CN114955280B

CN114955280B - Methyl trifluoroalkynoate product dehydration storage device

Info

Publication number: CN114955280B
Application number: CN202210374829.2A
Authority: CN
Inventors: 曹卫东; 魏康; 丁波
Original assignee: Jiangsu Chunjiangruntian Agrochemical Co ltd
Current assignee: Jiangsu Chunjiangruntian Agrochemical Co ltd
Priority date: 2022-04-11
Filing date: 2022-04-11
Publication date: 2023-10-27
Anticipated expiration: 2042-04-11
Also published as: CN114955280A

Abstract

The invention discloses a dehydration storage device for a methyl trifluoroalkynoate product, which comprises a storage tank, wherein a matched heat preservation box is sleeved on the outer wall of the storage tank, a heat preservation cavity is arranged on the inner wall of the heat preservation box, a through hot air pipe and a through cold air pipe are arranged on the outer wall of the heat preservation cavity, a first electromagnetic valve is arranged on the inner wall of the hot air pipe, a second electromagnetic valve is arranged on the inner wall of the cold air pipe, a high temperature control component and a low temperature control component are arranged on the inner wall of the heat preservation cavity, the high temperature control component is electrically connected with the first electromagnetic valve, and the low temperature control component is electrically connected with the second electromagnetic valve. The invention can monitor the temperature in the insulation can for storing the methyl trifluoroalkynoate product, can keep the environment of the storage tank in a constant temperature state all the time, is not influenced by low temperature or high temperature, is favorable for storing the methyl trifluoroalkynoate product, improves the storage stability of the device, and can carry out temperature measurement verification on the spaces with different depths again when the abnormal temperature is detected, and can improve the resource utilization rate.

Description

Methyl trifluoroalkynoate product dehydration storage device

Technical Field

The invention relates to the technical field of storage, in particular to a dehydration storage device for a methyl trifluoroalkynoate product.

Background

In 2003, the effect of indoor insecticide using tetrafluoromethrin and permethrin as main raw materials is much stronger than that of the first pyrethrin series products. After 2008, the "tefluthrin" synthesized by taking methyl trifluoroalkynate as a raw material is used as a third-generation pesticide, and the insecticidal efficacy is more superior to that of the first chrysanthemic acid series products, so that the research and development of the "alkynate" and the market supply are greatly promoted. In the process of synthesizing the pyrethrin, tetrafluorobenzyl alcohol, dextro first chrysanthemic acid and dextro DV chrysanthemic acid are easy to obtain, and the production of the sevoflurane pyrethrin which takes the methyl trifluoropropargyl as a raw material is difficult, because the alkyne ester is difficult to obtain, so the preparation of the alkyne ester is particularly important. To obtain a relatively low cost "alkyne ester", a clean production route is followed: separating, collecting and rectifying again. After the preparation problem of 'alkyne ester' is solved, a powerful driving force is provided for producing the trifluoro methyl alkynoate product.

The produced methyl trifluoroalkynoate product is generally stored in a storage tank, but the existing storage tank only has a storage function and does not have an automatic monitoring and temperature regulating function, so that the performance of the methyl trifluoroalkynoate product is easily influenced when the weather environment is changed and tested, and the performance of the product is reduced.

Disclosure of Invention

The invention aims to provide a dehydration storage device for a methyl trifluoroalkynoate product, which aims to solve the problems in the background art.

In order to solve the technical problems, the invention provides the following technical scheme: the utility model provides a trifluoro methyl alkyne acid product dehydration storage device, includes the holding vessel, holding vessel outer wall cover is equipped with assorted insulation can, the insulation can inner wall is equipped with the heat preservation cavity, the heat preservation cavity outer wall is equipped with the hot-blast main and the cold air pipe that link up, the hot-blast main inner wall is equipped with solenoid valve one, the cold air pipe inner wall is equipped with solenoid valve two, the heat preservation cavity inner wall is equipped with high temperature control assembly and low temperature control assembly, high temperature control assembly with solenoid valve one electric connection, low temperature control assembly with solenoid valve two electric connection.

Further, the high-temperature control assembly comprises a first supporting plate, an electric telescopic rod is arranged on the outer wall of the first supporting plate, a first memory metal strip is arranged at the bottom of the first electric telescopic rod, a first contact is arranged on the outer wall of the first supporting plate on one side of the first memory metal strip, the first contact is electrically connected with the first electric telescopic rod, a first microswitch is arranged below the first memory metal strip on the outer wall of the first supporting plate, the first microswitch is electrically connected with the first electromagnetic valve, a second contact is arranged between the first microswitch and the first memory metal strip, and the second contact is electrically connected with the first electric telescopic rod, so that the temperature inside the heat-preservation cavity is raised.

Further, the low temperature control assembly comprises a second supporting plate, an electric telescopic rod II is arranged on the outer wall of the second supporting plate, a memory metal strip II is arranged at the bottom of the second electric telescopic rod II, a third contact is arranged on one side of the second memory metal strip II, the third contact is electrically connected with the second electric telescopic rod II, a second microswitch is arranged below the second memory metal strip II on the outer wall of the second supporting plate, the second microswitch is electrically connected with the second electromagnetic valve, a fourth contact is arranged between the second microswitch and the second memory metal strip II, and the fourth contact is electrically connected with the second electric telescopic rod to achieve the purpose of reducing the temperature inside the heat preservation cavity.

Further, the inner wall of the heat-insulating cavity is provided with a support column which is rotationally connected below the storage tank, the top of the support column is provided with a groove, and the bottom of the storage tank is provided with a convex block matched with the groove to stably support the storage tank.

Further, the outer wall of the support column is sleeved with a first gear, the inner wall of the heat-insulating cavity is provided with a second gear meshed with the first gear, the bottom of the heat-insulating box is provided with a motor, and an output shaft of the motor is fixedly connected with the second gear, so that the purpose of driving the storage tank to rotate is achieved.

Further, the inner wall of the heat-insulating cavity is rotationally provided with an annular rack meshed with the gear in a two-phase manner, the outer wall of the annular rack is provided with a stirring rod, and a plurality of blades are arranged outside the stirring rod and can drive gas in the heat-insulating cavity to be mixed.

Further, a through connecting pipeline I is arranged on one side of the outer wall of the heat preservation cavity, a through connecting pipeline II is arranged on the other side of the outer wall of the heat preservation cavity, the connecting pipeline I and one end of the connecting pipeline II are all extended to the outer side of the heat preservation box, an annular protruding block I is sleeved on the outer wall of the connecting pipeline I, a threaded hole I is symmetrically arranged on the inner wall of the annular protruding block I, and an annular clamping block is arranged on the outer wall of the connecting pipeline I, so that the purpose of enabling two heat preservation boxes to be communicated together is achieved.

Further, the second outer wall of the connecting pipeline is provided with an annular clamping groove matched with the annular clamping block, and the inner wall of the annular clamping groove is provided with a sealing ring in a matched mode to seal the joint of the annular clamping block and the annular clamping groove.

Furthermore, the outer wall of the connecting pipeline II is provided with an annular convex block II, the inner wall of the annular convex block II is symmetrically provided with fastening bolts which are rotationally connected, and the fastening bolts are meshed with the threaded holes I to fix the connecting pipeline II and the connecting pipeline I together.

Further, the second outer wall of the connecting pipeline is provided with a control ring which is rotationally connected on one side of the second annular projection, the outer wall of the control ring is provided with a third gear, the outer wall of the fastening bolt is sleeved with a fourth gear meshed with the third gear, and meanwhile, the rotation of the two fastening bolts is controlled, so that the working efficiency is improved.

Compared with the prior art, the invention has the following beneficial effects:

1. according to the invention, the heat-preserving cavity, the hot air pipe, the cold air pipe, the electromagnetic valve I, the electromagnetic valve II, the high-temperature control component and the low-temperature control component are arranged, so that the temperature in the heat-preserving box storing the methyl trifluoroalkynoate product can be monitored, the environment where the storage tank is positioned is always in a constant temperature state and cannot be influenced by low temperature or high temperature, the storage of the methyl trifluoroalkynoate product is facilitated, the storage stability of the device is improved, when the temperature in the heat-preserving cavity is abnormal, the memory metal strip can be deformed, the temperature in the heat-preserving cavity can be correspondingly regulated by starting the high-temperature control component or the low-temperature control component, the aim of automatically regulating and controlling the storage temperature is fulfilled, in addition, in the process that the electric telescopic rod drives the memory metal strip to move to start the high-low temperature component, the memory metal strip can move in a vertical space, the temperature of different depths in the heat-preserving cavity can be detected, the space of different depths can be measured again, whether the abnormal conditions of the current temperature belong to local special conditions can be verified, the situation can not be caused by the local temperature to the special conditions, the whole device is started, a large quantity of the motor is improved, the temperature can be accurately distributed in the annular blades can be fully, the heat-preserving cavity can be fully realized, the temperature can be well regulated, and the temperature can be well stirred, and the temperature can be well kept inside the heat-preserving cavity, and the temperature can be well distributed in the air, and the heat-preserving cavity can be well, and the temperature can be well kept.

2. The invention can drive the storage tank storing the methyl trifluoroalkynoate product to rotate through arranging the support column, the groove, the convex block and the first gear, so that the methyl trifluoroalkynoate product in the storage tank is mixed under the action of centrifugal force, the temperature of the methyl trifluoroalkynoate product can be averaged, the condition that the temperature of the methyl trifluoroalkynoate product close to a heat preservation cavity is normal and the temperature of the methyl trifluoroalkynoate product far away from the heat preservation cavity is abnormal is avoided, the storage of the methyl trifluoroalkynoate product is not influenced, the same power source is adopted for product mixing and gas mixing, the resource is maximized, the resource utilization rate is improved, the first heat preservation box, the second heat preservation box and the second heat preservation box can be arranged together through the first connecting pipeline and the second connecting pipeline when a plurality of heat preservation boxes are simultaneously used, the temperature in a plurality of boxes can be carried out by only utilizing the first hot air blower and the first air cooler, the production cost is reduced, the storage of the methyl trifluoroalkynoate product can not be influenced, the first heat preservation box can be quickly realized, the first heat preservation box can be quickly compressed and deformed through the first connecting pipeline, the second heat preservation box, the sealing ring can be completely compressed and deformed through the annular clamping groove, the sealing ring can be completely, the sealing ring can be compressed and deformed through the annular clamping groove, the sealing device can be connected with the sealing ring and the sealing ring, the sealing device can be connected with the sealing device through the annular clamping groove, the sealing device can be deformed through the sealing ring and the sealing device, and the sealing device can be simultaneously, one side can be deformed through the sealing and the sealing device, and the sealing device can be used through the sealing and the sealing device through the sealing device and the sealing device through the sealing device and the sealing device, and the working efficiency is greatly improved.

Drawings

The accompanying drawings are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate the invention and together with the embodiments of the invention, serve to explain the invention. In the drawings:

FIG. 1 is a front cross-sectional view of the entirety of the present invention;

FIG. 2 is a side cross-sectional view of the whole of the present invention

FIG. 3 is a schematic view of the structure of the annular rack of the present invention;

FIG. 4 is a schematic view of the structure of the support column of the present invention;

FIG. 5 is a schematic view of the bump structure of the present invention;

FIG. 6 is a schematic view of the structure of the first connecting pipe of the present invention;

FIG. 7 is a schematic view of a second connecting pipe structure according to the present invention;

FIG. 8 is a schematic view of a first connecting pipe and a second connecting pipe of the present invention connected together;

FIG. 9 is an enlarged schematic view of the invention at A in FIG. 1;

FIG. 10 is an enlarged schematic view of the present invention at B in FIG. 1;

FIG. 11 is an enlarged schematic view of the present invention at C in FIG. 1;

FIG. 12 is an enlarged schematic view of the invention at D in FIG. 1;

in the figure: 1. a storage tank; 2. an insulation box; 3. a heat-preserving cavity; 4. a hot air pipe; 5. a cold air pipe; 6. a first electromagnetic valve; 7. a second electromagnetic valve; 8. a high temperature control assembly; 9. a cryogenic control assembly; 10. a first supporting plate; 11. an electric telescopic rod I; 12. a first memory metal strip; 13. a first contact; 14. a micro switch I; 15. a second contact; 16. a second supporting plate; 17. an electric telescopic rod II; 18. a second memory metal strip; 19. a third contact; 20. a micro switch II; 21. a contact fourth; 22. a support column; 23. a groove; 24. a bump; 25. a first gear; 26. a second gear; 27. a motor; 28. an annular rack; 29. a stirring rod; 30. a blade; 31. a first connecting pipeline; 32. a second connecting pipeline; 33. annular convex blocks I; 34. a first threaded hole; 35. an annular clamping block; 36. an annular clamping groove; 37. a seal ring; 38. annular convex blocks II; 39. a fastening bolt; 40. a control loop; 41. a third gear; 42. and a gear IV.

Detailed Description

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

Referring to fig. 1-5 and fig. 9-12, the present invention provides the following technical solutions: a trifluoro methyl acetylide product dehydration storage device comprises a storage tank 1, a matched insulation box 2 is sleeved on the outer wall of the storage tank 1, an insulation cavity 3 is arranged on the inner wall of the insulation box 2, a through hot air pipe 4 and a through cold air pipe 5 are arranged on the outer wall of the insulation cavity 3, a first electromagnetic valve 6 is arranged on the inner wall of the hot air pipe 4, a second electromagnetic valve 7 is arranged on the inner wall of the cold air pipe 5, a high-temperature control assembly 8 and a low-temperature control assembly 9 are arranged on the inner wall of the insulation cavity 3, the high-temperature control assembly 8 is electrically connected with the first electromagnetic valve 6, the low-temperature control assembly 9 is electrically connected with the second electromagnetic valve 7, the high-temperature control assembly 8 comprises a first supporting plate 10, an electric telescopic rod 11 is arranged on the outer wall of the first supporting plate 10, a first memory metal strip 12 is arranged at the bottom of the electric telescopic rod 11, a first contact 13 is arranged on one side of the first memory metal strip 12, a first micro-switch 14 is arranged on the outer wall of the first supporting plate 10, a second electromagnetic valve 14 is electrically connected with the first electromagnetic valve 11, a second contact 16 is electrically connected with the first electric telescopic rod 16, a second contact 16 is arranged on the second electric telescopic rod 16 is electrically connected with the first electric rod 16, a first contact 16 is electrically connected with the second electric telescopic rod 16, a second contact 16 is electrically connected with the first contact 16 is arranged on the second electric rod 16, a second contact 16 is electrically telescopic rod 18 is electrically connected with the first contact 16, a second contact 16 is electrically 18, a first contact 16 is electrically 18 is electrically connected with the first electric rod 18, the utility model discloses a heat preservation device, including a storage tank 1, a heat preservation cavity, a motor 27 is arranged at the bottom of the storage tank 2, a support column 22 is arranged at the top of the support column 22, a protruding block 24 matched with the protruding block 23 is arranged at the bottom of the storage tank 1, a gear 25 is sleeved on the outer wall of the support column 22, a gear 26 meshed with the gear 25 is arranged on the inner wall of the heat preservation cavity 3, a motor 27 is arranged at the bottom of the heat preservation cavity 2, a contact fourth 21 is arranged between the micro switch 20 and the memory metal strip 18, the contact fourth 21 is electrically connected with an electric telescopic rod 17, a support column 22 connected with the inner wall of the heat preservation cavity 3 in a rotating mode is arranged below the storage tank 1, a groove 23 is arranged at the top of the support column 22, a plurality of blades 30 are arranged at the outer wall of the annular rack 28 outside the stirring rod 29.

The specific implementation mode is as follows: when in use, the methyl trifluoroalkynoate product is dehydrated and stored in the storage tank 1, then the storage tank 1 is placed in the heat insulation box 2, the convex blocks 24 at the bottom of the storage tank 1 are matched with the grooves 23 on the inner wall of the support column 22, the storage tank 1 is used for storing the methyl trifluoroalkynoate product, and the surrounding temperature is monitored at the same time, so that the surrounding temperature is kept in a constant temperature state, the methyl trifluoroalkynoate product is stored, when the surrounding temperature is reduced to a certain temperature, the first memory metal strip 12 can be deformed, because the first memory metal strip 12 is in a Z shape at one end before being deformed, and the sharp angle of the Z-shaped end of the non-deformed memory metal strip is contacted with the first contact 13, when the first memory metal strip 12 is deformed and is not contacted with the first contact 13 after being straightened as a whole, the electric telescopic rod I11 is started to extend the electric telescopic rod I11, the electric telescopic rod I11 extends to drive the memory metal strip I12 to move downwards until one end of the memory metal strip I12 contacts with the micro switch I14 below, the micro switch I14 is triggered, the micro switch I14 controls the electromagnetic valve I6 to be opened, hot air is discharged into the heat preservation cavity 3 through the hot air pipe 4, the temperature around the storage tank 1 is increased, the influence of low temperature on the storage of methyl trifluoroalkynoate product is avoided, in the process that the electric telescopic rod I11 drives the memory metal strip I12 to move downwards, if the temperature below the inside of the heat preservation cavity 3 does not reach the critical value for deforming the memory metal strip I12, the memory metal strip I12 can recover the shape before deformation, one end of the memory metal strip I is in a Z shape again, and at the moment, the sharp corner of one end in the Z shape contacts with the contact II 15, the electric telescopic rod I11 is controlled to be shortened by the contact II 15, so that the electric telescopic rod I11 drives the memory metal strip I12 to move back to the initial position, the micro switch I14 is not triggered, the whole device is not started to regulate the temperature in the heat insulation cavity 3, the resource quantity is prevented from being caused, the space with different depths is measured by the memory metal strip I12 in the moving process, the whole device is ensured not to be started due to the special local temperature, the waste of a large amount of resources is prevented, the accuracy of monitoring temperature is improved, after the ambient temperature rises to the second fixed temperature, the memory metal strip II 18 can be deformed, as the two ends of the memory metal strip II 18 are Z-shaped before being deformed, and the sharp corners of the two Z-shaped ends of the memory metal strip which are not deformed are contacted with the contact III 19, after the memory metal strip II 18 is deformed and is generally straightened, when the contact III 19 is not contacted with the memory metal strip II 18, the electric telescopic rod II 17 is started to extend the electric telescopic rod II 17, the electric telescopic rod II 17 extends to drive the memory metal strip II 18 to move downwards until the two ends of the memory metal strip II 18 are contacted with the micro switch II 20 below, the micro switch II 20 is triggered to control the electromagnetic valve II 7 to be opened, cold air is discharged into the heat preservation cavity 3 through the cold air pipe 5, the temperature around the storage tank 1 is reduced, the influence of high temperature on the storage of a methyl trifluoroalkynoate product is avoided, in the process that the electric telescopic rod II 17 drives the memory metal strip II 18 to move downwards, if the temperature below the heat preservation cavity 3 does not reach a critical value for deforming the memory metal strip II 18, the memory metal strip II 18 can recover the shape before deformation, one end of the memory metal strip II is in a Z shape again, at this time, the sharp angle at one end of the Z-shaped part is contacted with the contact IV 21, the contact IV 21 is used for controlling the electric telescopic rod II 17 to shorten, so that the electric telescopic rod II 17 drives the memory metal strip II 18 to move back to the initial position, the micro switch II 20 is not triggered, the whole device is not started to regulate the temperature in the heat insulation cavity 3, the resource quantity is avoided, the working principle of the low-temperature control assembly 9 and the working principle of the high-temperature control assembly 8 are the same, only the low-temperature control assembly monitors the high-temperature and the low-temperature respectively, the environment where the storage tank 1 is positioned is always in a constant temperature state, the influence of the low temperature or the high temperature can not be avoided, the storage stability of the device is improved, when the heat insulation cavity 3 is subjected to temperature regulation, the motor 27 is synchronously started to drive the gear II 26 to rotate in the positive direction no matter the electromagnetic valve I6 is started to be fed with hot air or the electromagnetic valve II 7 is started to be fed with cold air, the gear II 26 can drive the meshed annular rack 28 to rotate, the annular rack 28 can drive the stirring rod 29 to move, so that the stirring rod 29 rotates around the storage tank 1, the stirring rod 29 can drive the blades 30 to move, the blades 30 can drive the gas in the heat insulation cavity 3 to flow, the gas is fully mixed together, thus the temperature adjustment working efficiency can be improved, the gear II 26 can drive the meshed gear I25 to rotate when rotating, the gear I25 can drive the support column 22 to rotate, the support column 22 can drive the lug 24 to rotate through the groove 23, the lug 24 can drive the storage tank 1 to rotate, thereby enabling the methyl trifluoroalkynoate product in the storage tank 1 to be mixed under the action of centrifugal force, further enabling the temperature of the methyl trifluoroalkynoate product to be even, avoiding the occurrence of normal temperature of the methyl trifluoroalkynoate product close to the heat insulation cavity 3, the abnormal temperature of the methyl trifluoroalkynoate product far away from the heat-preserving cavity 3 occurs, so that the storage of the methyl trifluoroalkynoate product is not influenced, the motor 27 does not need to rotate at a high speed in the process, and the influence on the product in the storage tank 1 is avoided.

Referring to fig. 2 and fig. 6-8, the present invention provides the following technical solutions: the utility model provides a trifluoro methyl acetylide product dehydration storage device, still including link up locate connecting tube one 31 of heat preservation cavity 3 outer wall one side, connecting tube two 32 that link up are equipped with to heat preservation cavity 3 outer wall opposite side, connecting tube one 31 with connecting tube two 32 one end all extends to the heat preservation 2 outside, connecting tube one 31 outer wall cover is equipped with annular lug one 33, annular lug one 33 inner wall symmetry is equipped with screw hole one 34, connecting tube one 31 outer wall is equipped with annular clamping block 35, connecting tube two 32 outer wall be equipped with annular clamping block 35 assorted annular clamping groove 36, annular clamping groove 36 inner wall match is equipped with sealing washer 37, connecting tube two 32 outer wall is equipped with annular lug two 38, annular lug two 38 inner wall symmetry is equipped with rotatory connecting fastening bolt 39, fastening bolt 39 with screw hole one 34 mesh, connecting tube two 32 outer wall in annular lug two 38 one side is equipped with rotatory control ring 40, control ring 40 outer wall is equipped with gear three 41, fastening bolt 39 outer wall cover be equipped with gear four 42 mesh with gear three 41.

The specific implementation mode is as follows: when the heat insulation device is used, the first connecting pipeline 31 and the second connecting pipeline 32 are respectively communicated with the heat insulation cavity 3 through hoses, when a plurality of heat insulation boxes 2 are used simultaneously, the heat insulation boxes 2 can be arranged together, then the adjacent two heat insulation boxes 2 are communicated through the first connecting pipeline 31 and the second connecting pipeline 32, accordingly, the purpose that the temperature in the heat insulation boxes 2 can be regulated and controlled by only using one hot air blower and one cold air blower is achieved, production cost is reduced, resource utilization rate is improved, when the two heat insulation boxes 2 are required to be communicated, only the annular clamping block 35 on the outer wall of the first connecting pipeline 31 is required to be inserted into the annular clamping groove 36 on the inner wall of the second connecting pipeline 32, the fastening bolt 39 is inserted into the threaded hole 34, then the control ring 40 is rotated, the control ring 40 drives the third gear 41 to rotate, the fourth gear 42 drives the fastening bolt 39 to rotate, the fastening bolt 39 is meshed with the threaded hole 34, the first threaded hole 33 can drive the first connecting pipeline 33 to move through the first threaded hole, the first connecting pipeline 31 can be driven by the fastening bolt 33, and when the first connecting pipeline 31 is required to be completely connected with the second connecting pipeline 32 through the annular clamping groove 36, and when the first connecting pipeline 31 is not connected with the first connecting pipeline 32, and the second connecting pipeline 32 is required to be completely sealed, and the first connecting pipeline 32 is not connected with the annular clamping groove 32, and the first connecting pipeline is connected with the second connecting pipeline 32, and the first connecting pipeline 32 can be completely sealed, and the second connecting pipeline is connected with the inner wall and the first connecting pipeline 32, and the first connecting pipeline is completely sealed, and the connecting pipeline 32 is completely sealed, and the sealing tightly and the first connecting pipeline is connected with the second connecting pipeline 32.

Finally, it should be noted that: the foregoing description is only a preferred embodiment of the present invention, and the present invention is not limited thereto, but it is to be understood that modifications and equivalents of some of the technical features described in the foregoing embodiments may be made by those skilled in the art, although the present invention has been described in detail with reference to the foregoing embodiments. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims

1. The utility model provides a trifluoro methyl alkynoate product dehydration storage device, includes holding vessel (1), its characterized in that: the heat-insulating storage tank is characterized in that a matched heat-insulating box (2) is sleeved on the outer wall of the storage tank (1), a heat-insulating cavity (3) is formed in the inner wall of the heat-insulating box (2), a through hot air pipe (4) and a through cold air pipe (5) are arranged on the outer wall of the heat-insulating cavity (3), a first electromagnetic valve (6) is arranged on the inner wall of the hot air pipe (4), a second electromagnetic valve (7) is arranged on the inner wall of the cold air pipe (5), a high-temperature control assembly (8) and a low-temperature control assembly (9) are arranged on the inner wall of the heat-insulating cavity (3), the high-temperature control assembly (8) is electrically connected with the first electromagnetic valve (6), and the low-temperature control assembly (9) is electrically connected with the second electromagnetic valve (7);

the high-temperature control assembly (8) comprises a first supporting plate (10), an electric telescopic rod (11) is arranged on the outer wall of the first supporting plate (10), a first memory metal strip (12) is arranged at the bottom of the first electric telescopic rod (11), a first contact (13) is arranged on one side of the outer wall of the first supporting plate (10) on the first memory metal strip (12), the first contact (13) is electrically connected with the first electric telescopic rod (11), a first microswitch (14) is arranged below the first memory metal strip (12) on the outer wall of the first supporting plate (10), the first microswitch (14) is electrically connected with the first electromagnetic valve (6), a second contact (15) is arranged between the first microswitch (14) and the first memory metal strip (12), and the second contact (15) is electrically connected with the first electric telescopic rod (11);

the low-temperature control assembly (9) comprises a support plate II (16), an electric telescopic rod II (17) is arranged on the outer wall of the support plate II (16), a memory metal strip II (18) is arranged at the bottom of the electric telescopic rod II (17), a contact III (19) is arranged on one side of the outer wall of the support plate II (16) on the memory metal strip II (18), the contact III (19) is electrically connected with the electric telescopic rod II (17), a micro switch II (20) is arranged below the memory metal strip II (18) on the outer wall of the support plate II (16), the micro switch II (20) is electrically connected with the electromagnetic valve II (7), a contact IV (21) is arranged between the micro switch II (20) and the memory metal strip II (18), and the contact IV (21) is electrically connected with the electric telescopic rod II (17);

the inner wall of the heat-insulating cavity (3) is provided with a support column (22) which is rotationally connected below the storage tank (1), the top of the support column (22) is provided with a groove (23), and the bottom of the storage tank (1) is provided with a convex block (24) matched with the groove (23);

the outer wall of the support column (22) is sleeved with a first gear (25), the inner wall of the heat-insulating cavity (3) is provided with a second gear (26) meshed with the first gear (25), the bottom of the heat-insulating box (2) is provided with a motor (27), and an output shaft of the motor (27) is fixedly connected with the second gear (26);

the inner wall of the heat preservation cavity (3) is rotatably provided with an annular rack (28) meshed with the gear II (26), the outer wall of the annular rack (28) is provided with a stirring rod (29), and a plurality of blades (30) are arranged outside the stirring rod (29).

2. A methyl trifluoroalkynoate product dehydration storage device according to claim 1, wherein: the heat preservation cavity (3) outer wall one side is equipped with connecting tube one (31) that link up, heat preservation cavity (3) outer wall opposite side is equipped with connecting tube two (32) that link up, connecting tube one (31) with connecting tube two (32) one end all extends to the insulation can (2) outside, connecting tube one (31) outer wall cover is equipped with annular lug one (33), annular lug one (33) inner wall symmetry is equipped with screw hole one (34), connecting tube one (31) outer wall is equipped with annular fixture block (35).

3. A methyl trifluoroalkynoate product dehydration storage apparatus according to claim 2, wherein: the outer wall of the second connecting pipeline (32) is provided with an annular clamping groove (36) matched with the annular clamping block (35), and the inner wall of the annular clamping groove (36) is provided with a sealing ring (37) in a matched mode.

4. A methyl trifluoroalkynoate product dehydration storage apparatus according to claim 2, wherein: the outer wall of the second connecting pipeline (32) is provided with a second annular projection (38), the inner wall of the second annular projection (38) is symmetrically provided with fastening bolts (39) which are connected in a rotating mode, and the fastening bolts (39) are meshed with the first threaded hole (34).

5. The device for dehydrating and storing a methyl trifluoroalkynoate product according to claim 4, wherein: the outer wall of the second connecting pipeline (32) is provided with a control ring (40) which is rotationally connected on one side of the second annular projection (38), the outer wall of the control ring (40) is provided with a third gear (41), and the outer wall of the fastening bolt (39) is sleeved with a fourth gear (42) meshed with the third gear (41).