CN216172235U - Enzymatic reaction device - Google Patents

Abstract

The utility model relates to an enzymatic reaction device, which comprises a barrel body and a cover body detachably connected to the barrel body, wherein the enzymatic reaction device further comprises: the power mechanism comprises a fixing part and a pushing part, wherein the fixing part is fixedly connected to the cover body, and the pushing part is connected to the fixing part and moves close to or far away from the barrel body; and the stirring mechanism is connected to the pushing part and penetrates through the cover body to extend into the barrel body. From this, solved current enzymatic reaction's reaction unit and only adopted stirring vane to stir the effect relatively poor, lead to stirring inefficiency problem.

Description

Enzymatic reaction device

Technical Field

The utility model relates to the technical field of enzymatic reaction, in particular to an enzymatic reaction device.

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 deficiencies of the prior art, the present application aims to provide an enzymatic reaction device, which aims to solve the problem that the stirring efficiency is low because the stirring effect of the existing reaction device is poor only by using stirring blades.

The technical scheme of the utility model is as follows:

there is provided an enzymatic reaction apparatus including a barrel body, and a cover body detachably attached to the barrel body, wherein the enzymatic reaction apparatus further includes:

the power mechanism comprises a fixing part and a pushing part, wherein the fixing part is fixedly connected to the cover body, and the pushing part is connected to the fixing part and moves close to or far away from the barrel body;

and the stirring mechanism is connected to the pushing part and penetrates through the cover body to extend into the barrel body.

Optionally, a support seat is arranged on the side surface of the cover body, the fixing portion comprises a push cylinder, and the push cylinder is connected to the support seat;

the pushing part comprises a support, and the support is connected to an output shaft of the pushing cylinder.

Optionally, two pushing cylinders are arranged on the side wall of the cover body in a mirror symmetry manner;

the support comprises a support ring, supporting plates are arranged on two sides of the support ring, the supporting plates are connected to two output shafts of the pushing cylinders respectively, and the stirring mechanism is connected to the support ring.

Optionally, the enzymatic reaction device further comprises a guide assembly, and the guide assembly is arranged on the bracket and the cover body and used for limiting the directional movement of the bracket.

Optionally, the guide assembly comprises:

the guide plate is fixedly connected to the side wall of the support ring and provided with a positioning hole;

the supporting boss is arranged on the side wall of the cover body;

the guide rod is fixedly arranged on the support boss and embedded in the positioning hole to slide.

Optionally, the number of the guide assemblies is two, and the two guide assemblies are arranged on the side wall of the cover body in a mirror symmetry manner.

Optionally, the stirring mechanism comprises:

the motor is connected to the power mechanism;

the rotating rod is connected to a rotating shaft of the motor, penetrates through the cover body and extends into the barrel body;

the stirring blade is arranged on the rotating rod; and

a stirring portion provided on the rotating lever.

Optionally, the agitating part comprises:

a connecting ring, which is arranged on the rotating rod, and

the stirring plates are uniformly distributed along the circumference of the connecting ring.

Optionally, the agitating plate comprises:

the connecting rod is connected to the connecting ring;

and the ramming plate is connected with one end of the connecting rod deviating from the rotating rod.

Has the advantages that: according to the enzymatic reaction device, raw materials to be stirred are placed into the barrel body, and the raw materials in the barrel body are stirred through the stirring mechanism. At the in-process of rabbling mechanism at work, start power unit, fixed part through power unit produces power, and promotion portion is along being close to or keeping away from the staving removes, through promotion portion drive rabbling mechanism, makes rabbling mechanism can reciprocating motion in the staving, and the rabbling mechanism of removal not only rotates the stirring, also can carry out reciprocating motion stirring, makes the rabbling mechanism stir more evenly to raw materials in the staving like this, because the rabbling mechanism rotates simultaneously and removes, has improved stirring efficiency like this, realizes the stirring effect in shorter time, improves reation kettle's work efficiency.

Drawings

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

FIG. 2 is an exploded view of an embodiment of an enzymatic reaction apparatus of the present invention.

Description of reference numerals: 100. a barrel body; 110. a reaction chamber; 200. a cover body; 210. a supporting seat; 300. A power mechanism; 310. a fixed part; 311. a push cylinder; 320. a pushing part; 321. a support; 322. A support ring; 323. a support plate; 330. a guide assembly; 331. a guide plate; 332. supporting the boss; 333. a guide bar; 400. a stirring mechanism; 410. a motor; 420. rotating the rod; 430. a stirring blade; 440. a stirring section; 441. a connecting ring; 442. stirring the plate; 443. a connecting rod; 444. a knockout plate.

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 an enzymatic reaction apparatus including a barrel body 100, and a cover body 200. For convenience of structural description, the tub 100 is configured as a circular tub 100, and the tub 100 is disposed along a vertical direction, a reaction chamber 110 is disposed in the tub 100, and an upper end of the tub 100 is configured as an opening to be an inner side in a direction toward the reaction chamber 110 and to be an outer side in a direction away from the tub 100. The cover 200 is detachably connected to the barrel 100, and the cover 200 is used for covering the opening of the reaction chamber 110. Wherein the enzymatic reaction apparatus further comprises: a power mechanism 300, and a stirring mechanism 400. The power mechanism 300 includes a fixing portion 310, the fixing portion 310 is fixedly connected to the cover 200, and a pushing portion 320 connected to the fixing portion 310 and moving toward or away from the tub 100. The stirring mechanism 400 is connected to the pushing part 320, and extends into the barrel 100 through the cover 200, and the stirring mechanism 400 stirs the raw material in the barrel 100.

In the above scheme, the raw material to be stirred is put into the tub 100, and the raw material in the tub 100 is stirred by the stirring mechanism 400. In the process of the operation of the stirring mechanism 400, the power mechanism 300 is started, the fixing part 310 of the power mechanism 300 generates power, the pushing part 320 moves close to or away from the barrel body 100, the stirring mechanism 400 is driven by the pushing part 320, so that the stirring mechanism 400 can move in the barrel body 100 in a reciprocating manner, the moving stirring mechanism 400 not only rotates for stirring, but also can move in a reciprocating manner, so that the stirring mechanism 400 can stir raw materials in the barrel body 100 more uniformly, and because the stirring mechanism 400 rotates and moves simultaneously, the stirring efficiency is improved, the stirring effect is realized in a shorter time, and the working efficiency of the reaction kettle is improved.

Referring to fig. 1 and fig. 2, based on the above scheme, the specific structure of the embodiment is as follows: the power mechanism 300 and the stirring mechanism 400 are both disposed on the cover 200, and when the cover 200 is detached from the tub 100, the power mechanism 300 and the stirring mechanism 400 can be detached together with the cover 200. The side of the cover body 200 is provided with a supporting seat 210, the fixing portion 310 includes a pushing cylinder 311, and the pushing cylinder 311 is connected to the supporting seat 210. Specifically, the support base 210 extends in the vertical direction, and the push cylinder 311 extends in the vertical direction, so that the output shaft of the push cylinder 311 can move in the vertical direction after ventilation. The pushing part 320 includes a bracket 321, and the bracket 321 is connected to an output shaft of the pushing cylinder 311. The support 321 is arranged along the horizontal direction, and the stirring mechanism 400 is connected to the support 321. When the pushing cylinder 311 is started, the support 321 is driven by the output shaft to move up and down, the output shaft drives the stirring mechanism 400 to move up and down, and the stirring mechanism 400 extends into the barrel 100, so that the part of the stirring mechanism 400 in the barrel 100 can move up and down. Like this rabbling mechanism 400 reciprocates through the drive that promotes cylinder 311 when realizing self pivoted, removes the in-process and not only rotates the raw materials of staving 100 different height position and mix, has realized the stirring of upper and lower direction moreover reciprocating the process, has improved stirring efficiency greatly.

The number of the push cylinders 311 in this embodiment is two, and the two push cylinders 311 are arranged on the side wall of the cover 200 in a mirror symmetry manner. This allows the cover body 200 to be evenly stressed in the diameter direction. Driving the support 321 in a symmetrical position also provides the support 321 with greater load carrying capacity. The support 321 includes a support ring 322, support plates 323 are disposed on two sides of the support ring 322, the support plates 323 on two sides are respectively connected to output shafts of the two push cylinders 311, and the stirring mechanism 400 is connected to the support ring 322. The support of both sides is seted up the through-hole, and the output shaft of pushing cylinder 311 passes through the through-hole after connect through the nut in on backup pad 323, make pushing cylinder 311 more stable drive support 321 like this, through the fixed rabbling mechanism 400 of support 321 to make the stable vertical direction of following of rabbling mechanism 400 slide.

Referring to fig. 2, the enzymatic reaction apparatus further includes a guide assembly 330, and the guide assembly 330 is disposed on the support 321 and the cover 200 and serves to limit the directional movement of the support 321. The movement of the support 321 is guided by the guide assembly 330, so that the support 321 can move smoothly in the up-and-down direction. The guiding assembly 330 includes two forms, in this embodiment, the guiding assembly 330 takes a first form, and the first form specifically includes: a guide plate 331, a support boss 332, and a guide rod 333. The guide plate 331 is fixedly connected to the sidewall of the support ring 322, and a positioning hole (not labeled in the figures) is formed in the guide plate 331, the guide plate 331 extends along the radial direction of the support ring 322, and the positioning hole is located at one end of the guide plate 331 away from the support ring 322. The support bosses 332 are disposed on the side wall of the cover body 200, and the support bosses 332 extend in the radial direction of the cover body 200. The guide rod 333 is fixedly arranged on the support boss 332, and the guide rod 333 is arranged in the vertical direction and embedded in the positioning hole to slide. When the support 321 slides up and down, the support plate 323 is driven to slide up and down, the support plate 323 drives the guide rod 333 to slide up and down, and the guide rod 333 is limited by the positioning hole and can only move stably in the up-down direction. Thereby enabling the guide assembly 330 to function as a guide.

The second form is specifically: the support is provided with a guide plate, the guide plate is connected to the side wall of the support ring, a guide rod is fixedly connected to the guide plate, and the guide rod is arranged in the vertical direction. The side wall of the cover body is provided with a supporting boss, the supporting boss extends along the radial direction of the cover body, the supporting boss is provided with a positioning hole, and the guide rod is positioned in the positioning hole to move. The guiding principle is similar to that of the first form.

Referring to fig. 2, the number of the guide assemblies 330 in this embodiment is two, and the two guide assemblies 330 are arranged on the side wall of the cover 200 in a mirror symmetry. In this way, the movement of the support 321 can be limited in the diameter direction of the cover 200 by the guide assembly 330, so that the support 321 can move more stably. In addition, two guide assembly 330, two push cylinder 311 is located the four quadrant points of lid 200 respectively, makes structural design more reasonable like this, and lid 200 structure atress is more even.

Referring to fig. 1 and 2, the stirring mechanism 400 in the present embodiment includes: motor 410, rotating rod 420, stirring blade 430. The motor 410 is connected to the support 321 of the power mechanism 300 along the vertical direction, the rotating rod 420 is connected to the rotating shaft of the motor 410 along the vertical direction, and the rotating rod 420 penetrates through the cover 200 and extends into the barrel body 100. The agitating blade 430 is disposed on the rotating rod 420, and the agitating blade 430 is disposed along a radial direction of the rotating rod 420. When the motor 410 is powered on and rotates, the rotating rod 420 is driven to rotate, and the rotating rod 420 drives the stirring blade 430 to rotate, so that stirring is performed by the rotating stirring blade 430. Meanwhile, the power mechanism 300 is started, and the bracket 321 of the power mechanism 300 drives the motor 410 to move, so as to drive the rotating rod 420 to move, so that the stirring blade 430 moves while rotating. The stirring range of the stirring blade 430 is increased. In addition, the stirring mechanism 400 further includes a stirring portion 440, and the stirring portion 440 is provided on the rotating lever 420. When the rotation lever 420 is rotated, the agitating part 440 is moved such that the agitating part 440 moves back and forth at an upper position within the tub 100, thereby agitating the raw material by the agitating part 440. The stirring is more uniform, and the stirring efficiency is improved.

Referring to fig. 1 and 2, the stirring part 440 includes: a connection ring 441, and a plurality of agitating plates 442. The connecting ring 441 is sleeved on the rotating rod 420, the connecting ring 441 in this embodiment is detachably connected to the rotating rod 420, and the plurality of stirring plates 442 are uniformly distributed along the circumference of the connecting ring 441. Thus, when the stirring portion 440 is not used, the stirring portion 440 can be detached from the rotating lever 420, and the stirring plate 442 can be connected to different height positions of the rotating lever 420 through the connection ring 441 according to the amount of the processing material, thereby being adaptively adjusted. The agitating plate 442 in this embodiment includes: a connecting rod 443, and a knockout plate 444. The connecting rod 443 is connected to the connecting ring 441, and the knockout plate 444 is connected to an end of the connecting rod facing away from the rotating rod 420. In a specific structure, the distance from the outer end of the striker plate 444 to the rotation center of the rotating rod 420 is greater than the distance from the outer end of the stirring blade 430 to the rotation center of the rotating rod 420, so that the stirring is more sufficient.

In summary, in the enzymatic reaction apparatus of the present invention, the raw material to be stirred is put into the barrel 100, and when the motor 410 is powered on and rotates, the rotating rod 420 is driven to rotate, and the rotating rod 420 drives the stirring blade 430 to rotate, so that the raw material is stirred by the rotating stirring blade 430. Meanwhile, the power mechanism 300 is started, and the bracket 321 of the power mechanism 300 drives the motor 410 to move, so as to drive the rotating rod 420 to move, so that the stirring blade 430 moves while rotating. The stirring range of the stirring blade 430 is increased and in addition, the stirring portion 440 is added to the rotating lever 420, and the stirring portion 440 moves in the up and down direction in the tub, thereby enabling stirring at different heights. Therefore, the stirring mechanism 400 rotates and moves simultaneously, so that the stirring efficiency is improved, the stirring effect is realized in a shorter time, and the working efficiency of the reaction kettle is improved.

It is to be understood that the utility model is not limited to the examples described above, but that modifications and variations may be effected thereto by those of ordinary skill in the art in light of the foregoing description, and that all such modifications and variations are intended to be within the scope of the utility model as defined by the appended claims.

Claims (5)

1. The utility model provides an enzymatic reaction device, includes the staving, and can dismantle the connection lid on the staving, its characterized in that, enzymatic reaction device still includes:

the power mechanism comprises a fixing part and a pushing part, wherein the fixing part is fixedly connected to the cover body, and the pushing part is connected to the fixing part and moves close to or far away from the barrel body;

the stirring mechanism is connected to the pushing part and extends into the barrel body through the cover body;

a supporting seat is arranged on the side face of the cover body, the fixing part comprises a pushing cylinder, and the pushing cylinder is connected to the supporting seat;

the pushing part comprises a bracket which is connected to an output shaft of the pushing cylinder;

the two pushing cylinders are arranged on the side wall of the cover body in a mirror symmetry mode;

the support comprises a support ring, support plates are arranged on two sides of the support ring, the support plates on the two sides are respectively connected to output shafts of the two pushing cylinders, and the stirring mechanism is connected to the support ring;

the enzymatic reaction device also comprises a guide assembly, and the guide assembly is arranged on the bracket and the cover body and is used for limiting the directional movement of the bracket;

the guide assembly includes:

the guide plate is fixedly connected to the side wall of the support ring and provided with a positioning hole;

the supporting boss is arranged on the side wall of the cover body;

the guide rod is fixedly arranged on the support boss and embedded in the positioning hole to slide.

2. Enzymatic reaction device in accordance with claim 1, characterised in that two guide elements are provided, two of which are arranged mirror-symmetrically on the side wall of the cover.

3. The enzymatic reaction device of claim 1, wherein said agitation mechanism comprises:

the motor is connected to the power mechanism;

the rotating rod is connected to a rotating shaft of the motor, penetrates through the cover body and extends into the barrel body;

the stirring blade is arranged on the rotating rod; and

a stirring portion provided on the rotating lever.

4. The enzymatic reaction device of claim 3, wherein the agitating part comprises:

a connecting ring, which is arranged on the rotating rod, and

the stirring plates are uniformly distributed along the circumference of the connecting ring.

5. The enzymatic reaction device of claim 4, wherein the agitation plate comprises:

the connecting rod is connected to the connecting ring;

and the ramming plate is connected with one end of the connecting rod deviating from the rotating rod.

Images