CN112125274A - Nanometer reagent recovery unit - Google Patents

Abstract

The invention discloses a nanometer reagent recovery device, which comprises a recovery machine body, wherein a rotating cavity is arranged in the recovery machine body, the left side of the rotating cavity is communicated with a feed inlet with a left opening, a bearing rotary disc which is rotatably connected to the lower wall of the rotating cavity is arranged in the rotating cavity, a storage bottle is arranged on the upper end surface of the bearing rotary disc, a storage cavity is arranged in the storage bottle, a bottleneck cavity with an upward opening is communicated in the storage cavity, the axle center of the lower end surface of the bearing rotary disc is fixedly connected with a driven rotating shaft, a trigger cavity which is positioned on the lower side of the rotating cavity is arranged in the recovery machine body, a trigger device is arranged on the lower side of the bearing rotary disc, when the storage bottle is placed at the center of the upper end surface of the bearing rotary disc, the device can be automatically started through the trigger device, the invention firstly slowly, make the relative storage bottle antiport of turning block again, relative motion accelerates, and then blow remaining nanometer reagent to the bottle in downside and accumulate, take it out again and retrieve, this device can be through changing the rotational speed simultaneously, increases centrifugal force, makes the wind regime more press close to the inner wall, improves the recovery effect.

Description

Nanometer reagent recovery unit

Technical Field

The invention relates to the technical field of nano reagents, in particular to a nano reagent recovery device.

Background

With the development of science and technology and the progress of human beings, nano materials are more and more popular in people's life, the nano materials refer to materials which have at least one dimension in a three-dimensional space in a nano size or are formed by taking the nano size as a basic unit, people pay more attention to the success of nano technology, but many nano materials are extremely difficult to recycle. The existing nano material is difficult to recover, a large amount of resources are wasted, simultaneously the global environment is polluted, and the human health is harmed.

Disclosure of Invention

In order to solve the problems, the embodiment designs a nanometer reagent recovery device, which comprises a recovery machine body, wherein a rotating cavity is arranged in the recovery machine body, the left side of the rotating cavity is communicated with a feed inlet with a leftward opening, a bearing rotary disc which is rotatably connected with the lower wall of the rotating cavity is arranged in the rotating cavity, the upper end surface of the bearing rotary disc is provided with a storage bottle, a storage cavity is arranged in the storage bottle, the storage cavity is communicated with a bottleneck cavity with an upward opening, the lower end surface axle center of the bearing rotary disc is fixedly connected with a driven rotating shaft, a trigger cavity which is arranged at the lower side of the rotating cavity is arranged in the recovery machine body, the lower side of the bearing rotary disc is provided with a trigger device, when the storage bottle is placed at the center of the upper end surface of the bearing rotary disc, the device can be automatically started by the trigger device, a first belt transmission cavity which is, a power motor is fixedly arranged in the lower wall of the first belt transmission cavity, a transmission device is arranged on the upper side of the power motor, a second belt transmission cavity which is positioned on the upper side of the rotation cavity is arranged in the recycling machine body, the upper wall of the second belt transmission cavity is rotatably connected with a rotation sleeve, a telescopic rotation shaft cavity with a downward opening is communicated in the rotation sleeve, a telescopic rotation shaft capable of sliding up and down is arranged in the telescopic rotation shaft cavity, a telescopic spline groove is communicated on the left side of the telescopic rotation shaft cavity, a telescopic spline is fixedly connected on the outer circular surface of the telescopic rotation shaft, the left end surface of the telescopic spline extends into the telescopic spline groove, a threaded sleeve is fixedly arranged in the lower wall of the second belt transmission cavity, the lower end surface of the threaded sleeve extends into the rotation cavity, and the lower end surface of the telescopic rotation shaft penetrates through the lower end surface of the, the outer disc of flexible pivot with threaded connection between the threaded sleeve inner wall, terminal surface fixedly connected with turning block under the flexible pivot, be equipped with centrifugal chamber in the turning block, be equipped with the centrifugal slide that can the horizontal slip in the centrifugal chamber, the centrifugal slide internal fixation is equipped with fan motor, fan motor left side is equipped with centrifugal device, centrifugal device can with bottleneck chamber with store remaining nano-reagent of intracavity wall and blow to store the chamber lower wall.

But preferably, flexible pivot internal fixation is equipped with the suction pump, the drinking-water pipe that runs through from top to bottom is connected with to power in the suction pump, the terminal surface extends to under the spring board terminal surface downside under the flexible pivot, the drinking-water pipe can be with accumulating the nanometer reagent of storing the chamber lower wall draws and discharges.

Preferably, the triggering device comprises a spring plate which is rotatably connected to the lower end face of the bearing turntable, a trigger spring surrounding the driven rotating shaft is fixedly connected between the lower end surface of the spring plate and the lower wall of the rotating cavity, the lower end surface of the driven rotating shaft extends into the trigger cavity, a driven rotating shaft cavity with a downward opening is arranged in the driven rotating shaft, the upper end surface of the power motor is in power connection with a driving rotating shaft, the upper end surface of the driving rotating shaft extends into the cavity of the driven rotating shaft, the left side of the driven rotating shaft cavity is communicated with a power chute, the outer circular surface of the driving rotating shaft positioned in the driven rotating shaft cavity is fixedly connected with a power spline, the left end surface of the power spline extends into the power chute, the lower end surface of the driven rotating shaft is fixedly connected with first electric shock switches positioned on the left side and the right side of the driving rotating shaft, and a second electric shock switch opposite to the first electric shock switch is fixedly arranged on the lower wall of the trigger cavity.

Preferably, when the first electric shock switch and the second electric shock switch are switched on, the power motor is started.

Preferably, the transmission device comprises a first belt pulley, the axis of the first belt pulley is fixedly sleeved on the outer circular surface of the driving rotating shaft in the first belt transmission cavity, a second belt pulley rotatably connected to the lower wall of the first belt transmission cavity is arranged on the right side of the first belt pulley, a first belt is wound between the second belt pulley and the first belt pulley, a gear transmission cavity is arranged on the upper side of the first belt transmission cavity, the power on the upper end of the second belt pulley extends into the gear transmission cavity, the axis of the second belt pulley is fixedly connected with a first bevel gear, a second bevel gear rotatably connected to the right wall of the gear transmission cavity is meshed with the upper side of the first bevel gear, a third bevel gear rotatably connected to the upper wall of the gear transmission cavity is meshed with the upper side of the second bevel gear, the power on the upper end of the third bevel gear extends into the second belt transmission cavity, and a third belt pulley, which is just opposite to the axis, is fixedly sleeved on the outer circular, the outer disc of the rotating sleeve is fixedly sleeved with a fourth belt pulley with the axis opposite to the axis, and a second belt is wound between the fourth belt pulley and the third belt pulley.

Preferably, the centrifugal device comprises a fan rotating shaft sleeve which is in power connection with the left end surface of the fan motor, a fan rotating shaft cavity is arranged in the fan rotating shaft sleeve, a fan rotating shaft capable of sliding left and right is arranged in the fan rotating shaft cavity, the upper side of the fan rotating shaft cavity is communicated with a fan spline groove, the outer circular surface of the fan rotating shaft is fixedly connected with a fan rotating shaft spline, the upper end surface of the fan rotating shaft spline extends into the fan spline groove, the left side of the centrifugal cavity is communicated with a centrifugal telescopic hole with a left opening, the left end face of the fan rotating shaft penetrates through the centrifugal telescopic hole and extends to the left side of the left end face of the rotating block, the axis of the left end surface of the fan rotating shaft is fixedly connected with a fan rotor, the outer circular surface of the fan rotor is fixedly connected with fan blades in an annular array, and a centrifugal spring surrounding the fan rotating shaft sleeve is fixedly connected between the left end surface of the centrifugal sliding plate and the left wall of the centrifugal cavity.

Preferably, an electromagnet is fixedly arranged in the right wall of the fan rotating shaft cavity, the elasticity of the centrifugal spring is small, and the lower wall of the storage cavity is arc-shaped.

The invention has the beneficial effects that: according to the device, the storage bottle is slowly rotated in a blowing mode on the inner wall of the nano reagent storage bottle, the rotating block is reversely rotated relative to the storage bottle, relative movement is accelerated, the residual nano reagent is blown to the lower side in the bottle and accumulated, and then is extracted out for recovery.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.

The invention is further illustrated with reference to the following figures and examples.

Fig. 1 is a schematic view of the overall structure of the present invention.

Fig. 2 is an enlarged schematic view of a in fig. 1.

Fig. 3 is an enlarged schematic view of B in fig. 1.

Fig. 4 is an enlarged schematic view of C in fig. 1.

Fig. 5 is an enlarged schematic view of D in fig. 4.

Detailed Description

The invention will now be described in detail with reference to fig. 1-5, wherein for ease of description the orientations described hereinafter are now defined as follows: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

The invention relates to a nanometer reagent recovery device, which comprises a recovery machine body 11, wherein a rotating cavity 12 is arranged in the recovery machine body 11, the left side of the rotating cavity 12 is communicated with a feed inlet 67 with a leftward opening, a bearing rotary table 13 which is rotatably connected with the lower wall of the rotating cavity 12 is arranged in the rotating cavity 12, a storage bottle 14 is arranged on the upper end surface of the bearing rotary table 13, a storage cavity 15 is arranged in the storage bottle 14, a bottleneck cavity 16 with an upward opening is communicated in the storage cavity 15, a driven rotary shaft 27 is fixedly connected with the shaft center of the lower end surface of the bearing rotary table 13, a trigger cavity 26 which is positioned on the lower side of the rotating cavity 12 is arranged in the recovery machine body 11, a trigger device 101 is arranged on the lower side of the bearing rotary table 13, when the storage bottle 14 is placed at the center of the upper end surface of the bearing rotary table 13, the device can be automatically started through the trigger device 101, a first belt, the lower wall of the first belt transmission cavity 20 is internally and fixedly provided with a power motor 21, the upper side of the power motor 21 is provided with a transmission device 102, the recovery machine body 11 is internally provided with a second belt transmission cavity 39 positioned at the upper side of the rotation cavity 12, the upper wall of the second belt transmission cavity 39 is rotatably connected with a rotation sleeve 41, the rotation sleeve 41 is internally and communicatively provided with a telescopic rotating shaft cavity 44 with a downward opening, the telescopic rotating shaft cavity 44 is internally provided with a telescopic rotating shaft 45 capable of sliding up and down, the left side of the telescopic rotating shaft cavity 44 is communicatively provided with a telescopic spline groove 46, the outer circular surface of the telescopic rotating shaft 45 is fixedly connected with a telescopic spline 47, the left end surface of the telescopic spline 47 extends into the telescopic spline groove 46, the lower wall of the second belt transmission cavity 39 is internally and fixedly provided with a threaded sleeve 49, the lower end surface of the threaded sleeve 49 extends into the rotation cavity 12, the lower end surface of the telescopic rotating shaft 45 penetrates through the lower end surface, the outer disc of flexible pivot 45 with threaded connection between the threaded sleeve 49 inner wall, terminal surface fixedly connected with turning block 50 under flexible pivot 45, be equipped with centrifugal chamber 51 in the turning block 50, be equipped with the centrifugal slide 52 that can the horizontal slip in the centrifugal chamber 51, centrifugal slide 52 internal fixation is equipped with fan motor 53, fan motor 53 left side is equipped with centrifugal device 103, centrifugal device 103 can with bottleneck chamber 16 with store the remaining nanometer reagent of chamber 15 inner wall and blow to store chamber 15 lower wall.

Beneficially, the telescopic rotating shaft 45 is internally and fixedly provided with a water suction pump 61, the water suction pump 61 is internally and dynamically connected with a water suction pipe 62 which penetrates through the water suction pipe from top to bottom, the lower end face of the spring plate 63 extends to the lower side of the lower end face of the telescopic rotating shaft 45, and the water suction pipe 62 can extract and discharge the nano reagent accumulated on the lower wall of the storage cavity 15.

Beneficially, the triggering device 101 includes a spring plate 63 rotatably connected to the lower end surface of the load-bearing rotary table 13, a triggering spring 17 surrounding the driven rotary shaft 27 is fixedly connected between the lower end surface of the spring plate 63 and the lower wall of the rotary cavity 12, the lower end surface of the driven rotary shaft 27 extends into the triggering cavity 26, a driven rotary shaft cavity 28 with a downward opening is arranged in the driven rotary shaft 27, a driving rotary shaft 22 is dynamically connected to the upper end surface of the power motor 21, the upper end surface of the driving rotary shaft 22 extends into the driven rotary shaft cavity 28, a power sliding slot 29 is communicated with the left side of the driven rotary shaft cavity 28, a power spline 30 is fixedly connected to the outer circumferential surface of the driving rotary shaft 22 in the driven rotary shaft cavity 28, the left end surface of the power spline 30 extends into the power sliding slot 29, first electric shock switches 31 positioned at the left and right sides of the driving rotary shaft 22 are fixedly connected to the lower end surface of, the lower wall of the trigger cavity 26 is fixedly provided with a second shock switch 32 opposite to the first shock switch 31.

Advantageously, when the first contact switch 31 and the second contact switch 32 are switched on, the power motor 21 is started.

Beneficially, the transmission device 102 includes a first belt pulley 23 whose axis is fixedly sleeved on the outer circumferential surface of the driving shaft 22 in the first belt transmission cavity 20, a second belt pulley 24 rotatably connected to the lower wall of the first belt transmission cavity 20 is disposed on the right side of the first belt pulley 23, a first belt 25 is wound between the second belt pulley 24 and the first belt pulley 23, a gear transmission cavity 35 is disposed on the upper side of the first belt transmission cavity 20, a first bevel gear 36 is fixedly connected to the axis and extends to the upper end of the second belt pulley 24, a second bevel gear 37 rotatably connected to the right wall of the gear transmission cavity 35 is engaged on the upper side of the first bevel gear 36, a third bevel gear 38 rotatably connected to the upper wall of the gear transmission cavity 35 is engaged on the upper side of the second bevel gear 37, and the upper end of the third bevel gear 38 extends to the second belt transmission cavity 39, the outer circular surface of the second belt transmission cavity 39 is fixedly sleeved with a third belt pulley 40 with a right axis, the outer circular surface of the rotating sleeve 41 is fixedly sleeved with a fourth belt pulley 42 with a right axis, and a second belt 43 is wound between the fourth belt pulley 42 and the third belt pulley 40.

Beneficially, the centrifugal device 103 includes a fan rotating shaft sleeve 54 dynamically connected to the left end surface of the fan motor 53, a fan rotating shaft cavity 55 is provided in the fan rotating shaft sleeve 54, a fan rotating shaft 56 capable of sliding left and right is provided in the fan rotating shaft cavity 55, a fan spline groove 65 is provided in communication with the upper side of the fan rotating shaft cavity 55, a fan rotating shaft spline 57 is fixedly connected to the outer circumferential surface of the fan rotating shaft 56, the upper end surface of the fan rotating shaft spline 57 extends into the fan spline groove 65, a centrifugal telescopic hole 64 with an opening to the left is provided in communication with the left side of the fan cavity 51, the left end surface of the fan rotating shaft 56 penetrates through the centrifugal telescopic hole 64 and extends to the left side of the left end surface of the rotating block 50, a fan rotor 58 is fixedly connected to the axis of the left end surface of the fan rotating shaft 56, and, a centrifugal spring 60 surrounding the fan rotating shaft sleeve 54 is fixedly connected between the left end surface of the centrifugal sliding plate 52 and the left wall of the centrifugal cavity 51.

Advantageously, an electromagnet 66 is fixedly arranged in the right wall of the fan rotating shaft cavity 55, and the lower wall of the storage cavity 15 is in a circular arc shape.

The following will describe in detail the use steps of a nano-reagent recycling apparatus in conjunction with fig. 1 to 5:

in an initial state, the trigger spring 17 enables the bearing rotary table 13 to be located at an upper limit position in the rotary cavity 12, the first electric shock switch 31 is separated from the second electric shock switch 32, the power spline 30 is located at a lower limit position in the power sliding groove 29, the rotary block 50 is located at an upper limit position, the telescopic spline 47 is located at an upper limit position in the telescopic spline groove 46, the centrifugal spring 60 enables the centrifugal sliding plate 52 to be located at a left limit position in the centrifugal cavity 51, and the electromagnet 66 enables the fan rotary shaft 56 to be located at a left limit position in the fan rotary shaft cavity 55 through magnetic force.

In operation, a user places a storage bottle 14 at the center of the upper end face of the bearing rotary disk 13, the storage bottle 14 drives the bearing rotary disk 13 to slide downward by gravity, so as to make the spring plate 63 slide downward and compress the trigger spring 17, the bearing rotary disk 13 drives the driven rotary shaft 27 to slide downward, the driven rotary shaft 27 makes the driving rotary shaft 22 slide upward in the driven rotary shaft cavity 28, the driving rotary shaft 22 drives the power spline 30 to slide upward in the power chute 29, and the driven rotary shaft 27 drives the first electric shock switch 31 to be connected with the second electric shock switch 32, at this time, the power motor 21 is started, the power motor 21 drives the driving rotary shaft 22 to rotate, the driving rotary shaft 22 drives the first belt pulley 23 to rotate by a spline, the first belt pulley 23 drives the second belt pulley 24 to rotate by the first belt pulley 25, the second belt pulley 24 drives the first bevel gear 36 to rotate by a spline, the first bevel gear 36 drives the second bevel gear 37 to rotate by, the second bevel gear 37 drives the third bevel gear 38 to rotate through gear teeth meshing, at this time, the rotation direction of the third bevel gear 38 is opposite to the rotation direction of the first belt pulley 23, the third bevel gear 38 drives the third belt pulley 40 to rotate through splines, the third belt pulley 40 drives the fourth belt pulley 42 to rotate through the second belt 43, the fourth belt pulley 42 drives the rotating sleeve 41 to rotate through splines, at this time, the rotating sleeve 41 rotates in an opposite direction to the rotation direction of the bearing rotary disk 13, the rotating sleeve 41 drives the telescopic rotary shaft 45 to rotate through the telescopic splines 47, the threaded sleeve 49 drives the telescopic rotary shaft 45 to slide downwards through threads, the telescopic rotary shaft 45 drives the telescopic splines 47 to slide downwards in the telescopic spline grooves 46, the telescopic rotary shaft 45 drives the rotating block 50 to slide downwards and rotate, when the rotating block 50 is located in the bottleneck cavity 16, at this time, the fan motor 53 is started, the fan motor 53 drives the fan rotary shaft 54 to rotate, the fan rotating shaft sleeve 54 drives the fan rotating shaft 56 to rotate through the fan rotating shaft spline 57, the fan rotating shaft 56 drives the fan rotor 58 to rotate through the spline, the fan rotor 58 drives the fan blades 59 to rotate, and further the nano reagent flows downwards through wind power, when the rotating block 50 is positioned in the storage cavity 15, the fan motor 53 is accelerated, the rotating block 50 drives the centrifugal sliding plate 52 to slide towards the side far away from the water pumping pipe 62 through centrifugal force, at the moment, the fan rotating shaft 56 loses the magnetic force constraint of the electromagnet 66, the fan motor 53 drives the fan rotating shaft sleeve 54 to rotate, the fan rotating shaft sleeve 54 drives the fan rotating shaft 56 to rotate through the fan rotating shaft spline 57, the fan rotating shaft 56 drives the fan rotor 58 to rotate through the spline, the fan rotor 58 drives the fan blades 59 to rotate, and further the nano reagent is completely accumulated on the lower wall of the storage, the water pump 61 pumps the nano reagent out for recycling, so that the nano reagent is prevented from being wasted, at the moment, the power motor 21 is reversed, the rotating sleeve 41 is further reversed, the rotating sleeve 41 drives the telescopic rotating shaft 45 to be reversed through the telescopic spline 47, and the threaded sleeve 49 enables the telescopic rotating shaft 45 to ascend through threads.

The invention has the beneficial effects that: according to the device, the storage bottle is slowly rotated in a blowing mode on the inner wall of the nano reagent storage bottle, the rotating block is reversely rotated relative to the storage bottle, relative movement is accelerated, the residual nano reagent is blown to the lower side in the bottle and accumulated, and then is extracted out for recovery.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims (7)

1. The utility model provides a nanometer reagent recovery unit, includes retrieves the fuselage, its characterized in that: a rotating cavity is arranged in the recycling machine body, the left side of the rotating cavity is communicated with a feed inlet with a left opening, a bearing rotary disc which is rotatably connected with the lower wall of the rotating cavity is arranged in the rotating cavity, a storage bottle is arranged on the upper end face of the bearing rotary disc, a storage cavity is arranged in the storage bottle, a bottleneck cavity with an upward opening is communicated in the storage cavity, a driven rotary shaft is fixedly connected with the axle center of the lower end face of the bearing rotary disc, a trigger cavity which is positioned on the lower side of the rotating cavity is arranged in the recycling machine body, a trigger device is arranged on the lower side of the bearing rotary disc, when the storage bottle is placed at the center of the upper end face of the bearing rotary disc, the device can be automatically started through the trigger device, a first belt transmission cavity which is positioned on the lower side of the trigger cavity is arranged in the recycling machine, a second belt transmission cavity is arranged in the recycling machine body and positioned on the upper side of the rotation cavity, the upper wall of the second belt transmission cavity is rotatably connected with a rotation sleeve, a telescopic rotation shaft cavity with a downward opening is communicated in the rotation sleeve, a telescopic rotation shaft capable of sliding up and down is arranged in the telescopic rotation shaft cavity, the left side of the telescopic rotation shaft cavity is communicated with a telescopic spline groove, a telescopic spline is fixedly connected to the outer circular surface of the telescopic rotation shaft, the left end surface of the telescopic spline extends into the telescopic spline groove, a threaded sleeve is fixedly arranged in the lower wall of the second belt transmission cavity, the lower end surface of the threaded sleeve extends into the rotation cavity, the lower end surface of the telescopic rotation shaft penetrates through the lower end surface of the threaded sleeve and extends into the rotation cavity, the outer circular surface of the telescopic rotation shaft is in threaded connection with the inner wall of the threaded sleeve, and a rotation block is, the rotary block is internally provided with a centrifugal cavity, a centrifugal sliding plate capable of sliding left and right is arranged in the centrifugal cavity, a fan motor is fixedly arranged in the centrifugal sliding plate, a centrifugal device is arranged on the left side of the fan motor, and the centrifugal device can blow the bottleneck cavity and the residual nano reagent on the inner wall of the storage cavity to the lower wall of the storage cavity.

2. The nano-reagent recycling apparatus according to claim 1, wherein: the flexible pivot internal fixation is equipped with the suction pump, the suction pipe that runs through from top to bottom is connected with to power in the suction pump, the terminal surface extends to under the spring board terminal surface downside under the flexible pivot, the suction pipe can will be saved the nanometer reagent of storing the chamber lower wall draws and discharges.

3. The nano-reagent recycling apparatus according to claim 2, wherein: the trigger device comprises a spring plate which is rotatably connected with the lower end surface of the feed inlet, a trigger spring which surrounds the driven rotating shaft is fixedly connected between the lower end surface of the spring plate and the lower wall of the rotating cavity, the lower end surface of the driven rotating shaft extends into the trigger cavity, a driven rotating shaft cavity with a downward opening is arranged in the driven rotating shaft, the upper end surface of the power motor is in power connection with a driving rotating shaft, the upper end surface of the driving rotating shaft extends into the cavity of the driven rotating shaft, the left side of the driven rotating shaft cavity is communicated with a power chute, the outer circular surface of the driving rotating shaft positioned in the driven rotating shaft cavity is fixedly connected with a power spline, the left end surface of the power spline extends into the power chute, the lower end surface of the driven rotating shaft is fixedly connected with first electric shock switches positioned on the left side and the right side of the driving rotating shaft, and a second electric shock switch opposite to the first electric shock switch is fixedly arranged on the lower wall of the trigger cavity.

4. A nano-reagent recycling apparatus as set forth in claim 3, wherein: and when the first electric shock switch and the second electric shock switch are switched on, the power motor is started.

5. The nano-reagent recycling apparatus according to claim 4, wherein: the transmission device comprises a first belt pulley, wherein the axis of the first belt pulley is fixedly sleeved on the outer circular surface of the driving rotating shaft in the first belt transmission cavity, the right side of the first belt pulley is provided with a second belt pulley which is rotatably connected with the lower wall of the first belt transmission cavity, a first belt is wound between the second belt pulley and the first belt pulley, the upper side of the first belt transmission cavity is provided with a gear transmission cavity, the upper end power of the second belt pulley extends into the gear transmission cavity, the axis of the second belt pulley is fixedly connected with a first bevel gear, the upper side of the first bevel gear is meshed with a second bevel gear which is rotatably connected with the right wall of the gear transmission cavity, the upper side of the second bevel gear is meshed with a third bevel gear which is rotatably connected with the upper wall of the gear transmission cavity, the upper end power of the third bevel gear extends into the second belt transmission cavity, and a third belt pulley which is opposite to the axis is fixedly sleeved on the, the outer disc of the rotating sleeve is fixedly sleeved with a fourth belt pulley with the axis opposite to the axis, and a second belt is wound between the fourth belt pulley and the third belt pulley.

6. The nano-reagent recycling apparatus according to claim 5, wherein: the centrifugal device comprises a fan rotating shaft sleeve which is connected with the left end surface of the fan motor in a power mode, a fan rotating shaft cavity is arranged in the fan rotating shaft sleeve, a fan rotating shaft capable of sliding left and right is arranged in the fan rotating shaft cavity, a fan spline groove is communicated with the upper side of the fan rotating shaft cavity, the outer circular surface of the fan rotating shaft is fixedly connected with a fan rotating shaft spline, the upper end surface of the fan rotating shaft spline extends into the fan spline groove, the left side of the centrifugal cavity is communicated with a centrifugal telescopic hole with a left opening, the left end face of the fan rotating shaft penetrates through the centrifugal telescopic hole and extends to the left side of the left end face of the rotating block, the axis of the left end surface of the fan rotating shaft is fixedly connected with a fan rotor, the outer circular surface of the fan rotor is fixedly connected with fan blades in an annular array, and a centrifugal spring surrounding the fan rotating shaft sleeve is fixedly connected between the left end surface of the centrifugal sliding plate and the left wall of the centrifugal cavity.

7. The nano-reagent recycling apparatus according to claim 6, wherein: an electromagnet is fixedly arranged in the right wall of the rotating shaft cavity of the fan, the elasticity of the centrifugal spring is small, and the lower wall of the storage cavity is arc-shaped.

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