CN117205863A - Filterable microwave reactor for developing anti-tumor drugs - Google Patents
Filterable microwave reactor for developing anti-tumor drugs Download PDFInfo
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- CN117205863A CN117205863A CN202311405365.8A CN202311405365A CN117205863A CN 117205863 A CN117205863 A CN 117205863A CN 202311405365 A CN202311405365 A CN 202311405365A CN 117205863 A CN117205863 A CN 117205863A
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Abstract
The invention discloses a filterable microwave reactor for developing anti-tumor drugs and a filtering method, comprising a microwave reaction shell and a driving mechanism; microwave reaction shell: the bottom wall of the anti-tumor drug research and development filter type microwave reactor and the filtering method are characterized in that the bottom wall of the anti-tumor drug research and development filter type microwave reactor is connected with a rotating shaft through a bearing, the upper end of the rotating shaft is provided with a rotating seat, the upper surface of the rotating seat is provided with clamping seats which are uniformly distributed, a rotating piece is clamped between the clamping seats, the upper surface of the clamping seat is rotatably connected with a rotating piece through the bearing, the upper side of the rotating piece is provided with a limiting seat through a telescopic column, the anti-tumor drug storage position is fixed through the meshing of an elastic element and a gear and is enabled to be alternately rotated and mixed in the forward and reverse directions, the anti-tumor drug research and development reaction rate is further accelerated, and meanwhile, the device drives air circulation through air pressure difference so as to perform activated carbon adsorption and filtration on harmful substances in chemical gas inside the device, so that the filtering part is convenient to detach and replace.
Description
Technical Field
The invention relates to the technical field of microwave reactors, in particular to a filterable microwave reactor for developing anti-tumor drugs.
Background
Along with development progress, the tumor treatment means are increased continuously, the overall curative effect is increased gradually, the chemical reaction rate in the development process of the tumor medicament is accelerated by means of a microwave reactor, the development process is improved, the microwave assisted reaction technology has been widely focused by scientists, some microwave reaction equipment is sold in the market, microwaves are combined with chemistry to form microwave chemical reaction, compared with the conventional reaction technology, the process flow is simple, the treatment time is short, gas products appear in the development process of the tumor medicament, therefore, the gas needs to be filtered to avoid environmental pollution caused by part of the gas, when the part of the filtered microwave reactor is used, the anti-tumor medicament is firstly put into a beaker, then the beaker is put into a storage rack, then the storage rack is put into a storage rack, then a door body is closed, a microwave element is started through a control unit to perform microwave heating on the preparation of the anti-tumor medicament, the development process of the anti-tumor medicament is accelerated, the generated gas in the device is input into external water through a gas guide pipe to filter harmful substances, the filtered water contains harmful substances, the harmful substances in the water after the device is required to be filtered, the anti-tumor medicament can be discharged again after the device is required to be filtered, and the anti-tumor medicament can not be processed in the development process through the storage rack, and the reaction space is not kept still in the development process, and the anti-tumor medicament is placed in the development process at the reaction stage.
Disclosure of Invention
The invention aims to overcome the existing defects, and provides the filterable microwave reactor for developing the anti-tumor drugs, which is characterized in that the elastic element is meshed with the gear to fix the storage position of the anti-tumor drugs and enable the storage position to alternately rotate and mix in the forward and reverse directions, so that the reaction rate of developing the anti-tumor drugs is accelerated, and meanwhile, the device utilizes the air pressure difference to drive the air circulation to perform activated carbon adsorption filtration on harmful substances in chemical gas inside the device, so that the filterable microwave reactor is convenient to use, and the filtration part is convenient to detach and replace, so that the problems in the background art can be effectively solved.
In order to achieve the above purpose, the present invention provides the following technical solutions: a filterable microwave reactor for developing antitumor drug and a filtering method thereof comprise a microwave reaction shell and a driving mechanism;
microwave reaction shell: the bottom wall of the microwave reactor is rotationally connected with a rotating shaft through a bearing, the upper end of the rotating shaft is provided with a rotating seat, the upper surface of the rotating seat is provided with clamping seats which are uniformly distributed, a storage seat is clamped between the clamping seats, the upper surface of the storage seat is rotationally connected with a rotating sheet through a bearing, the upper side of the rotating sheet is provided with a limiting seat through a telescopic column I, the bottom of a microwave reaction shell is provided with an inner cavity, and the bottom of the inner cavity is provided with a magnetron;
a driving mechanism: the rotary seat is arranged between the rotary seat and the inner cavity;
wherein: the device is fixed with the anti-tumor drug storage position through the meshing of the elastic element and the gear and enables the anti-tumor drug storage position to be alternately rotated and mixed in the forward and reverse directions, so that the anti-tumor drug research and development reaction rate is accelerated, and meanwhile, the device drives air circulation by utilizing air pressure difference to perform activated carbon adsorption filtration on harmful substances in chemical gas inside the device, so that the device is convenient to use, and the filtration part is convenient to detach, replace and operate.
Further, actuating mechanism includes outer ring gear, drive shaft, gear and motor, the outer ring gear sets up in the outside of roating seat, and the diapire of microwave reaction shell is connected with the drive shaft through the bearing rotation, and the upper end of drive shaft is equipped with the gear, and the gear is connected with outer ring gear meshing, and the top of inner chamber is equipped with the motor, and the input of motor is connected with the output electricity of singlechip, and the output shaft of motor and the lower extreme fixed connection of drive shaft make roating seat forward and reverse alternate rotation through the control unit.
Further, a first spring is arranged between the rotating piece and the limiting seat, the first spring is movably sleeved with the outer end of the first telescopic column, and a beaker for storing the anti-tumor drug on the opposite seat is vertically elastically limited.
Further, the spout of horizontal symmetric distribution has been seted up to the upper surface of roating seat, and the inside of spout all sliding connection has the removal seat, and one side that removes the seat and be close to the roating seat center all is pegged graft through inserting the post with put the jack on the thing seat, and the inside of spout all is through flexible post two and spring two and adjacent removal seat fixed connection, and spring two all cup joints with the outer activity of adjacent flexible post two, and vertical grafting is spacing to the thing seat of opposition, and later stage dismantles conveniently.
Furthermore, the left end of the front side of the microwave reaction shell is hinged with a closed door through evenly distributed hinges, and an observation window is arranged in a rectangular groove of the closed door, so that the observation of the microwave reaction process of the antitumor drug is facilitated.
Further, the left wall of the microwave reaction shell is provided with an air outlet pipe in a penetrating mode, the rear wall of the microwave reaction shell is provided with an air inlet pipe in a penetrating mode, and the rear end of the air inlet pipe and the left end of the air outlet pipe are provided with filter screens, so that the inside of the device is circulated with external air.
Further, the middle parts of the air inlet pipe and the air outlet pipe are all connected with electromagnetic valves in series, the right end of the air outlet pipe is communicated with a micro fan, the input ends of the electromagnetic valves and the micro fan are all electrically connected with the output end of the singlechip, the opening and the closing of the air inlet pipe and the air outlet pipe are controlled, and the air inside the device is driven to circulate through negative pressure difference.
Further, the outside right-hand member sliding connection of outlet duct has the cartridge filter, and the inside of cartridge filter is equipped with evenly distributed's active carbon adsorption layer, and evenly distributed's direction draw-in groove has been seted up in the left side of cartridge filter, and the outside of outlet duct is equipped with evenly distributed's card post, and the card post all with adjacent direction draw-in groove joint, the right side of outlet duct is equipped with the sealing ring, carries out multistage active carbon adsorption filtration to the chemical gas that produces in the anti-tumor drug research and development microwave reaction.
Further, the left wall of microwave reaction shell is equipped with the clamping ring through evenly distributed's flexible post III and spring III, and the spring III all cup joints with the outer activity of adjacent flexible post III, and the clamping ring contacts with the left side of cartridge filter, carries out horizontal extrusion spacing to the cartridge filter.
An anti-tumor drug research and development filtering method comprises the following steps:
s1) ventilation phase: the singlechip opens the electromagnetic valve to enable the air inlet pipe and the air outlet pipe to circulate with the outside air;
s2) boost filtration stage: the singlechip starts a micro fan, the micro fan operates to enable external gas to enter the microwave reaction shell after impurity filtration through the filter screen by the air inlet pipe through air pressure difference, chemical reaction gas generated by anti-tumor drug research and development in the gas carrying device passes through the filter cartridge together, the multistage activated carbon adsorption layer in the filter cartridge adsorbs harmful components in the chemical gas step by step, and the filtered gas is discharged through the air outlet pipe;
s3) a reset stage: the singlechip closes the micro fan and the electromagnetic valve, so that the air inlet pipe and the air outlet pipe of the device are closed, and preparation is made for filtering chemical gas generated in the next anti-tumor drug research and development process.
Compared with the prior art, the invention has the beneficial effects that: the filterable microwave reactor for developing antitumor medicine and the filtering method have the following advantages:
1. the reaction beaker for placing the anti-tumor drug is placed in the clamping groove of the placement seat, the limiting seat is pulled to enable the limiting seat to vertically move upwards to the upper end of the beaker, the telescopic end of the telescopic column I and the spring I stretch, then the annular clamping groove in the telescopic column I rotates to enable the limiting seat to be aligned with the bayonet at the upper end of the beaker, then the force applied to the limiting seat is released, the limiting seat vertically moves downwards through the stretching elastic force of the spring I so as to clamp the outer side of the radial opening at the upper end of the beaker, the beaker for placing the anti-tumor drug is fixed, then the singlechip starts a motor, an output shaft of the motor drives a driving shaft to rotate, the driving shaft drives a gear to rotate, the gear drives an outer gear ring to indirectly drive the beaker to rotate through the rotating seat through meshing connection, and the output shaft of the singlechip controls to enable the positive and negative rotation of the motor to enable the anti-tumor drug in the beaker to alternately rotate forwards and backwards, the anti-tumor drug preparation speed is accelerated, the anti-tumor drug research and development is fixed and the anti-tumor drug storage position through the elastic element and the gear to alternately rotate and mix, and the anti-tumor drug research and development reaction speed is accelerated.
2. After the preparation of the antitumor drug is finished, the electromagnetic valve is controlled by the singlechip to enable the air inlet pipe and the air outlet pipe to be communicated with the outside, then the singlechip is used for starting the micro fan, the micro fan operates to generate negative pressure, so that outside gas enters the device through the air inlet pipe and carries compound gas generated by the preparation of the antitumor drug in the device into the filter cylinder, harmful substances in chemical gas generated by the preparation of the antitumor drug are adsorbed through the active carbon adsorption layer in the filter cylinder and are discharged through the air outlet pipe, thereby the chemical gas in the device is filtered, the chemical gas in the device is prevented from diffusing to the outside polluted environment, and the filterable microwave reactor for research and development of the antitumor drug drives air circulation by utilizing air pressure difference to perform active carbon adsorption and filtration on the harmful substances in the chemical gas in the device.
3. After the cartridge filter is used for a long time, hold the cartridge filter and make the direction draw-in groove move a certain distance back reverse rotation along the draw-in column left side and withdraw, thereby dismantle the cartridge filter and change, cartridge filter installation in-process, make draw-in column and direction draw-in groove joint through the same principle, make out the trachea and vertically extrude the cartridge filter through the compression elasticity of spring three, thereby change and dismantle the cartridge filter, convenient operation can seal the gap between outlet duct and the cartridge filter through the sealing ring, this anti-tumor drug research and development is with filterable microwave reactor, change convenient operation is dismantled at the filtration position.
Drawings
FIG. 1 is a schematic diagram of the structure of the present invention;
FIG. 2 is a schematic diagram of the overall structure of the present invention;
FIG. 3 is a schematic view of the rear side structure of the present invention;
FIG. 4 is an enlarged schematic view of the structure of the present invention at A;
fig. 5 is an enlarged schematic view of the structure of the present invention at B.
In the figure: 1 a microwave reaction shell, 2 a closed door, 3 an observation window, 4 a singlechip, 5 a magnetron, 6 a rotary seat, 7 a driving mechanism, 71 an outer toothed ring, 72 a driving shaft, 73 gears, 74 a motor, 8 a clamping seat, 9 a storage seat, 10 a rotary sheet, 11 a telescopic column I, 12 a spring I, 13 a limiting seat, 14 a telescopic column II, 15 a spring II, 16 a moving seat, 17 a plug column, 18 an air outlet pipe, 19 an air inlet pipe, 20 an electromagnetic valve, 21 a filter screen, 22 a mini fan, 23 a filter cartridge, 24 an active carbon adsorption layer, 25 a clamping column, 26 a guide clamping groove, 27 a telescopic column III, 28 a spring III, 29 a compression ring and 30 a sealing ring.
Detailed Description
The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.
Referring to fig. 1-5, the present embodiment provides a technical solution: a filterable microwave reactor for developing anti-tumor drugs comprises a microwave reaction shell 1 and a driving mechanism 7;
microwave reaction shell 1: the bottom wall of the microwave reaction shell is rotatably connected with a rotating shaft through a bearing, the upper end of the rotating shaft is provided with a rotating seat 6, the upper surface of the rotating seat 6 is provided with evenly distributed clamping seats 8, a storage seat 9 is clamped between the clamping seats 8, the upper surface of the storage seat 9 is rotatably connected with a rotating plate 10 through the bearing, the upper side of the rotating plate 10 is provided with a limiting seat 13 through a telescopic column I11, the bottom of the microwave reaction shell 1 is provided with an inner cavity, the bottom of the inner cavity is provided with a magnetron 5, the left end of the front side of the microwave reaction shell 1 is hinged with a closing door 2 through evenly distributed hinges, an observation window 3 is arranged in a rectangular groove of the closing door 2, the left wall of the microwave reaction shell 1 is penetrated and provided with an air outlet pipe 18, the rear wall of the microwave reaction shell 1 is penetrated and provided with an air inlet pipe 19, the rear end of the air inlet pipe 19 and the left end of the air outlet pipe 18 are provided with a filter screen 21, the middle parts of the air inlet pipe 19 and the air outlet pipe 18 are connected with an electromagnetic valve 20 in series, the right end of the air outlet pipe 18 is communicated with a mini fan 22, the input ends of the electromagnetic valve 20 and the micro fan 22 are electrically connected with the output end of the single chip microcomputer 4, the right end of the outer side of the air outlet pipe 18 is slidably connected with a filter cylinder 23, an active carbon adsorption layer 24 which is uniformly distributed is arranged in the filter cylinder 23, a guide clamping groove 26 which is uniformly distributed is formed in the left side of the filter cylinder 23, a clamping column 25 which is uniformly distributed is arranged on the outer side of the air outlet pipe 18, the clamping columns 25 are clamped with the adjacent guide clamping groove 26, a sealing ring 30 is arranged on the right side of the air outlet pipe 18, a compression ring 29 is arranged on the left wall of the microwave reaction shell 1 through a telescopic column III 27 and a spring III 28 which are uniformly distributed, the spring III 27 is movably sleeved with the outer end of the adjacent telescopic column III 26, the compression ring 9 is contacted with the left side of the filter cylinder 23, a closing door 2 is closed, a magnetron 5 is started by the single chip microcomputer 4, and electrons in the magnetron 5 are controlled by a mutually perpendicular constant magnetic field and a constant electric field, the electromagnetic valve 20 is controlled by the singlechip 4 to enable the air inlet pipe 19 and the air outlet pipe 18 to be communicated with the outside after the preparation of the antitumor drug, then the singlechip 4 starts the micro-blower 22, the micro-blower 22 operates to generate negative pressure, so that the outside air enters the device through the air inlet pipe 19 and carries the compound gas generated by the preparation of the antitumor drug in the device into the filter cylinder 23, the harmful substances in the chemical gas generated by the preparation of the antitumor drug are adsorbed through the active carbon adsorption layer 24 in the filter cylinder 23 and are discharged through the air outlet pipe 18, the chemical gas in the device is filtered, the chemical gas in the device is prevented from being diffused to the outside polluted environment, the filter screen 21 can filter impurities in the gas entering and exiting the device, the filter cartridge 23 is held by a hand after long-time use, the filter cartridge 23 is held by the hand to enable the guide clamping groove 26 to move left a certain distance along the clamping column 25 and then reversely rotate to withdraw, so that the filter cartridge 23 is disassembled and replaced, the clamping column 25 is clamped with the guide clamping groove 26 by the same principle in the installation process of the filter cartridge 23, the air outlet pipe 18 longitudinally extrudes the filter cartridge 23 by the compression elastic force of the spring III 28, so that the filter cartridge 23 is replaced and disassembled, the operation is convenient, the gap between the air outlet pipe 18 and the filter cartridge 23 can be sealed by the sealing ring 30, the observation window 3 is convenient for observing the research and development preparation process of antitumor drugs, the filterable microwave reactor for research and development uses the air pressure difference to drive the air circulation so as to perform the adsorption and filtration of active carbon on harmful substances in the chemical gas inside the device, the use is convenient, and the disassembly and replacement operation of the filtering part are convenient;
driving mechanism 7: the driving mechanism 7 comprises an outer toothed ring 71, a driving shaft 72, a gear 73 and a motor 74, wherein the outer toothed ring 71 is arranged on the outer side of the rotating seat 6, the bottom wall of the microwave reaction shell 1 is rotationally connected with the driving shaft 72 through a bearing, the gear 73 is arranged at the upper end of the driving shaft 72 and is in meshed connection with the outer toothed ring 71, the motor 74 is arranged at the top of the inner cavity, the input end of the motor 74 is electrically connected with the output end of the singlechip 4, the output shaft of the motor 74 is fixedly connected with the lower end of the driving shaft 72, a first spring 12 is arranged between the rotating plate 10 and the limiting seat 13, the first spring 12 is movably sleeved with the outer end of the telescopic column 11, sliding grooves which are transversely and symmetrically distributed are formed in the upper surface of the rotating seat 6, the inner parts of the sliding grooves are all in sliding connection with the movable seat 16, one side of the movable seat 16 close to the center of the rotating seat 6 is in plug-in connection with a jack on the object placing seat 9 through a plug 17, the inside of the chute is fixedly connected with the adjacent movable seat 16 through the telescopic column II 14 and the spring II 15, the spring II 15 is movably sleeved with the outer end of the adjacent telescopic column II 14, a reaction beaker for placing an anti-tumor drug is placed in a clamping groove of the placement seat 9, then the limiting seat 13 is pulled to vertically move upwards to the upper end of the beaker, the telescopic end of the telescopic column I11 and the spring I12 stretch, then the limiting seat 13 is rotated to align an inner annular clamping groove of the limiting seat 13 with a bayonet at the upper end of the beaker, then the force applied to the limiting seat 13 is released, the limiting seat 13 is vertically moved downwards by the stretching elastic force of the spring I12 to clamp the outer side of the upper end of the beaker, so that the beaker for placing the anti-tumor drug is fixed, the motor 74 is started by the singlechip 4, the output shaft of the motor 74 drives the driving shaft 72 to rotate, the driving shaft 72 drives the gear 73 to rotate, the gear 73 is driven by engagement connection to enable the external gear ring 71 to indirectly drive the beaker to rotate through the rotating seat 6, the output shaft of the motor 74 is controlled by the singlechip 4 to alternately rotate forward and reverse, so that anti-tumor medicine in the beaker is alternately rotated and rocked forward and reverse, the preparation speed of the anti-tumor medicine is accelerated, after preparation is finished, the movable seat 16 is shifted to enable the movable seat 16 to slide along the sliding groove to one end far away from the center of the device, the inserting column 17 is moved out of the slot to relieve vertical limit of the opposite seat 9, then the opposite seat 9 is vertically moved upwards to be taken out to be cleaned, and when the opposite seat 9 is installed, the inserting column 17 is inserted into the slot by compression elasticity of the spring II 15, and then the opposite seat 9 is elastically fixed;
wherein: the microwave reactor also comprises a singlechip 4, wherein the singlechip 4 is arranged on the front side of the microwave reaction shell 1, the input end of the singlechip 4 is electrically connected with an external power supply, the output end of the singlechip 4 is electrically connected with the input end of the magnetron 5, and the control of electrical elements is convenient;
an anti-tumor drug research and development filtering method comprises the following steps:
s1) ventilation phase: the singlechip 4 opens the electromagnetic valve 20 to enable the air inlet pipe 19 and the air outlet pipe 18 to circulate with the outside air;
s2) boost filtration stage: the singlechip 4 starts the micro-fan 22, the micro-fan 22 operates to enable external gas to enter the microwave reaction shell 1 after impurity filtration through the filter screen 21 by the air inlet pipe 19, chemical reaction gas generated by the research and development of anti-tumor drugs in the gas carrying device passes through the filter cartridge 23 together, the multi-stage activated carbon adsorption layer 24 in the filter cartridge 23 adsorbs harmful components in the chemical gas step by step, and the filtered gas is discharged through the air outlet pipe 18;
s3) a reset stage: the singlechip 4 closes the micro fan 22 and the electromagnetic valve 20, so that the pipelines of the air inlet pipe 19 and the air outlet pipe 18 of the device are closed, and preparation is made for the chemical gas filtration generated in the next anti-tumor drug research and development process.
The invention provides a filterable microwave reactor for developing anti-tumor drugs and a filtering method, which have the following working principles: placing a reaction beaker for placing an anti-tumor drug into a clamping groove of a placement seat 9, then pulling a limit seat 13 to vertically move upwards to the upper end of the beaker, stretching the telescopic end of a telescopic column I11 and a spring I12, then rotating the limit seat 13 to align an inner annular clamping groove of the limit seat with a bayonet at the upper end of the beaker, then loosening the force applied to the limit seat 13, vertically moving the limit seat 13 downwards by the stretching elastic force of the spring I12 to clamp the outer side of the upper end of the beaker, thereby fixing the beaker for placing the anti-tumor drug, then closing a closing door 2, starting a magnetron 5 by a singlechip 4, interacting with a high-frequency electromagnetic field under the control of a mutually perpendicular constant magnetic field and a constant electric field by electrons in the magnetron 5, converting energy obtained from the constant electric field into microwave energy, thereby generating microwave energy to provide temperature reaction conditions for the antitumor drugs, meanwhile, the singlechip 4 starts the motor 74, the output shaft of the motor 74 drives the driving shaft 72 to rotate, the driving shaft 72 drives the gear 73 to rotate, the gear 73 drives the external tooth ring 71 to indirectly drive the beaker to rotate through the rotating seat 6 through meshing connection, the output shaft of the motor 74 rotates forward and backward alternately through the control of the singlechip 4, thereby enabling the antitumor drugs in the beaker to rotate forward and backward alternately and shake, accelerating the preparation speed of the antitumor drugs, after the preparation of the antitumor drugs is finished, the singlechip 4 controls the electromagnetic valve 20 to enable the air inlet pipe 19 and the air outlet pipe 18 to be communicated with the outside, then the singlechip 4 starts the micro fan 22, the micro fan 22 operates to generate negative pressure, so that external gas enters the device through the air inlet pipe 19 and carries compound gas generated by the preparation of the antitumor drugs in the device into the filter cylinder 23, the active carbon adsorption layer 24 in the filter cartridge 23 is used for adsorbing harmful substances in chemical gas generated by antitumor drug preparation and exhausting the harmful substances through the air outlet pipe 18, so that the chemical gas in the device is filtered, the chemical gas in the device is prevented from being diffused to the external polluted environment, the filter screen 21 can filter impurities in the gas entering and exiting the device, after the filter cartridge 23 is used for a long time, the filter cartridge 23 is held by a hand, the guide clamping groove 26 is reversely rotated and withdrawn after a certain distance is left moved along the clamping column 25, so that the filter cartridge 23 is detached and replaced, the clamping column 25 is clamped with the guide clamping groove 26 through the same principle in the filter cartridge 23 installation process, the air outlet pipe 18 is longitudinally extruded through the compression elasticity of the spring III 28, so that the filter cartridge 23 is replaced and detached, the operation is convenient, the sealing ring 30 can seal a gap between the air outlet pipe 18 and the filter cartridge 23, the movable seat 16 is stirred along the sliding groove to one end far away from the center of the device, the vertical limit of the opposite object seat 9 is released when the inserting column 17 is moved out of the slot, the opposite object seat 9 is then moved upwards and removed for cleaning, the opposite object seat 9 is removed, the opposite object seat 9 is installed, the elastic force 15 is used for fixing the opposite object seat 9, and the tumor is convenient to observe and research and development process through the elastic window 17, and research and development process.
It should be noted that the singlechip 4 disclosed in the above embodiment may be an MSP430, the magnetron 5 may be a 2M210-M1 water-cooled magnetron, the motor 74 may be 130SZ01, the solenoid valve 20 may be ZQDF-3Y-40, the micro fan 22 may be a micro fan 22, and the singlechip 4 controls the magnetron 5, the motor 74, the solenoid valve 20 and the micro fan 22 to operate by methods commonly used in the prior art.
The foregoing description is only illustrative of the present invention and is not intended to limit the scope of the invention, and all equivalent structures or equivalent processes or direct or indirect application in other related technical fields are included in the scope of the present invention.
Claims (10)
1. A filterable microwave reactor for developing anti-tumor drugs is characterized in that: comprises a microwave reaction shell (1) and a driving mechanism (7);
microwave reaction shell (1): the bottom wall of the microwave oven is rotationally connected with a rotating shaft through a bearing, the upper end of the rotating shaft is provided with rotating seats (6), the upper surfaces of the rotating seats (6) are provided with clamping seats (8) which are uniformly distributed, object placing seats (9) are clamped between the clamping seats (8), the upper surfaces of the object placing seats (9) are rotationally connected with rotating sheets (10) through the bearing, the upper sides of the rotating sheets (10) are provided with limiting seats (13) through telescopic columns I (11), the bottom of a microwave reaction shell (1) is provided with an inner cavity, and the bottom of the inner cavity is provided with a magnetron (5);
drive mechanism (7): the rotary seat is arranged between the rotary seat (6) and the inner cavity;
wherein: the microwave reactor further comprises a singlechip (4), wherein the singlechip (4) is arranged on the front side of the microwave reaction shell (1), the input end of the singlechip (4) is electrically connected with an external power supply, and the output end of the singlechip (4) is electrically connected with the input end of the magnetron (5).
2. The filterable microwave reactor for developing an antitumor drug according to claim 1, wherein: the driving mechanism (7) comprises an outer toothed ring (71), a driving shaft (72), a gear (73) and a motor (74), wherein the outer toothed ring (71) is arranged on the outer side of the rotating seat (6), the bottom wall of the microwave reaction shell (1) is rotationally connected with the driving shaft (72) through a bearing, the gear (73) is arranged at the upper end of the driving shaft (72), the gear (73) is meshed with the outer toothed ring (71) and connected, the motor (74) is arranged at the top of the inner cavity, the input end of the motor (74) is electrically connected with the output end of the single chip microcomputer (4), and the output shaft of the motor (74) is fixedly connected with the lower end of the driving shaft (72).
3. The filterable microwave reactor for developing an antitumor drug according to claim 1, wherein: a first spring (12) is arranged between the rotary piece (10) and the limiting seat (13), and the first spring (12) is movably sleeved with the outer end of the first telescopic column (11).
4. The filterable microwave reactor for developing an antitumor drug according to claim 1, wherein: the sliding groove is formed in the upper surface of the rotating seat (6), the sliding seat (16) is slidably connected in the sliding groove, one side, close to the center of the rotating seat (6), of the moving seat (16) is inserted into a jack on the object placing seat (9) through an inserting column (17), the sliding groove is fixedly connected with the adjacent moving seat (16) through a second telescopic column (14) and a second spring (15), and the second spring (15) is movably sleeved with the outer end of the second adjacent telescopic column (14).
5. The filterable microwave reactor for developing an antitumor drug according to claim 1, wherein: the left end of the front side of the microwave reaction shell (1) is hinged with a closed door (2) through evenly distributed hinges, and an observation window (3) is arranged in a rectangular groove of the closed door (2).
6. The filterable microwave reactor for developing an antitumor drug according to claim 1, wherein: the left wall of microwave reaction shell (1) runs through and is equipped with outlet duct (18), and the back wall of microwave reaction shell (1) runs through and is equipped with intake pipe (19), and the rear end of intake pipe (19) and the left end of outlet duct (18) all are equipped with filter screen (21).
7. The filterable microwave reactor for developing an antitumor drug according to claim 6, wherein: the middle parts of the air inlet pipe (19) and the air outlet pipe (18) are respectively connected with an electromagnetic valve (20) in series, the right end of the air outlet pipe (18) is communicated with a micro fan (22), and the input ends of the electromagnetic valves (20) and the micro fan (22) are respectively electrically connected with the output end of the single chip microcomputer (4).
8. The filterable microwave reactor for developing an antitumor drug according to claim 6, wherein: the outside right-hand member sliding connection of outlet duct (18) has cartridge filter (23), and the inside of cartridge filter (23) is equipped with evenly distributed's active carbon adsorbed layer (24), and evenly distributed's guide draw-in groove (26) have been seted up in the left side of cartridge filter (23), and the outside of outlet duct (18) is equipped with evenly distributed's card post (25), card post (25) all with adjacent guide draw-in groove (26) joint, the right side of outlet duct (18) is equipped with sealing ring (30).
9. The filterable microwave reactor for developing an antitumor drug according to claim 8, wherein: the left wall of the microwave reaction shell (1) is provided with a compression ring (29) through a telescopic column III (27) and a spring III (28) which are uniformly distributed, the spring III (27) is movably sleeved with the outer end of an adjacent telescopic column III (26), and the compression ring (9) is in contact with the left side of the filter cartridge (23).
10. An anti-tumor drug research and development filtering method is characterized in that: a filterable microwave reactor for the development of an antitumor drug using any one of claims 1 to 9, comprising the steps of:
s1) ventilation phase: the singlechip (4) opens the electromagnetic valve (20) to enable the air inlet pipe (19) and the air outlet pipe (18) to circulate with the outside air;
s2) boost filtration stage: the singlechip (4) starts the micro fan (22), the micro fan (22) operates to enable external gas to enter the microwave reaction shell (1) after impurity filtration through the filter screen (21) through the air inlet pipe (19), chemical reaction gas generated by research and development of anti-tumor drugs in the gas carrying device passes through the filter cartridge (23) together, the multistage activated carbon adsorption layer (24) in the filter cartridge (23) adsorbs harmful components in the chemical gas step by step, and the filtered gas is discharged through the air outlet pipe (18);
s3) a reset stage: the micro fan (22) and the electromagnetic valve (20) are closed by the singlechip (4), so that the pipelines of the air inlet pipe (19) and the air outlet pipe (18) of the device are closed, and preparation is made for filtering chemical gas generated in the next anti-tumor drug research and development process.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202311405365.8A CN117205863A (en) | 2023-10-27 | 2023-10-27 | Filterable microwave reactor for developing anti-tumor drugs |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202311405365.8A CN117205863A (en) | 2023-10-27 | 2023-10-27 | Filterable microwave reactor for developing anti-tumor drugs |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CN117205863A true CN117205863A (en) | 2023-12-12 |
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ID=89049439
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| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CN202311405365.8A Withdrawn CN117205863A (en) | 2023-10-27 | 2023-10-27 | Filterable microwave reactor for developing anti-tumor drugs |
Country Status (1)
| Country | Link |
|---|---|
| CN (1) | CN117205863A (en) |
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2023
- 2023-10-27 CN CN202311405365.8A patent/CN117205863A/en not_active Withdrawn
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Application publication date: 20231212 |