronic flexible post 3 sets up respectively in the middle of the bottom surface of brace table 1, and the output of control switch group 9 is connected to electronic flexible post 3's input electricity, removes equipment to suitable position earlier during the use, adjusts the extension of electronic flexible post 3 through control switch group 9, makes the gasket and the ground in close contact with of flexible post lower surface, prevents that equipment from taking place to remove at the during operation.

The working principle of the dryer for producing organic silicon provided by the utility model is as follows: when the device is used, the device is moved to a proper position, the control switch group 9 is used for adjusting the electric telescopic column 3 to extend, so that the gasket on the lower surface of the telescopic column is in close contact with the ground, the device is prevented from moving during operation, the control switch group 9 is used for controlling the heating pipe 81 to heat, the preheating is firstly carried out for about half a minute, then the control switch group 9 is used for controlling the operation of the fan 82 and the motor 6, the air blown by the fan 82 drives the circulation of the air flow in the device, meanwhile, the output shaft of the motor 6 rotates clockwise, the output shaft of the motor 6 is fixedly connected with the first transmission shaft 703, so that the first transmission shaft 703 is driven to rotate, the conveyor belt 702 at the upper end inside the support frame 701 is further driven to operate, meanwhile, the first transmission shaft 703 also drives the main transmission gear 706 to rotate, the direction adjusting gear 707 is further driven to rotate, the second transmission gear 708 is further driven to rotate, and the conveyor belt 702 in the middle inside the support frame 701 is further driven to operate, meanwhile, the main transmission gear 706 also drives the synchronous gear 709 to rotate, so that the third transmission gear 710 is driven to rotate, the conveyor belt 702 at the lower end inside the support frame 701 is driven to operate, then materials are discharged, the materials are placed into the machine through the feed hopper 5, the materials firstly fall into the conveyor belt 702 at the upper end inside the support frame 701, then the materials tend to the middle position of the conveyor belt 702 through the baffle 711, then the materials are uniformly raked through the rakes 83, the bottoms of the rakes 83 can be always in contact with the upper surface of the conveyor belt 702 through the springs 84, the materials sequentially pass through the conveyor belt 702 inside the support frame 701, and then the materials flow out of the conveyor belt 702 at the lower end inside the support frame 701.

It should be noted that the motor 6 disclosed in the above embodiments may be a YZF22-0.2W motor, the fan 82 may be a W2E250-HL06-01 fan, the heating tube 81 may be a titanium heating tube, and the control switch set 9 is provided with switch buttons corresponding to the motor 6, the fan 82 and the heating tube 81 one by one for controlling the on-off operation thereof.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims

1. A desiccator of organosilicon production which characterized in that: comprises a supporting table (1), a conveying mechanism (7) and a drying mechanism (8);

support table (1): a shell (4) is arranged on the upper surface of the support platform, a motor (6) is arranged on the left side of the front surface of the shell (4), an output shaft of the motor (6) is rotatably connected with the left side of the front wall of the shell (4) through a bearing I and extends towards the inside of the shell (4), and guide wheels (2) are arranged at four corners of the lower end surface of the support platform (1);

conveying mechanism (7): the automatic transmission device comprises a support frame (701), a conveyor belt (702), first transmission shafts (703), second transmission shafts (704) and third transmission shafts (705), wherein the support frame (701) is arranged on the upper surface of a support table (1), the two first transmission shafts (703) are symmetrically and rotatably connected to the upper end of the interior of the support frame (701) through two bearings, the two second transmission shafts (704) are rotatably connected to the middle of the interior of the support frame (701) through three bearings, the two third transmission shafts (705) are rotatably connected to the lower end of the interior of the support frame (701) through four bearings, and the two first transmission shafts (703), the two second transmission shafts (704) and the two third transmission shafts (705) are in transmission connection through the conveyor belt (702);

drying mechanism (8): is arranged inside the shell (4);

wherein: still include control switch group (9), control switch group (9) set up in the front surface left end of shell (4), and external power source is connected to the input electricity of control switch group (9), and the input of motor (6) is connected to the output electricity of control switch group (9).

2. The drier for silicone production according to claim 1, wherein: the right ends of the conveyor belts (702) are distributed in a step shape, and the left ends of the three conveyor belts (702) are distributed in a shape of '>'.

3. The drier for silicone production according to claim 1, wherein: the transmission mechanism (7) further comprises a main transmission gear (706), direction-adjusting gears (707), a second transmission gear (708), a synchronous gear (709) and a third transmission gear (710), the main transmission gear (706) is arranged at the front end of the first transmission shaft (703), the second transmission gear (708) is arranged at the front end of the second transmission shaft (704), the two direction-adjusting gears (707) are respectively and rotatably connected to the front wall surface of the shell (4) through five bearings, the two direction-adjusting gears (707) are meshed and connected, the direction-adjusting gears (707) are respectively meshed and connected with the main transmission gear (706) and the second transmission gear (708), the synchronous gear (709) is rotatably connected to the lower end of the inner wall surface of the shell (4) through six bearings, the synchronous gear (709) is meshed and connected with the main transmission gear (706), the third transmission gear (710) is arranged at the front end of the third transmission shaft (705), the third transmission gear (710) is meshed with the synchronous gear (709).

4. The drier for silicone production according to claim 1, wherein: the conveying mechanism (7) further comprises baffle plates (711), the baffle plates (711) are respectively arranged in the middle of the support body of the support frame (701), the two baffle plates (711) located on the same horizontal plane are arranged in an inclined mode from outside to inside, and the two baffle plates (711) located on the same horizontal plane are in contact with the edges of the upper surfaces of the adjacent conveying belts (702).

5. The drier for silicone production according to claim 1, wherein: drying mechanism (8) include heating pipe (81) and fan (82), heating pipe (81) set up respectively in the front and back both sides of support frame (701), and fan (82) set up in the inside right-hand member of support frame (701), and the output of control switch group (9) is connected to the input of heating pipe (81) and fan (82) electricity respectively.

6. A dryer for the production of silicone according to claim 5, characterised in that: the drying mechanism (8) further comprises rakes (83) and springs (84), the rakes (83) are rotatably connected to the left end and the right end of the interior of the support frame (701) through bearings respectively, the upper ends of the springs (84) are fixedly connected with an inner plate body of the support frame (701) respectively, and the lower ends of the springs (84) are fixedly connected with the lower surfaces of the rakes (83) respectively.

7. The drier for silicone production according to claim 1, wherein: still include feeder hopper (5), feeder hopper (5) set up in the upper surface left side of shell (4).

8. The drier for silicone production according to claim 1, wherein: the electric telescopic column is characterized by further comprising an electric telescopic column (3), wherein the electric telescopic column (3) is arranged in the middle of the bottom surface of the supporting table (1) respectively, and the input end of the electric telescopic column (3) is electrically connected with the output end of the control switch group (9).