CN113318694B - Organic synthesizer of biological imaging material - Google Patents

Abstract

The invention discloses an organic synthesis device for biological imaging materials, which comprises a manual positioning device, a storage barrel, a manual positioning assembly and a bearing plate, wherein the bearing plate is connected with the manual positioning assembly; the working device comprises a first workbench arranged on one side of the storage barrel, a second workbench arranged on one side of the first workbench, a containing barrel assembly arranged on the first workbench, a power assembly connected with the second workbench, and a stirring reaction assembly arranged above the second workbench. According to the invention, through the matching use of all the components, the switching between the stirring function and the cleaning function can be realized quickly only through manual adjustment, the reaction of organic matters in the stirring barrel is accelerated through stirring, the synthesis efficiency of the organic matters is effectively improved, the inner wall which is difficult to clean can be cleaned quickly through simple operation after the mixing process, and the next use is facilitated.

Description

Organic synthesizer of biological imaging material

Technical Field

The invention relates to the technical field of synthesis equipment, in particular to an organic synthesis device for biological imaging materials.

Background

The human beings have close relationship with chemical engineering, are popularized to the aspects of life, and almost have no separation from organic compounds at any time and any place in modern life. The preparation of the organic matter is a process of chemically converting simple substances, simple inorganic substances or organic substances into more complex organic substances, or a process of decomposing the complex substances into simpler substances, or a process of extracting a certain component from natural products or processing the natural substances. The organic matter need use the agitator at the in-process of synthesis, and the stirring enables fully contact between the reactant, makes individual part of individual reactant be heated evenly to make the reaction give off heat and in time scatter, thereby make the reaction go on smoothly, use agitating unit, both can shorten reaction time, can improve reaction yield again. And present current organic matter synthesis agitating unit can not carry out the flash mixed to organic compound, and quick heat dissipation, the organic matter needs to consume longer time when carrying out the synthesis of next process like this to lead to being used for the organic matter synthesis to appear the slow problem of synthetic efficiency, reduced the productivity of enterprise, bring great economic loss for the enterprise.

Disclosure of Invention

This section is for the purpose of summarizing some aspects of embodiments of the invention and to briefly introduce some preferred embodiments. In this section, as well as in the abstract and the title of the invention of this application, simplifications or omissions may be made to avoid obscuring the purpose of the section, the abstract and the title, and such simplifications or omissions are not intended to limit the scope of the invention.

The present invention has been made keeping in mind the above and/or other problems occurring in the prior art.

Therefore, it is an object of the present invention to provide an organic synthesis apparatus for a biological imaging material, which can allow a composition to react sufficiently during synthesis and facilitate rapid cleaning after completion of the reaction.

In order to solve the technical problems, the invention provides the following technical scheme: a biological imaging material organic synthesis device comprises a manual positioning device, a biological imaging material organic synthesis device and a biological imaging material organic synthesis device, wherein the manual positioning device comprises a storage barrel, a manual positioning assembly and a bearing plate connected with the manual positioning assembly; the working device comprises a first working platform arranged on one side of the containing barrel, a second working platform arranged on one side of the first working platform, a containing barrel assembly arranged on the first working platform, a power assembly connected with the second working platform, and a stirring reaction assembly arranged above the second working platform.

As a preferable embodiment of the organic synthesis apparatus for biological imaging material of the invention, wherein: the manual positioning assembly comprises an operation fixing table, a manual driving piece connected with the operation fixing table and two groups of lifting pieces which are symmetrically arranged; the two lifting pieces have the same structure.

As a preferable embodiment of the organic synthesis apparatus for a biological imaging material of the present invention, wherein: the manual driving piece comprises a handle, a rotary table connected with the handle and a manual shaft connected with the middle part of the rotary table; the manual shaft is connected with the operation fixing table.

As a preferable embodiment of the organic synthesis apparatus for biological imaging material of the invention, wherein: the lifting piece comprises a meshing gear connected with the manual shaft, a matching gear meshed with the meshing gear, a transmission lead screw connected with the top of the matching gear, a transmission sleeve matched with the transmission lead screw and fixedly connected with the bearing plate, and a limiting bearing plate matched with two ends of the bearing plate; the bearing plate both ends are provided with the lug with spacing bearing plate complex.

As a preferable embodiment of the organic synthesis apparatus for a biological imaging material of the present invention, wherein: the first workbench comprises a first half frame, a second half frame, arc-shaped limiting grooves arranged in the middle of the first half frame and the second half frame, four groups of stabilizing leg plates arranged below the first workbench, and a fixed support arranged on one side of each stabilizing leg plate; the fixed bolster is including setting up in the first axis of rotation of its top, setting up in the three-jaw dish at first axis of rotation top to and set up in the three groups of sliding columns at three-jaw dish top.

As a preferable embodiment of the organic synthesis apparatus for a biological imaging material of the present invention, wherein: the holding barrel component comprises a stirring barrel body, an end cover connected with the stirring barrel body, a feeding port and a discharging port arranged on one side of the stirring barrel body, an annular limiting ring arranged on the side face of the stirring barrel body, three groups of through grooves arranged on the bottom of the stirring barrel body in an array mode, and an arc moving groove arranged above the end cover.

As a preferable embodiment of the organic synthesis apparatus for a biological imaging material of the present invention, wherein: the second working table comprises a frame body, three groups of limiting plates arranged in the middle of the frame body, a first transmission piece arranged at the top of the frame body, a first sleeve connected with the bottom of one end of the first transmission piece, a second sleeve arranged below the first sleeve, a moving plate arranged on the side surface of the second sleeve, a second transmission piece arranged below the second sleeve, and a third sleeve connected with the bottom of the second transmission piece; the first sleeve, the second sleeve and the third sleeve are identical in structure, and the first sleeve comprises a plurality of groups of clamping openings arranged on the inner wall of the first sleeve in an array mode.

As a preferable embodiment of the organic synthesis apparatus for biological imaging material of the invention, wherein: the power assembly comprises a driving motor, a second rotating shaft connected with the driving motor, a first matching block arranged on the side face of the second rotating shaft, a first matching block arranged right below the third sleeve, a second matching block arranged on the second sleeve and a second matching block arranged between the first sleeves.

As a preferable embodiment of the organic synthesis apparatus for a biological imaging material of the present invention, wherein: the stirring reaction assembly comprises a third rotating shaft, a reversing connecting piece arranged below the third rotating shaft, a first helical gear arranged in the reversing connecting piece and connected with the third rotating shaft, a second helical gear meshed with the first helical gear, a third helical gear meshed with the second helical gear, a fourth rotating shaft connected with the third helical gear, and a plurality of groups of stirring blades arranged at the bottom of the fourth rotating shaft in an array manner; the end of the stirring blade is set as a tip.

As a preferable embodiment of the organic synthesis apparatus for biological imaging material of the invention, wherein: the containment drum assembly further includes a sealed condensing jacket disposed above the arcuate moving trough.

The invention has the beneficial effects that: this device uses through the cooperation of each subassembly, only needs manual adjustment, can realize stirring fast and the switching of two kinds of functions of clearance to accelerate the organic matter reaction in the agitator through the stirring, the effectual synthetic efficiency that improves the organic matter, only need simple operation can be to being difficult to abluent inner wall clear up fast after the process of mixing, the next use of being convenient for.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings needed to be used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without inventive exercise. Wherein:

fig. 1 is an external structural view of an organic synthesis apparatus for a bio-imaging material.

Fig. 2 is an omitted view of the organic synthesis apparatus for a bio-imaging material.

Fig. 3 is another view of the external structure of the organic synthesis device for biological imaging materials.

Fig. 4 is an omitted illustration of the organic synthesis apparatus for a bio-imaging material.

Fig. 5 is an omitted view of the organic synthesis apparatus for a bio-imaging material.

Fig. 6 is a view showing a structure of a sleeve of the organic synthesis apparatus for a bio-imaging material.

Fig. 7 is an exploded view of a receiving tub assembly of the organic synthesis apparatus for bio-imaging material.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention, but the present invention may be practiced in other ways than those specifically described and will be readily apparent to those of ordinary skill in the art without departing from the spirit of the present invention, and therefore the present invention is not limited to the specific embodiments disclosed below.

Furthermore, reference herein to "one embodiment" or "an embodiment" means that a particular feature, structure, or characteristic described in connection with the embodiment is included in at least one implementation of the invention. The appearances of the phrase "in one embodiment" in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments.

Example 1

Referring to fig. 1 to 7, a first embodiment of the present invention provides an organic synthesis apparatus for biological imaging materials, which includes a manual positioning device 100 and a working device 200, wherein the working device 200 controls two processes of stirring and cleaning by a motor, and the manual positioning device 100 switches different processes.

Specifically, the manual positioning device 100 includes a receiving barrel 101, a manual positioning assembly 102, and a bearing plate 103 connected to the manual positioning assembly 102;

the working device 200 comprises a first workbench 201 arranged on one side of the storage barrel 101, a second workbench 202 arranged on one side of the first workbench 201, a containing barrel component 203 arranged on the first workbench 201, a power component 204 connected with the second workbench 202, and a stirring reaction component 205 arranged above the second workbench 202.

Further, the manual positioning assembly 102 includes an operation fixing table 102a, a manual driving member 102b connected to the operation fixing table 102a, and two sets of symmetrically arranged lifting members 102c; the two sets of lifters 102c are identical in structure.

Further, the manual driving member 102b comprises a handle 102b-1, a rotary disc 102b-2 connected with the handle 102b-1, and a manual shaft 102b-3 connected with the middle part of the rotary disc 102 b-2; the manual shaft 102b-3 is connected to the operation fixing table 102 a.

Further, the lifting piece 102c comprises an engaging gear 102c-1 connected with the manual shaft 102b-3, a matching gear 102c-2 engaged with the engaging gear 102c-1, a transmission lead screw 102c-3 connected with the top of the matching gear 102c-2, a transmission sleeve 102c-4 matched with the transmission lead screw 102c-3 and fixedly connected with the bearing plate 103, and a limiting bearing plate 102c-5 matched with two ends of the bearing plate 103; the two ends of the bearing plate 103 are provided with bumps matched with the limiting bearing plate 102 c-5. The operator only needs to rotate the handle 102b-1 to rotate the two sets of gears on the manual shaft 102b-3, so that the transmission lead screw 102c-3 controls the up-and-down movement of the bearing plate 103 under the cooperation of the transmission sleeve 102 c-4.

Further, the first workbench 201 comprises a first half frame 201a, a second half frame 201b, an arc-shaped limiting groove 201c formed in the middle of the first half frame 201a and the second half frame 201b, four groups of stabilizing leg plates 201d arranged below the first workbench 201, and a fixing support 201e arranged on one side of the stabilizing leg plates 201 d. The holding tub assembly 203 is fixed on the first work stage 201 by engaging the arc-shaped stopper groove 201c with the annular stopper ring 203e on the side of the stirring tub body 203a, and the stirring tub body 203a is made rotatable in the arc-shaped stopper groove 201 c. The fixing bracket 201e is arranged to fix the three-jaw plate 201e-2.

Further, the holding barrel assembly 203 comprises a stirring barrel 203a, an end cover 203b connected with the stirring barrel 203a, a feeding port 203c and a discharging port 203d arranged on one side of the stirring barrel 203a, an annular spacing ring 203e arranged on the side surface of the stirring barrel 203a, three groups of through grooves 203f arranged at the bottom of the stirring barrel 203a in an array manner, and an arc-shaped moving groove 203g arranged above the end cover 203 b.

Further, the fixed bracket 201e includes a first rotating shaft 201e-1 disposed above it, a three-jaw plate 201e-2 disposed on top of the first rotating shaft 201e-1, and three sets of sliding columns 201e-3 disposed on top of the three-jaw plate 201e-2. The three-jaw disc 201e-2 is arranged below the stirring barrel body 203a, and is matched with the three sets of through grooves 203f through the three sets of sliding columns 201e-3, when the three-jaw disc 201e-2 rotates, the stirring barrel body 203a rotates along with the rotation of the three-jaw disc 201e-2 due to the fact that the sliding columns 201e-3 move in the through grooves 203 f.

Further, the second workbench 202 comprises a frame 202a, three sets of limiting plates 202b arranged in the middle of the frame 202a, a first transmission piece 202c arranged at the top of the frame 202a, a first sleeve 202d connected with the bottom of one end of the first transmission piece 202c, a second sleeve 202e arranged below the first sleeve 202d, a moving plate 202f arranged on the side of the second sleeve 202e, a second transmission piece 202g arranged below the second sleeve 202e, and a third sleeve 202h connected with the bottom of the second transmission piece 202 g; the first sleeve 202d, the second sleeve 202e, and the third sleeve 202h have the same structure, and the first sleeve 202d includes a plurality of sets of engaging openings 202d-1 arranged in an array on an inner wall thereof. First sleeve 202d, second sleeve 202e to and third sleeve 202h are fixed respectively and set up on three group limiting plate 202b, and second axis of rotation 204b runs through and sets up in three group sleeve middles, and second axis of rotation 204b leaves certain gap with the sleeve inner wall. It should be noted that, by adopting the prior art, the fixed sleeve can rotate by matching, such as adopting a connecting piece such as a bearing; the first transmission member 202c and the second transmission member 202g can be driven by a transmission belt or a gear chain.

Further, the power assembly 204 includes a driving motor 204a, a second rotating shaft 204b connected to the driving motor 204a, a first engaging block 204c disposed on a side of the second rotating shaft 204b and directly below the third sleeve 202g, a second engaging block 204d disposed between the second sleeve 202e and the first sleeve 202 d. The first mating block 204c and the second mating block 204d can both mate with the snap-fit opening 202d-1.

Further, the stirring reaction assembly 205 comprises a third rotating shaft 205a, a reversing connection piece 205b arranged below the third rotating shaft 205a, a first helical gear 205c arranged inside the reversing connection piece 205b and connected with the third rotating shaft 205a, a second helical gear 205d meshed with the first helical gear 205c, a third helical gear 205e meshed with the second helical gear 205d, a fourth rotating shaft 205f connected with the third helical gear 205e, and a plurality of groups of stirring blades 205g arranged at the bottom of the fourth rotating shaft 205f in an array manner; the end of the stirring blade 205g is provided with a tip, so that the inner wall can be cleaned more easily. The reversing connection 205b is disposed on the moving plate 202f, and controls the movement of the stirring reaction unit 205 through the moving plate 202f, and fixes the stirring reaction unit 205.

Further, one end of second transmission member 202e is connected to first rotating shaft 201 e-1. One end of the first transmission member 202c is connected to the third rotating shaft 205 a; the moving plate 202f is connected to the fourth rotating shaft 205 f. The manual positioning device 100 carries the driving motor 204a through the carrying plate 103, so as to adjust the height of the driving motor 204 a.

When the device is used, the handle 102b-1 is rotated, the bearing plate 103 is controlled to drive the power assembly 204 to move upwards, the first matching block 204c and the second matching block 204d on the second rotating shaft 204b are respectively clamped with the first sleeve 202d and the third sleeve 202h, the handle 102b-1 is stopped rotating, and raw materials are discharged into the stirring barrel body 203a through the material inlet 203 c; after the blanking is finished, the driving motor 204a is started, so that the first sleeve 202d and the third sleeve 202h respectively drive the first transmission piece 202c and the second transmission piece 202g to move; the motion process of the first transmission piece 202c is as follows: the first sleeve 202d rotates to simultaneously rotate the third rotating shafts 205a by the first transmission members 202c, and the fourth rotating shafts 205f rotate in the opposite direction to the third rotating shafts 205a by engaging the three sets of bevel gears with the reversing connection members 205b disposed below the third rotating shafts 205a, i.e., to change the stirring direction of the stirring vanes 205 g. The motion process of second transmission member 202g is: when the second sleeve 202e rotates, the first rotating shaft 201e-1 is simultaneously rotated through the second transmission piece 202g, so that the first rotating shaft 201e-1 drives the three-jaw disc 201e-2 to synchronously rotate under the action of the second transmission piece 202g, and therefore the three sets of sliding columns 201e-3 move in the three sets of through grooves 203f, and the rotation of the stirring barrel body 203a is controlled; in conclusion, the rotation direction of the stirring barrel body 203a is opposite to the rotation direction of the stirring blades 205g, so that the stirring efficiency and the reaction degree are greatly improved.

After the reaction is finished, after the driving motor 204a is stopped, the inner wall of the stirring barrel body 203a which is difficult to clean needs to be cleaned, and only the handle 102b-1 needs to be rotated reversely to move downwards, so that the first sleeve 202d and the third sleeve 202h are separated from the matching block, and the first sleeve 202d and the third sleeve 202h move to be clamped with the second matching block 204d and then stop; then, the driving motor 204a is started, the moving plate 202f drives the stirring reaction component 205 to move to the tail end of the arc-shaped moving groove 203g along the direction of the arc-shaped moving groove 203g, then, the driving motor 204a is stopped, the tip of the stirring blade 205g is attached to the inner wall of the stirring barrel body 203a, then, according to the use process of reaction, the stirring reaction component 205 and the stirring barrel body 203a are controlled to rotate, the stirring reaction component 205 keeps stationary at one side of the stirring barrel body 203a to rotate and scratch the inner wall of the stirring barrel body 203a, the stirring barrel body 203a rotates, the stirring reaction component 205 can completely clean the inner wall in the state that the position is stationary, cleaning fluid enters the barrel through the material inlet 203c during cleaning, and finally, impurities are discharged through the material outlet 203 d; and after the cleaning is finished, resetting according to the reverse process. It should be noted that the arc degree of the arc-shaped moving groove 203g is set according to the distance between the second rotating shaft 204b and the third rotating shaft 205 a.

To sum up, this device uses through the cooperation of each subassembly, stirs the reaction to the organic matter in the agitator, and the effectual synthetic efficiency that improves the organic matter only needs simple operation can be to being difficult to abluent inner wall clear up fast after the process of mixing, is convenient for use next time.

Example 2

Referring to fig. 3, a second embodiment of the present invention, which is different from the first embodiment, is: and also comprises a sealed condensing jacket 203h. In the above embodiment, the organic synthesis apparatus for biological imaging material includes the manual positioning apparatus 100 and the working apparatus 200, the working apparatus 200 controls the two processes of stirring and cleaning by one motor, and the different processes are switched by the manual positioning apparatus 100.

Specifically, the manual positioning device 100 includes an accommodating barrel 101, a manual positioning assembly 102, and a bearing plate 103 connected to the manual positioning assembly 102;

the working device 200 comprises a first working platform 201 arranged on one side of the containing barrel 101, a second working platform 202 arranged on one side of the first working platform 201, a containing barrel component 203 arranged on the first working platform 201, a power component 204 connected with the second working platform 202, and a stirring reaction component 205 arranged above the second working platform 202.

Further, the manual positioning assembly 102 includes an operation fixing table 102a, a manual driving member 102b connected to the operation fixing table 102a, and two sets of symmetrically arranged lifting members 102c; the two sets of lifters 102c are identical in structure.

Further, the manual driving member 102b comprises a handle 102b-1, a rotating disc 102b-2 connected with the handle 102b-1, and a manual shaft 102b-3 connected with the middle part of the rotating disc 102 b-2; the manual shaft 102b-3 is connected to the operation fixing table 102 a.

Further, the lifting piece 102c comprises an engaging gear 102c-1 connected with the manual shaft 102b-3, a matching gear 102c-2 engaged with the engaging gear 102c-1, a transmission lead screw 102c-3 connected with the top of the matching gear 102c-2, a transmission sleeve 102c-4 matched with the transmission lead screw 102c-3 and fixedly connected with the bearing plate 103, and a limiting bearing plate 102c-5 matched with two ends of the bearing plate 103; the two ends of the bearing plate 103 are provided with bumps matched with the limiting bearing plate 102 c-5. The operator only needs to rotate the handle 102b-1 to rotate the two sets of gears on the manual shaft 102b-3, so that the transmission lead screw 102c-3 controls the up-and-down movement of the bearing plate 103 under the cooperation of the transmission sleeve 102 c-4.

Further, the first working platform 201 includes a first half frame 201a and a second half frame 201b, an arc-shaped limiting groove 201c disposed in the middle of the first half frame 201a and the second half frame 201b, four sets of stabilizing leg plates 201d disposed below the first working platform 201, and a fixing support 201e disposed on one side of the stabilizing leg plates 201 d. The holding tub assembly 203 is fixed on the first work stage 201 by engaging the arc-shaped stopper groove 201c with the annular stopper ring 203e on the side of the stirring tub body 203a, and the stirring tub body 203a is made rotatable in the arc-shaped stopper groove 201 c. The fixing bracket 201e is arranged to fix the three-jaw plate 201e-2.

Further, the holding barrel assembly 203 comprises a stirring barrel 203a, an end cover 203b connected with the stirring barrel 203a, a feeding port 203c and a discharging port 203d arranged on one side of the stirring barrel 203a, an annular spacing ring 203e arranged on the side surface of the stirring barrel 203a, three groups of through grooves 203f arranged at the bottom of the stirring barrel 203a in an array manner, and an arc-shaped moving groove 203g arranged above the end cover 203 b.

Further, the fixed bracket 201e includes a first rotating shaft 201e-1 disposed above the fixed bracket, a three-jaw plate 201e-2 disposed on the top of the first rotating shaft 201e-1, and three sets of sliding columns 201e-3 disposed on the top of the three-jaw plate 201e-2. The three-jaw disc 201e-2 is arranged below the stirring barrel body 203a, and is matched with the three sets of through grooves 203f through the three sets of sliding columns 201e-3, when the three-jaw disc 201e-2 rotates, the stirring barrel body 203a rotates along with the rotation of the three-jaw disc 201e-2 due to the fact that the sliding columns 201e-3 move in the through grooves 203 f.

Further, the second workbench 202 comprises a frame 202a, three sets of limiting plates 202b arranged in the middle of the frame 202a, a first transmission piece 202c arranged at the top of the frame 202a, a first sleeve 202d connected with the bottom of one end of the first transmission piece 202c, a second sleeve 202e arranged below the first sleeve 202d, a moving plate 202f arranged on the side of the second sleeve 202e, a second transmission piece 202g arranged below the second sleeve 202e, and a third sleeve 202h connected with the bottom of the second transmission piece 202 g; the first sleeve 202d, the second sleeve 202e, and the third sleeve 202h have the same structure, and the first sleeve 202d includes a plurality of sets of engaging openings 202d-1 arranged in an array on an inner wall thereof. First sleeve 202d, second sleeve 202e to and third sleeve 202h are fixed respectively and are set up on three group limiting plate 202b, and second axis of rotation 204b runs through and sets up in three group sleeve middle parts, and certain gap is left with the sleeve inner wall to second axis of rotation 204 b. It should be noted that, by adopting the prior art, the fixed sleeve can rotate by matching, such as adopting a connecting piece such as a bearing; the first transmission member 202c and the second transmission member 202g can be driven by a transmission belt or a gear chain.

Further, the power assembly 204 includes a driving motor 204a, a second rotating shaft 204b connected to the driving motor 204a, a first engaging block 204c disposed on a side of the second rotating shaft 204b and directly below the third sleeve 202g, a second engaging block 204d disposed between the second sleeve 202e and the first sleeve 202 d. The first mating block 204c and the second mating block 204d can both mate with the snap-fit opening 202d-1.

Further, the stirring reaction assembly 205 comprises a third rotating shaft 205a, a reversing connection piece 205b arranged below the third rotating shaft 205a, a first helical gear 205c arranged inside the reversing connection piece 205b and connected with the third rotating shaft 205a, a second helical gear 205d meshed with the first helical gear 205c, a third helical gear 205e meshed with the second helical gear 205d, a fourth rotating shaft 205f connected with the third helical gear 205e, and a plurality of groups of stirring blades 205g arranged at the bottom of the fourth rotating shaft 205f in an array manner; the end of the stirring blade 205g is provided with a tip, so that the inner wall can be cleaned more easily. The reversing connection 205b is disposed on the moving plate 202f, and controls the movement of the stirring reaction unit 205 through the moving plate 202f, and fixes the stirring reaction unit 205.

Further, one end of second transmission member 202e is connected to first rotating shaft 201 e-1. One end of the first transmission member 202c is connected to the third rotating shaft 205 a; the moving plate 202f is connected to the fourth rotating shaft 205 f. The manual positioning device 100 carries the driving motor 204a through the carrying plate 103, so as to adjust the height of the driving motor 204 a.

Preferably, the accommodating tub assembly 203 further includes a sealing condensation cover 203h disposed above the arc-shaped moving groove 203g. The sealed condensing sleeve 203h is installed during reaction, plays a role in sealing and condensing reactants, and can be detached when cleaning is needed.

When the device is used, the handle 102b-1 is rotated, the bearing plate 103 is controlled to drive the power assembly 204 to move upwards, the first matching block 204c and the second matching block 204d on the second rotating shaft 204b are respectively clamped with the first sleeve 202d and the third sleeve 202h, the handle 102b-1 is stopped rotating, and raw materials are discharged into the stirring barrel body 203a through the material inlet 203 c; after the blanking is finished, the driving motor 204a is started, so that the first sleeve 202d and the third sleeve 202h respectively drive the first transmission piece 202c and the second transmission piece 202g to move; the motion process of the first transmission member 202c is as follows: the first sleeve 202d rotates to rotate the third rotating shaft 205a simultaneously by the first transmission member 202c, and the fourth rotating shaft 205f rotates in the opposite direction to the third rotating shaft 205a by engaging with three sets of bevel gears by the reversing connection member 205b disposed under the third rotating shaft 205a, i.e. the stirring direction of the stirring blades 205g is changed. The motion process of second transmission member 202g is: when the second sleeve 202e rotates, the first rotating shaft 201e-1 is simultaneously rotated through the second transmission piece 202g, so that the first rotating shaft 201e-1 drives the three-jaw disc 201e-2 to synchronously rotate under the action of the second transmission piece 202g, and therefore the three sets of sliding columns 201e-3 move in the three sets of through grooves 203f, and the rotation of the stirring barrel body 203a is controlled; in conclusion, the rotation direction of the stirring barrel body 203a is opposite to the rotation direction of the stirring blades 205g, so that the stirring efficiency and the reaction degree are greatly improved.

After the reaction is finished, after the driving motor 204a is stopped, the inner wall of the stirring barrel body 203a which is difficult to clean needs to be cleaned, and only the handle 102b-1 needs to be rotated reversely to move downwards, so that the first sleeve 202d and the third sleeve 202h are separated from the matching block, and the first sleeve 202d and the third sleeve 202h move to be clamped with the second matching block 204d and then stop; then, the driving motor 204a is started, the moving plate 202f drives the stirring reaction component 205 to move to the tail end of the arc-shaped moving groove 203g along the direction of the arc-shaped moving groove 203g, then, the driving motor 204a is stopped, the tip of the stirring blade 205g is attached to the inner wall of the stirring barrel body 203a, then, according to the use process of reaction, the stirring reaction component 205 and the stirring barrel body 203a are controlled to rotate, the stirring reaction component 205 keeps stationary at one side of the stirring barrel body 203a to rotate and scratch the inner wall of the stirring barrel body 203a, the stirring barrel body 203a rotates, the stirring reaction component 205 can completely clean the inner wall in the state that the position is stationary, cleaning fluid enters the barrel through the material inlet 203c during cleaning, and finally, impurities are discharged through the material outlet 203 d; after cleaning, resetting according to the reverse process. It should be noted that the arc degree of the arc-shaped moving groove 203g is set according to the distance between the second rotating shaft 204b and the third rotating shaft 205 a.

To sum up, this device uses through the cooperation of each subassembly, only needs manual adjustment, can realize stirring fast and the switching of two kinds of functions of clearance to accelerate the organic matter reaction in the agitator through the stirring, the effectual synthetic efficiency that improves the organic matter, only need simple operation can be to being difficult to abluent inner wall clear up fast after the process of mixing, the next use of being convenient for.

It is important to note that the construction and arrangement of the present application as shown in the various exemplary embodiments is illustrative only. Although only a few embodiments have been described in detail in this disclosure, those skilled in the art who review this disclosure will readily appreciate that many modifications are possible (e.g., variations in sizes, dimensions, structures, shapes and proportions of the various elements, values of parameters (e.g., temperatures, pressures, etc.), mounting arrangements, use of materials, colors, orientations, etc.) without materially departing from the novel teachings and advantages of the subject matter recited in this application. For example, elements shown as integrally formed may be constructed of multiple parts or elements, the position of elements may be reversed or otherwise varied, and the nature or number of discrete elements or positions may be altered or varied. Accordingly, all such modifications are intended to be included within the scope of this invention. The order or sequence of any process or method steps may be varied or re-sequenced according to alternative embodiments. In the claims, any means-plus-function clause is intended to cover the structures described herein as performing the recited function and not only structural equivalents but also equivalent structures. Other substitutions, modifications, changes and omissions may be made in the design, operating conditions and arrangement of the exemplary embodiments without departing from the scope of the present inventions. Therefore, the present invention is not limited to a particular embodiment, but extends to various modifications that nevertheless fall within the scope of the appended claims.

Moreover, in an effort to provide a concise description of the exemplary embodiments, all features of an actual implementation may not be described (i.e., those unrelated to the presently contemplated best mode of carrying out the invention, or those unrelated to enabling the invention).

It should be appreciated that in the development of any such actual implementation, as in any engineering or design project, numerous implementation-specific decisions may be made. Such a development effort might be complex and time consuming, but would nevertheless be a routine undertaking of design, fabrication, and manufacture for those of ordinary skill having the benefit of this disclosure, without undue experimentation.

It should be noted that the above-mentioned embodiments are only for illustrating the technical solutions of the present invention and not for limiting, and although the present invention has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications or equivalent substitutions may be made on the technical solutions of the present invention without departing from the spirit and scope of the technical solutions of the present invention, which should be covered by the claims of the present invention.

Claims (2)

1. An organic synthesis device of biological imaging materials is characterized in that: comprises the steps of (a) preparing a mixture of a plurality of raw materials,

the manual positioning device (100) comprises a storage barrel (101), a manual positioning assembly (102) and a bearing plate (103) connected with the manual positioning assembly (102);

the working device (200) comprises a first working table (201) arranged on one side of the containing barrel (101), a second working table (202) arranged on one side of the first working table (201), a containing barrel assembly (203) arranged on the first working table (201), a power assembly (204) connected with the second working table (202), and a stirring reaction assembly (205) arranged above the second working table (202);

the manual positioning assembly (102) comprises an operation fixed table (102 a), a manual driving piece (102 b) connected with the operation fixed table (102 a), and two groups of lifting pieces (102 c) which are symmetrically arranged; the two groups of lifting pieces (102 c) have the same structure;

the manual driving piece (102 b) comprises a handle (102 b-1), a rotating disc (102 b-2) connected with the handle (102 b-1), and a manual shaft (102 b-3) connected with the middle part of the rotating disc (102 b-2); the manual shaft (102 b-3) is connected with the operation fixing table (102 a);

the lifting piece (102 c) comprises an engaging gear (102 c-1) connected with the manual shaft (102 b-3), a matching gear (102 c-2) engaged with the engaging gear (102 c-1), a transmission lead screw (102 c-3) connected with the top of the matching gear (102 c-2), a transmission sleeve (102 c-4) matched with the transmission lead screw (102 c-3) and fixedly connected with the bearing plate (103), and a limiting bearing plate (102 c-5) matched with two ends of the bearing plate (103); bumps matched with the limiting bearing plates (102 c-5) are arranged at two ends of the bearing plate (103);

the first workbench (201) comprises a first half frame (201 a) and a second half frame (201 b), arc-shaped limiting grooves (201 c) arranged in the middle of the first half frame (201 a) and the second half frame (201 b), four groups of stabilizing leg plates (201 d) arranged below the first workbench (201), and a fixed support (201 e) arranged on one side of the stabilizing leg plates (201 d); the fixed support (201 e) comprises a first rotating shaft (201 e-1) arranged above the fixed support, a three-jaw disc (201 e-2) arranged at the top of the first rotating shaft (201 e-1), and three groups of sliding columns (201 e-3) arranged at the top of the three-jaw disc (201 e-2);

the accommodating barrel assembly (203) comprises a stirring barrel body (203 a), an end cover (203 b) connected with the stirring barrel body (203 a), a feeding port (203 c) and a discharging port (203 d) arranged on one side of the stirring barrel body (203 a), an annular limiting ring (203 e) arranged on the side surface of the stirring barrel body (203 a), three groups of through grooves (203 f) arranged at the bottom of the stirring barrel body (203 a) in an array manner, and an arc-shaped moving groove (203 g) arranged above the end cover (203 b);

the second workbench (202) comprises a frame body (202 a), three groups of limiting plates (202 b) arranged in the middle of the frame body (202 a), a first transmission piece (202 c) arranged at the top of the frame body (202 a), a first sleeve (202 d) connected with the bottom of one end of the first transmission piece (202 c), a second sleeve (202 e) arranged below the first sleeve (202 d), a moving plate (202 f) arranged on the side surface of the second sleeve (202 e), a second transmission piece (202 g) arranged below the second sleeve (202 e), and a third sleeve (202 h) connected with the bottom of the second transmission piece (202 g); the first sleeve (202 d), the second sleeve (202 e) and the third sleeve (202 h) are identical in structure, and the first sleeve (202 d) comprises multiple groups of clamping ports (202 d-1) arranged on the inner wall of the first sleeve in an array mode;

the power assembly (204) comprises a driving motor (204 a), a second rotating shaft (204 b) connected with the driving motor (204 a), a first matching block (204 c) arranged on the side surface of the second rotating shaft (204 b) and right below the third sleeve (202 h), a second matching block (204 d) arranged between the second sleeve (202 e) and the first sleeve (202 d);

the stirring reaction component (205) comprises a third rotating shaft (205 a), a reversing connection piece (205 b) arranged below the third rotating shaft (205 a), a first helical gear (205 c) arranged inside the reversing connection piece (205 b) and connected with the third rotating shaft (205 a), a second helical gear (205 d) meshed with the first helical gear (205 c), a third helical gear (205 e) meshed with the second helical gear (205 d), a fourth rotating shaft (205 f) connected with the third helical gear (205 e), and a plurality of groups of stirring blades (205 g) arranged at the bottom of the fourth rotating shaft (205 f) in an array manner; the tail end of the stirring blade (205 g) is arranged to be a tip;

after the reaction is finished, after the driving motor (204 a) is stopped, the inner wall of the stirring barrel body (203 a) which is difficult to clean needs to be cleaned, and only the handle (102 b-1) needs to be rotated reversely to move downwards, so that the first sleeve (202 d) and the third sleeve (202 h) are separated from the matching block, and the first sleeve (202 d) and the third sleeve (202 h) move to the second sleeve (202 e) to be clamped with the second matching block (204 d) and then stop; then starting a driving motor (204 a), enabling a moving plate (202 f) to drive a stirring assembly (205) to move to the tail end of an arc-shaped moving groove (203 g) along the direction of the arc-shaped moving groove (203 g) and then stopping the driving motor (204 a), enabling the tip of a stirring blade (205 g) to be attached to the inner wall of a stirring barrel body (203 a), then controlling the stirring assembly (205) and the stirring barrel body (203 a) to rotate according to the using process during reaction, enabling the stirring assembly (205) to be kept still at one side of the stirring barrel body (203 a) to rotate and scratch the inner wall of the stirring barrel body (203 a), enabling the stirring barrel body (203 a) to rotate, enabling the stirring assembly (205) to be capable of completely cleaning the inner wall in the state that the position is kept still, enabling cleaning fluid to enter the barrel through a material inlet (203 c) during cleaning, and finally discharging sundries through a material outlet (203 d); after cleaning, resetting according to the reverse process; the arc degree of the arc-shaped moving groove (203 g) is set according to the distance between the second rotating shaft (204 b) and the third rotating shaft (205 a).

2. The organic synthesis apparatus for biological imaging material as claimed in claim 1, wherein: the receiving tub assembly (203) further includes a sealing condensing jacket (203 h) disposed above the arc-shaped moving groove (203 g).

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