CN117903936A - Biological enzyme catalysis chemical reaction tank device - Google Patents

Abstract

The invention discloses a biological enzyme catalysis chemical reaction tank device, which relates to the technical field of catalysis reaction tanks, and comprises a reaction tank body, wherein the top of the side end of the reaction tank body is communicated with an optimized enzyme conveying channel, a quantitative balance component is arranged in the optimized enzyme conveying channel, the side end of the top of the optimized enzyme conveying channel is communicated with an adding port, the substrate concentration is effectively improved by matching the quantitative balance component, a detector, a graphene conductive layer, a waterproof electric telescopic rod and a temperature control heating conductive block, the substrate conversion rate is conveniently improved, the improved substrate concentration is appropriately balanced and controlled according to the whole biological enzyme catalysis reaction rate, the whole catalytic reaction is prevented from being inhibited due to the excessive substrate concentration, the whole device effectively achieves catalytic balance under the regulation of the whole temperature, ph, ions and the substrate conversion rate, the whole catalytic accuracy is improved, and the influence of residual impurities in the reaction on the whole biological enzyme catalysis is reduced.

Description

A bio-enzyme catalytic chemical reaction tank device

Technical Field

The invention relates to the technical field of catalytic reaction tanks, in particular to a bio-enzyme catalytic chemical reaction tank device.

Background technique

A chemical reaction carried out under the action of a catalyst is called a catalytic reaction. In a chemical reaction, some of the original chemical bonds of the reaction molecules must be dissociated and new chemical bonds must be formed, which requires a certain amount of activation energy. In some systems where chemical reactions are difficult to occur, the addition of a third substance (catalyst) that helps the chemical bonds of the reaction molecules to rearrange can reduce the activation energy of the reaction, thereby accelerating the chemical reaction and controlling the selectivity and stereoregularity of the product.

However, in the prior art, when the bio-enzyme catalyzed chemical reactor is operating, the overall reaction rate cannot be precisely controlled. An environmental variable such as temperature or pH will affect the overall reaction and make the overall substrate conversion rate low, resulting in the reaction effect cannot be effectively guaranteed, which may cause impurities to remain in the reaction and affect the efficiency of the bio-enzyme operation. Therefore, it is necessary to propose a bio-enzyme catalyzed chemical reactor device.

Summary of the invention

The object of the present invention is to provide a bio-enzyme catalyzed chemical reaction tank device to solve the problem proposed in the above-mentioned background technology that when the bio-enzyme catalyzed chemical reaction tank is operating, the overall reaction rate cannot be accurately controlled, an environmental variable of temperature or pH will affect the overall reaction and make the overall substrate conversion rate low, resulting in the reaction effect cannot be effectively guaranteed, which may cause impurities to remain in the reaction, affecting the efficiency of the bio-enzyme operation.

To achieve the above-mentioned purpose, the present invention provides the following technical solutions: a bio-enzyme catalytic chemical reaction tank device, comprising a reaction tank body, the top of the side end of the reaction tank body is connected to an optimized enzyme delivery channel, a quantitative balance component is installed inside the optimized enzyme delivery channel, and the top side end of the optimized enzyme delivery channel is connected to a dosing port; the quantitative balance component comprises a driving brushless motor, a directional speed regulator is installed at the bottom of the driving brushless motor, a ratchet wheel is installed at the bottom axial end of the directional speed regulator, a directional turntable is installed at the bottom axial end of the ratchet wheel, a cone claw is engaged with the side angle edge of the ratchet wheel, a force-bearing rotating gear clamp rod is integrally formed at the side end of the cone claw, a central shaft column is penetrated through the side end surface of the force-bearing rotating gear clamp rod, a guide contact spring is installed on the surface of the directional turntable, and the force-bearing rotating gear clamp rod is The side end is contact-connected with a contact rod, and a directional connecting pin is installed on the side end of the contact rod through a connecting rod column. The side end of the contact rod is fastened with a force-bearing point contact rod, and a first cobalt magnet is installed on the side wall surface of the force-bearing point contact rod. A connecting structure is installed at the bottom of the directional connecting pin, and an optimized enzyme box is installed on the side end of the connecting structure. A motion controller is fastened to the side wall surface of the optimized enzyme box, and an electric control push rod is installed on the side end of the motion controller. A second cobalt magnet is installed on the top of the electric control push rod, and the first cobalt magnet and the second cobalt magnet are magnetically connected. An axial rotating column is connected to the bottom of the axial end of the directional turntable, and a feed disc is installed on the bottom peripheral side of the axial rotating column. The side end of the feed disc is connected with a flexible telescopic axial tube, and the side end of the flexible telescopic axial tube is connected to the surface of the optimized enzyme box.

Preferably, a contact slide groove is provided on the peripheral surface of the top wall of the feed tray, and four groups of pressurized feeding ends are equidistantly installed on the surface of the feed tray. Contact springs are connected to the sides of the four groups of pressurized feeding ends, and the contact springs are fitted inside the contact slide groove. A contact telescopic feeler rod is fastened to the bottom side of the directional turntable, and the contact telescopic feeler rod is linearly installed on the top of the contact slide groove.

Preferably, a microprocessor controller is installed on the side wall surface of the optimized enzyme delivery channel, a feedback circuit frame is installed on the top of the optimized enzyme delivery channel, a micro pump is connected to the side end of the feedback circuit frame, an activity sensor is installed on the bottom side end of the micro pump, and a sampling tube is connected to the bottom of the micro pump.

Preferably, the other side end of the reaction tank body is connected to a feed control valve end, the bottom surface of the reaction tank body is connected to a liquid outlet control valve end, the side end of the liquid outlet control valve end is connected to the bottom end of the sampling tube, the other side surface of the bottom of the reaction tank body is connected to a waste liquid treatment valve end, and the other side surface of the top of the reaction tank body is symmetrically connected to a first liquid control valve end and a second liquid control valve end respectively.

Preferably, a planetary control gear set is installed on the top of the reaction tank body, and a control motor is connected to the top of the axial end of the planetary control gear set. The axial ends of the three sets of planetary gears inside the planetary control gear set are fastened to an upper turntable through connecting columns, and a protective cover plate is installed on the top of the upper turntable.

Preferably, the circumferential side of the upper turntable is rotatably connected to a track, the track is installed on the top of the reaction tank body, the protective cover is installed on the top of the reaction tank body, the bottom axial end of the upper turntable is connected to a central column, the bottom circumferential side of the upper turntable is connected to a stirring rod, and a detector is installed on the bottom circumferential sleeve of the central column.

Preferably, a gear drive group is installed at the bottom of the reaction tank body, a control and adjustment motor is installed at the shaft center end of the gear on one side of the gear drive group, and a bottom shaft rail is connected to the top shaft center end of the gear on the other side of the gear drive group.

Preferably, the bottom shaft rail is installed at the inner bottom end of the reaction tank body, and the top of the bottom shaft rail is rotatably connected to a side adjustment reaction rod.

Preferably, the outer peripheral cover of the reaction tank body is provided with a heat-insulating protective shell, the inner wall surface of the heat-insulating protective shell is provided with a graphene conductive layer, and the outer wall surface of the side-adjusting reaction rod is installed with a waterproof electric telescopic rod.

Preferably, a temperature-controlled heating conductive block is connected to the side end of the waterproof electric telescopic rod, the temperature-controlled heating conductive block is in contact with the graphene conductive layer, and a supporting leg frame is sleeved and installed around the bottom of the reaction tank body.

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

In the present invention, the directional speed regulator is used to drive the ratchet wheel to rotate under the cooperation of the quantitative balancing component. However, the rotation drive at this time is premised on the motion controller receiving the driving signal required to drive the brushless motor to rotate, so that the electric control push rod is extended forward, so that the first cobalt magnet and the second cobalt magnet are magnetically connected, so that under the driving force of the electric control push rod, the force point contact rod is forced to rotate, and further the force-bearing rotating gear clamping rod drives the cone claw to rotate outside the directional connecting shaft pin, that is, the cone claw and the ratchet wheel are separated, so that the ratchet wheel is restricted from falling off, and then the guide contact spring and the surface of the force-bearing rotating gear clamping rod are in contact, so that the force condition signal of the force-bearing rotating gear clamping rod is transmitted to the motion controller, and then the ratchet wheel drives the directional turntable to rotate, so that when the internal substrate conversion rate of the biological enzyme catalytic reaction is affected, an electrical signal is sent to the contact telescopic contact rod, so that the contact telescopic contact rod is driven by the steering of the directional turntable to perform circumferential adjustment operation, and according to the feedback signal, it is downward. The bottom of the contact telescopic feeler rod contacts the contact spring after sliding one circle, and the conductive trigger signal is transmitted to the pressurized dosing end by using the contact, so that one group of the pressurized dosing end controlled by the contact spring performs auxiliary optimization enzyme dosing operation, and when the contact telescopic feeler rod forms the first circle and contacts the contact spring, the contact telescopic feeler rod returns to its original position, and performs subsequent contact control operations such as the second circle, the third circle and the fourth circle according to the feedback substrate conversion rate, effectively improving the substrate concentration, facilitating the improvement of the substrate conversion rate, and the increased substrate concentration is appropriately balanced and controlled according to the overall bio-enzyme catalytic reaction rate, avoiding the inhibition of the overall catalytic reaction due to excessive substrate concentration, and the overall device effectively adjusts the catalytic reaction rate of the bio-enzyme under the regulation of the overall temperature, pH, ions and substrate conversion rate to achieve catalytic balance, improve the overall catalytic accuracy, and reduce the influence of impurities remaining in the reaction on the overall bio-enzyme catalysis.

2. In the present invention, by cooperating with the detector, the graphene conductive layer, the waterproof electric telescopic rod and the temperature-controlled heating conductive block, when it is detected that the overall internal catalytic rate is affected by the environmental variables, the waterproof electric telescopic rod is controlled and adjusted to extend according to the size of the generated temperature environmental variables. For example, when the temperature environmental variable is small, a waterproof electric telescopic rod is extended to make the temperature-controlled heating conductive block contact the graphene conductive layer, and utilize the contact reaction with the graphene conductive layer to increase the overall reaction environment temperature. Simultaneously, under the rotation adjustment of the above-mentioned stirring rod and the side adjustment reaction rod, the temperature of the internal reactants can be effectively and evenly heated to avoid the temperature variables affecting the overall reaction rate.

3. In the present invention, the planetary control gear set is driven to rotate by the started control motor under the cooperation of the planetary control gear set, the sub-stirring rod, the gear drive set and the side adjustment reaction rod, so that the upper turntable to which the axial ends of the three sets of planetary gears inside the planetary control gear set are fastened through the connecting column is controlled to rotate clockwise on the top of the reaction tank body, and the sub-stirring rod is synchronously driven to rotate in the reaction tank body to promote the reaction rate, and the reaction rate inside the reaction tank body is controlled in real time through the ion control regulator on the surface of the sub-stirring rod in cooperation with the detector, and at the same time, under the action of the control and adjustment motor, according to the feedback signal detected by the detector, the gear drive set is driven to rotate and adjust, and then the bottom shaft rail is driven to rotate in contact with the bottom inner wall surface of the reaction tank body, and the side adjustment reaction rod is rotated synchronously, and the entire reaction catalytic rate is adjusted in real time through the pH controller installed on the surface of the rod body, so as to further ensure the operating efficiency of the overall reaction.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG1 is a schematic diagram of the structure of a bio-enzyme catalyzed chemical reaction tank device according to the present invention from a front view;

FIG2 is a schematic diagram of the structure of a bio-enzyme catalyzed chemical reaction tank device in the present invention when viewed from above;

FIG3 is a schematic diagram of the internal structure of a reaction tank body in a bio-enzyme catalytic chemical reaction tank device of the present invention;

FIG4 is a schematic cross-sectional view of a reaction tank body in a bio-enzyme catalyzed chemical reaction tank device according to the present invention;

FIG5 is a schematic diagram of the structure of an enlarged portion A in FIG3 of a bio-enzyme catalyzed chemical reaction tank device of the present invention;

FIG6 is a schematic diagram of the installation position structure of a quantitative balance component in a bio-enzyme catalytic chemical reaction tank device of the present invention;

FIG7 is a schematic structural diagram of a quantitative balance component in a bio-enzyme catalytic chemical reaction tank device of the present invention;

FIG8 is a schematic diagram of a top view of a quantitative balance assembly in a bio-enzyme catalyzed chemical reaction tank device according to the present invention;

FIG. 9 is a schematic structural diagram of a quantitative balance component in a bio-enzyme catalyzed chemical reaction tank device according to another angle of the present invention.

In the figure: 1, reaction tank; 2, support leg frame; 3, insulation protection shell; 4, optimized enzyme delivery channel; 5, addition port; 6, microprocessor controller; 7, feedback circuit frame; 8, micro pump; 9, activity sensor; 10, feed control valve end; 11, sampling tube; 12, waste liquid treatment valve end; 13, first liquid control valve end; 14, protective cover; 15, liquid outlet control valve end; 16, control motor; 17, control and adjustment motor; 18, quantitative balance component; 180, drive brushless motor; 181, directional speed regulator; 182, ratchet wheel; 183, cone claw; 184, force-bearing gear clamping rod; 185, central shaft column; 186, guide contact spring; 187, directional turntable; 188 , contact rod; 189, directional connecting shaft pin; 1890, connecting structure; 1891, optimized enzyme box; 1892, flexible telescopic axial tube; 1893, feed tray; 1894, contact slide; 1895, contact spring; 1896, force point contact rod; 1897, motion controller; 1898, electric control push rod; 1899, first cobalt magnet; 1801, pressurized feeding end; 1802, contact telescopic contact rod; 19, bottom shaft rail; 20, side adjustment reaction rod; 21, planetary control gear set; 22, sub-stirring rod; 23, central column; 24, detector; 25, gear drive group; 26, waterproof electric telescopic rod; 27, temperature-controlled heating conductive block; 28, graphene conductive layer.

Detailed ways

The following will be combined with the drawings in the embodiments of the present invention to clearly and completely describe the technical solutions in the embodiments of the present invention. Obviously, the implementation regulations described are only part of the embodiments of the present invention, not all of the embodiments. Based on the embodiments of the present invention, all other embodiments obtained by ordinary technicians in this field without creative work are within the scope of protection of the present invention.

Referring to Figures 1 to 9: a bio-enzyme catalytic chemical reaction tank device, comprising a reaction tank body 1, the top of the side end of the reaction tank body 1 is connected to an optimized enzyme delivery channel 4, the inside of the optimized enzyme delivery channel 4 is installed with a quantitative balance component 18, and the top side end of the optimized enzyme delivery channel 4 is connected to a dosing port 5; the quantitative balance component 18 comprises a driving brushless motor 180, a directional speed regulator 181 is installed at the bottom of the driving brushless motor 180, a ratchet wheel 182 is installed at the bottom axial end of the directional speed regulator 181, a directional turntable 187 is installed at the bottom axial end of the ratchet wheel 182, a cone claw 183 is connected to the side corner edge of the ratchet wheel 182, and a force-bearing rotating gear clamping rod 184 is integrally formed at the side end of the cone claw 183, a central shaft column 185 is set through the side end surface of the force-bearing rotating gear clamping rod 184, a guide contact spring 186 is installed on the surface of the directional turntable 187, and the side end of the force-bearing rotating gear clamping rod 184 is contact-connected with a contact rod 188, and the contact rod 1 The side end of the contact rod 188 is provided with a directional connecting shaft pin 189 through a connecting rod column, the side end of the contact rod 188 is fastened with a force point contact rod 1896, the side wall surface of the force point contact rod 1896 is installed with a first cobalt magnet 1899, the bottom of the directional connecting shaft pin 189 is installed with a connecting frame 1890, the side end of the connecting frame 1890 is installed with an optimized enzyme box 1891, the side wall surface of the optimized enzyme box 1891 is fastened with a motion controller 1897, and the motion controller 1897 is fastened with a motion controller 1897. An electric control push rod 1898 is installed on the side end of 97, and a second cobalt magnet is installed on the top of the electric control push rod 1898. The first cobalt magnet 1899 is magnetically connected to the second cobalt magnet. An axial rotating column is connected to the bottom of the axial end of the directional turntable 187, and a feed disk 1893 is installed on the bottom circumference of the axial rotating column. The side end of the feed disk 1893 is connected to a flexible telescopic axial tube 1892, and the side end of the flexible telescopic axial tube 1892 is connected to the surface of the optimized enzyme box 1891.

As shown in Figures 3, 4, 6, 7 and 9, a contact chute 1894 is provided on the circumferential surface of the top wall of the feed tray 1893, and four groups of pressurized feeding ends 1801 are equidistantly installed on the surface of the feed tray 1893. The sides of the four groups of pressurized feeding ends 1801 are connected with contact springs 1895, and the contact springs 1895 are fitted inside the contact chute 1894. The bottom side of the directional turntable 187 is fastened with a contact telescopic feeler rod 1802, and the contact telescopic feeler rod 1802 is linearly installed on the top of the contact chute 1894. When the internal substrate conversion rate of the bio-enzyme catalytic reaction is affected, an electrical signal is sent to the contact telescopic feeler rod 1802, so that the contact telescopic feeler rod 1802 is driven by the steering of the above-mentioned directional turntable 187 to perform circumferential adjustment operation, and extends downward according to the feedback signal, so as to facilitate the contact telescopic feeler rod 1802 to move downward. The bottom of the contact rod 1802 contacts and slides inside the contact groove 1894. After sliding one circle, the bottom of the contact telescopic contact rod 1802 contacts the contact spring 1895, and the conductive initial signal is transmitted to the pressurized addition end 1801 by means of the contact, so that one group of the pressurized addition end 1801 controlled by the contact spring 1895 performs auxiliary optimization enzyme addition operation. After the contact telescopic contact rod 1802 forms the first circle and contacts the contact spring 1895, the contact telescopic contact rod 1802 returns to its original position, and performs subsequent contact control operations such as the second circle, the third circle and the fourth circle according to the feedback substrate conversion rate, thereby effectively increasing the substrate concentration and facilitating the improvement of the substrate conversion rate. The increased substrate concentration is appropriately balanced and controlled according to the overall enzyme catalytic reaction rate to avoid the inhibition of the overall catalytic reaction due to excessive substrate concentration.

As shown in Figures 1 to 4, a microprocessor controller 6 is installed on the side wall surface of the optimized enzyme delivery channel 4, a feedback circuit frame 7 is installed on the top of the optimized enzyme delivery channel 4, a micro pump 8 is connected to the side end of the feedback circuit frame 7, an activity sensor 9 is installed on the bottom side end of the micro pump 8, and a sampling tube 11 is connected to the bottom of the micro pump 8. With the cooperation of the feedback circuit frame 7, it is convenient to extract an equal amount of the discharge test sample drawn from the sampling tube 11 and extract it according to the preset time with the cooperation of the micro pump 8, and under the action of the activity sensor 9, the extracted sample liquid is tested, and then the feedback circuit frame 7 is used to feed back to the above-mentioned driving brushless motor 180 for adjustment and control operations.

As shown in Figures 1 to 4, the other side end of the reaction tank body 1 is connected to a feed control valve end 10, the bottom surface of the reaction tank body 1 is connected to a liquid outlet control valve end 15, the side end of the liquid outlet control valve end 15 is connected to the bottom end of the sampling tube 11, the other side surface of the bottom of the reaction tank body 1 is connected to a waste liquid treatment valve end 12, and the other side surface of the top of the reaction tank body 1 is symmetrically connected to a first liquid control valve end 13 and a second liquid control valve end, respectively. With the cooperation of the feed control valve end 10, it is convenient to effectively control the feed amount and feed rate. With the cooperation of the liquid outlet control valve end 15, it is convenient for the above-mentioned sampling tube 11 to sample and extract the liquid sample discharged by the liquid outlet control valve end 15 according to demand, and multiple sampling controls are performed in different time periods, so as to effectively adjust the overall catalytic reaction rate in real time, and avoid the overall reaction rate being affected by the environmental variables of temperature or pH, which affects the overall reaction.

As shown in Figures 1 to 3, a planetary control gear set 21 is installed on the top of the reaction tank body 1, and a control motor 16 is connected to the top of the axial end of the planetary control gear set 21. The axial ends of the three sets of planetary gears inside the planetary control gear set 21 are fastened to the upper turntable through connecting columns, and a protective cover plate 14 is installed on the top of the upper turntable. Under the action of the control motor 16, when the bio-enzyme catalytic reaction operation is carried out, the started control motor 16 is used to drive the planetary control gear set 21 to rotate, so that the upper turntable to which the axial ends of the three sets of planetary gears inside the planetary control gear set 21 are fastened through the connecting column is controlled to rotate clockwise on the top of the reaction tank body 1.

As shown in Figure 4, the circumferential side of the upper turntable is connected to a track for rotation, the track is installed on the top of the reaction tank body 1, the protective cover 14 is installed on the top of the reaction tank body 1, the bottom axial end of the upper turntable is connected to the central column 23, the bottom circumferential side of the upper turntable is connected to the sub-stirring rod 22, and the bottom circumferential sleeve of the central column 23 is installed with a detector 24. When the upper turntable rotates clockwise, it synchronously drives the sub-stirring rod 22 to rotate in the reaction tank body 1 to promote the reaction rate, and the reaction rate inside the reaction tank body 1 is controlled in real time through the ion control regulator on the surface of the sub-stirring rod 22 with the cooperation of the detector 24.

As shown in Figures 2 to 4, a gear drive group 25 is installed at the bottom of the reaction tank body 1, and a control and adjustment motor 17 is installed at the shaft center end of the gear on one side of the gear drive group 25. The shaft center end of the top gear on the other side of the gear drive group 25 is connected to the bottom shaft rail 19. Under the action of the control and adjustment motor 17, according to the feedback signal detected by the detector 24, the gear drive group 25 is driven to rotate and adjust, thereby driving the bottom shaft rail 19 to rotate in contact with the bottom inner wall surface of the reaction tank body 1.

As shown in Figures 3 to 5, the bottom shaft rail 19 is installed at the inner bottom end of the reaction tank body 1, and the top of the bottom shaft rail 19 is rotatably connected to the side adjustment reaction rod 20. When the bottom shaft rail 19 rotates, the side adjustment reaction rod 20 rotates synchronously, and the entire reaction catalytic rate is adjusted in real time through the pH controller installed on the surface of the rod body.

As shown in Figures 1 and 5, the outer peripheral sleeve of the reaction tank body 1 is provided with a thermal insulation protective shell 3, the inner wall surface of the thermal insulation protective shell 3 is provided with a graphene conductive layer 28, and the outer wall surface of the side adjustment reaction rod 20 is installed with a waterproof electric telescopic rod 26. When the side adjustment reaction rod 20 rotates, the waterproof electric telescopic rod 26 synchronously follows the rotation, and synchronously under the action of the internal real-time detection feedback data of the detector 24, when it is detected that the overall internal catalytic rate is affected by the environmental variables, the waterproof electric telescopic rod 26 is controlled and adjusted to extend according to the size of the generated temperature environmental variables.

As shown in Figure 5, the side end of the waterproof electric telescopic rod 26 is connected to a temperature-controlled heating conductive block 27, and the temperature-controlled heating conductive block 27 is in contact with the graphene conductive layer 28. The bottom periphery of the reaction tank body 1 is sleeved with a support leg frame 2. If the temperature environment variable is small, a waterproof electric telescopic rod 26 is extended to make the temperature-controlled heating conductive block 27 contact with the graphene conductive layer 28, and utilize the contact reaction with the graphene conductive layer 28 to increase the overall reaction environment temperature. Synchronously, under the rotation adjustment of the above-mentioned sub-stirring rod 22 and the side adjustment reaction rod 20, the temperature of the internal reactants can be effectively and evenly heated to avoid the temperature variable affecting the overall reaction rate.

The wiring diagram of the reaction tank body 1, microprocessor controller 6, micro pump 8, activity sensor 9, control motor 16, control and adjustment motor 17, drive brushless motor 180, directional speed regulator 181, optimized enzyme box 1891, motion controller 1897, detector 24, temperature-controlled heating conductive block 27 and graphene conductive layer 28 in the present invention belongs to the common knowledge in the field, and its working principle is a well-known technology. The model is selected according to the actual use. Therefore, the control method and wiring arrangement of the reaction tank body 1, microprocessor controller 6, micro pump 8, activity sensor 9, control motor 16, control and adjustment motor 17, drive brushless motor 180, directional speed regulator 181, optimized enzyme box 1891, motion controller 1897, detector 24, temperature-controlled heating conductive block 27 and graphene conductive layer 28 will no longer be explained in detail.

The use method and working principle of the device are as follows: first, when the bio-enzyme catalytic reaction is carried out, the material is fed from the feed control valve end 10, so as to effectively control the feed amount and feed rate. When the material is placed inside the reaction tank body 1, the activated control motor 16 is used to drive the planetary control gear set 21 to rotate, so that the upper turntable to which the shaft ends of the three sets of planetary gears inside the planetary control gear set 21 are fastened through the connecting column and is controlled to rotate clockwise on the top of the reaction tank body 1, and the sub-stirring rod 22 is synchronously driven to rotate in the reaction tank body 1 to promote the reaction rate, and the ion control on the surface of the sub-stirring rod 22 is The regulator controls the reaction rate inside the reaction tank body 1 in real time with the cooperation of the detector 24. At the same time, under the action of the control and adjustment motor 17, according to the feedback signal detected by the detector 24, the gear drive group 25 is driven to rotate and adjust, thereby driving the bottom shaft rail 19 to rotate in contact with the bottom inner wall surface of the reaction tank body 1, and the side adjustment reaction rod 20 rotates synchronously, and the overall reaction catalytic rate is adjusted in real time through the ph controller installed on the surface of the rod body. When the side adjustment reaction rod 20 rotates, the waterproof electric telescopic rod 26 rotates synchronously, and synchronously detects the feedback data in real time inside the detector 24 Under the action, when it is detected that the overall internal catalytic rate is affected by the environmental variables, the waterproof electric telescopic rod 26 is controlled and adjusted to extend according to the size of the temperature environmental variables generated. For example, when the temperature environmental variables are small, a waterproof electric telescopic rod 26 is extended to make the temperature-controlled heating conductive block 27 contact the graphene conductive layer 28, and utilize the contact reaction with the graphene conductive layer 28 to increase the overall reaction environment temperature. Synchronously, under the rotation adjustment of the above-mentioned sub-stirring rod 22 and the side adjustment reaction rod 20, the temperature of the internal reactants can be effectively and evenly heated to avoid the temperature variables affecting the overall reaction rate. With the cooperation of the liquid outlet control valve end 15, it is convenient for the sampling tube 11 to sample and extract the liquid sample discharged by the liquid outlet control valve end 15 according to the demand, and to perform multiple sampling controls in different time periods, so as to effectively adjust the overall catalytic reaction rate in real time, and avoid the overall reaction rate being affected by the environmental variables of temperature or pH, that is, under the cooperation of the feedback circuit frame 7, it is convenient to extract the discharge test sample extracted from the sampling tube 11 in equal amounts and according to the preset time under the cooperation of the micro pump 8, and detect the extracted sample liquid under the action of the activity sensor 9, Afterwards, the feedback circuit frame 7 is used to feed back to the brushless motor 180 for adjustment and control. When the brushless motor 180 receives the control signal, it is started, and then the ratchet wheel 182 is driven to rotate with the cooperation of the directional speed regulator 181. However, the rotation drive at this time is premised on the motion controller 1897 receiving the driving signal required for the brushless motor 180 to rotate, so that the electric control push rod 1898 extends forward, so that the first cobalt magnet 1899 and the second cobalt magnet are magnetically connected, so that under the driving force of the electric control push rod 1898, the force point contact rod 1896 is forced to rotate, and the rotation is carried out. In one step, the stressed rotating gear clamp rod 184 drives the cone claw 183 to rotate outside the directional connecting shaft pin 189, that is, the cone claw 183 and the ratchet wheel 182 are separated, so that the ratchet wheel 182 is restricted from falling off, and then the fuse contact spring 186 contacts the surface of the stressed rotating gear clamp rod 184, so that the force condition signal of the stressed rotating gear clamp rod 184 is transmitted to the motion controller 1897, and then the ratchet wheel 182 drives the directional rotating disk 187 to rotate, so that when the internal substrate conversion rate of the biological enzyme catalytic reaction is affected, an electrical signal is sent to the contact telescopic contact rod 1802, so that the contact telescopic contact rod 1802 is 02 Under the steering drive of the directional turntable 187, it performs circumferential adjustment operation, and according to the feedback signal, it extends downward to facilitate the bottom of the contact telescopic feeler rod 1802 and the internal contact sliding of the contact chute 1894. After sliding a circle, the bottom of the contact telescopic feeler rod 1802 contacts the contact spring 1895, and the conductive initial signal is transmitted to the pressurized dosing end 1801 by the contact, so that one group of the pressurized dosing end 1801 controlled by the contact spring 1895 performs auxiliary optimization enzyme dosing operation, and when the contact telescopic feeler rod 1802 forms the first circle and contacts the contact spring 1895, , the contact telescopic feeler rod 1802 returns to its original position, and the subsequent second, third and fourth contact control operations are performed according to the feedback substrate conversion rate, which effectively increases the substrate concentration and facilitates the improvement of the substrate conversion rate. The increased substrate concentration is appropriately balanced and controlled according to the overall bio-enzyme catalytic reaction rate to avoid the inhibition of the overall catalytic reaction due to excessive substrate concentration. The overall device effectively adjusts the catalytic reaction rate of the bio-enzyme under the overall temperature, pH, ions, and substrate conversion rate to achieve catalytic balance, improve the overall catalytic accuracy, and reduce the influence of residual impurities in the reaction on the overall bio-enzyme catalysis.

Although the present invention has been described in detail with reference to the aforementioned embodiments, it is still possible for those skilled in the art to modify the technical solutions described in the aforementioned embodiments, or to make equivalent substitutions for some of the technical features therein. Any modifications, equivalent substitutions, improvements, etc. made within the spirit and principles of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. A bio-enzyme catalytic chemical reaction tank device, characterized in that it comprises a reaction tank body (1), the top of the side end of the reaction tank body (1) is connected to an optimized enzyme delivery channel (4), a quantitative balance component (18) is installed inside the optimized enzyme delivery channel (4), and the top side end of the optimized enzyme delivery channel (4) is connected to a dosing port (5); The quantitative balancing component (18) comprises a brushless driving motor (180), a directional speed regulator (181) is mounted on the bottom of the brushless driving motor (180), a ratchet wheel (182) is mounted on the bottom axial end of the directional speed regulator (181), a directional rotating disk (187) is mounted on the bottom axial end of the ratchet wheel (182), a cone claw (183) is snap-connected to the side corner edge of the ratchet wheel (182), and the side end of the cone claw (183) is integrally formed with a A force-bearing rotating gear clamp rod (184), a central shaft column (185) is provided through the side end surface of the force-bearing rotating gear clamp rod (184), a guide contact spring (186) is installed on the surface of the directional rotating disk (187), the side end of the force-bearing rotating gear clamp rod (184) is in contact with a contact rod (188), a directional connecting shaft pin (189) is installed on the side end of the contact rod (188) through a connecting rod column, and the side end of the contact rod (188) is fastened and connected to a force-bearing point contact rod (189). 6), a first cobalt magnet (1899) is installed on the side wall surface of the force-bearing point contact rod (1896), a connecting frame (1890) is installed on the bottom of the directional connecting shaft pin (189), an optimized enzyme box (1891) is installed on the side end of the connecting frame (1890), a motion controller (1897) is fastened to the side wall surface of the optimized enzyme box (1891), an electric control push rod (1898) is installed on the side end of the motion controller (1897), and the A second cobalt magnet is installed on the top of the electric control push rod (1898), the first cobalt magnet (1899) and the second cobalt magnet are magnetically connected, an axial rotating column is connected to the bottom of the axial end of the directional turntable (187), a feed disc (1893) is installed on the bottom circumference of the axial rotating column, the side end of the feed disc (1893) is connected to a flexible telescopic axial tube (1892), and the side end of the flexible telescopic axial tube (1892) is connected to the surface of the optimized enzyme box (1891). 2. The bio-enzyme catalytic chemical reaction tank device according to claim 1 is characterized in that: a contact chute (1894) is provided on the peripheral surface of the top wall of the feed disc (1893), four groups of pressurized feeding ends (1801) are equidistantly installed on the surface of the feed disc (1893), and contact springs (1895) are connected to the sides of the four groups of pressurized feeding ends (1801), and the contact springs (1895) are fitted inside the contact chute (1894), and a contact telescopic contact rod (1802) is fastened to the bottom side of the directional turntable (187), and the contact telescopic contact rod (1802) is linearly installed on the top of the contact chute (1894). 3. The bio-enzyme catalytic chemical reaction tank device according to claim 1 is characterized in that: a microprocessor controller (6) is installed on the side wall surface of the optimized enzyme delivery channel (4), a feedback circuit frame (7) is installed on the top of the optimized enzyme delivery channel (4), a micro pump (8) is connected to the side end of the feedback circuit frame (7), an activity sensor (9) is installed on the bottom side end of the micro pump (8), and a sampling tube (11) is connected to the bottom of the micro pump (8). 4. The bio-enzyme catalytic chemical reaction tank device according to claim 1 is characterized in that: the other side end of the reaction tank body (1) is connected to a feed control valve end (10), the bottom surface of the reaction tank body (1) is connected to a liquid outlet control valve end (15), the side end of the liquid outlet control valve end (15) is connected to the bottom end of a sampling tube (11), the other side surface of the bottom of the reaction tank body (1) is connected to a waste liquid treatment valve end (12), and the other side surface of the top of the reaction tank body (1) is symmetrically connected to a first liquid control valve end (13) and a second liquid control valve end. 5. The bio-enzyme catalytic chemical reaction tank device according to claim 1 is characterized in that: a planetary control gear set (21) is installed on the top of the reaction tank body (1), and a control motor (16) is connected to the top of the axial end of the planetary control gear set (21), and the axial ends of the three sets of planetary gears inside the planetary control gear set (21) are fastened to an upper turntable through connecting columns, and a protective cover plate (14) is installed on the top of the upper turntable. 6. The bio-enzyme catalytic chemical reaction tank device according to claim 5 is characterized in that: the circumferential side of the upper turntable is rotatably connected to a track, the track is installed on the top of the reaction tank body (1), the protective cover plate (14) is installed on the top of the reaction tank body (1), the bottom axial end of the upper turntable is connected to a central column (23), the bottom circumferential side of the upper turntable is connected to a stirring rod (22), and the bottom circumferential sleeve of the central column (23) is equipped with a detector (24). 7. The bio-enzyme catalytic chemical reaction tank device according to claim 1 is characterized in that: a gear drive group (25) is installed at the bottom of the reaction tank body (1), a control and adjustment motor (17) is installed at the shaft center end of the gear on one side of the gear drive group (25), and a bottom shaft rail (19) is connected to the top shaft center end of the gear on the other side of the gear drive group (25). 8. The bio-enzyme catalytic chemical reaction tank device according to claim 7 is characterized in that: the bottom shaft rail (19) is installed at the bottom end of the interior of the reaction tank body (1), and the top of the bottom shaft rail (19) is rotatably connected to a side adjustment reaction rod (20). 9. The bio-enzyme catalytic chemical reaction tank device according to claim 8 is characterized in that: the outer peripheral casing of the reaction tank body (1) is provided with a heat-insulating protective shell (3), the inner wall surface of the heat-insulating protective shell (3) is provided with a graphene conductive layer (28), and the outer wall surface of the side adjustment reaction rod (20) is installed with a waterproof electric telescopic rod (26). 10. The bio-enzyme catalytic chemical reaction tank device according to claim 9 is characterized in that: a temperature-controlled heating conductive block (27) is connected to the side end of the waterproof electric telescopic rod (26), the temperature-controlled heating conductive block (27) is in contact with the graphene conductive layer (28), and a support leg frame (2) is sleeved and installed on the bottom circumference of the reaction tank body (1).