CN112191210A - Chemical industry reation kettle with function is joined in marriage in advance to preliminary adjustment - Google Patents

Abstract

The invention discloses a chemical reaction kettle with a pre-adjusting function, which comprises a reaction kettle main body, a main shaft, a forward ratchet wheel, a rotating rod, a half gear and a collecting and sampling device, wherein a servo motor is installed at the top of the reaction kettle main body, the servo motor is connected with the forward ratchet wheel through the main shaft, the forward ratchet wheel is connected with the ratchet wheel through a fixing block, and the ratchet wheel is connected with the main shaft through a return spring. This chemical industry reation kettle with pre-adjustment function, top in the reation kettle main part is provided with the hopper, when servo motor clockwise turning, make the semi-gear can drive the rack and slide right, make the rack extrude resistance spring, thereby accomplish rack roll-off pan feeding mouth, make chemical material can fall into the inside of reation kettle main part through the pan feeding mouth, when needs increase pan feeding volume, can open the electro-magnet simultaneously, make the electro-magnet adsorb movable sleeve, accomplish the work is opened to second pan feeding mouth, be favorable to the chemical material ration to drop into the reation kettle main part regularly.

Description

Chemical industry reation kettle with function is joined in marriage in advance to preliminary adjustment

Technical Field

The invention relates to the technical field of chemical reaction kettles, in particular to a chemical reaction kettle with a pre-blending function.

Background

A chemical reaction vessel is a container for performing high temperature, evaporation and cooling on various chemical materials to generate chemical reactions.

Common chemical reaction cauldron in the existing market, most do not have the function of allotting in advance, the speed of pan feeding can not be controlled simultaneously, make to be more troublesome adding chemical material, thereby production efficiency has been reduced, and when utilizing chemical reaction cauldron to carry out chemical synthesis, need regularly take a sample to the inside material of chemical reaction cauldron, and reation kettle is mostly airtight space, make the difficulty of comparison when taking a sample, so we have proposed a chemical reaction cauldron with allotment function in advance, so that solve the problem of proposing in the above-mentioned.

Disclosure of Invention

The invention aims to provide a chemical reaction kettle with a pre-blending function, and aims to solve the problems that most of the chemical reaction kettles in the prior market do not have the pre-blending function, the feeding speed cannot be controlled, the chemical materials are relatively troublesome to add, the production efficiency is reduced, and when the chemical reaction kettles are used for chemical synthesis, the materials in the chemical reaction kettles need to be sampled regularly, the reaction kettles are mostly closed spaces, and the sampling is relatively difficult.

In order to achieve the purpose, the invention provides the following technical scheme: a chemical reaction kettle with a pre-adjusting function comprises a reaction kettle body, a main shaft, a forward ratchet wheel, a rotary rod, a half gear and a collecting and sampling device, wherein a servo motor is installed at the top of the reaction kettle body and is connected with the forward ratchet wheel through the main shaft, the forward ratchet wheel is connected with the ratchet wheel through a fixing block, meanwhile, the ratchet wheel is connected with the main shaft through a reset spring, the forward ratchet wheel is connected with a power bevel gear through a power gear, the power bevel gear is connected with the rotary rod through a driven bevel gear, the right side of the rotary rod penetrates through the bottom of a hopper to be connected with the half gear, the top end of the rotary rod is provided with an electromagnet, the rotary rod is connected with a connecting rod through a movable sleeve, one side of the movable sleeve is connected with a telescopic spring, the right side of the telescopic spring, and the rack is connected with the limiting block through a limiting groove, the top of the rack penetrates through the feeding port to be contacted with the hopper, the bottom of the rack is connected with the hopper through a resistance spring, a reverse ratchet wheel is installed in the middle of the main shaft and is connected with a pulley through a belt, the pulley is connected with a linkage gear through a linkage rod, a first valve and a second valve are arranged inside the collecting and sampling device, one side of the first valve and one side of the second valve are connected to the two sides of the linkage gear respectively, a sampling chamber is arranged in the middle of the first valve and the second valve, and sampling pipelines are arranged on the left side and the right side of the sampling chamber simultaneously.

Preferably, the servo motor is located outside the reaction kettle main body, the reaction kettle main body and the forward ratchet form a rotating structure through the main shaft, the forward ratchet is connected with the ratchet in a clamping mode through the fixing block, and the fixing block is distributed in the forward ratchet at equal intervals.

Preferably, the ratchets are distributed on the main shaft at equal intervals, the ratchets are rotatably connected with the main shaft, and the middle of each ratchet and the lug on the main shaft form a telescopic structure through a return spring.

Preferably, the power gear is in meshed connection with the forward ratchet wheel, the power gear and the power bevel gear are of an integrated structure, the power bevel gear and the rotating rod form a meshed structure through the driven bevel gear, and the right end of the rotating rod is located inside the hopper.

Preferably, the rotary rod is fixed connection with the semi-gear, and the rotary rod slides in the electro-magnet is inside to the rotary rod passes through movable sleeve and constitutes the block structure with the connecting rod, and movable sleeve passes through expanding spring and constitutes extending structure with the connecting rod simultaneously.

Preferably, only half of the half gear has a tooth angle, and the half gear and the rack constitute a meshing structure, and the half gear and the rack use the hopper as central symmetry and distribute, and the rack passes through the spacing groove simultaneously and constitutes the block structure with the stopper.

Preferably, the pan feeding mouth is located the inside both sides of hopper, and the hopper is inside to be the slope form to the hopper passes through the pan feeding mouth and constitutes block structure with the top of rack, and resistance spring and hopper constitution extending structure are passed through to the bottom of rack simultaneously.

Preferably, the pulley and the reverse ratchet wheel form a rotating structure through a belt, the pulley is positioned on the outer side of the collecting and sampling device, the pulley and the first valve and the second valve form a meshing structure through a linkage gear, meanwhile, the middle of the first valve and the second valve is positioned in the sampling chamber, and the part with the tooth angle is positioned in the collecting and sampling device.

Preferably, the first valve and the second valve are respectively positioned at two sides of the sampling chamber, round holes are formed in the first valve and the second valve, the first valve and the second valve are rotatably connected with the collecting and sampling device, round holes in the first valve and the second valve are positioned at the top and at the bottom, and the diameter of the round holes is larger than that of the sampling pipeline.

Compared with the prior art, the invention has the beneficial effects that: the chemical reaction kettle with the pre-adjusting function,

1. the top of the reaction kettle main body is provided with a hopper, so that the hopper can contain more chemical materials, a feeding port is arranged in the hopper, when the servo motor rotates clockwise, the main shaft drives the positive ratchet wheel to rotate, so that the rotating rod rotates along with the positive ratchet wheel, then the half gear can drive the rack to slide rightwards, so that the rack extrudes the resistance spring, the rack slides out of the feeding port, chemical materials can fall into the reaction kettle main body through the feeding port, meanwhile, when the feeding quantity needs to be increased, the electromagnet can be turned on to enable the electromagnet to adsorb the movable sleeve, the clamping of the rotary rod and the connecting rod is completed, so that the second feeding port is opened, the chemical materials can be quantitatively and regularly fed into the reaction kettle body, and the quantity of the chemical materials fed in a certain time can be controlled;

2. be provided with in the left side of reation kettle main part and collect sampling device, when servo motor anticlockwise rotation, because the reason of forward ratchet inner structure, make the main shaft idle run in forward ratchet inside, it is rotatory that the main shaft passes through reverse ratchet drive pulley after that, make the pulley drive first valve and second valve rotation through the linkage gear, when round hole and sample pipeline on the first valve overlap, the inside material of reation kettle main part can flow into the inside storage of sample room, when round hole and sample pipeline on the second valve overlap, the material will flow into inside the glass container, first valve will block up the sample pipeline that is close to reation kettle main part one side simultaneously, make the material not flow out, be favorable to the automatic outflow that the material can be regularly, make the staff more simple when the sample.

Drawings

FIG. 1 is a schematic view of an overall front-view cross-sectional structure of a chemical reaction kettle with a pre-blending function according to the present invention;

FIG. 2 is a schematic view of a downward connection structure of a forward ratchet and a power gear of a chemical reaction kettle with a pre-adjusting function according to the present invention;

FIG. 3 is an enlarged schematic view of the position A in FIG. 1 of a chemical reaction kettle with a pre-blending function according to the present invention;

FIG. 4 is a schematic view of a cross-sectional structure of a chemical reaction kettle structure hopper with a pre-blending function in a front view;

FIG. 5 is a schematic diagram of a side view connection structure of a half gear and a rack of a chemical reaction kettle with a pre-blending function according to the present invention;

FIG. 6 is a schematic top view cross-sectional structure of a chemical reaction kettle collection and sampling device with pre-blending function according to the present invention;

FIG. 7 is a schematic view of a front cross-sectional structure of a chemical reaction kettle collection and sampling device with a pre-blending function according to the present invention.

In the figure: 1. a reaction kettle main body; 2. a servo motor; 3. a main shaft; 4. a forward ratchet; 5. a reverse ratchet wheel; 6. a fixed block; 7. a ratchet; 8. a return spring; 9. a power gear; 10. a power bevel gear; 11. a driven bevel gear; 12. rotating the rod; 13. a half gear; 14. a rack; 15. a limiting block; 16. a feeding port; 17. an electromagnet; 18. a movable sleeve; 19. a tension spring; 20. a connecting rod; 21. a hopper; 22. a belt; 23. a collecting and sampling device; 24. a pulley; 25. a linkage rod; 26. a linkage gear; 27. a first valve; 28. a second valve; 29. a sampling chamber; 30. a sampling pipe; 31. a resistance spring; 32. a limiting groove.

Detailed Description

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

Referring to fig. 1-7, the present invention provides a technical solution: a chemical reaction kettle with a pre-adjusting function comprises a reaction kettle body 1, a main shaft 3, a forward ratchet 4, a rotary rod 12, a half gear 13 and a collecting and sampling device 23, wherein a servo motor 2 is installed at the top of the reaction kettle body 1, the servo motor 2 is connected with the forward ratchet 4 through the main shaft 3, the forward ratchet 4 is connected with a ratchet 7 through a fixing block 6, the ratchet 7 is connected with the main shaft 3 through a reset spring 8, the forward ratchet 4 is connected with a power bevel gear 10 through a power gear 9, the power bevel gear 10 is connected with the rotary rod 12 through a driven bevel gear 11, the right side of the rotary rod 12 penetrates through the bottom of a hopper 21 to be connected with the half gear 13, an electromagnet 17 is arranged at the top end of the rotary rod 12, the rotary rod 12 is connected with a connecting rod 20 through a movable sleeve 18, and one side of the movable, the right side of the telescopic spring 19 is connected with the connecting rod 20, the top of the half gear 13 is contacted with the bottom of the rack 14, the rack 14 is connected with the limiting block 15 through the limiting groove 32, the top of the rack 14 penetrates through the feeding port 16 to be contacted with the hopper 21, meanwhile, the bottom of the rack 14 is connected with the hopper 21 through the resistance spring 31, the reverse ratchet wheel 5 is installed in the middle of the main shaft 3, the reverse ratchet wheel 5 is connected with the pulley 24 through the belt 22, the pulley 24 is connected with the linkage gear 26 through the linkage rod 25, the first valve 27 and the second valve 28 are arranged inside the collecting and sampling device 23, one sides of the first valve 27 and the second valve 28 are respectively connected to two sides of the linkage gear 26, the sampling chamber 29 is arranged in the middle of the first valve 27 and the second valve 28, and the sampling pipelines 30 are arranged on the left side.

Servo motor 2 is located the outside of reation kettle main part 1, and reation kettle main part 1 constitutes revolution mechanic through main shaft 3 and forward ratchet 4, and forward ratchet 4 is connected for the block through fixed block 6 and ratchet 7, and fixed block 6 distributes equally in the inside of forward ratchet 4 simultaneously, is favorable to when servo motor 2 clockwise rotation, and main shaft 3 can drive forward ratchet 4 through ratchet 7 and fixed block 6 and rotate.

The ratchets 7 are distributed on the main shaft 3 at equal intervals, the ratchets 7 are in rotary connection with the main shaft 3, the middle of each ratchet 7 and a lug on the main shaft 3 form a telescopic structure through a return spring 8, and the main shaft 3 can idle inside the forward ratchet 4 when the servo motor 2 rotates anticlockwise.

Power gear 9 is connected for the meshing with forward ratchet 4, and power gear 9 and power bevel gear 10 are the integral structure to power bevel gear 10 constitutes the engagement structure through driven bevel gear 11 and rotary rod 12, and rotary rod 12 right-hand member is located the inside of hopper 21 simultaneously, is favorable to power gear 9 to drive rotary rod 12 and rotates.

Rotary rod 12 is fixed connection with semi-gear 13, and rotary rod 12 slides in electro-magnet 17 is inside, and rotary rod 12 constitutes the block structure through activity sleeve 18 and connecting rod 20, and activity sleeve 18 passes through expanding spring 19 simultaneously and constitutes extending structure with connecting rod 20, is favorable to opening behind electro-magnet 17, and rotary rod 12 can drive connecting rod 20 and rotate together, makes a plurality of pan feeding mouths 16 can simultaneous working.

Only half of the half gear 13 has a tooth angle, the half gear 13 and the rack 14 form an engaging structure, the half gear 13 and the rack 14 are symmetrically distributed by taking the hopper 21 as a center, and the rack 14 and the limiting block 15 form a clamping structure through the limiting groove 32, so that the sliding of the rack 14 is controlled by the half gear 13, and the opening of the feeding port 16 is controlled.

Pan feeding mouth 16 is located the inside both sides of hopper 21, and hopper 21 is inside to be the slope form to hopper 21 constitutes the block structure through pan feeding mouth 16 and the top of rack 14, and resistance spring 31 and hopper 21 constitution extending structure are passed through to the bottom of rack 14 simultaneously, are favorable to the whereabouts that the material can be more convenient, make resistance spring 31 can promote rack 14 to close pan feeding mouth 16 under elastic effect simultaneously.

The pulley 24 and the reverse ratchet wheel 5 form a rotating structure through the belt 22, the pulley 24 is positioned at the outer side of the collecting and sampling device 23, the pulley 24 and the first valve 27 and the second valve 28 form a meshing structure through the linkage gear 26, meanwhile, the middle of the first valve 27 and the second valve 28 is positioned at the inner part of the sampling chamber 29, and the tooth-angled part of the sampling chamber is positioned at the inner part of the collecting and sampling device 23, so that the material in the reaction kettle main body 1 can be controlled to flow into the inner part of the sampling chamber 29 through the rotation of the first valve 27 and the second valve 28.

First valve 27 and second valve 28 are located the both sides of sampling chamber 29 respectively, and have circular shape hole on first valve 27 and the second valve 28, and first valve 27 and second valve 28 and collection sampling device 23 are swivelling joint, and round hole one on first valve 27 and the second valve 28 is located the bottom in the top simultaneously, and the diameter of its round hole is greater than the diameter of sampling pipe 30, is favorable to the automatic outflow that the material can be regularly for the staff is more simple when the sample.

The working principle of the embodiment is as follows: according to fig. 1-7, when using the chemical reaction kettle with the pre-adjusting function, firstly, chemical materials are poured into the hopper 21, so that the hopper 21 can contain a large amount of chemical materials, then the servo motor 2 is turned on, when the servo motor 2 rotates counterclockwise, so that the positive ratchet 4 extrudes the ratchet 7 by the fixing block 6 under the action of external friction force, so that the ratchet 7 compresses the reset spring 8, which is beneficial to realize that the main shaft 3 idles inside the reverse ratchet 5 when the servo motor 2 rotates clockwise, and the main shaft 3 idles inside the positive ratchet 4 when the servo motor 2 rotates counterclockwise, then the servo motor 2 rotates clockwise, so that the main shaft 3 drives the positive ratchet 4 to rotate through the main shaft 3, so that the positive ratchet 4 and the power gear 9 do meshing motion, so that the power gear 9 drives the driven bevel gear 11 to rotate through the power bevel gear 10, the driven bevel gear 11 is facilitated to drive the half gear 13 and the rack 14 to do meshing motion through the rotary rod 12, the rack 14 slides on the limiting block 15 through the limiting groove 32, so that the rack 14 extrudes the resistance spring 31, chemical materials can fall into the reaction kettle main body 1 through the feeding port 16, when the half gear 13 continuously rotates to a part without a tooth angle, the rack 14 can reset under the pushing of the resistance spring 31, so that the rack 14 blocks the feeding port 16, meanwhile, when the feeding amount needs to be increased, the electromagnet 17 can be opened, so that the electromagnet 17 adsorbs the movable sleeve 18, so that the clamping of the rotary rod 12 and the connecting rod 20 is completed, the second feeding port 16 is opened, and after the electromagnet 17 is closed, the movable sleeve 18 can reset under the elastic action of the telescopic spring 19, so that the connecting rod 20 stops rotating, when the servo motor 2 rotates anticlockwise, due to the internal structure of the forward ratchet 4, the main shaft 3 idles in the forward ratchet 4, then the main shaft 3 drives the pulley 24 to rotate through the reverse ratchet 5, so that the pulley 24 drives the linkage gear 26 to rotate through the linkage rod 25, so that the linkage gear 26 drives the first valve 27 and the second valve 28 to rotate, when the round hole in the first valve 27 is overlapped with the sampling pipeline 30, the material in the reaction kettle main body 1 flows into the sampling chamber 29 for storage, when the round hole in the second valve 28 is overlapped with the sampling pipeline 30, the material flows into the glass container, and meanwhile, the first valve 27 blocks the sampling pipeline 30 close to one side of the reaction kettle main body 1, the material does not flow out, the material can flow out regularly and automatically, and the sampling is simple and convenient for workers to complete a series of work.

Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that various changes in the embodiments and/or modifications of the invention can be made, and equivalents and modifications of some features of the invention can be made without departing from the spirit and scope of the invention.

Claims (9)

1. The utility model provides a chemical industry reation kettle with preset function, includes reation kettle main part (1), main shaft (3), forward ratchet (4), rotary rod (12), half gear (13) and collects sampling device (23), its characterized in that: the reaction kettle comprises a reaction kettle main body (1), wherein a servo motor (2) is installed at the top of the reaction kettle main body (1), the servo motor (2) is connected with a forward ratchet wheel (4) through a main shaft (3), the forward ratchet wheel (4) is connected with ratchets (7) through a fixing block (6), the ratchets (7) are connected with the main shaft (3) through return springs (8), the forward ratchet wheel (4) is connected with a power bevel gear (10) through a power gear (9), the power bevel gear (10) is connected with a rotary rod (12) through a driven bevel gear (11), the right side of the rotary rod (12) penetrates through the bottom of a hopper (21) and is connected with a half gear (13), an electromagnet (17) is arranged at the top end of the rotary rod (12), the rotary rod (12) is connected with a connecting rod (20) through a movable sleeve (18), and one side of the movable sleeve, the right side of the telescopic spring (19) is connected with the connecting rod (20), the top of the half gear (13) is in contact with the bottom of the rack (14), the rack (14) is connected with the limiting block (15) through the limiting groove (32), the top of the rack (14) penetrates through the feeding port (16) to be in contact with the hopper (21), meanwhile, the bottom of the rack (14) is connected with the hopper (21) through the resistance spring (31), the middle of the spindle (3) is provided with the reverse ratchet wheel (5), the reverse ratchet wheel (5) is connected with the pulley (24) through the belt (22), the pulley (24) is connected with the linkage gear (26) through the linkage rod (25), the collecting and sampling device (23) is internally provided with the first valve (27) and the second valve (28), and one sides of the first valve (27) and the second valve (28) are respectively connected with two sides of the linkage gear (26), and a sampling chamber (29) is arranged between the first valve (27) and the second valve (28), and sampling pipelines (30) are arranged at the left side and the right side of the sampling chamber (29).

2. The chemical reaction kettle with the pre-blending function according to claim 1, is characterized in that: the servo motor (2) is located outside the reaction kettle main body (1), the reaction kettle main body (1) and the forward ratchet wheel (4) form a rotating structure through the main shaft (3), the forward ratchet wheel (4) is connected with the ratchet wheel (7) in a clamping mode through the fixing block (6), and meanwhile the fixing block (6) is distributed in the forward ratchet wheel (4) in an equal interval mode.

3. The chemical reaction kettle with the pre-blending function according to claim 1, is characterized in that: the ratchets (7) are distributed on the main shaft (3) at equal intervals, the ratchets (7) are in rotary connection with the main shaft (3), and the middles of the ratchets (7) and the lugs on the main shaft (3) form a telescopic structure through return springs (8).

4. The chemical reaction kettle with the pre-blending function according to claim 1, is characterized in that: the power gear (9) is in meshed connection with the forward ratchet wheel (4), the power gear (9) and the power bevel gear (10) are of an integrated structure, the power bevel gear (10) forms a meshed structure with the rotating rod (12) through the driven bevel gear (11), and meanwhile the right end of the rotating rod (12) is located inside the hopper (21).

5. The chemical reaction kettle with the pre-blending function according to claim 1, is characterized in that: the rotary rod (12) is fixedly connected with the half gear (13), the rotary rod (12) slides in the electromagnet (17), the rotary rod (12) forms a clamping structure with the connecting rod (20) through the movable sleeve (18), and the movable sleeve (18) forms a telescopic structure with the connecting rod (20) through the telescopic spring (19).

6. The chemical reaction kettle with the pre-blending function according to claim 1, is characterized in that: only half of the half gear (13) has a tooth angle, the half gear (13) and the rack (14) form a meshing structure, the half gear (13) and the rack (14) are symmetrically distributed by taking the hopper (21) as a center, and meanwhile, the rack (14) and the limiting block (15) form a clamping structure through the limiting groove (32).

7. The chemical reaction kettle with the pre-blending function according to claim 1, is characterized in that: the feeding ports (16) are located on two sides of the interior of the hopper (21), the interior of the hopper (21) is inclined, the hopper (21) forms a clamping structure with the top of the rack (14) through the feeding ports (16), and meanwhile the bottom of the rack (14) forms a telescopic structure with the hopper (21) through the resistance spring (31).

8. The chemical reaction kettle with the pre-blending function according to claim 1, is characterized in that: the pulley (24) and the reverse ratchet wheel (5) form a rotating structure through a belt (22), the pulley (24) is located on the outer side of the collecting and sampling device (23), the pulley (24) and the first valve (27) and the second valve (28) form a meshing structure through a linkage gear (26), meanwhile, the middle of the first valve (27) and the middle of the second valve (28) are located inside the sampling chamber (29), and the part with the tooth angle is located inside the collecting and sampling device (23).

9. The chemical reaction kettle with the pre-blending function according to claim 1, is characterized in that: the first valve (27) and the second valve (28) are respectively positioned at two sides of the sampling chamber (29), round holes are formed in the first valve (27) and the second valve (28), the first valve (27) and the second valve (28) are rotatably connected with the collecting and sampling device (23), meanwhile, round holes in the first valve (27) and the second valve (28) are positioned at the top and at the bottom, and the diameter of each round hole is larger than that of the sampling pipeline (30).

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