CN112798344B

CN112798344B - Intelligent collector capable of extracting biological energy health index

Info

Publication number: CN112798344B
Application number: CN202011580215.7A
Authority: CN
Inventors: 吴冰冰
Original assignee: Aobosidi Biotechnology Guangzhou Co ltd
Current assignee: Aobosidi Biotechnology Guangzhou Co ltd
Priority date: 2020-12-28
Filing date: 2020-12-28
Publication date: 2021-09-21
Anticipated expiration: 2040-12-28
Also published as: CN112798344A

Abstract

The invention discloses an intelligent collector capable of extracting biological energy health index, which comprises a collecting box, a collection cavity with a leftward opening is arranged in the collection box, a rotating cavity is communicated with the lower wall of the collection cavity, the rotating cavity is rotatably connected with a thawing box which extends upwards into the collecting cavity, a fan cavity with an upward opening is arranged in the thawing box, the lower wall of the fan cavity is communicated with a communicating cavity with a downward opening, the left side wall and the right side wall of the fan cavity are communicated with symmetrical pull rope cavities in an initial state, the upper side of the pull rope cavity is communicated with a spring cavity, the pull rope cavity is connected with a connecting plate which extends inwards into the fan cavity in a vertical sliding manner, the end face of one side, far away from the pull rope cavity, of the connecting plate is fixedly connected with the placing plate which is connected with the fan cavity in a vertical sliding mode.

Description

Intelligent collector capable of extracting biological energy health index

Technical Field

The invention relates to the field of biological energy health, in particular to an intelligent collector capable of extracting a biological energy health index.

Background

Whether the health of blood always influences the healthy index of biological energy, and the extraction of freezing blood of hiding is comparatively troublesome, needs to unfreeze earlier, thereby it can't gather to need stir and rock the solidification that prevents freezing blood of hiding, and the intelligent collector of some present healthy indexes of biological energy is difficult to play the function of thawing frozen blood of hiding, and be difficult to automatic stretch into the test tube with the pipeline, degree of automation is lower, is difficult to bring the facility for the acquisition process.

Disclosure of Invention

The invention aims to solve the technical problem of providing an intelligent collector capable of extracting a biological energy health index, and solves the problem that the biological energy health index is difficult to collect.

The invention is realized by the following technical scheme.

The invention relates to an intelligent collector capable of extracting a biological energy health index, which comprises a collecting box, wherein a collecting cavity with a left opening is arranged in the collecting box, a rotating cavity is communicated with the lower wall of the collecting cavity and is provided with a rotating cavity, the rotating cavity is rotatably connected with a unfreezing box which extends upwards into the collecting cavity, a fan cavity with an upward opening is arranged in the unfreezing box, a communicating cavity with a downward opening is communicated with the lower wall of the fan cavity, symmetrical pull rope cavities are communicated with the left side wall and the right side wall of the fan cavity in an initial state, a spring cavity is communicated with the upper side of the pull rope cavity, the pull rope cavity is vertically and slidably connected with a connecting plate which extends inwards into the fan cavity, a placing plate which is vertically and slidably connected with the fan cavity is fixedly connected with the end surface of the connecting plate, which is far away from the pull rope cavity, a placing cavity with an upward opening is arranged in the placing plate, and a unfreezing mechanism is arranged in the unfreezing box, a blood test tube is placed in the placing cavity, a test tube cover is tightly clamped at the top end of the blood test tube, a separation screw cavity is communicated with the upper wall of the collecting cavity, a separation screw is connected with the upper wall of the separation screw cavity in a rotating manner, a belt cavity is communicated with the right wall of the separation screw cavity, an active belt wheel cavity is communicated with the right side of the belt cavity, a pushing cavity is communicated with the right wall of the collecting cavity, a flexible tube cavity is communicated with the upper wall of the pushing cavity, the upper end surface of the collecting box is rotationally connected with a driving shaft which penetrates through the active belt wheel cavity and extends downwards into the pushing cavity, a separating mechanism which extends rightwards into the active belt wheel cavity is arranged in the separating screw cavity, a pushing block is connected to the outer circular surface of one side of the driving shaft, which is positioned in the flexible tube cavity, a fixed block is fixedly connected to the left end surface of the pushing block, and a fixed cavity which is communicated up and down is arranged in the fixed block, gather chamber right side wall fixedly connected with and be located the deflector of propelling movement chamber downside, propelling movement chamber lower wall left end fixedly connected with sloping piece, the push rod chamber that link up about being equipped with in the sloping piece, the propelling movement intracavity is equipped with upwards extends to the push mechanism of hose intracavity.

Preferably, the mechanism of unfreezing is including locating the motor that unfreezes that rotates the chamber lower wall, the motor up end power connection that unfreezes runs through the intercommunication chamber and upwards extend to the driving gear axle of fan intracavity, the driving gear axle is located the outer disc fixedly connected with driving gear of one side of fan intracavity, it is connected with to rotate the chamber lower wall and runs through the intercommunication chamber and upwards extend to the fan axle of fan intracavity, the outer disc top fixedly connected with fan of fan axle, the outer disc fixedly connected with of fan axle is located the fan downside and with the driven fan gear of driving gear meshing, fan chamber internal face fixedly connected with the driven ring gear of driving gear meshing.

Preferably, the thawing mechanism further comprises a winding wheel shaft rotatably connected with the front wall and the rear wall of the stay cord cavity, a winding wheel is fixedly connected with the outer circular surface of the winding wheel shaft, a torsion spring is fixedly arranged at the joint of the winding wheel shaft and the winding wheel shaft, a bottom end is wound on the outer circular surface of the winding wheel, the stay cord is fixedly connected with the upper end surface of the connecting plate, a clamping block extending inwards into the fan cavity is connected in a sliding mode in the spring cavity, the clamping block is far away from one side end surface of the fan cavity and a clamping block spring is fixedly connected between one side wall of the fan cavity, the top end of the stay cord is fixedly connected with the lower end surface of the clamping block, and a heating plate is fixedly arranged in the placing plate.

Preferably, the pushing mechanism comprises a driving bevel gear fixedly connected with the bottom end of the outer circular surface of the driving shaft, the bottom end of the right wall of the pushing cavity is rotatably connected with a pushing screw rod, the left and right of the pushing rod cavity are connected with a transverse pushing block in a sliding manner, the transverse pushing block is internally provided with a pushing block inner thread with a right opening, the pushing screw rod extends into the pushing block inner thread and is in threaded connection with the pushing block inner thread, the outer circular surface of the pushing screw rod is fixedly connected with a driven bevel gear which is positioned on the right side of the transverse pushing block and is in meshing transmission with the driving bevel gear, the right wall of the soft tube cavity is communicated with a pushing cavity with a right opening, a soft tube extending leftwards into the soft tube cavity is arranged in the pushing cavity, the soft tube penetrates through the fixed cavity and extends downwards, the bottom end of the soft tube extends leftwards into the collecting cavity and is arranged on the upper end surface of the guide plate, the right side of the collection box is provided with a needle tube.

Preferably, the pushing mechanism further comprises a storage cavity communicated with the top end of the left wall of the flexible pipe cavity, the rear wall of the storage cavity is provided with a storage wheel device, a storage hose is wound and stored on the outer circular surface of the storage wheel device, the left wall of the flexible pipe cavity is communicated with a screw cavity positioned on the lower side of the storage cavity, the left wall of the screw cavity is fixedly provided with an extrusion motor, the right end surface of the extrusion motor is in power connection with an extrusion screw, the outer circular surface of the extrusion screw is in threaded connection with a threaded connecting block in left-right sliding connection with the screw cavity, the right end surface of the threaded connecting block is fixedly connected with an extrusion block, the upper end surface of the threaded connecting block is fixedly connected with a cutting block, the right wall of the flexible pipe cavity is fixedly connected with a cutting edge positioned on the upper side of the extrusion cavity, the left wall of the fixed cavity is communicated with a clamping cavity, the left-right sliding connection of the clamping cavity is connected with an elastic block, and an elastic block spring is fixedly connected between the left end surface of the elastic block and the left wall of the clamping cavity, the left wall of the clamping cavity is fixedly connected with an elastic block electromagnet positioned on the lower side of the elastic block spring, an elastic block magnetic block corresponding to the elastic block electromagnet is fixedly arranged on the left end face of the elastic block, and an induction block is fixedly arranged on the upper end face of the guide plate.

Preferably, the right wall of the collection cavity is fixedly connected with a collection box, and a collection cavity with an upward opening is arranged in the collection box.

The invention has the beneficial effects that: the automatic cover opening device can automatically clamp the placed blood test tube, and then can simultaneously perform hot air thawing and rotation anti-coagulation, so that the frozen blood can be rapidly thawed.

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.

FIG. 1 is a schematic structural diagram of an embodiment of the present invention;

FIG. 2 is an enlarged schematic view of the embodiment of the present invention at A in FIG. 1;

FIG. 3 is an enlarged schematic view of the embodiment of the present invention at B in FIG. 1;

FIG. 4 is an enlarged schematic view of the embodiment of the present invention at C in FIG. 3;

FIG. 5 is an enlarged view of the embodiment of the present invention at D in FIG. 3.

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 intelligent collector capable of extracting the bio-energy health index described in conjunction with fig. 1-5 comprises a collection box 11, a collection chamber 12 with a leftward opening is provided in the collection box 11, a rotation chamber 30 is provided in the lower wall of the collection chamber 12 in a communicating manner, the rotation chamber 30 is rotatably connected to a thawing box 31 extending upward into the collection chamber 12, a fan chamber 39 with an upward opening is provided in the thawing box 31, a communicating chamber 33 with a downward opening is provided in the lower wall of the fan chamber 39 in a communicating manner, symmetrical pull rope chambers 46 are provided in the left and right side walls of the fan chamber 39 in an initial state in a communicating manner, a spring chamber 47 is provided in the upper side of the pull rope chamber 46 in a communicating manner, the pull rope chamber 46 is vertically and slidably connected to a connecting plate 41 extending inward into the fan chamber 39, a placing plate 40 is fixedly connected to the end surface of one side of the connecting plate 41 far away from the pull rope chamber 46 and vertically and slidably connected to the fan chamber 39, the blood collection and thawing device is characterized in that a placing cavity 50 with an upward opening is arranged in the placing plate 40, a thawing mechanism 101 is arranged in the thawing box 31, a blood test tube 20 is arranged in the placing cavity 50, a test tube cover 19 is tightly clamped at the top end of the blood test tube 20, a separating screw cavity 13 is communicated with the upper wall of the collecting cavity 12, a separating screw 15 is rotatably connected to the upper wall of the separating screw cavity 13, a belt cavity 21 is communicated with the right wall of the separating screw cavity 13, an active pulley cavity 24 is communicated with the right side of the belt cavity 21, a pushing cavity 52 is communicated with the right wall of the collecting cavity 12, a hose cavity 57 is communicated with the upper wall of the pushing cavity 52, the upper end face of the collecting box 11 is rotatably connected with a driving shaft 25 which penetrates through the active pulley cavity 24 and downwardly extends to the pushing cavity 52, a separating mechanism 102 which extends to the active pulley cavity 24 rightwards is arranged in the separating screw cavity 13, and a driving shaft 53 is in threaded connection with an outer circular face of the driving shaft 25 which is positioned in the hose cavity 57, the left end face of the pushing block 53 is fixedly connected with a fixing block 55, a fixing cavity 56 which is through from top to bottom is arranged in the fixing block 55, the right wall of the collecting cavity 12 is fixedly connected with a guide plate 28 on the lower side of the pushing cavity 52, the lower wall of the pushing cavity 52 is fixedly connected with an inclined surface block 62, a left pushing rod cavity 63 which is through from top to bottom is arranged in the inclined surface block 62, and a pushing mechanism 103 which extends upwards to the interior of the soft tube cavity 57 is arranged in the pushing cavity 52.

Beneficially, the thawing mechanism 101 includes a thawing motor 29 disposed on the lower wall of the rotating cavity 30, an upper end surface of the thawing motor 29 is in power connection with a driving gear shaft 32 penetrating through the communicating cavity 33 and extending upward into the fan cavity 39, the driving gear shaft 32 is located on an outer circumferential surface of one side of the fan cavity 39 and is fixedly connected with a driving gear 36, the lower wall of the rotating cavity 30 is in rotation connection with a fan shaft 34 penetrating through the communicating cavity 33 and extending upward into the fan cavity 39, the top end of the outer circumferential surface of the fan shaft 34 is fixedly connected with a fan 35, the outer circumferential surface of the fan shaft 34 is fixedly connected with a fan gear 38 located on the lower side of the fan 35 and in meshing transmission with the driving gear 36, and the inner wall surface of the fan cavity 39 is fixedly connected with a gear ring 37 in meshing transmission with the driving gear 36.

Advantageously, the thawing mechanism 101 further comprises a winding wheel shaft 45 rotatably connected to the front and rear walls of the rope cavity 46, a winding wheel 43 is fixedly connected to the outer circumferential surface of the winding wheel shaft 45, a torsion spring 44 is fixedly disposed at the connection position of the winding wheel 43 and the winding wheel shaft 45, a rope 42 with the bottom end fixedly connected to the upper end surface of the connecting plate 41 is wound on the outer circumferential surface of the winding wheel 43, a clamping block 49 extending inwards into the fan cavity 39 is slidably connected to the spring cavity 47 from left to right, a clamping block spring 48 is fixedly connected between the end surface of the clamping block 49 far away from the fan cavity 39 and the side wall of the spring cavity 47 far away from the fan cavity 39, the top end of the rope 42 is fixedly connected to the lower end surface of the clamping block 49, and a heating plate 51 is fixedly disposed in the placing plate 40.

Beneficially, the separation mechanism 102 includes a separation connecting block 16 vertically and slidably connected to the separation screw cavity 13, an internal threaded cavity 17 with an upward opening is provided in the separation connecting block 16, the separation screw 15 extends into the internal threaded cavity 17 and is in threaded connection with the internal threaded cavity 17, a barb block 18 is fixedly connected to a lower end face of the separation connecting block 16, a driven pulley 14 is fixedly connected to a top end of an outer circular face of the separation screw 15, a driving pulley 26 is fixedly connected to an outer circular face of one side of the driving pulley 25 located in the driving pulley cavity 24, a belt 22 penetrating through the belt cavity 21 is wound around outer circular faces of the driving pulley 26 and the driven pulley 14, a push motor 23 is fixedly provided to an upper end face of the collection box 11, and a lower end face of the push motor 23 is in power connection with a top end of the driving pulley 25.

Advantageously, the pushing mechanism 103 comprises a driving bevel gear 58 fixedly connected with the bottom end of the outer circular surface of the driving shaft 25, a pushing screw 60 is rotatably connected with the bottom end of the right wall of the pushing cavity 52, a transverse pushing block 61 is slidably connected with the pushing rod cavity 63 in a left-right direction, a pushing block internal thread 64 with a right opening is arranged in the transverse pushing block 61, the pushing screw 60 extends into the pushing block internal thread 64 and is in threaded connection with the pushing block internal thread 64, a driven bevel gear 59 which is positioned at the right side of the transverse pushing block 61 and is in meshing transmission with the driving bevel gear 58 is fixedly connected with the outer circular surface of the pushing screw 60, a pushing cavity 66 with a right opening is arranged on the right wall of the flexible tube cavity 57 in a communicating manner, a flexible tube 54 extending leftwards into the flexible tube cavity 57 is arranged in the pushing cavity 66, the flexible tube 54 extends through the fixed cavity 56 and downwards, the bottom end of the flexible tube 54 extends leftwards into the collection cavity 12 and is placed on the upper end surface of the guide plate 28, the right side of the collection box 11 is provided with a needle tube 27.

Advantageously, the pushing mechanism 103 further comprises a receiving cavity 68 communicated with the top end of the left wall of the soft tube cavity 57, the rear wall of the receiving cavity 68 is provided with a receiving wheel device 69, the outer circular surface of the receiving wheel device 69 is wound and received with a storage hose 70, the left wall of the soft tube cavity 57 is communicated with a screw cavity 71 positioned at the lower side of the receiving cavity 68, the left wall of the screw cavity 71 is fixedly provided with an extrusion motor 72, the right end surface of the extrusion motor 72 is in power connection with an extrusion screw 73, the outer circular surface of the extrusion screw 73 is in threaded connection with a threaded connection block 74 in left-right sliding connection with the screw cavity 71, the right end surface of the threaded connection block 74 is fixedly connected with an extrusion block 75, the upper end surface of the threaded connection block 74 is fixedly connected with a cutting block 76, the right wall of the soft tube cavity 57 is fixedly connected with a cutting edge 67 positioned at the upper side of the extrusion cavity 66, the left wall of the fixed cavity 56 is communicated with a clamping cavity 78, it has bullet piece 82 to press from both sides tight chamber 78 side-to-side sliding connection, bullet piece 82 left end face with press from both sides fixedly connected with bullet piece spring 81 between the tight chamber 78 left wall, press from both sides tight chamber 78 left wall fixedly connected with and be located bullet piece electro-magnet 79 of bullet piece spring 81 downside, bullet piece 82 left end face fixed be equipped with bullet piece magnetic path 80 corresponding to bullet piece electro-magnet 79, the fixed response piece 65 that is equipped with of deflector 28 upper end face.

Advantageously, a collecting chamber 84 is fixedly connected to the right wall of the collecting chamber 12, and a collecting chamber 85 with an upward opening is arranged in the collecting chamber 84.

In the initial state, the barb block 18 is located at the lower limit position in the separation screw cavity 13, the pulling rope 42 is wound by the torsion spring force of the torsion spring 44, so that the clamping block spring 48 is tightened, the transverse pushing block 61 is located at the right limit position in the pushing cavity 52, and the elastic block 82 is pushed by the pushing force of the elastic block spring 81 to clamp the hose 54.

Place blood test tube 20 and locate the lower wall department of placing chamber 50, barb piece 18 stretches into the test tube lid 19 downside this moment to drive through the dead weight of blood test tube 20 and place board 40 and move down, thereby drive connecting plate 41 and move down through the downward movement who places board 40, thereby drive the take-up reel 43 true through the connection of stay cord 42, thereby tighten torsional spring 44 and through the rotation of take-up reel 43 and through the thrust promotion of pressing from both sides tight piece spring 48 and inwards move thereby press from both sides blood test tube 20 tightly.

The thawing motor 29 is started to drive the driving gear shaft 32 to rotate, the driving gear 36 is driven to rotate by the rotation of the driving gear shaft 32, the driving gear 36 rotates to drive the fan gear 38 and the gear ring 37 to rotate by meshing, the fan shaft 34 is driven to rotate by the rotation of the fan gear 38, the fan 35 is driven to rotate upwards to generate wind power, the heating plate 51 is started to generate heat, the heat is driven to the upper side of the thawing box 31 by the wind power generated by the fan 35 to thaw the blood test tube 20, the thawing box 31 is driven to rotate in the rotating cavity 30 by the rotation of the gear ring 37, the blood test tube 20 is driven to rotate, frozen blood in the blood test tube 20 can be prevented from coagulating, after the thawing, the pushing motor 23 is started to drive the driving shaft 25 to rotate, the driving belt wheel 26 is driven to rotate by the rotation of the driving belt wheel 26, and the driven belt wheel 14 is driven to rotate by the driving belt wheel 26, the separation screw rod 15 is driven to rotate by the rotation of the driven belt wheel 14, the separation connecting block 16 is driven to move upwards by the rotation of the separation screw rod 15 through threaded connection, so that the barb block 18 is driven to move upwards, the test tube cover 19 is pulled upwards by the upward movement of the barb block 18, frozen blood in the blood test tube 20 is not sealed any more, meanwhile, the pushing block 53 is driven to move downwards by the rotation of the driving shaft 25 through threaded connection, the hose 54 is pushed downwards by the downward movement of the pushing block 53, the driving bevel gear 58 is driven to rotate by the rotation of the driving shaft 25, the driven bevel gear 59 is driven to rotate by the rotation of the driving bevel gear 58 through meshing, the transverse pushing block 61 is driven to move leftwards by the rotation of the driven bevel gear 59 and threaded connection, and the downward movement of the hose 54 is guided to slide downwards by the inclination of the left end face of the bevel block 62, and at the same time, the flexible tube 54 is pushed leftwards by the leftward movement of the transverse pushing block 61, so that the flexible tube 54 can be moved to the inner side of the blood test tube 20 through the guiding slide of the guiding plate 28, at this time, the frozen blood in the blood test tube 20 is sucked through the needle tube 27, the needle tube 27 is taken down after the sampling is finished, and the blood test tube 20 is closed again and the device is driven to return to the initial state.

When the hose 54 is replaced, the elastic block electromagnet 79 is started to adsorb the elastic block magnet 80, so that the elastic block spring 81 is tightened and the elastic block 82 is driven to move leftwards to avoid clamping the hose 54, at the moment, the hose 54 loses clamping force to naturally fall downwards and then to fall downwards into the collection cavity 85, the storage wheel device 69 is started to drive the storage hose 70 to naturally move downwards through the rotation of the storage wheel device 69, the storage hose 70 moves downwards to penetrate through the fixed cavity 56 and moves downwards to the upper end face of the guide plate 28, when the sensing block 65 is contacted, the elastic block electromagnet 79 is closed to clamp the storage hose 70, the squeezing motor 72 is started to drive the squeezing screw 73 to rotate, the threaded connecting block 74 is driven to move rightwards through the threaded connection through the rotation of the squeezing screw 73, at the moment, the squeezing block 75 can push the storage hose 70 rightwards, thereby squeezing into the push-out cavity 66, simultaneously cutting the storage hose 70 through the contact of the cutting blade 67 and the cutting block 76, and pushing the storage hose 70 to the outside of the collection box 11 through the continuous pushing of the squeezing block 75, thereby completing the replacement.

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

1. The utility model provides an intelligent collector of biological energy health index can draw, includes the vasculum, its characterized in that: the collecting box is internally provided with a collecting cavity with a leftward opening, the lower wall of the collecting cavity is communicated with a rotating cavity, the rotating cavity is rotatably connected with a thawing box which extends upwards into the collecting cavity, the thawing box is internally provided with a fan cavity with an upward opening, the lower wall of the fan cavity is communicated with a communicating cavity with a downward opening, in an initial state, the left side wall and the right side wall of the fan cavity are communicated with symmetrical pull rope cavities, the upper side of each pull rope cavity is communicated with a spring cavity, the pull rope cavities are vertically and slidably connected with a connecting plate which extends inwards into the fan cavity, one end surface of the connecting plate, which is far away from the pull rope cavities, is fixedly connected with a placing plate which is vertically and slidably connected with the fan cavity, the placing plate is internally provided with a placing cavity with an upward opening, the thawing box is internally provided with a thawing mechanism, a blood test tube, the upper wall of the collection cavity is communicated with a separation screw cavity, the upper wall of the separation screw cavity is rotatably connected with a separation screw, the right wall of the separation screw cavity is communicated with a belt cavity, the right side of the belt cavity is communicated with an active pulley cavity, the right wall of the collection cavity is communicated with a pushing cavity, the upper wall of the pushing cavity is communicated with a soft tube cavity, the upper end surface of the collection box is rotatably connected with a driving shaft which penetrates through the active pulley cavity and extends downwards into the pushing cavity, a separation mechanism which extends rightwards into the active pulley cavity is arranged in the separation screw cavity, the outer circular surface of one side of the driving shaft in the soft tube cavity is in threaded connection with a pushing block, the left end surface of the pushing block is fixedly connected with a fixed block, a vertically through fixed cavity is arranged in the fixed block, the right wall of the collection cavity is fixedly connected with a guide plate which is arranged on the lower side of the pushing cavity, and the left end of the pushing cavity is fixedly connected with a bevel block, the inner side of the inclined plane block is provided with a left push rod cavity and a right push rod cavity which are communicated, and a pushing mechanism which extends upwards to the inner side of the hose cavity is arranged in the pushing cavity.

2. The intelligent collector capable of extracting the bio-energy health index as claimed in claim 1, wherein: unfreezing mechanism is including locating the motor that unfreezes that rotates the chamber lower wall, motor up end power connection that unfreezes runs through the intercommunication chamber just upwards extends to the driving gear axle of fan intracavity, the driving gear axle is located the outer disc fixedly connected with driving gear of one side of fan intracavity, it is connected with to rotate the chamber lower wall and runs through the intercommunication chamber just upwards extends to the fan axle of fan intracavity, the outer disc top fixedly connected with fan of fan axle, the outer disc fixedly connected with of fan axle is located the fan downside and with the driven fan gear of driving gear meshing, fan chamber internal face fixedly connected with the driven ring gear of driving gear meshing.

3. The intelligent collector capable of extracting the bio-energy health index as claimed in claim 1, wherein: the thawing mechanism further comprises a winding wheel shaft which is rotatably connected with the front wall and the rear wall of the stay cord cavity, a winding wheel is fixedly connected with the outer circular surface of the winding wheel shaft, a torsional spring is fixedly arranged at the joint of the winding wheel shaft and the winding wheel shaft, the outer circular surface of the winding wheel is wound with a bottom end and the stay cord which is fixedly connected with the upper end surface of the connecting plate, a spring cavity is connected in a sliding mode and extends inwards to a clamping block in the fan cavity, the clamping block is far away from one side end surface of the fan cavity and a spring cavity is far away from a clamping block spring which is fixedly connected between one side walls of the fan cavity, the top end of the stay cord is fixedly connected with the lower end surface of the clamping block, and a heating plate is fixedly arranged in the placing plate.

4. The intelligent collector capable of extracting the bio-energy health index as claimed in claim 1, wherein: the pushing mechanism comprises a driving bevel gear fixedly connected with the bottom end of the outer circular surface of the driving shaft, the bottom end of the right wall of the pushing cavity is rotatably connected with a pushing screw rod, the left and right of the pushing cavity is connected with a transverse pushing block in a sliding manner, the transverse pushing block is internally provided with a pushing block internal thread with a right opening, the pushing screw rod extends into the pushing block internal thread and is in threaded connection with the pushing block internal thread, the outer circular surface of the pushing screw rod is fixedly connected with a driven bevel gear which is positioned on the right side of the transverse pushing block and is in meshing transmission with the driving bevel gear, the right wall of the soft tube cavity is communicated with a pushing cavity with a right opening, a soft tube which extends leftwards into the soft tube cavity is arranged in the pushing cavity, the soft tube penetrates through the fixed cavity and extends downwards, the bottom end of the soft tube extends leftwards into the collection cavity and is arranged on the upper end surface of the guide plate, the right side of the collection box is provided with a needle tube.

5. The intelligent collector capable of extracting the bioenergy health index according to claim 4, wherein: the pushing mechanism further comprises a containing cavity communicated with the top end of the left wall of the flexible pipe cavity, the rear wall of the containing cavity is provided with a containing wheel device, a storage hose is wound and contained on the outer circular surface of the containing wheel device, the left wall of the flexible pipe cavity is communicated with a screw cavity positioned on the lower side of the containing cavity, the left wall of the screw cavity is fixedly provided with an extruding motor, the right end surface of the extruding motor is in power connection with an extruding screw, the outer circular surface of the extruding screw is in threaded connection with a threaded connecting block in left-right sliding connection with the screw cavity, the right end surface of the threaded connecting block is fixedly connected with an extruding block, the upper end surface of the threaded connecting block is fixedly connected with a cutting block, the right wall of the flexible pipe cavity is fixedly connected with a cutting edge positioned on the upper side of the pushing cavity, the left wall of the fixing cavity is communicated with a clamping cavity, the left-right sliding connection of the clamping cavity is connected with an elastic block, and an elastic block spring is fixedly connected between the left end surface of the elastic block and the left wall of the clamping cavity, the left wall of the clamping cavity is fixedly connected with an elastic block electromagnet positioned on the lower side of the elastic block spring, an elastic block magnetic block corresponding to the elastic block electromagnet is fixedly arranged on the left end face of the elastic block, and an induction block is fixedly arranged on the upper end face of the guide plate.

6. The intelligent collector capable of extracting the bio-energy health index as claimed in claim 1, wherein: the collecting chamber right wall is fixedly connected with a collecting box, and a collecting chamber with an upward opening is arranged in the collecting box.