CN215139892U - Enzymatic reaction's reation kettle - Google Patents

Abstract

The utility model relates to an enzymatic reaction's reation kettle, including the reaction chamber, wherein, reation kettle still includes: the first stirring assembly comprises a rotating supporting part and a first stirring part, the rotating supporting part is rotatably arranged in the reaction cavity, and the first stirring part extends along the radial direction and is arranged on the rotating supporting part; the second stirring assembly is partially positioned in the reaction cavity, the second stirring assembly is detachably connected with the first stirring assembly, and the first stirring assembly is driven to rotate by the second stirring assembly. From this, solve the reation kettle of current enzymatic reaction and only adopt stirring vane to stir the effect relatively poor, lead to the problem of stirring inefficiency.

Description

Enzymatic reaction's reation kettle

Technical Field

The utility model relates to an enzymatic reaction technical field especially relates to an enzymatic reaction's reation kettle.

Background

In the production process of biological pharmacy or health products, biological pharmacy raw materials such as adenosine butanedisulfonate methionine, p-toluenesulfonic acid adenosine methionine, cubilose acid and the like need to be prepared. The biopharmaceutical raw materials need to be stirred in a reaction device during the preparation process.

Among the current reaction unit, only put into the inner chamber with the raw materials, then open rabbling mechanism, the rabbling mechanism stirs the reaction to the raw materials in the inner chamber, and the effect that only stirs through stirring vane is relatively poor, and the time that needs the cost is longer, causes reation kettle's work efficiency to reduce.

Accordingly, the prior art is yet to be improved and developed.

SUMMERY OF THE UTILITY MODEL

In view of the defects of the prior art, the present application aims to provide a reaction kettle for enzymatic reaction, and aims to solve the problem that the stirring effect of the reaction kettle for enzymatic reaction is poor only by using a stirring blade, which results in low stirring efficiency.

The technical scheme of the utility model as follows:

there is provided a reaction vessel for an enzymatic reaction, comprising a reaction chamber, wherein the reaction vessel further comprises:

the first stirring assembly comprises a rotating supporting part and a first stirring part, the rotating supporting part is rotatably arranged in the reaction cavity, and the first stirring part extends along the radial direction and is arranged on the rotating supporting part;

the second stirring assembly is partially positioned in the reaction cavity, the second stirring assembly is detachably connected with the first stirring assembly, and the first stirring assembly is driven to rotate by the second stirring assembly.

Optionally, the first stirring part is rotatably arranged on the rotary supporting part;

a face gear is fixedly arranged in the reaction cavity;

the first stirring assembly further comprises a gear, the gear is arranged at one end, deviating from the rotating supporting part, of the first stirring part, and the gear is meshed with the face gear.

Optionally, the first stirring section includes:

the first rotating shaft is rotatably connected to the side wall of the rotating support part;

the first blade, first blade is followed the axial extension of first pivot sets up, and is a plurality of first blade is in along circumference evenly distributed on the lateral wall of first pivot.

Optionally, the rotation support portion includes a rotation support table, a first mounting hole has been seted up on the lateral wall of rotation support table, the inlay card has first bearing in the first mounting hole, first stirring portion inlay card is in the first bearing.

Optionally, a support rod is arranged at the bottom of the reaction cavity;

and a second mounting hole is formed in one side, facing the bottom of the reaction cavity, of the rotary support platform, a second bearing is embedded in the second mounting hole in a clamping manner, and the second bearing is sleeved on the support rod.

Optionally, the first stirring assemblies are provided in plurality, and the first stirring assemblies are uniformly distributed on the side wall of the rotating support part along the circumference.

Optionally, the second stirring assembly comprises:

the motor is fixedly arranged outside the reaction cavity;

one end of the second rotating shaft is connected with the rotating shaft of the motor, and the other end of the second rotating shaft extends into the reaction cavity;

the second stirring part is positioned in the reaction cavity and connected to the second rotating shaft;

and the connecting part is arranged at one end of the second rotating shaft, which faces the rotating supporting part, and is connected with the rotating supporting part.

Optionally, the rotary support part further comprises a first clamping boss, the first clamping boss is fixedly arranged on the rotary support platform, and a clamping groove is formed in the first clamping boss;

the connecting portion includes: the clamping platform is arranged on the second clamping boss;

the clamping table is embedded in the clamping groove.

Optionally, the clamping table is a cross clamping table, and the clamping groove is a cross clamping groove.

Optionally, the reaction kettle further comprises a bucket body and a bucket cover, the bucket cover is detachably connected to the bucket body, and the bucket body and the bucket cover are connected to form the reaction cavity;

the first stirring assembly is connected in the barrel body, and the second stirring assembly is connected on the barrel cover.

Has the advantages that: the utility model provides an enzymatic reaction's reation kettle puts into the reaction chamber with the raw materials, stirs the part of subassembly setting in the reaction chamber through the second, stirs the raw materials in the reaction chamber. Meanwhile, the second stirring assembly is connected with the first stirring assembly located in the reaction cavity, so that power on the second stirring assembly is transmitted to the first stirring assembly, and the first stirring assembly is driven to rotate. Rotatory first stirring subassembly also stirs the raw materials of reaction intracavity, stirs the raw materials simultaneously through first stirring subassembly and second stirring subassembly like this, makes more abundant of raw materials stirring. Compare in the mode that only adopts stirring vane to stir among the prior art, this scheme stirring is more abundant, and stirring efficiency is higher, has improved reation kettle's production efficiency.

Drawings

FIG. 1 is a cross-sectional view of an embodiment of an enzymatic reaction kettle of the present invention;

FIG. 2 is an enlarged view of portion A of FIG. 1;

FIG. 3 is a cross-sectional view from another perspective of an embodiment of an enzymatic reaction vessel of the present invention;

FIG. 4 is an exploded view of an example of an enzymatic reaction vessel according to the present invention.

Description of reference numerals: 100. a barrel body; 110. a reaction chamber; 120. a support bar; 200. a barrel cover; 300. a first stirring assembly; 310. a rotation support; 311. rotating the support table; 312. a second mounting hole; 313. a second bearing; 314. a first clamping boss; 315. a card slot; 316. a first mounting hole; 317. a first bearing; 320. a first stirring section; 321. a first rotating shaft; 322. a first blade; 330. a face gear; 340. a gear; 400. a second stirring assembly; 410. a motor; 420. a second rotating shaft; 430. a second stirring section; 440. a connecting portion; 441. a second clamping boss; 442. and (7) clamping the table.

Detailed Description

To facilitate an understanding of the present application, the present application will now be described more fully with reference to the accompanying drawings. Preferred embodiments of the present application are given in the accompanying drawings. This application may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this application belongs. The terminology used herein in the description of the present application is for the purpose of describing particular embodiments only and is not intended to be limiting of the application.

As shown in FIG. 1, the present application provides a reaction kettle for enzymatic reaction, comprising a reaction chamber 110, wherein the reaction chamber 110 is a circular reaction chamber 110 arranged in a vertical direction. Raw materials to be stirred or reacted are put into the reaction chamber 110, and the reaction kettle further comprises a first stirring assembly 300 and a second stirring assembly 400. The first stirring assembly 300 includes a rotation support part 310, and a first stirring part 320, the rotation support part 310 is rotatably disposed in the reaction chamber 110, and the first stirring part 320 extends in a radial direction and is disposed on the rotation support part 310. The second stirring assembly 400 is partially located in the reaction chamber 110, the second stirring assembly 400 is detachably connected to the first stirring assembly 300, and the first stirring assembly 300 is driven to rotate by the second stirring assembly 400.

In the above scheme, the raw materials are put into the reaction chamber 110, and the raw materials in the reaction chamber 110 are stirred by the portion of the second stirring assembly 400 disposed in the reaction chamber 110. Meanwhile, the second stirring assembly 400 is connected to the first stirring assembly 300 located in the reaction chamber 110, so that the power of the second stirring assembly 400 is transmitted to the first stirring assembly 300, and thus the first stirring assembly 300 is driven to rotate. The rotating first stirring assembly 300 also stirs the raw materials in the reaction chamber 110, so that the raw materials are stirred simultaneously by the first stirring assembly 300 and the second stirring assembly 400, and the raw materials are stirred more fully. Compare in the mode that only adopts stirring vane to stir among the prior art, this scheme stirring is more abundant, and stirring efficiency is higher, has improved reation kettle's production efficiency.

As shown in fig. 1 and fig. 3, based on the above scheme, the specific structure of the present embodiment includes: a tub 100, for convenience of structural description, the tub 100 is configured as a circular tub, and the tub 100 is disposed in a vertical direction, and an upper end of the tub 100 is configured as an opening to have an inner side in a direction toward the reaction chamber 110 and an outer side in a direction away from the tub 100. The barrel body 100 is detachably connected with a barrel cover 200, the barrel body 100 and the barrel cover 200 are connected to form the reaction cavity 110, the first stirring assembly 300 is connected in the barrel body 100, and the second stirring assembly 400 is connected on the barrel cover 200. By providing the tub 100 and the detachably coupled tub cover 200, the reaction chamber 110 can be frequently opened, so that the raw material can be added to the reaction chamber 110, or the reaction chamber 110 can be cleaned. In addition, it is easy to think that the reaction chamber 110 can also be integrated, that is, the reaction chamber 110 is directly opened in the housing, and the reaction chamber 110 is charged with raw materials or discharged with raw materials through the pipeline connected to the housing.

As shown in fig. 1 and 3, in this embodiment, a face gear 330 is fixedly disposed in the reaction chamber 110, the face gear 330 is disposed around the circumference of the inner wall of the barrel 100, and the teeth of the face gear 330 face upward. The first stirring assembly 300 further includes a gear 340, the gear 340 is disposed at an end of the first stirring portion 320 facing away from the rotation support portion 310, the gear 340 is engaged with the face gear 330, and the first stirring portion 320 is rotatably disposed on the rotation support portion 310. The rotation support portion 310 rotates around the axial direction of the reaction chamber 110, when the rotation support portion 310 is driven by the second stirring assembly 400 to rotate, the first stirring portion 320 is driven to rotate around the axial direction of the reaction chamber 110, so that the gear 340 is driven to rotate around the axial direction of the reaction chamber 110, because the gear 340 is meshed with the face gear 330, when the gear 340 moves along the circumference of the face gear 330, the gear 340 can rotate by itself, and because the gear 340 is driven by the rotation by itself, the first stirring portion rotates around the radial direction of the reaction chamber 110, therefore, the first stirring portion 320 not only rotates along the axial direction of the reaction chamber 110 after being driven by the second stirring assembly 400, but also can generate self-rotation through the matching of the gear 340 and the face gear 330. The raw materials are stirred together by the rotation of the plurality of parts. The stirring efficiency is accelerated.

As shown in fig. 1 and 4, the second stirring assembly 400 includes a motor 410, a second rotating shaft 420, a second stirring part 430, and a connecting part 440. The motor 410 is fixedly coupled to the upper surface of the tub cover 200 by a screw, so that the motor 410 is located outside the reaction chamber 110. The second rotating shaft 420 is axially disposed along the barrel body 100, one end of the second rotating shaft 420 is connected to the rotating shaft of the motor 410 through a coupling, and the other end of the second rotating shaft 420 penetrates through the barrel cover 200 and extends into the reaction chamber 110. The second stirring part 430 is located in the reaction chamber 110 and connected to the second rotating shaft 420. Thus, when the motor 410 is powered on, the second rotating shaft 420 is driven to rotate, the second stirring portion 430 is also driven, and the raw material in the barrel 100 is stirred by the rotating second stirring portion 430.

In this embodiment, in order to connect the second stirring assembly 400 to the first stirring assembly 300, the connecting portion 440 is disposed at one end of the second rotating shaft 420 facing the rotation support portion 310 and is used for connecting the rotation support portion 310. Thus, when the second stirring assembly 400 is disassembled together with the tub cover 200, the connection part 440 is separated from the rotation support part 310. When the second agitation assembly 400 is mounted to the tub 100 along with the tub cover 200, the connection part 440 is connected to the rotation support part 310.

As shown in fig. 1 and 2, the rotation support 310 in this embodiment includes a rotation support 311, and as shown in fig. 2 and 3, the rotation support 311 in this embodiment is provided with a square shape, the bottom of the reaction chamber 110 is provided with a support rod 120, and the support rod 120 extends in the vertical direction and is disposed at the center of the bottom of the reaction chamber 110. A second mounting hole 312 is formed in one side of the rotary support platform 311 facing the bottom of the reaction chamber 110, a second bearing 313 is embedded in the second mounting hole 312 in a clamping manner, and the support rod 120 is sleeved with the second bearing 313. Thus, the rotary support 311 is rotatably connected to the support rod 120 via the second bearing 313. The rotating support 310 further comprises a first clamping boss 314, the first clamping boss 314 is fixedly arranged on the rotating support 311, a clamping groove 315 is formed in the first clamping boss 314, correspondingly, the connecting portion 440 comprises a second clamping boss 441 and a clamping table 442 arranged on the second clamping boss 441. The card platform 442 fits within the card slot 315. In this way, the rotation support portion 310 and the connection portion 440 are detachably connected by the engagement of the locking platform 442 and the locking groove 315. In this embodiment, the clamping platform 442 is a cross-shaped clamping platform, and the clamping groove 315 is a cross-shaped clamping groove. The cross clamping table is matched with the cross clamping groove, so that the second stirring component 400 is stably connected with the first stirring component 300, and the second stirring component 400 is conveniently detached from the first stirring component 300.

As shown in fig. 2 and 4, a first mounting hole 316 is formed in a side wall of the rotary support 311 in this embodiment, a first bearing 317 is embedded in the first mounting hole 316, and the first stirring portion 320 is embedded in the first bearing 317. Thus, the first stirring portion 320 is rotatably connected to the rotary support 311, and when the first stirring portion 320 is driven by the gear 340, the gear 340 can drive the first stirring portion 320 to rotate. The first stirring section 320 in this embodiment includes: a first shaft 321, and a first blade 322. The first rotating shaft 321 is rotatably connected to a sidewall of the rotating support 310, and the first rotating shaft 321 extends along a radial direction of the reaction chamber 110. The first blades 322 extend along the axial direction of the first shaft 321, and a plurality of the first blades 322 are uniformly distributed along the circumference on the sidewall of the first shaft 321. One end of the first rotating shaft 321 is embedded in the first bearing 317, and the other end is connected to the gear 340, so that when the gear 340 moves on the face gear 330, the first rotating shaft 321 is driven to rotate, and the first rotating shaft 321 drives the first blade 322 to rotate. This allows the first stirring assembly 300 to self-rotate. The raw materials positioned at the lower portion of the reaction chamber 110 are agitated so that the raw materials can be sufficiently mixed or reacted.

As shown in fig. 2 and 3, the first stirring assembly 300 in this embodiment is provided in plural, and the plural first stirring assemblies 300 are uniformly distributed on the side wall of the rotation support portion 310 along the circumference. Specifically, the rotary supporting platform 311 is a cube, and four side walls of the rotary supporting platform 311 are respectively connected with a first stirring assembly 300. Thus, after being driven by the second stirring assembly, the plurality of first stirring assemblies 300 can stir the raw materials while rotating around the axial direction of the reaction chamber 110, and can self-rotate. The stirring efficiency is accelerated.

To sum up, the utility model provides an enzymatic reaction's reation kettle puts into reaction chamber 110 with the raw materials, stirs the raw materials in reaction chamber 110 through the part of second stirring subassembly 400 setting in reaction chamber 110. Meanwhile, the second stirring assembly 400 is connected to the first stirring assembly 300 located in the reaction chamber 110, so that the power of the second stirring assembly 400 is transmitted to the first stirring assembly 300, and thus the first stirring assembly 300 is driven to rotate. The rotating first stirring assembly 300 also stirs the raw materials in the reaction chamber 110, so that the raw materials are stirred simultaneously by the first stirring assembly 300 and the second stirring assembly 400, and the raw materials are stirred more fully.

In a specific process, after the motor 410 is powered on, the second rotating shaft 420 is driven to rotate, the second stirring portion 430 is also driven, and the raw material in the barrel 100 is stirred by the rotating second stirring portion 430. When the second stirring assembly 400 is mounted to the tub 100 along with the tub cover 200, the connection portion 440 is connected to the rotation support 310, so that the second rotation shaft 420 drives the rotation support 311 to rotate. The rotating rotary support 311 drives the first stirring portion 320 to rotate around the axial direction of the reaction chamber 110, so as to drive the gear 340 to rotate around the axial direction of the reaction chamber 110, because the gear 340 is meshed with the face gear 330, when the gear 340 moves along the circumference of the face gear 330, the gear 340 can also rotate by itself, and because the gear 340 is driven by itself to rotate, the first stirring portion rotates around the radial direction of the reaction chamber 110. The raw materials are stirred more fully.

Compare in the mode that only adopts stirring vane to stir among the prior art, this scheme stirring is more abundant, and stirring efficiency is higher, has improved reation kettle's production efficiency.

It is to be understood that the invention is not limited to the above-described embodiments, and that modifications and variations may be made by those skilled in the art in light of the above teachings, and all such modifications and variations are intended to be included within the scope of the invention as defined in the appended claims.

Claims (10)

1. An enzymatic reaction kettle, comprising a reaction cavity, characterized in that the reaction kettle further comprises:

the first stirring assembly comprises a rotating supporting part and a first stirring part, the rotating supporting part is rotatably arranged in the reaction cavity, and the first stirring part extends along the radial direction and is arranged on the rotating supporting part;

the second stirring assembly is partially positioned in the reaction cavity, the second stirring assembly is detachably connected with the first stirring assembly, and the first stirring assembly is driven to rotate by the second stirring assembly.

2. The enzymatic reaction kettle according to claim 1, wherein said first stirring part is rotatably provided on said rotation support part;

a face gear is fixedly arranged in the reaction cavity;

the first stirring assembly further comprises a gear, the gear is arranged at one end, deviating from the rotating supporting part, of the first stirring part, and the gear is meshed with the face gear.

3. The enzymatic reaction kettle of claim 2, wherein said first stirring section comprises:

the first rotating shaft is rotatably connected to the side wall of the rotating support part;

the first blade, first blade is followed the axial extension of first pivot sets up, and is a plurality of first blade is in along circumference evenly distributed on the lateral wall of first pivot.

4. The enzymatic reaction kettle of claim 2, wherein the rotary supporting part comprises a rotary supporting platform, a first mounting hole is opened on a side wall of the rotary supporting platform, a first bearing is embedded in the first mounting hole, and the first stirring part is embedded in the first bearing.

5. The reaction kettle for enzymatic reaction according to claim 4, wherein a support rod is arranged at the bottom of the reaction cavity;

and a second mounting hole is formed in one side, facing the bottom of the reaction cavity, of the rotary support platform, a second bearing is embedded in the second mounting hole in a clamping manner, and the second bearing is sleeved on the support rod.

6. The enzymatic reaction kettle of claim 2, wherein said first stirring assembly is provided in plurality, and said plurality of first stirring assemblies are uniformly distributed along the circumference on the side wall of said rotary support.

7. The enzymatic reaction kettle of claim 4, wherein said second stirring assembly comprises:

the motor is fixedly arranged outside the reaction cavity;

one end of the second rotating shaft is connected with the rotating shaft of the motor, and the other end of the second rotating shaft extends into the reaction cavity;

the second stirring part is positioned in the reaction cavity and connected to the second rotating shaft;

and the connecting part is arranged at one end of the second rotating shaft, which faces the rotating supporting part, and is connected with the rotating supporting part.

8. The enzymatic reaction kettle of claim 7, wherein the rotary support part further comprises a first clamping boss, the first clamping boss is fixedly arranged on the rotary support platform, and a clamping groove is formed in the first clamping boss;

the connecting portion includes: the clamping platform is arranged on the second clamping boss;

the clamping table is embedded in the clamping groove.

9. The enzymatic reaction kettle of claim 8, wherein said clamping platform is a cross clamping platform, and said clamping groove is a cross clamping groove.

10. The reaction kettle for enzymatic reaction according to any one of claims 1 to 9, further comprising a bucket body and a bucket cover, wherein the bucket cover is detachably connected to the bucket body, and the bucket body and the bucket cover are connected to form the reaction cavity;

the first stirring assembly is connected in the barrel body, and the second stirring assembly is connected on the barrel cover.

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