CN114279178B

CN114279178B - Drying device is used in production of metal synthesis heterocyclic compound

Info

Publication number: CN114279178B
Application number: CN202111448847.2A
Authority: CN
Inventors: 王也铭; 张朝群; 刘力辉
Original assignee: Jilin Teachers Institute of Engineering and Technology
Current assignee: Jilin Teachers Institute of Engineering and Technology
Priority date: 2021-12-01
Filing date: 2021-12-01
Publication date: 2022-11-18
Anticipated expiration: 2041-12-01
Also published as: CN114279178A

Abstract

The invention discloses a drying device for metal synthesis heterocyclic compound production, which comprises a main body mechanism, a multi-surface stress type stagnation and air-separation mechanism, a freezing type airflow circulation heating mechanism and a feeding and discharging mechanism, wherein the multi-surface stress type stagnation and air-separation mechanism is arranged on the main body mechanism, the freezing type airflow circulation heating mechanism is arranged on the side wall of the main body mechanism, the feeding and discharging mechanism is arranged on one side of the main body mechanism, which is far away from the freezing type airflow circulation heating mechanism, and the multi-surface stress type stagnation and air-separation mechanism comprises a rotation separation mechanism, a vibration contact mechanism and an impurity stagnation mechanism. The invention belongs to the field of heterocyclic compounds, and particularly relates to a drying device for producing a metal synthetic heterocyclic compound; the invention provides a drying device for producing a metal synthetic heterocyclic compound, which can increase the contact area of a heterozygote and hot gas, accelerate the drying of the heterozygote by gas flow and recycle the gas.

Description

Drying device is used in production of metal synthesis heterocyclic compound

Technical Field

The invention belongs to the technical field of heterocyclic compounds, and particularly relates to a drying device for metal synthesis heterocyclic compound production.

Background

The metal-synthesized heterocyclic compound is an organic compound having a heterocyclic structure in a molecule. The atoms constituting the ring contain at least one hetero atom in addition to carbon atoms. Is the most numerous class of organic compounds. The most common heteroatoms are nitrogen, sulfur, oxygen.

The prior heterocyclic compound drying device has the following problems:

1. the traditional drying device only dries raw materials and does not quickly discharge moisture in the raw materials, so that the drying speed is low;

2. most of the existing drying devices turn over materials in a stirring mode, and the materials are crowded in a drying box, so that the contact area of hot air is reduced, and the overall drying efficiency is influenced;

3. the existing drying device can not collect and clean dust adsorbed on the surface of a material.

Disclosure of Invention

Aiming at the situation and overcoming the defects of the prior art, the scheme provides a drying device for producing the metal synthetic heterocyclic compound, aiming at the problems that the contact area of a metal synthetic heterozygote and hot air is not large and the discharge efficiency of vapor-containing gas is poor, creatively combines a resonance principle, a centrifugal effect and a magnetic induction phenomenon, increases the contact area of the heterozygote and the hot air under the action of scattered spreading through an arranged multi-surface stress type stagnation and separation mechanism, improves the drying efficiency of the heterozygote, and solves the technical problems that the stirring mechanism is not used for stirring, overturning and drying (the stirring mechanism is convenient and quick to use) and the stirring mechanism is not used for overturning and drying (the stirring mechanism is overturned to cause materials to be crowded, and the materials are difficult to be uniformly and quickly dried), and the gas in the heat preservation box body is driven to flow under the action of centrifugal motion, so that the evaporation of the surface moisture of the heterozygote is accelerated; meanwhile, the invention adopts a cold and hot combination mode to intervene in the drying work of the heterozygote, the cyclic utilization of the drying air flow is realized through the arranged freezing type air flow cyclic heating mechanism, the entrance of water vapor and dust in the outside air is reduced, the condensation and freezing of the water vapor in the water vapor-containing gas and the conveying of hot air are finished through the bidirectional acting force of the vortex tube, the freezing of the water vapor is finished under the condition of no intervention of any condensation mechanism under the combination of the air jet effect, so that the drying use of the circulating gas is carried out, the suspension time of the heterozygote in the air is increased and the contact time of the water-containing surface of the heterozygote and the hot air is increased through the intervention of a gas flow structure from bottom to top, the drying efficiency of the heterozygote is improved to a certain degree, and the rapid and uniform drying of the heterozygote is really realized; provided is a drying device for producing a metal synthetic heterocyclic compound, which can increase the contact area between a hybrid and hot gas, can accelerate the drying of the hybrid by gas flow, and can recycle the gas.

The technical scheme adopted by the scheme is as follows: the utility model provides a drying device is used in production of metal synthesis heterocyclic compound, stagnate empty mechanism, the freezing type air current circulation heating mechanism of getting rid of including main part mechanism, multiaspect atress type and go up unloading mechanism, multiaspect atress type stagnates empty mechanism of getting rid of and locates on the main part mechanism, freezing type air current circulation heating mechanism locates the main part mechanism lateral wall, go up unloading mechanism and locate one side that freezing type air current circulation heating mechanism was kept away from to the main part mechanism, multiaspect atress type stagnates empty mechanism of getting rid of and gets rid of the mechanism and stagnates the mechanism including rotation separation mechanism, vibration contact mechanism and impurity, rotation separation mechanism locates the main part mechanism upper wall, the diapire of main part mechanism is located to the vibration contact mechanism, impurity stagnates the empty mechanism and locates inside the main part mechanism.

As a further preferred option of the scheme, the main mechanism comprises a bottom plate, support columns, a heat preservation box body, water absorption cotton and a hot air box, the hot air box is arranged in the middle of the upper wall of the main mechanism, a plurality of groups of the support columns are arranged on the upper wall of the bottom plate outside the hot air box, the heat preservation box body is arranged on the upper wall of the support columns, and the water absorption cotton is symmetrically arranged on the inner walls of two sides of the heat preservation box body.

Preferably, the rotary separating mechanism comprises a rotary motor, a rotating shaft, a collecting box, a rotary disc, a drying cylinder, a separating port and a through port, the rotary motor is arranged on the upper wall of the heat preservation box body, the collecting box is arranged on the inner wall of the top of the heat preservation box body, the rotating shaft penetrates through the collecting box and the upper wall of the heat preservation box body and is arranged at the power output end of the rotary motor, the rotary disc is arranged at one end, away from the rotary motor, of the rotating shaft, the drying cylinder is arranged on the bottom wall of the rotary disc, multiple groups of exhaust pipes are respectively arranged on the bottom wall of the collecting box, the upper wall of the rotary disc and the upper wall of the drying cylinder, and multiple groups of the separating port are arranged on the side wall of one end, away from the rotary disc, of the drying cylinder; the vibration contact mechanism comprises an air cylinder, an arranging opening, a connecting plate, a spring, a bearing plate and a sliding opening, wherein the arranging opening is formed in the bottom wall of the heat preservation box body, the air cylinder is arranged in the arranging opening, the sliding opening is formed in the bottom wall of the drying cylinder, the connecting plate is arranged on the inner wall of the bottom of the drying cylinder in a sliding mode, the power end of the air cylinder penetrates through the sliding opening and is formed in the bottom wall of the connecting plate, a plurality of groups of springs are arranged on the upper wall of the connecting plate, the bearing plate is arranged on one side, away from the connecting plate, of the spring, and the bearing plate is arranged on the inner wall of the drying cylinder in a sliding mode; the coil is arranged on the inner wall of the top of the drying cylinder, the iron rod is arranged on the upper wall of the drying cylinder, and the iron rod is arranged in the coil; the heterozygote is placed on the upper wall of a bearing plate, a cylinder is started to drive a connecting plate to slide along the inner wall of a drying cylinder through a power end, the bearing plate is driven by the connecting plate through a spring, the bearing plate drives the heterozygote to move up and down in the drying cylinder, the heterozygote is spread under the stretching and contracting thrust of the cylinder in a scattered mode, the contact surface of the heterozygote and hot air is enlarged, so that the surface moisture of the heterozygote is evaporated quickly, a rotary motor is started to drive a rotary disc through a rotary shaft to rotate, the rotary disc drives the drying cylinder to rotate, the hot air without the moisture is thrown out of the drying cylinder through a separation port under the action of centrifugal motion, the hot air with the moisture enters a heat insulation box body, absorbent cotton absorbs the moisture in the hot air, so that the overall humidity in the heat insulation box body is reduced, the drying cylinder drives the air in the heat insulation box body to flow while rotating, so that the drying speed of the heterozygote is accelerated, when the heterozygote moves up and down in the drying cylinder, the heterozygote, the surface dust falls off, an iron rod is electrified, so that a magnetic field is generated in a coil, the dust is reduced in gravity, the dust falling speed is reduced, and the dust is absorbed by the dust on the surface of the heterozygote, so that the dust is cleaned.

The freezing type airflow circulation heating mechanism comprises an impurity filtering mechanism, an air conditioning conveying mechanism and a water drop condensing mechanism, wherein the impurity filtering mechanism is arranged on the side wall of the insulation box body, the air conditioning conveying mechanism is arranged on one side, away from the impurity filtering mechanism, of the insulation box body, the water drop condensing mechanism is arranged on one side of the insulation box body, the impurity filtering mechanism comprises an air pump, an air exhaust pipe, an air outlet pipe, a filter box, a filter screen and a drying pipe, the air pump is arranged on the side wall of the top of the insulation box body, the filter box is arranged on the side wall of the insulation box body below the air pump, the air exhaust pipe penetrates through the upper wall of the insulation box body and is communicated between the collection box and the power input end of the air pump, the air outlet pipe is communicated between the filter box and the power output end of the air pump, multiple groups of the filter screens are arranged on the inner wall of the filter box, and the drying pipe is communicated with one side, away from the air outlet pipe, of the filter box; the water drop condensation mechanism comprises a condensation box, copper blocks, condensation ports, copper plates, heat conducting columns and a circulating pipe, wherein the condensation box is arranged on the side wall of the heat insulation box body on one side of the filter box, one end of the drying pipe, far away from the filter box, is communicated with the side wall of the condensation box, the copper blocks are arranged on the inner wall of one end, close to the drying pipe, of the condensation box, multiple groups of the condensation ports are arranged on the side wall of the copper blocks, the copper plates are arranged on the inner wall of the condensation box on one side of the copper blocks, far away from the drying pipe, the heat conducting columns are arranged between the copper plates, and the circulating pipe is communicated with the bottom wall of the condensation box, between the copper blocks and the copper plates; the cold air conveying mechanism comprises a vortex tube, an air compressor, a cold air tube, a hot air tube, a power tube and an exhaust tube, the air compressor is arranged on the side wall of the insulation box body below the condensation box, one end of the circulating tube, far away from the condensation box, is arranged at the power input end of the air compressor, the vortex tube is arranged on one side, far away from the filter box, of the insulation box body, the power tube is arranged between the power output end of the air compressor and the power input end of the vortex tube, the cold air tube is communicated between the cold air end of the vortex tube and one side, far away from the drying tube, of the condensation box, the cold air tube is vertically arranged with the copper plate, the hot air tube is communicated between the hot air end of the vortex tube and the side wall of the hot air box, and the exhaust tube is communicated with the bottom wall of the condensation box, far away from the heat conducting column, of the copper plate; the air pump collects dust adsorbed inside a magnetic field through the opening, the dust-containing gas enters the inside of the collection box, the dust-containing gas inside the collection box enters the inside of the filter box through the air exhaust pipe through the air outlet pipe, the dust-containing gas is filtered layer by layer through the filter screen and then enters the inside of the condensation box through the drying pipe, the air compressor is started to deliver the generated compressed gas to the inside of the vortex tube through the power pipe, the vortex tube takes the compressed gas as a power source, the generated cold air is sprayed to the surface of the vortex tube through the cold air pipe by the vortex tube, the vortex tube rapidly cools under the effect of air jet flow, the copper plate conducts cold temperature to the inside of the copper block through the heat conduction column, the filtered gas enters the inside of the copper block through the condensation opening, water vapor inside the gas is frozen on the inner wall of the condensation opening, the dried gas is absorbed and used by the air compressor through the circulating pipe, thereby completing the recycling of the dry gas, the energy consumption of the drying equipment is reduced, the cold air after impacting the copper plate is discharged through the exhaust pipe, and the hot gas generated by the hot gas enters the inside of the collection box through the hot gas pipe for storage and use.

Wherein, hot-air box upper wall is equipped with annular jet-propelled mechanism, annular jet-propelled mechanism includes intake pipe, pressure manifold, jet-propelled pipe and air jet, hot-air box top is located to the pressure manifold, hot-air box upper wall both ends are located to the intake pipe symmetry, the intake pipe intercommunication is located between pressure manifold and the hot-air box, jet-propelled pipe multiunit intercommunication is located between pressure manifold and the insulation can, the air jet is the multiunit respectively and locates the drying cylinder diapire, loading board upper wall and the connecting plate upper wall of settling the mouthful outside, and inside hot-air box enters into the pressure manifold through the intake pipe, and the pressure manifold spouts hot air into the insulation can through jet-propelled pipe inside, and inside hot air enters into the drying cylinder through the air jet, the steam from the bottom up flows for the heterozygote increases at aerial dwell time, thereby makes hot air and heterozygote surface contact time increase, has improved the drying efficiency of heterozygote to a certain extent.

Preferably, go up unloading mechanism and include discharge gate, folding axle, magnetism door, magnet, iron plate, cock board and feed opening, the discharge gate is located the insulation can and is kept away from one side of condensation mouth, folding axisymmetric locates discharge gate top inner wall, magnetism door rotates and locates between the folding axle, magnetism door diapire is located to iron plate, the discharge gate diapire is located to magnet, magnet and iron plate pass through magnetic force actuation, dry bobbin base portion lateral wall is located to the feed opening, and the discharge gate sets up with the feed opening level, in the feed opening was located to the cock board, outside pulling magnetism door, magnetism door rotates around folding axle and opens, extracts the cock board from the feed opening inside, and it is inside to place dry heterozygote.

Furthermore, a controller is arranged on the side wall of the heat insulation box body.

Still further, the controller is respectively and electrically connected with rotating electrical machines, cylinder, iron bar, aspiration pump and air compressor.

The beneficial effect who adopts above-mentioned structure this scheme to gain as follows:

1. according to the scheme, the multi-surface stress type stagnation and separation mechanism is arranged through the stagnation effect, so that the contact area of the heterozygote and hot gas is increased, the heterozygote is dried in a multi-position and dead-angle-free manner, and the heterozygote is dried in a stagnation manner fully under the combined use of the rotary separation mechanism, the vibration contact mechanism and the impurity stagnation mechanism;

2. the heterozygote is scattered and paved by the arranged vibration contact mechanism, so that the hot air contact area is increased, the heterozygote is placed on the upper wall of the bearing plate, the cylinder is started to drive the connecting plate to slide along the inner wall of the drying cylinder through the power end, the connecting plate drives the bearing plate through the spring, the bearing plate drives the heterozygote to move up and down in the drying cylinder, the heterozygote is scattered and paved under the stretching and contracting thrust of the cylinder, the contact surface of the heterozygote and the hot air is increased, and the surface moisture of the heterozygote is quickly evaporated;

3. the drying device has the advantages that separation treatment of evaporated moisture is realized through the arranged rotary separation mechanism, gas is driven to flow at the same time, drying of heterozygotes is accelerated, the rotary motor is started to drive the rotary disc to rotate through the rotary shaft, the rotary disc drives the drying cylinder to rotate, due to the fact that the moisture has certain weight, hot gas without moisture is thrown out of the inside of the drying cylinder through the separation port under the action of centrifugal motion, the hot gas with the moisture enters the heat preservation box body, the water absorption cotton absorbs the moisture in the hot gas, the humidity of the whole inside of the heat preservation box body is reduced, the drying cylinder drives the gas inside the heat preservation box body to flow while rotating, and therefore the drying speed of the heterozygotes is accelerated;

4. the dust attached to the surface of the heterozygote is adsorbed by the arranged impurity emptying mechanism, when the heterozygote moves up and down in the drying cylinder, the dust on the surface of the heterozygote falls off, the iron rod is electrified, so that a magnetic field is generated in the coil, and the dust is adsorbed by the magnetic field due to the fact that the dust gravity is small and the falling speed of the dust is slow, so that the dust on the surface of the heterozygote is cleaned;

5. the invention adopts the form of cold and heat treatment to recycle the gas containing water vapor, and realizes the transportation of hot gas and the condensation drying of the gas containing water vapor through the double-sided action of the vortex tube;

6. the device is characterized in that the device is provided with an impurity filtering mechanism, so that the impurity in the dust-containing gas is filtered, the air pump collects dust adsorbed in the magnetic field through a port, the dust-containing gas enters the collecting box, the dust-containing gas in the collecting box enters the filtering box through an air outlet pipe through an air exhaust pipe, and the dust-containing gas is filtered layer by layer through a filter screen and then enters the condensing box through a drying pipe;

7. the condensation drying treatment of gas containing water vapor is realized through the arranged water drop condensation mechanism, the air compressor is started to convey the generated compressed gas into the vortex tube through the power tube, the vortex tube takes the compressed gas as a power source, the vortex tube sprays the generated cold air to the surface of the vortex tube through the cold air tube, the vortex tube rapidly cools under the effect of air jet flow, the copper plate conducts the cold temperature into the copper block through the heat conduction column, the filtered gas enters the copper block through the condensation port, and the water vapor in the gas is frozen on the inner wall of the condensation port;

8. the circulation use of gas is realized through the arranged cold gas conveying mechanism, the dried gas is absorbed and used by the air compressor through the circulating pipe, so that the circulation use of the dried gas is completed, the energy consumption of drying equipment is reduced, the cold gas impacting the copper plate is discharged through the exhaust pipe, and the hot gas generated by the vortex tube enters the hot gas box through the hot gas pipe for storage and use;

9. the refrigeration type drying of the gas containing the water vapor is realized under the condition that no condensing equipment is involved;

10. under the condition of no intervention of stirring equipment, the heterozygote can be spread and turned over when being dried.

Drawings

FIG. 1 is a schematic diagram of the overall structure of a drying device for producing a metal-synthesized heterocyclic compound according to the present invention;

FIG. 2 is a perspective view of a drying device for producing a metal synthetic heterocyclic compound according to the present invention;

FIG. 3 is an exploded view of a drying apparatus for producing a metal-synthesized heterocyclic compound according to the present invention;

FIG. 4 is a front view of a drying device for producing metal synthetic heterocyclic compound according to the present invention;

FIG. 5 is a rear view of a drying apparatus for producing a metal-synthesized heterocyclic compound according to the present embodiment;

FIG. 6 is a left side view of a drying device for producing metal-synthesized heterocyclic compounds according to the present embodiment;

FIG. 7 isbase:Sub>A sectional view taken along section line A-A of FIG. 4;

FIG. 8 is a sectional view of portion B-B of FIG. 6;

FIG. 9 is a schematic structural diagram of a drying cylinder of a drying device for producing metal synthetic heterocyclic compounds according to the present invention;

FIG. 10 is a schematic structural view of an annular air injection mechanism of a drying device for producing metal synthetic heterocyclic compounds according to the present invention;

FIG. 11 is a schematic structural view of a vibration contact mechanism of a drying device for producing metal synthetic heterocyclic compounds according to the present invention;

FIG. 12 is a schematic structural view of a bead condensing mechanism of a drying device for producing metal-synthesized heterocyclic compounds according to the present embodiment;

FIG. 13 is a circuit diagram of a controller of a drying device for producing a metal-synthesized heterocyclic compound according to the present invention;

FIG. 14 is a circuit diagram of a rotary motor of a drying device for producing metal synthetic heterocyclic compounds according to the present invention;

FIG. 15 is a circuit diagram of an air pump of a drying device for producing metal synthetic heterocyclic compounds according to the present embodiment;

FIG. 16 is a circuit diagram of a drying device cylinder for metal synthesis heterocyclic compound production according to the present invention;

fig. 17 is a schematic block diagram of a drying device for producing metal synthetic heterocyclic compound according to the present invention.

Wherein, 1, a main body mechanism, 2, a bottom plate, 3, a support column, 4, a heat preservation box body, 5, absorbent cotton, 6, a hot air box, 7, a multi-surface stress type stagnation and separation mechanism, 8, a rotary separation mechanism, 9, a rotary motor, 10, a rotary shaft, 11, a collection box, 12, a rotary disk, 13, a drying cylinder, 14, a separation port, 15, a vibration contact mechanism, 16, an air cylinder, 17, a placement port, 18, a connecting plate, 19, a spring, 20, a bearing plate, 21, a sliding port, 22, an impurity stagnation mechanism, 23, a coil, 24, an iron rod, 25, a freezing type air flow circulation heating mechanism, 26, an impurity filtering mechanism, 27, an air pump, 28, an air suction pipe, 29 and an air outlet pipe, 30, a filter box, 31, a filter screen, 32, a drying tube, 33, a cold air conveying mechanism, 34, a vortex tube, 35, an air compressor, 36, a cold air tube, 37, a hot air tube, 38, a power tube, 39, a water droplet condensing mechanism, 40, a condensing box, 41, a copper block, 42, a condensing port, 43, a copper plate, 44, a heat conducting column, 45, a circulating tube, 46, a feeding and discharging mechanism, 47, a discharging port, 48, a folding shaft, 49, a magnetic door, 50, a magnet, 51, an iron plate, 52, a plug plate, 53, a discharging port, 54, a controller, 55, a through port, 56, an exhaust tube, 57, an annular air injection mechanism, 58, an air inlet tube, 59, a collecting pipe, 60, an air injection tube, 61 and an air injection port.

The accompanying drawings are included to provide a further understanding of the present solution and are incorporated in and constitute a part of this specification, illustrate embodiments of the solution and together with the description serve to explain the principles of the solution and not to limit the solution.

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 solution.

In the description of the present solution, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present solution.

As shown in fig. 1-3, this scheme provides a drying device is used in production of metal synthesis heterocyclic compound, including main body mechanism 1, multiaspect atress type stagnates empty throwing mechanism 7, freezing type air current circulation heating mechanism 25 and goes up unloading mechanism 46, multiaspect atress type stagnates empty throwing mechanism 7 and locates on main body mechanism 1, freezing type air current circulation heating mechanism 25 locates 1 lateral wall of main body mechanism, go up unloading mechanism 46 and locate one side that main body mechanism 1 kept away from freezing type air current circulation heating mechanism 25, multiaspect atress type stagnates empty throwing mechanism 7 and includes rotation separating mechanism 8, vibration contact mechanism 15 and impurity stagnation mechanism 22, rotation separating mechanism 8 locates 1 upper wall of main body mechanism, vibration contact mechanism 15 locates 1 diapire of main body mechanism, impurity stagnation mechanism 22 locates inside main body mechanism 1.

As shown in fig. 2, the main body mechanism 1 comprises a bottom plate 2, support columns 3, an insulation box body 4, water-absorbing cotton 5 and a hot air box 6, the hot air box 6 is arranged at the middle position of the upper wall of the main body mechanism 1, the plurality of groups of support columns 3 are arranged on the upper wall of the bottom plate 2 outside the hot air box 6, the insulation box body 4 is arranged on the upper wall of the support columns 3, and the water-absorbing cotton 5 is symmetrically arranged on the inner walls of the two sides of the insulation box body 4.

As shown in fig. 7-9, the rotating and separating mechanism 8 includes a rotating electrical machine 9, a rotating shaft 10, a collecting box 11, a rotating disk 12, a drying cylinder 13, a separating port 14 and a through port 55, the rotating electrical machine 9 is disposed on the upper wall of the heat insulation box 4, the collecting box 11 is disposed on the inner wall of the top of the heat insulation box 4, the rotating shaft 10 penetrates through the collecting box 11 and the upper wall of the heat insulation box 4 and is disposed at the power output end of the rotating electrical machine 9, the rotating disk 12 is disposed at one end of the rotating shaft 10 far away from the rotating electrical machine 9, the drying cylinder 13 is disposed at the bottom wall of the rotating disk 12, a plurality of sets of exhaust pipes 56 are respectively disposed at the bottom wall of the collecting box 11, the upper wall of the rotating disk 12 and the upper wall of the drying cylinder 13, and a plurality of sets of separating ports 14 are disposed at one end side wall of the drying cylinder 13 far away from the rotating disk 12; the vibration contact mechanism 15 comprises an air cylinder 16, a mounting hole 17, a connecting plate 18, a spring 19, a bearing plate 20 and a sliding hole 21, wherein the mounting hole 17 is formed in the bottom wall of the heat preservation box body 4, the air cylinder 16 is arranged in the mounting hole 17, the sliding hole 21 is formed in the bottom wall of the drying cylinder 13, the connecting plate 18 is arranged on the inner wall of the bottom of the drying cylinder 13 in a sliding mode, the power end of the air cylinder 16 penetrates through the sliding hole 21 and is arranged on the bottom wall of the connecting plate 18, multiple groups of the springs 19 are arranged on the upper wall of the connecting plate 18, the bearing plate 20 is arranged on one side, far away from the connecting plate 18, of the springs 19, and the bearing plate 20 is arranged on the inner wall of the drying cylinder 13 in a sliding mode; the coil 23 is arranged on the inner wall of the top of the drying cylinder 13, the iron rod 24 is arranged on the upper wall of the drying cylinder 13, and the iron rod 24 is arranged in the coil 23; the heterozygote is placed on the upper wall of a bearing plate 20, an air cylinder 16 is started to drive a connecting plate 18 to slide along the inner wall of a drying cylinder 13 through a power end, the bearing plate 20 is driven by the connecting plate 18 through a spring 19, the bearing plate 20 drives the heterozygote to move up and down in the drying cylinder 13, the heterozygote is scattered under the stretching and contracting thrust of the air cylinder 16, the contact surface of the heterozygote and hot air is enlarged, so that the surface moisture of the heterozygote is evaporated quickly, a rotary motor 9 is started to drive a rotary disc 12 to rotate through a rotary shaft 10, the rotary disc 12 drives the drying cylinder 13 to rotate, the hot air without the moisture is thrown out of the drying cylinder 13 through a separation port 14 under the action of centrifugal motion, the hot air with the moisture enters the heat-insulation box 4, moisture-absorbing cotton 5 absorbs the moisture in the hot air, so as to reduce the overall humidity in the heat-insulation box 4, the drying cylinder 13 drives the air in the heat-insulation box 4 to flow while rotating, so as to accelerate the drying speed of the heterozygote, when the heterozygote moves up and down in the drying cylinder 13, the surface dust falls, an iron rod 24 is electrified, so that the magnetic field is generated in the coil 23, the dust is absorbed by the dust, and the dust falls slowly, so as to clean the dust surface.

As shown in fig. 2, 3, 5 and 6, the freezing type air flow circulation heating mechanism 25 includes an impurity filtering mechanism 26, an air-conditioning conveying mechanism 33 and a water drop condensing mechanism 39, the impurity filtering mechanism 26 is disposed on the side wall of the heat preservation box 4, the air-conditioning conveying mechanism 33 is disposed on one side of the heat preservation box 4 away from the impurity filtering mechanism 26, the water drop condensing mechanism 39 is disposed on one side of the heat preservation box 4, the impurity filtering mechanism 26 includes an air suction pump 27, an air suction pipe 28, an air outlet pipe 29, a filtering box 30, a filtering net 31 and a drying pipe 32, the air suction pump 27 is disposed on the side wall of the top of the heat preservation box 4, the filtering box 30 is disposed on the side wall of the heat preservation box 4 below the air suction pump 27, the air suction pipe 28 penetrates through the upper wall of the heat preservation box 4 and is communicated between the collecting box 11 and the power input end of the air suction pump 27, the air outlet pipe 29 is communicated between the filtering box 30 and the power output end of the air suction pump 27, a plurality of groups of the filtering nets 31 are disposed on the inner wall of the filtering box 30, and the drying pipe 32 is communicated with one side of the filtering box 30 away from the air outlet pipe 29; the water drop condensation mechanism 39 comprises a condensation box 40, a copper block 41, a condensation port 42, a copper plate 43, a heat conduction column 44 and a circulating pipe 45, wherein the condensation box 40 is arranged on the side wall of the insulation box body 4 on one side of the filter box 30, one end of the drying pipe 32, which is far away from the filter box 30, is communicated with the side wall of the condensation box 40, the copper block 41 is arranged on the inner wall of one end of the condensation box 40, which is close to the drying pipe 32, multiple groups of the condensation ports 42 are arranged on the side wall of the copper block 41, the copper plate 43 is arranged on the inner wall of the condensation box 40, which is far away from the drying pipe 32, the heat conduction column 44 is arranged between the copper plate 43 and the copper block 41, and the circulating pipe 45 is communicated with the bottom wall of the condensation box 40, which is arranged between the copper block 41 and the copper plate 43; the cold air conveying mechanism 33 comprises a vortex tube 34, an air compressor 35, a cold air tube 36, a hot air tube 37, a power tube 38 and an exhaust tube 56, wherein the air compressor 35 is arranged on the side wall of the heat preservation box body 4 below the condensation box 40, one end of the circulating tube 45, which is far away from the condensation box 40, is arranged at the power input end of the air compressor 35, the vortex tube 34 is arranged on one side, which is far away from the filter box 30, of the heat preservation box body 4, the power tube 38 is arranged between the power output end of the air compressor 35 and the power input end of the vortex tube 34, the cold air tube 36 is communicated between the cold air end of the vortex tube 34 and one side, which is far away from the drying tube 32, of the condensation box 40, the cold air tube 36 is perpendicular to the copper plate 43, the hot air tube 37 is communicated between the hot air end of the vortex tube 34 and the side wall of the hot air box 6, and the exhaust tube 56 is communicated with the bottom wall of the condensation box 40, which is far away from the heat conducting column 44, of the copper plate 43; the air pump 27 collects dust adsorbed inside the magnetic field through the port 55, the dust-containing gas enters the collecting box 11, the dust-containing gas inside the collecting box 11 enters the filtering box 30 through the air exhaust pipe 28 through the air outlet pipe 29, the dust-containing gas is filtered layer by layer through the filtering net 31 and then enters the condensing box 40 through the drying pipe 32, the air compressor 35 is started to deliver the generated compressed gas to the interior of the vortex tube 34 through the power pipe 38, the vortex tube 34 uses the compressed gas as a power source, the vortex tube 34 sprays the generated cold air to the surface of the vortex tube 34 through the cold air pipe 36, the vortex tube 34 rapidly cools under the effect of air jet flow, the copper plate 43 conducts cold temperature into the copper block 41 through the heat conduction column 44, the filtered gas enters the interior of the copper block 41 through the condensing port 42, vapor in the gas is frozen on the inner wall of the condensing port 42, and the dried gas is absorbed and used by the air compressor 35 through the circulating pipe 45, so that the cycle of the dry gas is completed, the energy consumption of the drying equipment is reduced, the cold gas after impacting the cold gas is exhausted through the exhaust pipe 56, and the hot gas generated by the vortex tube 34 enters the copper plate 6 for storage.

As shown in fig. 3, 7 and 10, the upper wall of the hot air box 6 is provided with an annular air injection mechanism 57, the annular air injection mechanism 57 comprises air inlet pipes 58, a collecting pipe 59, air injection pipes 60 and air injection ports 61, the collecting pipe 59 is arranged above the hot air box 6, the air inlet pipes 58 are symmetrically arranged at two ends of the upper wall of the hot air box 6, the air inlet pipes 58 are communicated between the collecting pipe 59 and the hot air box 6, a plurality of groups of air injection pipes 60 are communicated between the collecting pipe 59 and the insulation box body 4, the air injection ports 61 are respectively arranged at the bottom wall of the drying cylinder 13 outside the mounting port 17, the upper wall of the bearing plate 20 and the upper wall of the connecting plate 18, hot air in the hot air box 6 enters the collecting pipe 59 through the air inlet pipes 58, the collecting pipe 59 injects the hot air into the insulation box body 4 through the air injection pipes 60, the hot air enters the inside of the drying cylinder 13 through the air injection ports 61, the hot air flows from bottom to top, so that the residence time of the hot air in the air is increased, thereby increasing the surface contact time of the hot air and the hybrid, and improving the drying efficiency of the hybrid to a certain extent.

As shown in fig. 4 and fig. 7, the loading and unloading mechanism 46 includes a discharge port 47, a folding shaft 48, a magnetic door 49, a magnet 50, an iron plate 51, a plug plate 52 and a discharge port 53, the discharge port 47 is disposed on a side of the insulation box 4 away from the condensation port 42, the folding shaft 48 is symmetrically disposed on an inner wall of a top of the discharge port 47, the magnetic door 49 is rotatably disposed between the folding shafts 48, the iron plate 51 is disposed on a bottom wall of the magnetic door 49, the magnet 50 is disposed on a bottom wall of the discharge port 47, the magnet 50 and the iron plate 51 are attracted by magnetic force, the discharge port 53 is disposed on a bottom side wall of the drying cylinder 13, the discharge port 47 and the discharge port 53 are horizontally disposed, the plug plate 52 is disposed in the discharge port 53, the magnetic door 49 is pulled outwards, the magnetic door 49 rotates around the folding shaft 48 to open, the plug plate 52 is pulled out from the interior of the discharge port 53, and a heterozygote to be dried is placed in the drying cylinder 13.

As shown in FIG. 3, the side wall of the thermal insulation case 4 is provided with a controller 54.

As shown in fig. 13 to 17, the controller 54 is electrically connected to the rotary electric machine 9, the air cylinder 16, the iron rod 24, the suction pump 27, and the air compressor 35, respectively.

During specific use, in an initial state, the plug plate 52 is arranged on the inner wall of the feed opening 53, the magnetic door 49 is vertically arranged, and the magnet 50 and the iron plate 51 are adsorbed together through magnetic force.

The first embodiment is as follows: putting the heterozygote to be dried into the drying cylinder 13, pulling the magnetic door 49 outwards, rotating and opening the magnetic door 49 around the folding shaft 48, pulling the plug plate 52 out of the discharging opening 53, putting the heterozygote to be dried into the drying cylinder 13, putting the heterozygote on the upper wall of the bearing plate 20, after the putting is finished, inserting the plug plate 52 into the discharging opening 53, pulling the magnetic door 49, rotating the magnetic door 49 around the folding shaft 48 to drive the iron plate 51 to be attached to the magnet 50, and magnetically adsorbing and fixing the magnet 50 and the iron plate 51 to start drying the heterozygote.

The second embodiment is as follows: the controller 54 controls the cylinder 16 to start, the cylinder 16 starts to drive the connecting plate 18 to slide along the inner wall of the drying cylinder 13 through a power end, the connecting plate 18 drives the bearing plate 20 through the spring 19, the bearing plate 20 drives the heterozygote to move up and down in the drying cylinder 13, the heterozygote is spread under the stretching and shrinking thrust of the cylinder 16, the contact surface of the heterozygote and hot air is enlarged, so that the moisture on the surface of the heterozygote is evaporated quickly, the magnet 50 controls the rotating motor 9 to start, the rotating motor 9 starts to drive the rotating disc 12 to rotate through the rotating shaft 10, the rotating disc 12 drives the drying cylinder 13 to rotate, the hot air without the moisture is thrown out of the drying cylinder 13 through the separating port 14 under the action of centrifugal motion, the hot air with the moisture enters the heat preservation box 4, the water-absorbing cotton 5 absorbs the moisture in the hot air, so as to reduce the humidity of the whole inside of the heat preservation box 4, the drying cylinder 13 drives the air inside of the heat preservation box 4 to flow while rotating, so as to accelerate the drying speed of the heterozygote, when the heterozygote moves up and down in the inside the drying cylinder 13, the drying cylinder 54 controls the iron rod 24, so that the dust is absorbed by the dust, the dust is absorbed by the dust, the dust is reduced by the dust generated by the magnetic field, and the dust generated by the magnetic field of the magnetic field.

Example three: the controller 54 controls the air pump 27 to start, the air pump 27 collects dust adsorbed in the magnetic field through the port 55, the dust-containing gas enters the collecting box 11, the dust-containing gas in the collecting box 11 enters the filtering box 30 through the air exhaust pipe 28 and the air outlet pipe 29, the dust-containing gas is filtered layer by layer through the filtering net 31 and then enters the condensing box 40 through the drying pipe 32, the controller 54 controls the air compressor 35 to start, the air compressor 35 starts to deliver the generated compressed gas to the interior of the vortex tube 34 through the power pipe 38, the vortex tube 34 uses the compressed gas as a power source, the vortex tube 34 sprays the generated cold air to the surface of the vortex tube 34 through the cold air pipe 36, the vortex tube 34 rapidly cools under the effect of air jet flow, and the copper plate 43 conducts the cold temperature into the copper block 41 through the heat conduction column 44, filtered gas enters the copper block 41 through the condensation port 42, water vapor in the gas is frozen on the inner wall of the condensation port 42, the dried gas is absorbed and used by the air compressor 35 through the circulating pipe 45, so that the recycling of the dried gas is completed, the energy consumption of drying equipment is reduced, cold air impacting the copper plate 43 is discharged through the exhaust pipe 56, hot gas generated by the vortex tube 34 enters the hot gas box 6 through the hot gas pipe 37 for storage and use, hot gas in the hot gas box 6 enters the collecting pipe 59 through the air inlet pipe 58, the collecting pipe 59 sprays the hot gas into the heat preservation box body 4 through the gas spraying pipe 60, the hot gas enters the drying cylinder 13 through the gas spraying port 61, the hot gas flows from bottom to top, the residence time of the heterozygote in the air is increased, the contact time of the hot gas and the surface of the heterozygote is increased, and the drying efficiency of the heterozygote is improved to a certain extent; repeating the above operations when using the product for the next time.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present solution 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 solution, the scope of which is defined in the appended claims and their equivalents.

The present solution and its embodiments have been described above, but the description is not limited thereto, and what is shown in the drawings is only one of the embodiments of the present solution, and the actual structure is not limited thereto. In summary, those skilled in the art should be able to devise similar structural modes and embodiments without inventing any departure from the spirit and scope of the present disclosure.

Claims

1. The utility model provides a drying device is used in production of metal synthesis heterocyclic compound which characterized in that: the multi-face stress type stagnation and separation mechanism comprises a main body mechanism (1), a multi-face stress type stagnation and separation mechanism (7), a freezing type air flow circulation heating mechanism (25) and a feeding and discharging mechanism (46), wherein the multi-face stress type stagnation and separation mechanism (7) is arranged on the main body mechanism (1), the freezing type air flow circulation heating mechanism (25) is arranged on the side wall of the main body mechanism (1), the feeding and discharging mechanism (46) is arranged on one side, far away from the freezing type air flow circulation heating mechanism (25), of the main body mechanism (1), the multi-face stress type stagnation and separation mechanism (7) comprises a rotation separation mechanism (8), a vibration contact mechanism (15) and an impurity stagnation mechanism (22), the rotation separation mechanism (8) is arranged on the upper wall of the main body mechanism (1), the vibration contact mechanism (15) is arranged on the bottom wall of the main body mechanism (1), and the impurity stagnation mechanism (22) is arranged inside the main body mechanism (1);

the main mechanism (1) comprises a bottom plate (2), support columns (3), a heat preservation box body (4), water absorption cotton (5) and a hot air box (6), wherein the hot air box (6) is arranged in the middle of the upper wall of the main mechanism (1), a plurality of groups of the support columns (3) are arranged on the upper wall of the bottom plate (2) at the outer side of the hot air box (6), the heat preservation box body (4) is arranged on the upper wall of the support columns (3), and the water absorption cotton (5) is symmetrically arranged on the inner walls at two sides of the heat preservation box body (4);

the rotary separating mechanism (8) comprises a rotary motor (9), a rotating shaft (10), a collecting box (11), a rotating disc (12), a drying cylinder (13), a separating port (14) and a through port (55), wherein the rotary motor (9) is arranged on the upper wall of the heat preservation box body (4), the collecting box (11) is arranged on the inner wall of the top of the heat preservation box body (4), the rotating shaft (10) penetrates through the collecting box (11) and the upper wall of the heat preservation box body (4) to be arranged at the power output end of the rotary motor (9), the rotating disc (12) is arranged at one end, far away from the rotary motor (9), of the rotating shaft (10), the drying cylinder (13) is arranged at the bottom wall of the rotating disc (12), a plurality of groups of exhaust pipes (56) are respectively arranged at the bottom wall of the collecting box (11), the upper wall of the rotating disc (12) and the upper wall of the drying cylinder (13), and a plurality of groups of the separating port (14) are arranged at one end, far away from the rotating disc (12), of the drying cylinder (13);

the vibration contact mechanism (15) comprises an air cylinder (16), a placement opening (17), a connecting plate (18), a spring (19), a bearing plate (20) and a sliding opening (21), the placement opening (17) is formed in the bottom wall of the heat preservation box body (4), the air cylinder (16) is arranged in the placement opening (17), the sliding opening (21) is formed in the bottom wall of the drying cylinder (13), the connecting plate (18) is arranged on the inner wall of the bottom of the drying cylinder (13) in a sliding mode, the power end of the air cylinder (16) penetrates through the sliding opening (21) and is arranged on the bottom wall of the connecting plate (18), multiple groups of the springs (19) are arranged on the upper wall of the connecting plate (18), the bearing plate (20) is arranged on one side, far away from the connecting plate (18), of the spring (19), and the bearing plate (20) is arranged on the inner wall of the drying cylinder (13) in a sliding mode;

the coil (23) is arranged on the inner wall of the top of the drying cylinder (13), the iron rod (24) is arranged on the upper wall of the drying cylinder (13), and the iron rod (24) is arranged in the coil (23);

the freezing type airflow circulating heating mechanism (25) comprises an impurity filtering mechanism (26), a cold air conveying mechanism (33) and a water drop condensing mechanism (39), wherein the impurity filtering mechanism (26) is arranged on the side wall of the heat preservation box body (4), the cold air conveying mechanism (33) is arranged on one side, far away from the impurity filtering mechanism (26), of the heat preservation box body (4), and the water drop condensing mechanism (39) is arranged on one side of the heat preservation box body (4);

the impurity filtering mechanism (26) comprises an air suction pump (27), an air suction pipe (28), an air outlet pipe (29), a filtering box (30), a filtering net (31) and a drying pipe (32), wherein the air suction pump (27) is arranged on the side wall of the top of the heat preservation box body (4), the filtering box (30) is arranged on the side wall of the heat preservation box body (4) below the air suction pump (27), the air suction pipe (28) penetrates through the upper wall of the heat preservation box body (4) and is communicated between the collecting box (11) and the power input end of the air suction pump (27), the air outlet pipe (29) is communicated between the filtering box (30) and the power output end of the air suction pump (27), multiple groups of the filtering nets (31) are arranged on the inner wall of the filtering box (30), and the drying pipe (32) is communicated with one side of the filtering box (30) far away from the air outlet pipe (29);

the water drop condensation mechanism (39) comprises a condensation box (40), a copper block (41), a condensation port (42), a copper plate (43), heat conduction columns (44) and a circulating pipe (45), wherein the condensation box (40) is arranged on the side wall of the heat insulation box body (4) on one side of the filter box (30), one end, far away from the filter box (30), of the drying pipe (32) is communicated with the side wall of the condensation box (40), the copper block (41) is arranged on the inner wall, close to the drying pipe (32), of the condensation box (40), multiple groups of the condensation port (42) are arranged on the side wall of the copper block (41), the copper plate (43) is arranged on the inner wall of the condensation box (40) on one side, far away from the drying pipe (32), of the copper block (41), the heat conduction columns (44) are arranged between the copper plate (43) and the copper block (41), and the circulating pipe (45) is communicated with the bottom wall of the condensation box (40) between the copper block (41) and the copper plate (43);

the cold air conveying mechanism (33) comprises a vortex tube (34), an air compressor (35), a cold air tube (36), a hot air tube (37), a power tube (38) and an exhaust tube (56), the air compressor (35) is arranged on the side wall of the heat preservation box body (4) below the condensation box (40), one end, far away from the condensation box (40), of the circulating tube (45) is arranged at the power input end of the air compressor (35), the vortex tube (34) is arranged on one side, far away from the filter box (30), of the heat preservation box body (4), the power tube (38) is arranged between the power output end of the air compressor (35) and the power input end of the vortex tube (34), the cold air tube (36) is communicated between the cold air end of the vortex tube (34) and one side, far away from the drying tube (32), of the condensation box (40), the cold air tube (36) is perpendicular to the copper plate (43), the hot air tube (37) is communicated between the cold air end of the vortex tube (34) and the side wall of the hot air box (6), and the exhaust tube (56) is communicated with the bottom wall of the condensation box (40) arranged on one side, far away from the condensation box column (44);

hot-air box (6) upper wall is equipped with annular jet-propelled mechanism (57), annular jet-propelled mechanism (57) include intake pipe (58), pressure manifold (59), fumarole (60) and jet orifice (61), hot-air box (6) top is located in pressure manifold (59), intake pipe (58) symmetry is located hot-air box (6) upper wall both ends, intake pipe (58) intercommunication is located between pressure manifold (59) and hot-air box (6), fumarole (60) multiunit intercommunication is located between pressure manifold (59) and insulation box (4), jet orifice (61) multiunit are located respectively and are settled drying cylinder (13) diapire, loading board (20) upper wall and connecting plate (18) upper wall in the mouth (17) outside.