CN113506643A - Gene health management system - Google Patents

Abstract

The invention provides a gene health management system, and relates to the technical field of gene health. The gene health management probe detection device comprises a probe positioning mechanism, wherein the probe positioning mechanism comprises a first shell, an arc-shaped rod is movably connected inside the first shell, a first sliding plate is movably connected to the top end of the arc-shaped rod, a connecting shaft is fixedly connected to the surface of the first sliding plate, and a sliding shell is slidably connected to the outer side of the connecting shaft. This gene health management system calculates through the CPU algorithm for the light and shade stripe can be detected to the location matrix board, fixes a position the fluorescence sequence of probe piece, reduces positioning error, makes sequencing device only need one-dimensional moving mechanism to remove and scan, survey gene sequence, and the coordinate system error that two kinds of signals of CPU synchronous analysis generated carries out error feedback and compensation, obtains accurate data, utilizes healthy bracelet system, reminds when tracking human data in real time, improves the health management effect.

Description

Gene health management system

Technical Field

The invention relates to the technical field of gene health, in particular to a gene health management system.

Background

The gene health management system in the prior art has the following problems:

firstly, because the gene detection device in the prior art uses the reflecting mirror to reflect laser, and the X-axis and the Y-axis on the platform of the two-dimensional moving mechanism move and scan the probe matrix, thereby determining the gene sequence, in the scanning process, the requirement on the two-dimensional moving mechanism is higher, otherwise, errors are easy to occur, and in addition, when the probe matrix needs to be positioned, the focusing of the reflecting mirror is needed, so that the operation is complicated, and the practicability is low;

second, prior art's gene management system, when carrying out gene chip's information acquisition, has positioning error's problem, and the system can't in time compensate and revise for the data that gene detection module detected out have the error, makes system processing data inaccurate, and human data is not in time tracked through instruments etc. to current system simultaneously, reminds, makes real-time data chain fracture, and the health management effect is not obvious.

In order to solve the above problems, the inventor provides a gene health management system, which enables a positioning matrix plate to detect light and dark stripes through calculation of a CPU algorithm, positions a fluorescence sequence of a probe block, reduces a positioning error, enables a sequencing device to move and scan only by a one-dimensional moving mechanism, determines a gene sequence, and enables the CPU to synchronously analyze a coordinate system error generated by two signals, perform error feedback and compensation, obtain accurate data, and utilizes a health bracelet system to track human body data in real time and simultaneously perform reminding, thereby improving a health management effect.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides a gene health management system which has the advantages of high practicability and high reliability and solves the problems.

In order to achieve the purpose, the invention provides the following technical scheme: the utility model provides a gene health management probe detection device, includes probe positioning mechanism, probe positioning mechanism is including casing one, the inside swing joint of casing one has the arc pole, the top swing joint of arc pole has sliding plate one, the fixed surface of sliding plate one is connected with the connecting axle, the outside sliding connection of connecting axle has the slip shell, the top fixedly connected with probe block of slip shell, the middle part fixedly connected with fixed plate of slip shell, the inside sliding connection of fixed plate has the copper wire subassembly.

Preferably, the bottom and the apron joint of casing one, the top of casing one is provided with the through-hole, the inside of through-hole is provided with the copper wire subassembly, the connecting axle all with connecting pipe fixed connection with the probe block, the copper wire subassembly outside is provided with the polystyrene pipe, the inside fixedly connected with copper wire of polystyrene pipe, consequently, calculates through the CPU algorithm for the light and shade stripe that the equal interval distribution of copper wire subassembly reflection of probe block side can be detected to the location matrix board, fixes a position the fluorescence sequence of probe block, reduces positioning error.

Preferably, still including transmission damper, transmission damper is including the spout, the inside sliding connection of spout has fixed block one, the inside fixedly connected with current control piece of fixed block one, the inside fixedly connected with circular telegram solenoid of fixed block one, the one end fixedly connected with slide bar of circular telegram solenoid, the one end threaded connection of slide bar has the screw rod, the outside sliding connection of fixed block one has the shock attenuation shell, the bottom fixedly connected with laser emission device of shock attenuation shell, the bottom fixedly connected with fluorescence photosensitive device of shock attenuation shell.

Preferably, the current control piece is electrically connected with the electromagnetic device, the inside electromagnetic rheological fluid that is provided with of shock attenuation shell, fixed block one is connected with circular telegram solenoid electricity, the one end of slide bar is provided with the screw thread piece, the screw rod is connected with motor drive, fluorescence sensitization device and guide bar sliding connection, consequently, open electromagnetic device through the current control piece, shock when the screw thread piece carries out the transmission with the screw rod meshing effectively absorbs, error when reducing laser emission device and fluorescence sensitization device and advance line location.

Preferably, still including fixed establishment, fixed establishment is including the arc, the both ends of arc are all rotated and are connected with the wedge, the surperficial sliding connection of wedge has fixed block two, the downside of fixed block two is provided with the slide, and the inside sliding connection of slide has the location matrix board, consequently, through the location matrix board, effectively fixes a position.

Preferably, the second fixing block is fixedly connected with a spring, and the positioning matrix plate is fixedly connected with a pneumatic device.

Preferably, the device further comprises a shell, a transmission damping mechanism is movably connected inside the shell, a probe positioning mechanism is movably connected inside the shell, and a fixing mechanism is movably connected inside the shell.

A gene health management system comprises a system processor, a gene detection module, a gene chip module, a cloud server module, a health bracelet module and a report analysis module;

a system processor: converting a prepared gene chip data format, storing data into a cloud server, comparing set health data with gene chip data, automatically generating an algorithm by a system under the condition of reaching standards, analyzing various data of a human body according to physical examination data, automatically generating the algorithm, matching a health management scheme, transmitting feedback scheme data to a health bracelet memory, converting and transmitting monitoring data to the cloud server after the health bracelet finishes detection, analyzing the data through a gene detection module to generate a report, analyzing the data after the physical examination, and transmitting the data to the cloud server;

a gene detection module: CPU starts motor control program to control motor, CPU starts current controller program to make laser emitter move for initial positioning and positioning shell, CPU synchronously starts pneumatic device program to make positioning matrix plate be positioned, photosensitive device on the positioning matrix plate is used for detecting light and shade stripe of diffraction light field, and feeding detection result back to CPU for data processing to obtain initial data and coordinate, after the positioning is judged, outputting high level to make CPU pass through derivation formula, namely

；

Wherein:

: the radius of the ring of light;

: the vertical distance between the laser emission position and the light ring;

: the horizontal distance between the laser emission position and the light ring;

: an emission angle;

calculating the initial coordinate of the photosensitive element to obtain initial coordinate data, turning off a first current controller by a CPU, turning on a second current controller by the CPU, moving the photosensitive element, judging that the photosensitive element moves to the initial coordinate position, outputting a high level, synchronously turning on the first current controller and a second current controller by the CPU, synchronously moving a laser emitting device and the photosensitive element, synchronously detecting a photosensitive device of a positioning matrix plate and the photosensitive element, converting the data into an analog quantity, processing by the CPU, signaling a signal of the photosensitive device of the positioning matrix and the photosensitive element to be transferred to a coordinate system production unit by the CPU, sequencing the photosensitive element when moving, synchronously analyzing a coordinate system error generated by the two signals by the CPU, feeding back and compensating the error by adjusting the first current controller and the second current controller again, obtaining accurate data and then finishing gene detection;

gene chip module: preparing a personal gene chip according to the gene detection data and the sequence;

a cloud server module: storing the data of the gene chip, the data of the report analysis module and the monitoring data of the health bracelet module, and uploading the data to a system processor;

health bracelet module: executing a program on data processed by a system processor, detecting a human body, analyzing and processing real-time data by a health bracelet CPU, and uploading the data to a cloud server module;

a report analysis module: the genetic test module data is analyzed and reports are generated by algorithms.

Advantageous effects

Compared with the prior art, the invention provides a gene health management system, which has the following beneficial effects:

1. this gene health management system calculates through the CPU algorithm for fluorescence photosensitive device can fix a position to the position of receiving fluorescence reflection fast, can detect the light and shade stripe of the equidistant distribution of the copper wire subassembly reflection of probe piece side through the location matrix board, fixes a position the fluorescence sequence of probe piece, reduces positioning error, makes the sequencing device only need one-dimensional moving mechanism to remove and scan, survey gene sequence, reduces error and vibrations, great improve equipment's practicality and reliability.

2. This gene health management system, through location matrix board photosensitive element and photosensitive element synchronous detection, photosensitive element sequences when removing, and the coordinate system error that two kinds of signals of CPU synchronous analysis generated carries out error feedback and compensation, obtains accurate data, reduces the error when laser emission device and fluorescence photosensitive device advance line location, and is easy and simple to handle, utilizes healthy bracelet system, reminds when tracking the human data in real time, improves the health management effect.

Drawings

FIG. 1 is a schematic view of the overall structure of the probe positioning mechanism of the present invention;

FIG. 2 is a schematic view of the overall structure of the present invention;

FIG. 3 is a schematic cross-sectional view of the probe positioning mechanism of the present invention;

FIG. 4 is a schematic structural view of the transmission damping mechanism of the present invention;

FIG. 5 is an enlarged view of the structure at A in FIG. 2 according to the present invention;

FIG. 6 is a schematic block diagram of the present invention;

FIG. 7 is a schematic view of the system flow structure of the present invention;

FIG. 8 is a schematic view of the flow structure of the gene detection subsystem of the present invention.

In the figure: 1. a housing; 2. a transmission damping mechanism; 21. a chute; 22. a first fixed block; 23. a current control block; 24. an energized solenoid coil; 25. a slide bar; 26. a screw; 27. a shock-absorbing shell; 28. a laser emitting device; 29. a fluorescent light sensing device; 3. a probe positioning mechanism; 31. a first shell; 32. an arcuate bar; 33. a first sliding plate; 34. a connecting shaft; 35. a sliding shell; 36. a probe block; 37. a fixing plate; 38. a copper wire assembly; 4. a fixing mechanism; 41. an arc-shaped plate; 42. a wedge block; 43. a second fixed block; 44. a slideway; 45. a matrix plate is positioned.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The first embodiment is as follows:

referring to fig. 1-8, a gene health management probe detection device, comprising a probe positioning mechanism 3, the probe positioning mechanism 3 comprises a first casing 31, the first casing 31 is movably connected with an arc rod 32, the top end of the arc rod 32 is movably connected with a first sliding plate 33, the surface of the first sliding plate 33 is fixedly connected with a connecting shaft 34, the outer side of the connecting shaft 34 is slidably connected with a sliding casing 35, the top end of the sliding casing 35 is fixedly connected with a probe block 36, the middle part of the sliding casing 35 is fixedly connected with a fixing plate 37, the inner part of the fixing plate 37 is slidably connected with a copper wire component 38, the bottom end of the first casing 31 is clamped with a cover plate, the top end of the first casing 31 is provided with a through hole, the inner part of the through hole is provided with a copper wire component 38, the connecting shaft 34 and the probe block 36 are both fixedly connected with a connecting pipe, the outer side of the copper wire component 38 is provided with a polystyrene pipe, the inner part of the polystyrene pipe is fixedly connected with a copper wire, therefore, through calculation of a CPU algorithm, the positioning matrix board 45 can detect light and dark stripes which are reflected by the copper wire assembly 38 on the side surface of the probe block 36 and distributed at equal intervals, the fluorescent sequence of the probe block 36 is positioned, and the positioning error is reduced.

Example two:

referring to fig. 1-8, a gene health management probe detection device, comprising a probe positioning mechanism 3, the probe positioning mechanism 3 comprises a first casing 31, the first casing 31 is movably connected with an arc rod 32, the top end of the arc rod 32 is movably connected with a first sliding plate 33, the surface of the first sliding plate 33 is fixedly connected with a connecting shaft 34, the outer side of the connecting shaft 34 is slidably connected with a sliding casing 35, the top end of the sliding casing 35 is fixedly connected with a probe block 36, the middle part of the sliding casing 35 is fixedly connected with a fixing plate 37, the inner part of the fixing plate 37 is slidably connected with a copper wire component 38, the bottom end of the first casing 31 is clamped with a cover plate, the top end of the first casing 31 is provided with a through hole, the inner part of the through hole is provided with a copper wire component 38, the connecting shaft 34 and the probe block 36 are both fixedly connected with a connecting pipe, the outer side of the copper wire component 38 is provided with a polystyrene pipe, the inner part of the polystyrene pipe is fixedly connected with a copper wire, therefore, through calculation of a CPU (Central processing Unit) algorithm, the positioning matrix plate 45 can detect light and shade stripes which are distributed at equal intervals and reflected by the copper wire assembly 38 on the side surface of the probe block 36, position the fluorescence sequence of the probe block 36 and reduce positioning errors, and further comprises the transmission damping mechanism 2, wherein the transmission damping mechanism 2 comprises a chute 21, a first fixed block 22 is slidably connected inside the chute 21, a current control block 23 is fixedly connected inside the first fixed block 22, an electrified solenoid 24 is fixedly connected inside the first fixed block 22, one end of the electrified solenoid 24 is fixedly connected with a sliding rod 25, one end of the sliding rod 25 is in threaded connection with a screw rod 26, a damping shell 27 is slidably connected outside the first fixed block 22, a laser emission device 28 is fixedly connected at the bottom end of the damping shell 27, a fluorescence photosensitive device 29 is fixedly connected at the bottom end of the damping shell 27, and the current control block 23 is electrically connected with an electromagnetic device, the electromagnetic liquid is arranged in the damping shell 27, the first fixing block 22 is electrically connected with the energized solenoid coil 24, the threaded block is arranged at one end of the sliding rod 25, the screw rod 26 is in transmission connection with the motor, and the fluorescent light sensing device 29 is in sliding connection with the guide rod, so that the electromagnetic device is opened through the current control block 23, vibration generated when the threaded block is meshed with the screw rod 26 for transmission is effectively absorbed, and errors generated when the laser emitting device 28 and the fluorescent light sensing device 29 are positioned are reduced.

Example three:

referring to fig. 1-8, a gene health management probe detection device, comprising a probe positioning mechanism 3, the probe positioning mechanism 3 comprises a first casing 31, the first casing 31 is movably connected with an arc rod 32, the top end of the arc rod 32 is movably connected with a first sliding plate 33, the surface of the first sliding plate 33 is fixedly connected with a connecting shaft 34, the outer side of the connecting shaft 34 is slidably connected with a sliding casing 35, the top end of the sliding casing 35 is fixedly connected with a probe block 36, the middle part of the sliding casing 35 is fixedly connected with a fixing plate 37, the inner part of the fixing plate 37 is slidably connected with a copper wire component 38, the bottom end of the first casing 31 is clamped with a cover plate, the top end of the first casing 31 is provided with a through hole, the inner part of the through hole is provided with a copper wire component 38, the connecting shaft 34 and the probe block 36 are both fixedly connected with a connecting pipe, the outer side of the copper wire component 38 is provided with a polystyrene pipe, the inner part of the polystyrene pipe is fixedly connected with a copper wire, therefore, through calculation of a CPU (Central processing Unit) algorithm, the positioning matrix plate 45 can detect light and shade stripes which are distributed at equal intervals and reflected by the copper wire assembly 38 on the side surface of the probe block 36, position the fluorescence sequence of the probe block 36 and reduce positioning errors, and further comprises the transmission damping mechanism 2, wherein the transmission damping mechanism 2 comprises a chute 21, a first fixed block 22 is slidably connected inside the chute 21, a current control block 23 is fixedly connected inside the first fixed block 22, an electrified solenoid 24 is fixedly connected inside the first fixed block 22, one end of the electrified solenoid 24 is fixedly connected with a sliding rod 25, one end of the sliding rod 25 is in threaded connection with a screw rod 26, a damping shell 27 is slidably connected outside the first fixed block 22, a laser emission device 28 is fixedly connected at the bottom end of the damping shell 27, a fluorescence photosensitive device 29 is fixedly connected at the bottom end of the damping shell 27, and the current control block 23 is electrically connected with an electromagnetic device, the electromagnetic liquid is arranged in the damping shell 27, the first fixing block 22 is electrically connected with the energized solenoid coil 24, one end of the sliding rod 25 is provided with a threaded block, the screw rod 26 is in transmission connection with the motor, the fluorescence photosensitive device 29 is in sliding connection with the guide rod, therefore, the electromagnetic device is opened through the current control block 23, the vibration generated when the threaded block is meshed with the screw rod 26 for transmission is effectively absorbed, the error of the laser emission device 28 and the fluorescence photosensitive device 29 for positioning is reduced, the electromagnetic device further comprises a fixing mechanism 4, the fixing mechanism 4 comprises an arc-shaped plate 41, two ends of the arc-shaped plate 41 are rotatably connected with wedge-shaped blocks 42, the surface of the wedge-shaped blocks 42 is in sliding connection with a second fixing block 43, a slide way 44 is arranged on the lower side of the second fixing block 43, a positioning matrix plate 45 is in sliding connection with the inside of the slide way 44, therefore, the positioning is effectively performed through the positioning matrix plate 45, and the second fixing block 43 is fixedly connected with the spring, the positioning matrix plate 45 is fixedly connected with a pneumatic device and further comprises a shell 1, the inside of the shell 1 is movably connected with a transmission damping mechanism 2, the inside of the shell 1 is movably connected with a probe positioning mechanism 3, and the inside of the shell 1 is movably connected with a fixing mechanism 4.

Example four:

referring to fig. 1 to 8, a gene health management system includes a system processor, a gene detection module, a gene chip module, a cloud server module, a health bracelet module, and a report analysis module;

a system processor: converting a prepared gene chip data format, storing data into a cloud server, comparing set health data with gene chip data, automatically generating an algorithm by a system under the condition of reaching standards, analyzing various data of a human body according to physical examination data, automatically generating the algorithm, matching a health management scheme, transmitting feedback scheme data to a health bracelet memory, converting and transmitting monitoring data to the cloud server after the health bracelet finishes detection, analyzing the data through a gene detection module to generate a report, analyzing the data after the physical examination, and transmitting the data to the cloud server;

a gene detection module: CPU starts motor control program to control motor, CPU starts current controller program to make laser emission device 28 move to carry out initial positioning to position boundary position of first shell 31, CPU synchronously starts pneumatic device program to make positioning matrix plate 45 position, photosensitive device on positioning matrix plate 45 detects light and shade stripe of diffraction light field, and feeds back detection result to CPU to process data to obtain initial data and coordinate, after the positioning is judged, high level is outputted to make CPU pass through derivation formula, namely

；

Wherein:

: the radius of the ring of light;

: the vertical distance between the laser emission position and the light ring;

: the horizontal distance between the laser emission position and the light ring;

: an emission angle;

calculating the initial coordinate of the photosensitive element to obtain initial coordinate data, turning off a first current controller by a CPU, turning on a second current controller by the CPU, moving the photosensitive element, judging that the photosensitive element moves to the initial coordinate position, outputting high level, synchronously turning on the first current controller and a second current controller by the CPU, synchronously moving a laser emitting device 28 and the photosensitive element, synchronously detecting a photosensitive device and the photosensitive element by a positioning matrix plate 45, converting the data into analog quantity, processing by the CPU, signaling a positioning matrix photosensitive device signal and the photosensitive element to be transferred to a coordinate system production unit by the CPU, sequencing the photosensitive element when moving, synchronously analyzing a coordinate system error generated by the two signals by the CPU, and finishing gene detection after obtaining accurate data by adjusting the first current controller and the second current controller again to feed back and compensate errors;

gene chip module: preparing a personal gene chip according to the gene detection data and the sequence;

a cloud server module: storing the data of the gene chip, the data of the report analysis module and the monitoring data of the health bracelet module, and uploading the data to a system processor;

health bracelet module: executing a program on data processed by a system processor, detecting a human body, analyzing and processing real-time data by a health bracelet CPU, and uploading the data to a cloud server module;

a report analysis module: the genetic test module data is analyzed and reports are generated by algorithms.

The working principle is as follows: when the laser emission device is used, the screw rod 26 is driven to rotate by the motor, the current control block 23 is controlled by the CPU, the current control block 23 is opened, the electrifying spiral coil 24 is electrified by electric connection, the current of the electrifying spiral coil 24 is increased by the Faraday electromagnetic induction principle, after the electrifying spiral coil 24 is electrified, the single turns of the electrifying spiral coil 24 are not contacted or insulated, each turn of the electrifying spiral coil 24 is equivalent to annular current, the current direction in each turn of the coil is the same, each turn of the coil is mutually attracted with adjacent coils according to the mutual attraction of magnetic fields between currents in the same direction, then the whole electrifying spiral coil 24 is contracted, the sliding rod 25 moves towards the screw rod 26, the sliding rod 25 drives the thread block to be meshed with the screw rod 26, the first fixed block 22 is connected with the inside of the sliding groove 21 through threads to slide, and the laser emission device 28 and the fluorescence photosensitive device 29 move, when the thread block is meshed with the screw rod 26 for transmission, the electromagnetic device is opened through the current control block 23, so that the electromagnetic device generates an induction magnetic field, the electromagnetic liquid in the damping shell 27 controls the intensity of current through the current control block 23, the magnetic field of the electromagnetic device is changed, the viscosity of the electromagnetic liquid is changed, the friction force between the electromagnetic liquid and the damping shell 27 is increased, vibration generated when the thread block is meshed with the screw rod 26 for transmission is absorbed, and errors generated when the laser emitting device 28 and the fluorescent light sensing device 29 are positioned are reduced;

the Stokes shift light is emitted through the fluorescent probe block 36 on the gene chip by irradiating the laser on the probe block 36, and the emitted light is collected by the photomultiplier on the fluorescent photosensitive device 29, so that the information of the microarray chip is conveniently obtained, when the probe positioning mechanism 3 is used, the collected probe block 36 matrix is placed into the first shell 31, after the probe block is clamped into the cover plate, the cover plate extrudes the arc-shaped rod 32, the arc-shaped rod 32 is stressed to extrude the first sliding plate 33, the first sliding plate 33 drives the connecting shaft 34 to extrude the connecting pipe, the first sliding plate 33 and the fixed plate 37 move relatively, so that the substance in the slit inside the probe block 36 can more easily emit the Stokes shift light, the first shell 31 extrudes the arc-shaped plate 41 when being fixed, the arc-shaped plate 41 is extruded to drive the wedge blocks 42 on two sides to slide, and the wedge block 42 moves to push the second fixed block 43 to move outwards, the second fixing block 43 is fixed on the first shell 31 to reduce errors, the copper wire component 38 is irradiated by laser, light and shade stripes distributed at equal intervals can be observed near the bright point of the light ring because the polystyrene tube outside the copper wire component 38 has light transmission property and has transmitted light after being irradiated by the laser, the copper wire inside the polystyrene tube is irradiated by the laser to generate reflected light, when the diameter of the copper wire is smaller, the copper wire component 38 at the leftmost side of the first shell 31 is firstly scanned by the laser emitting device 28, the positioning matrix plate 45 is upwards pushed by the pneumatic device at the lower side, so that the positioning matrix plate 45 can detect the light and shade stripes distributed at equal intervals, the fluorescence sensing device 29 can be quickly positioned to the position for receiving fluorescence reflection through calculation of a CPU (central processing unit) algorithm, and meanwhile, when the laser emitting device 28 moves, the copper wire component 38 at the side of the probe block 36 is irradiated, and the positioning matrix board 45 can detect light and dark stripes which are reflected by the copper wire assembly 38 on the side surface of the probe block 36 and distributed at equal intervals, so that the fluorescent sequence of the probe block 36 is positioned, and the positioning error is reduced.

In summary, the gene health management system calculates through the CPU algorithm, so that the fluorescence sensing device 29 can be quickly positioned to the position where the fluorescence reflection is received, the light and dark stripes distributed at equal intervals and reflected by the copper wire assembly 38 on the side of the probe block 36 can be detected through the positioning matrix plate 45, the fluorescence sequence of the probe block 36 is positioned, the positioning error is reduced, the sequencing device only needs a one-dimensional moving mechanism to move and scan, the gene sequence is determined, the error and vibration are reduced, and the practicability and reliability of the device are greatly improved.

This gene health management system, through 45 photosensitive elements of location matrix board and photosensitive element synchronous detection, photosensitive element carries out the sequencing when removing, and the coordinate system error that two kinds of signals of CPU synchronous analysis generated carries out error feedback and compensation, obtains accurate data, reduces the error when laser emission device 28 and fluorescence photosensitive device 29 advance line location, and is easy and simple to handle, utilizes healthy bracelet system, reminds when tracking human data in real time, improves the health management effect.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (8)

1. The utility model provides a gene health management probe detection device, includes probe positioning mechanism (3), its characterized in that: the probe positioning mechanism (3) comprises a first shell (31), an arc-shaped rod (32) is movably connected inside the first shell (31), a sliding plate I (33) is movably connected to the top end of the arc-shaped rod (32), a connecting shaft (34) is fixedly connected to the surface of the sliding plate I (33), a sliding shell (35) is slidably connected to the outer side of the connecting shaft (34), a probe block (36) is fixedly connected to the top end of the sliding shell (35), a fixing plate (37) is fixedly connected to the middle of the sliding shell (35), and a copper wire assembly (38) is slidably connected inside the fixing plate (37).

2. The gene health management probe detection device of claim 1, wherein: the bottom and the apron joint of casing (31), the top of casing (31) is provided with the through-hole, the inside of through-hole is provided with copper wire subassembly (38), connecting axle (34) and probe block (36) all with connecting pipe fixed connection, the copper wire subassembly (38) outside is provided with the polystyrene pipe, the inside fixedly connected with copper wire of polystyrene pipe.

3. The gene health management probe detection device of claim 1, wherein: still including transmission damper (2), transmission damper (2) are including spout (21), the inside sliding connection of spout (21) has fixed block (22), the inside fixedly connected with current control piece (23) of fixed block (22), the inside fixedly connected with circular telegram solenoid (24) of fixed block (22), the one end fixedly connected with slide bar (25) of circular telegram solenoid (24), the one end threaded connection of slide bar (25) has screw rod (26), the outside sliding connection of fixed block (22) has shock attenuation shell (27), the bottom fixedly connected with laser emission device (28) of shock attenuation shell (27), the bottom fixedly connected with fluorescence photosensitive device (29) of shock attenuation shell (27).

4. The device for detecting gene health management probe according to claim 3, wherein: the current control block (23) is electrically connected with the electromagnetic device, electromagnetic liquid is arranged inside the damping shell (27), the first fixing block (22) is electrically connected with the electrified solenoid coil (24), a threaded block is arranged at one end of the sliding rod (25), the threaded rod (26) is in transmission connection with the motor, and the fluorescent light sensing device (29) is in sliding connection with the guide rod.

5. The gene health management probe detection device of claim 1, wherein: still including fixed establishment (4), fixed establishment (4) are including arc (41), the both ends of arc (41) are all rotated and are connected with wedge (42), the surperficial sliding connection of wedge (42) has fixed block two (43), the downside of fixed block two (43) is provided with slide (44), and the inside sliding connection of slide (44) has location matrix board (45).

6. The device for detecting gene health management probe according to claim 5, wherein: the second fixing block (43) is fixedly connected with the spring, and the positioning matrix plate (45) is fixedly connected with the pneumatic device.

7. The gene health management probe detection device of claim 1, wherein: still including shell (1), the inside swing joint of shell (1) has transmission damper (2), the inside swing joint of shell (1) has probe positioning mechanism (3), the inside swing joint of shell (1) has fixed establishment (4).

8. A genetic health management system according to claim 1, wherein: the system comprises a system processor, a gene detection module, a gene chip module, a cloud server module, a health bracelet module and a report analysis module;

a system processor: converting a prepared gene chip data format, storing data into a cloud server, comparing set health data with gene chip data, automatically generating an algorithm by a system under the condition of reaching standards, analyzing various data of a human body according to physical examination data, automatically generating the algorithm, matching a health management scheme, transmitting feedback scheme data to a health bracelet memory, converting and transmitting monitoring data to the cloud server after the health bracelet finishes detection, analyzing the data through a gene detection module to generate a report, analyzing the data after the physical examination, and transmitting the data to the cloud server;

a gene detection module: CPU starts motor control program to control motor, CPU starts current controller program to make laser emission device (28) move to carry out initial positioning to position boundary position of first shell (31), CPU synchronously starts pneumatic device program to make positioning matrix plate (45) carry out positioning, photosensitive device on positioning matrix plate (45) detects light and shade stripe of diffraction light field, and feeds back detection result to CPU to carry out data processing to obtain initial data and coordinate, after positioning is judged, high level is outputted to make CPU pass through derivation formula, namely CPU

；

Wherein:

: the radius of the ring of light;

: the vertical distance between the laser emission position and the light ring;

: the horizontal distance between the laser emission position and the light ring;

: an emission angle;

calculating the initial coordinate of the photosensitive element to obtain initial coordinate data, turning off a first current controller by a CPU, turning on a second current controller by a CPU, moving the photosensitive element, judging that the photosensitive element moves to the initial coordinate position, outputting high level, synchronously turning on the first current controller and a second current controller by the CPU, synchronously moving a laser emitting device (28) and the photosensitive element, synchronously detecting a photosensitive device and the photosensitive element by a positioning matrix plate (45), converting the data into analog quantity, processing by the CPU, and communicating a signal of the photosensitive device of the positioning matrix and the photosensitive element into a transfer-to-coordinate system production unit by the CPU so that the photosensitive element performs sequencing when moving, synchronously analyzing a coordinate system error generated by two signals by the CPU, performing error feedback and compensation by adjusting the first current controller and the second current controller again, and finishing gene detection after obtaining accurate data;

gene chip module: preparing a personal gene chip according to the gene detection data and the sequence;

a cloud server module: storing the data of the gene chip, the data of the report analysis module and the monitoring data of the health bracelet module, and uploading the data to a system processor;

health bracelet module: executing a program on data processed by a system processor, detecting a human body, analyzing and processing real-time data by a health bracelet CPU, and uploading the data to a cloud server module;

a report analysis module: the genetic test module data is analyzed and reports are generated by algorithms.

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