CN211823391U - A rapid cooling device for producing organosilicon - Google Patents

Abstract

The utility model discloses a rapid cooling device for producing organosilicon, including bottom plate, outer cooling structure, interior cooling structure and aeration unit, the upper surface of bottom plate is equipped with a supporting bench, the bottom surface four corners of bottom plate respectively with mounting panel fixed connection, the mounting hole symmetry sets up in the four corners of mounting panel, outer cooling structure sets up in a supporting bench's upper surface, and the upper end of outer cooling structure is provided with the connecting plate, interior cooling structure sets up in a supporting bench top, and is located the inside of outer cooling structure, aeration unit sets up in the right flank of connecting plate to correspond the installation with outer cooling structure, wherein: still include the control switch group, the upper surface at the bottom plate is set up in the control switch group, and external power source is connected to the input of control switch group, this a rapid cooling device for producing organosilicon, inside and outside two cooling structure make cooling efficiency improve and guarantee the cooling quality.

Description

A rapid cooling device for producing organosilicon

Technical Field

The utility model relates to a cooling device technical field specifically is a rapid cooling device for producing organosilicon.

Background

Organosilicon, namely organosilicon compound, mean contain Si-O bond and have at least one organic radical to link with silicon atom compound directly, usually also regard compound that make organic radical link with silicon atom as organosilicon compound through oxygen, sulphur, nitrogen, etc. conventionally, in the organosilicon production run, produce emulsion of this polymer under high-speed stirring, this is the same with principle of oil and water phase mixing, and need to cool it in the production run, it is not thorough to cool down usually to have in the existing cooling technology, cool down the poor effect, cool down the slow defect of efficiency, therefore, design a new kind of fast cooling device used for producing organosilicon to be imperative.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is to overcome current defect, provide a rapid cooling device for producing organosilicon, double-deck cooling structure has guaranteed the cooling quality, still makes cooling water cyclic utilization simultaneously, reduces the waste of water resource, can effectively solve the problem in the background art.

In order to achieve the above object, the utility model provides a following technical scheme: a rapid cooling device for producing organic silicon comprises a bottom plate, an outer cooling structure, an inner cooling structure and an aeration unit;

a bottom plate: the upper surface of the bottom plate is provided with a supporting table, four corners of the bottom surface of the bottom plate are respectively fixedly connected with the mounting plate, and the mounting holes are symmetrically arranged at the four corners of the mounting plate;

the outer cooling structure is arranged on the upper surface of the supporting table, and a connecting plate is arranged at the upper end of the outer cooling structure;

the inner cooling structure is arranged above the support table and is positioned inside the outer cooling structure;

an aeration unit: the aeration unit is arranged on the right side surface of the connecting plate and corresponds to the outer cooling structure;

wherein: still include control switch group, control switch group sets up in the upper surface of bottom plate, and external power source is connected to control switch group's input, and convenient dismantlement and installation have still accomplished water cycle's structure when guaranteeing the cooling, and inside and outside two cooling structures make cooling efficiency improve and guarantee the cooling quality.

Further, interior cooling structure includes inner chamber inlet tube, inner chamber outlet pipe, motor, circulating pipe, flight and inner chamber wall, inner chamber inlet tube and inner chamber outlet pipe symmetry set up in the upper surface of connecting plate, and the motor symmetry sets up in the upper surface of connecting plate, and circulating pipe's both ends are connected with the bottom of inner chamber inlet tube and inner chamber outlet pipe respectively, the upper end of flight and the output shaft of motor, the bottom and the brace table fixed connection of inner chamber wall, and the input of motor is connected with control switch group's output electricity, cools down through hydrologic cycle's technique, has practiced thrift the water resource when reaching the cooling purpose again.

Further, outer cooling structure includes outer chamber wall, through-hole, heat exchanger fin, exocoel water inlet and exocoel delivery port, the bottom of outer chamber wall and the last fixed surface of brace table are connected, and heat exchanger fin evenly distributed is in the surface of inner chamber wall, and the through-hole symmetry sets up in the lateral wall of heat exchanger fin, and exocoel water inlet and exocoel delivery port symmetry set up in the lower extreme lateral surface of outer chamber wall, and double-deck cooling structure has guaranteed the cooling quality.

Further, the aeration unit includes air pump, gas outlet, admission line, gas pocket and aeration pipe, the air pump sets up in the upper surface right side of connecting plate, and the inlet end of admission line is connected with the output of air pump, and the aeration pipe sets up in the clearance of inner chamber wall and outer chamber wall, and the inlet end of aeration pipe is connected with the output of admission line, and the gas outlet sets up in the right side surface of outer chamber wall, and gas pocket evenly distributed is on the surface of aeration pipe, and the input of air pump is connected with control switch group's output electricity, has accelerated cooling efficiency, saves time.

Further, still include feeder hopper and discharging pipe, the feeder hopper sets up in the center of connecting plate to be connected with the through-hole of inner chamber wall upper end, the discharging pipe sets up in the bottom center of inner chamber wall, and the discharging pipe runs through the through-hole at bottom plate center, and the inside of discharging pipe is established ties there is the pipe valve, and the organosilicon is conveniently added to the infundibulate feed inlet.

Compared with the prior art, the beneficial effects of the utility model are that: this quick cooling device of production organosilicon has following benefit:

1. the outer cavity water inlet, the outer cavity water outlet, the inner cavity water inlet pipe and the inner cavity water outlet pipe are connected with an external water chilling unit, so that cooling water is recycled while cooling is guaranteed, and waste of water resources is reduced;

2. the motor is operated by controlling the switch group, the output shaft of the motor drives the spiral sheet to rotate, so that the organic silicon can be uniformly cooled, the cooling quality is ensured, air is sent into the outer cavity wall through the aeration pipe and the air hole by the operation of the air pump, each part of moisture can be ensured to be fully exchanged with heat, the moisture waste is avoided, and the cooling efficiency can be accelerated;

3. the cooling water pipe in the inner cavity wall is cooled from the inside, the cooling water in the outer cavity wall is cooled through the heat exchange sheets by the heat transfer principle, the contact surface of the cooling water and the heat exchange sheets is increased by the through holes to be cooled at an accelerated speed, and the cooling efficiency is improved and the cooling quality is ensured by the inner and outer cooling structures.

Drawings

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

fig. 2 is a schematic view of the main sectional structure of the present invention.

In the figure: the device comprises a base plate 1, a support table 2, an outer cooling structure 3, an outer cavity wall 31, a through hole 32, a heat exchange plate 33, an outer cavity water inlet 34, an outer cavity water outlet 35, an inner cooling structure 4, an inner cavity water inlet 41, an inner cavity water outlet 42, a motor 43, a circulating water pipe 44, a spiral plate 45, an inner cavity wall 46, a connecting plate 5, an aeration unit 6, an air pump 61, an air outlet 62, an air inlet pipeline 63, an air hole 64, an aeration pipe 65, a control switch group 7, a feed hopper 8, a discharge pipe 9, a mounting plate 10 and a mounting hole.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-2, the present invention provides a technical solution: a rapid cooling device for producing organic silicon comprises a bottom plate 1, an outer cooling structure 3, an inner cooling structure 4 and an aeration unit 6;

bottom plate 1: the upper surface of the bottom plate 1 is provided with a support table 2, four corners of the bottom surface of the bottom plate 1 are respectively fixedly connected with the mounting plate 10, and the mounting holes 11 are symmetrically arranged at the four corners of the mounting plate 10, so that the disassembly and the assembly are convenient;

the outer cooling structure 3 is arranged on the upper surface of the support table 2, a connecting plate 5 is arranged at the upper end of the outer cooling structure 3, the outer cooling structure 3 comprises an outer chamber wall 31, through holes 32, heat exchange plates 33, an outer chamber water inlet 34 and an outer chamber water outlet 35, the bottom end of the outer chamber wall 31 is fixedly connected with the upper surface of the support table 2, the heat exchange plates 33 are uniformly distributed on the outer surface of an inner chamber wall 46, the through holes 32 are symmetrically arranged on the side wall of the heat exchange plates 33, the outer chamber water inlet 34 and the outer chamber water outlet 35 are symmetrically arranged on the outer side surface of the lower end of the outer chamber wall 31, and the double;

the inner cooling structure 4 is arranged above the support platform 2 and positioned inside the outer cooling structure 3, the inner cooling structure 4 comprises an inner cavity water inlet pipe 41, an inner cavity water outlet pipe 42, a motor 43, a circulating water pipe 44, a spiral sheet 45 and an inner cavity wall 46, the inner cavity water inlet pipe 41 and the inner cavity water outlet pipe 42 are symmetrically arranged on the upper surface of the connecting plate 5, the motor 43 is symmetrically arranged on the upper surface of the connecting plate 5, two ends of the circulating water pipe 44 are respectively connected with the bottom ends of the inner cavity water inlet pipe 41 and the inner cavity water outlet pipe 42, the upper end of the spiral sheet 45 is connected with an output shaft of the motor 43, the bottom end of the inner cavity wall 46 is fixedly connected with the support platform 2, an input end of the motor 43 is electrically connected with an output end of the control switch group 7, the temperature is;

the aeration unit 6: the aeration unit 6 is arranged on the right side surface of the connecting plate 5 and corresponds to the external cooling structure 3, the aeration unit 6 comprises an air pump 61, an air outlet 62, an air inlet pipeline 63, an air hole 64 and an aeration pipe 65, the air pump 61 is arranged on the right side of the upper surface of the connecting plate 5, the air inlet end of the air inlet pipeline 63 is connected with the output end of the air pump 61, the aeration pipe 65 is arranged in the gap between the inner cavity wall 46 and the outer cavity wall 31, the air inlet end of the aeration pipe 65 is connected with the exhaust end of the air inlet pipeline 63, the air outlet 62 is arranged on the right side surface of the outer cavity wall 31, the air holes 64 are uniformly distributed on the surface of the aeration pipe 65, the input end of the air pump 61 is electrically connected with the output;

wherein: still include control switch group 7, control switch group 7 sets up in the upper surface of bottom plate 1, and external power source is connected to control switch group 7's input, realizes can intelligently controlling.

Wherein: still include feeder hopper 8 and discharging pipe 9, feeder hopper 8 sets up in the center of connecting plate 5 to be connected with the through-hole of inner chamber wall 46 upper end, discharging pipe 9 sets up in the bottom center of inner chamber wall 46, and discharging pipe 9 runs through the through-hole at bottom plate 1 center, and discharging pipe 9's inside is established ties there is the pipe valve, and the organosilicon is conveniently added to the infundibulate feed inlet.

When in use: the mounting plate 10 is connected with the mounting part through the mounting hole 11 by using bolts, so as to realize the mounting and fixing of the bottom plate 1, the support table 2 and the upper structure, the outer cavity water inlet 34, the outer cavity water outlet 35, the inner cavity water inlet pipe 41 and the inner cavity water outlet pipe 42 are connected with an external water chilling unit, the cooling is ensured, the cooling water is recycled, the waste of water resources is reduced, the organic silicon is sent into the inner cavity wall 46 through the feed hopper 8, the motor 43 is operated by controlling the control switch unit 7, the output shaft of the motor 43 drives the spiral sheet 45 to rotate, the organic silicon can be uniformly cooled, the cooling quality is ensured, the air pump 61 is operated to send the air into the outer cavity wall 31 through the aeration pipe 65 and the air holes 64, the sufficient heat exchange of each part of water is ensured, the water waste is avoided, the cooling efficiency can be accelerated, the redundant gas is discharged through the air outlet 62, the contact surface of cold water and the heat exchange fins 33 is increased through the through holes 32, the cooling efficiency is improved and the cooling quality is guaranteed due to the internal and external double cooling structures, when the cooling process is finished, the motor 43 stops running, the spiral fins 45 are static, the manual valve on the discharge pipe 9 is opened, and the organosilicon after cooling is outwards discharged under the influence of gravity.

It should be noted that the motor 43 and the air pump 61 disclosed in this embodiment may be freely configured according to actual application scenarios, the motor 43 is suggested to be a 5IK150RGU-CF adjustable-speed motor available from wapont electromechanical limited, guan, and the air pump 61 may be a VAY8828 vacuum pump both new to sincerity technologies limited, and the control switch group 7 controls the motor 43 and the air pump 61 to operate by methods commonly used in the prior art.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (5)

1. A rapid cooling device for producing organosilicon which characterized in that: comprises a bottom plate (1), an outer cooling structure (3), an inner cooling structure (4) and an aeration unit (6);

base plate (1): the upper surface of the bottom plate (1) is provided with a support table (2), four corners of the bottom surface of the bottom plate (1) are respectively fixedly connected with the mounting plate (10), and the mounting holes (11) are symmetrically arranged at the four corners of the mounting plate (10);

the outer cooling structure (3) is arranged on the upper surface of the support table (2), and the upper end of the outer cooling structure (3) is provided with a connecting plate (5);

inner cooling structure (4): the inner cooling structure (4) is arranged above the support table (2) and is positioned inside the outer cooling structure (3);

aeration unit (6): the aeration unit (6) is arranged on the right side surface of the connecting plate (5) and is correspondingly arranged with the outer cooling structure (3);

wherein: the power supply device is characterized by further comprising a control switch group (7), wherein the control switch group (7) is arranged on the upper surface of the bottom plate (1), and the input end of the control switch group (7) is connected with an external power supply.

2. The rapid cooling device for producing organic silicon according to claim 1, wherein: interior cooling structure (4) include inner chamber inlet tube (41), inner chamber outlet pipe (42), motor (43), circulating water pipe (44), flight (45) and inner chamber wall (46), inner chamber inlet tube (41) and inner chamber outlet pipe (42) symmetry set up in the upper surface of connecting plate (5), and motor (43) symmetry sets up in the upper surface of connecting plate (5), and the both ends of circulating water pipe (44) are connected with the bottom of inner chamber inlet tube (41) and inner chamber outlet pipe (42) respectively, the upper end of flight (45) and the output shaft of motor (43), the bottom and the brace table (2) fixed connection of inner chamber wall (46), and the input of motor (43) is connected with the output electricity of control switch group (7).

3. The rapid cooling device for producing organic silicon according to claim 1, wherein: outer cooling structure (3) include outer chamber wall (31), through-hole (32), heat exchanger fin (33), exocoel water inlet (34) and exocoel delivery port (35), the bottom of outer chamber wall (31) is connected with the last fixed surface of brace table (2), and heat exchanger fin (33) evenly distributed is in the surface of inner chamber wall (46), and through-hole (32) symmetry sets up in the lateral wall of heat exchanger fin (33), and exocoel water inlet (34) and exocoel delivery port (35) symmetry set up in the lower extreme lateral surface of outer chamber wall (31).

4. The rapid cooling device for producing organic silicon according to claim 1, wherein: aeration unit (6) include air pump (61), gas outlet (62), admission line (63), gas pocket (64) and aeration pipe (65), air pump (61) set up in the upper surface right side of connecting plate (5), the inlet end of admission line (63) is connected with the output of air pump (61), aeration pipe (65) set up in the clearance of inner chamber wall (46) and exocoel wall (31), the inlet end and the exhaust end of admission line (63) of aeration pipe (65) are connected, gas outlet (62) set up in the right side surface of exocoel wall (31), gas pocket (64) evenly distributed is on the surface of aeration pipe (65), the input of air pump (61) is connected with the output electricity of control switch group (7).

5. The rapid cooling device for producing organic silicon according to claim 2, wherein: still include feeder hopper (8) and discharging pipe (9), feeder hopper (8) set up in the center of connecting plate (5) to be connected with the through-hole of inner chamber wall (46) upper end, discharging pipe (9) set up in the bottom center of inner chamber wall (46), and discharging pipe (9) run through the through-hole at bottom plate (1) center, and the inside of discharging pipe (9) is established ties there is the pipe valve.

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