CN112881434B - Tumor cell radiosensitivity detection system and method based on 5G and block chain - Google Patents

Abstract

The invention provides a tumor cell radiosensitivity detection system and method based on 5G and a block chain, which belong to the technical field of biomedical detection high-end equipment and comprise the following steps: a housing; the detector is internally provided with a 5G communication module, can upload data to the block chain node and is used for detecting tumor cells; the containing mechanism is arranged in the shell and is positioned at the lower side of the detector; the test tube placing mechanism is connected with the storage mechanism; the sealing cover plate is arranged in the test tube placing mechanism and used for sealing the test tube placing mechanism; the chain transmission mechanism is arranged in the shell and is positioned at the lower side of the detector; the lifting mechanism is arranged in the shell and positioned on the upper side of the containing mechanism, and is used for lifting the detector; the test tubes are detected one by one, and the efficiency of replacing the test tubes one by one manually in the prior art is improved.

Description

Tumor cell radiosensitivity detection system and method based on 5G and block chain

Technical Field

The invention belongs to the technical field of biomedical detection high-end equipment, and particularly relates to a tumor cell radiosensitivity detection system and method based on 5G and a block chain.

Background

The tumor cell parenchyma is a tumor. The tumor tissue is composed of parenchyma and stroma, and the tumor parenchyma is tumor cells, is a main component of the tumor and has tissue source specificity. It determines the biological characteristics of the tumor and the specificity of each tumor. The tissue origin of various tumors is generally identified according to the parenchymal morphology of the tumor, classification, naming and histological diagnosis of the tumor are performed, and the benign and malignant degree of the tumor and the malignant degree of the tumor are determined according to the differentiation maturity degree and the size of the heterogeneity. Tumor cells have three significant basic features: immobility, migration and loss of contact inhibition. In addition, tumor cells have many physiological, biochemical and morphological features that differ from normal cells.

Need detect the cell in the test tube through the detector when detecting tumor cell, the check out test set commonly used at present is detecting the test tube, mostly through artifical one detection, can make detection efficiency step-down like this, influences work efficiency.

Disclosure of Invention

The invention aims to provide a tumor cell radiosensitivity detection system and method based on 5G and a block chain, and aims to solve the problem that in the prior art, tumor cells in test tubes are low in efficiency one by one through manual work.

In order to achieve the purpose, the invention provides the following technical scheme: a 5G and blockchain based tumor cell radiosensitivity detection system comprising: a housing; the detector is arranged in the shell and is used for detecting tumor cells; the containing mechanism is arranged in the shell and is positioned at the lower side of the detector; the test tube placing mechanism is arranged in the shell and is connected with the storage mechanism; the sealing cover plate is arranged in the test tube placing mechanism and used for sealing the test tube placing mechanism; the chain transmission mechanism is arranged in the shell and is positioned at the lower side of the detector; the lifting mechanism is arranged in the shell and positioned on the upper side of the containing mechanism, and the lifting mechanism is used for lifting the detector; the closing mechanism is arranged on the outer side of the shell and is used for closing the shell; and the supporting mechanism is arranged on the lower side of the shell and is used for realizing the support of the shell.

As a preferred aspect of the present invention, the housing includes a first square hole, two first sliding holes, two second sliding holes, two first mounting holes, two mounting plates, two first support plates, two second square holes, and two second mounting holes, the first square hole is disposed at the front end of the housing, the first sliding holes are disposed at the left and right ends of the housing, the second sliding holes are disposed at the rear end of the housing, each first mounting hole is disposed at the rear end of the housing, the mounting plates are fixedly connected to the rear end of the housing, the first support plates are fixedly connected to the left and right inner walls of the housing, and the second square hole and the second mounting holes are disposed at the upper side of the first support plate.

As a preferred scheme of the present invention, the accommodating mechanism includes two moving screws, two moving nuts, two fixing blocks, a first servo motor, a driving pulley, a driven pulley, a connecting belt and a fixing plate, the two moving screws are rotatably connected to the front inner wall of the housing, the moving screws movably penetrate through the first mounting hole, the two moving nuts are screwed to the surfaces of the moving screws, the two fixing blocks are fixedly connected to opposite ends of the two moving nuts, the fixing plate is fixedly connected to the lower end of the housing, the first servo motor is fixedly connected to the rear end of the fixing plate, the two driving pulleys, the two driven pulleys and the connecting belt are fixedly connected to the surface of the output end of the first servo motor, the two driven pulleys are fixedly connected to the surfaces of the two moving screws, the connecting belt is sleeved on the surfaces of the driving pulley and the driven pulley, and the driving pulley and the driven pulley are in transmission connection through the connecting belt.

As a preferred embodiment of the present invention, the test tube placing mechanism includes a test tube box, an insertion slot, a first rotating rod, a first gear, a gear belt, a limiting ring, a second supporting plate, a limiting chute, a third mounting hole, a fixing rod, a test tube limiting sleeve, an auxiliary sliding rod, a second servo motor, and a second gear, the test tube box is fixedly connected between two fixing blocks, the insertion slot is formed in the upper end of the test tube box, the first rotating rod, the first gear, and the limiting ring are rotatably connected to the lower inner wall of the test tube box, the first gear and the limiting ring are both fixedly connected to the surface of the test tube box, the first rotating rod is located at the lower side of the limiting ring, the gear belt is sleeved on the surfaces of the four first gears, the gear belt is engaged with the four first gears, the second supporting plate is disposed in the test tube placing mechanism, the limiting chute is formed in the surface of the second supporting plate, the four third mounting holes are formed in the upper end of the second supporting plate, the first rotating rod movably penetrates through the third mounting hole, the sliding rod and the limiting chute are connected to the surface of the sliding rod, the limiting chute is connected to the fixing rod, and the limiting sleeve is connected to the surface of the limiting chute.

As a preferable aspect of the present invention, the sealing cover plate includes a holding groove and a fourth mounting hole, the holding groove and the fourth mounting hole are opened at the upper end of the sealing cover plate, and the holding groove is located at the front side of the fourth mounting hole.

As a preferable scheme of the present invention, the chain transmission mechanism includes four second rotating rods, four third gears, four chains, a third servo motor, and four fourth gears, the second rotating rods are rotatably connected to the lower end of the first support plate, the third gears are fixedly connected to the surface of the second rotating rods, the four third gears are sleeved on the surface of the four third gears, the four third gears are connected by the chains in a transmission manner, the third servo motor is fixedly connected to the upper end of the first support plate, the output end of the third servo motor movably penetrates through the second mounting hole, the fourth gears are fixedly connected to the output end of the third servo motor, and the fourth gears are engaged with the second rotating rods.

As a preferred scheme of the invention, the lifting mechanism comprises four lifting screws, two lifting nuts, two square rods and a third support plate, the lifting screws and the lifting nuts are rotatably connected to the upper end of the first support plate, the second rotating rod movably penetrates through the lower end of the first support plate, the upper end of the second rotating rod is fixedly connected to the lower end of the lifting screws, the lifting nuts are in threaded connection to the surface of the lifting screws, the number of the square rods is two, each square rod is fixedly connected between the two lifting nuts, the third support plate is fixedly connected between the two square rods, the detector is fixedly connected to the upper end of the third support plate, and a 5G communication module is arranged in the detector.

As a preferred scheme of the invention, the closing mechanism comprises two closing cover plates, two round rods, two pulleys, two electric telescopic rods, two connecting rods and two observation glasses, the closing cover plates are slidably connected in the first sliding holes, the round rods are fixedly connected to the rear ends of the closing cover plates, the pulleys are fixedly connected to the surfaces of the round rods, the electric telescopic rods are fixedly connected to the upper ends of the mounting plates, the connecting rods are movably hinged with the round rods and the connecting rods through hinge shafts, and the observation glasses are fixedly connected in the closing cover plates.

As a preferable scheme of the present invention, the support mechanism includes four support legs and two cross bars, the four support legs are respectively and fixedly connected to four corners of the lower end of the housing, and each cross bar is fixedly connected between the two support legs.

The use method of the tumor cell radiosensitivity detection system based on 5G and a block chain comprises the following steps:

s1, detecting tumor cells in a test tube:

s11, moving the test tube box in front and outside: the first servo motor is started to rotate reversely, the driving belt pulley is rotated reversely by the reverse rotation of the first servo motor, the reverse rotation of the driving belt pulley drives the movable screw to rotate reversely through the mutual matching of the connecting belt and the driven belt pulley, the movable nut moves forwards on the surface of the movable screw by the reverse rotation of the movable screw, the test tube box is driven to move forwards by the movement of the movable nut through the fixing block, the first servo motor is closed when the movable nut is in contact with the front inner wall of the shell, and the test tube box is moved at the moment;

s12, placing a test tube to be detected: holding the sealing cover plate by hand, taking the sealing cover plate out of the slot, then sequentially placing the test tubes into the test tube stop collar, holding the sealing cover plate by hand after the test tubes are placed, and inserting the sealing cover plate into the slot;

s13, moving the test tube box inwards: the test tube box can be moved into the shell according to the reverse operation of the step S1;

s14, detecting test tubes one by one: the second gear is started to rotate, the second servo motor is rotated forwardly through the forward rotation of the second gear, the first gear is driven to rotate reversely through the forward rotation of the second servo motor, the gear belt rotates reversely through the reverse rotation of the first gear, the test tube limiting sleeve moves intuitively and slowly in the test tube limiting sleeve through the reverse rotation of the gear belt, the test tube limiting sleeve is detected one by one through the detector, and the detection result is detected through observing the penetration of glass;

s2, overhauling the detector:

s21, opening and closing the mechanism: starting the electric telescopic rod to extend, wherein the two connecting rods move upwards due to the extension of the electric telescopic rod, the two round rods move towards the side away from the round rods due to the upward movement of the two connecting rods, the closed cover plate is driven to move due to the movement of the round rods, the two closed cover plates move towards the end away from the round rods, the electric telescopic rod is closed when the two pulleys are in contact with the left inner wall and the right inner wall of the second sliding hole, and the pulleys are used for reducing the friction force generated when the closed cover plate moves;

s22, an ascending detector: the third servo motor is started to rotate reversely, the fourth gear rotates reversely due to the reverse rotation of the third servo motor, the third gear is driven to rotate positively due to the reverse rotation of the fourth gear, the second rotating rod is driven to rotate positively due to the forward rotation of the third gear, the chain is driven to rotate positively due to the forward rotation of the third gear, four third gears are driven to rotate positively due to the forward rotation of the chain, the lifting screw rod is driven to rotate positively due to the forward rotation of the second rotating rod, the lifting nut moves upwards on the surface of the lifting screw rod due to the forward rotation of the lifting screw rod, the lifting nut moves upwards through the square rod to drive the third supporting plate, and the detector moves upwards due to the upwards movement of the third supporting plate.

Compared with the prior art, the invention has the beneficial effects that:

1. in this scheme, the shell is for the convenience of protecting the detector, the detector is for the convenience of detecting tumor cells, receiving mechanism is for the convenience of driving the test tube and lays the mechanism and remove, the test tube is laid the mechanism and is for the convenience of replacing the manual work and make the test tube detect by the detector one by one, sealed apron is for the convenience of sealed test tube laying mechanism, chain drive is for the convenience of providing power for elevating system, elevating system is for the convenience of the lift detector, closing mechanism is for the convenience of closed shell, and then the protection detector, supporting mechanism is for the convenience of supporting housing.

2. In this scheme, remove the screw rod for the convenience of threaded connection removes the nut, remove the nut for the convenience of connecting the fixed block, first servo motor is for the convenience of driving drive pulley pivoted, drive pulley, driven pulley and connecting belt are for the convenience of mutually supporting, connecting the belt is for the convenience of connecting drive pulley and driven pulley transmission, the fixed plate is for the convenience of fixing first servo motor, the test tube box is for the convenience of rotating and connecting first pivot, the slot is for the convenience of sealing cover board male, first pivot is for the convenience of fixing first gear, first gear is for the convenience of mutually supporting with the gear belt, the spacing ring is for the convenience of supporting the second backup pad, the second backup pad is for the convenience of excavating spacing spout and third mounting hole, spacing spout is for the convenience of assisting the slide bar gliding, the third mounting hole is for the convenience of first pivot activity run-through, the dead lever is for the convenience of rotating and connects test tube spacing sleeve, the test tube spacing sleeve is for the convenience of placing the test tube spacing sleeve, assist slide bar is for the convenience of facilitating the chiseling on the test tube mounting hole, the second gear is for the convenience of facilitating fixing second servo motor, the test tube mounting hole is for the convenience of holding in the test tube mounting hole, the fourth side is held the test tube mounting hole, the test tube side is held in the convenience of holding the test tube mounting hole, the test tube side is held in the convenience of holding the test tube side.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention. In the drawings:

FIG. 1 is an exploded view of the present invention;

FIG. 2 is a front perspective view of the present invention;

FIG. 3 is a rear perspective view of the present invention;

fig. 4 is a first partial structural view of the housing 1 in the present invention;

fig. 5 is a second partial structural view of the housing 1 of the present invention;

fig. 6 is a structural view of the storage mechanism 3 of the present invention;

FIG. 7 is a first configuration diagram of the test tube placement mechanism 4 according to the present invention;

FIG. 8 is a second structural view of the test tube setting mechanism 4 in the present invention;

FIG. 9 is a third configuration of the cuvette holder mechanism 4 according to the present invention;

fig. 10 is a structural view of the sealing cover 5 of the present invention;

fig. 11 is a structural view of the chain drive mechanism 6 of the present invention;

fig. 12 is a structural view of the lifting mechanism 7 of the present invention;

FIG. 13 is a block diagram of the closure mechanism 8 of the present invention;

fig. 14 is a structural view of the support mechanism 9 of the present invention.

In the figure: 1. a housing; 101. a first square hole; 102. a first slide hole; 103. a second slide hole; 104. a first mounting hole; 105. mounting a plate; 106. a first support plate; 107. a second square hole; 108. a second mounting hole; 2. a detector; 3. a storage mechanism; 301. moving the screw; 302. moving the nut; 303. a fixed block; 304. a first servo motor; 305. a drive pulley; 306. a driven pulley; 307. connecting a belt; 308. a fixing plate; 4. a test tube placement mechanism; 401. a test tube box; 402. a slot; 403. a first rotating lever; 404. a first gear; 405. a gear belt; 406. a limiting ring; 407. a second support plate; 408. a limiting chute; 409. a third mounting hole; 410. fixing the rod; 411. a test tube stop collar; 412. an auxiliary slide bar; 413. a second servo motor; 414. a second gear; 5. sealing the cover plate; 501. a holding groove; 502. a fourth mounting hole; 6. a chain transmission mechanism; 601. a second rotating rod; 602. a third gear; 603. a chain; 604. a third servo motor; 605. a fourth gear; 7. a lifting mechanism; 701. a lifting screw; 702. a lifting nut; 703. a square bar; 704. a third support plate; 8. a closing mechanism; 801. closing the cover plate; 802. a round bar; 803. a pulley; 804. an electric telescopic rod; 805. a connecting rod; 806. observing glass; 9. a support mechanism; 901. supporting legs; 902. a cross bar.

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 obtained by a person skilled in the art without making any creative effort based on the embodiments in the present invention, belong to the protection scope of the present invention.

In the description of the present invention, it should be noted that the terms "upper", "lower", "inner", "outer", "top/bottom", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "disposed," "sleeved/connected," "connected," and the like are to be construed broadly, e.g., "connected," which may be fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Examples

Referring to fig. 1-14, the technical solution provided by the present embodiment is as follows: a 5G and blockchain based tumor cell radiosensitivity detection system comprising: a housing 1; the detector 2 is arranged in the shell 1, and the detector 2 is used for detecting tumor cells; the containing mechanism 3 is arranged in the shell 1, and the containing mechanism 3 is positioned at the lower side of the detector 2; the test tube placing mechanism 4 is arranged in the shell 1, and the test tube placing mechanism 4 is connected with the storage mechanism 3; the sealing cover plate 5 is arranged in the test tube placing mechanism 4, and the sealing cover plate 5 is used for sealing the test tube placing mechanism 4; the chain transmission mechanism 6 is arranged in the shell 1, and the chain transmission mechanism 6 is positioned at the lower side of the detector 2; the lifting mechanism 7 is arranged in the shell 1 and positioned on the upper side of the accommodating mechanism 3, and the lifting mechanism 7 is used for realizing the lifting of the detector 2; the closing mechanism 8 is arranged on the outer side of the shell 1, and the closing mechanism 8 is used for closing the shell 1; and the supporting mechanism 9, the supporting mechanism 9 is arranged at the lower side of the shell 1, and the supporting mechanism 9 is used for realizing the supporting of the shell 1.

In the embodiment of the present invention, the housing 1 is for protecting the detector 2, the detector 2 is for detecting tumor cells, the accommodating mechanism 3 is for driving the test tube placing mechanism 4 to move, the test tube placing mechanism 4 is for detecting test tubes by the detector 2 one by one instead of manual work, the sealing cover plate 5 is for sealing the test tube placing mechanism 4, the chain transmission mechanism 6 is for supplying power to the lifting mechanism 7, the lifting mechanism 7 is for lifting the detector 2, the closing mechanism 8 is for closing the housing 1 and further protecting the detector 2, and the supporting mechanism 9 is for supporting the housing 1.

Specifically, referring to fig. 4-5, the housing 1 includes a first square hole 101, a first slide hole 102, a second slide hole 103, a first mounting hole 104, a mounting plate 105, a first supporting plate 106, a second square hole 107, and a second mounting hole 108, the first square hole 101 is disposed at the front end of the housing 1, the first slide hole 102 is disposed at the left and right ends of the housing 1, the second slide hole 103 is disposed at the rear end of the housing 1, the first mounting holes 104 are two, each first mounting hole 104 is disposed at the rear end of the housing 1, the mounting plate 105 is fixedly connected to the rear end of the housing 1, the first supporting plate 106 is fixedly connected to the left and right inner walls of the housing 1, and the second square hole 107 and the second mounting hole 108 are disposed at the upper side of the first supporting plate 106.

In the embodiment of the present invention, the first square hole 101 is for facilitating the movable insertion of the test tube box 401, the first sliding hole 102 is for facilitating the movable insertion of the closing cover plate 801, the second sliding hole 103 is for facilitating the sliding of the pulley 803, the first mounting hole 104 is for facilitating the movable penetration of the moving screw 301, the mounting plate 105 is for facilitating the fixing of the electric telescopic rod 804, the first support plate 106 is for facilitating the rotating connection with the lifting screw 701, the second square hole 107 is for facilitating the detection of the test tube by the detector 2, and the second mounting hole 108 is for facilitating the movable penetration of the output end of the third servo motor 604.

Specifically, referring to fig. 6, the accommodating mechanism 3 includes two movable screws 301, two movable nuts 302, two fixed blocks 303, a first servo motor 304, a driving pulley 305, two driven pulleys 306, a connecting belt 307 and a fixed plate 308, the two movable screws 301 are rotatably connected to the front inner wall of the housing 1, the movable screws 301 movably penetrate through the first mounting hole 104, the two movable nuts 302 are threadedly connected to the surface of the movable screws 301, the two fixed blocks 303 are fixedly connected to the opposite ends of the two movable nuts 302, the fixed plate 308 is fixedly connected to the lower end of the housing 1, the first servo motor 304 is fixedly connected to the rear end of the fixed plate 308, the two driving pulleys 305, the two driven pulleys 306 and the connecting belt 307 are respectively connected to the surface of the output end of the first servo motor 304, the two driven pulleys 306 are respectively fixedly connected to the surfaces of the two movable screws 301, the connecting belt 307 is sleeved on the surfaces of the driving pulley 305 and the driven pulley 306, and the driving pulley 305 and the driven pulley 306 are in transmission connection through the connecting belt 307.

In the embodiment of the present invention, the movable screw 301 is for screwing the movable nut 302, the movable nut 302 is for connecting the fixed block 303, the first servomotor 304 is for driving the driving pulley 305 to rotate, the driving pulley 305, the driven pulley 306 and the connecting belt 307 are for cooperating with each other, the connecting belt 307 is for driving the driving pulley 305 and the driven pulley 306, and the fixed plate 308 is for fixing the first servomotor 304.

Specifically, please refer to fig. 7-9, the test tube placing mechanism 4 includes a test tube box 401, a slot 402, a first rotating rod 403, a first gear 404, a gear belt 405, a stop ring 406, a second supporting plate 407, a stop sliding groove 408, a third mounting hole 409, a fixing rod 410, a test tube stop collar 411, an auxiliary sliding rod 412, a second servo motor 413 and a second gear 414, the test tube box 401 is fixedly connected between two fixing blocks 303, the slot 402 is arranged at the upper end of the test tube box 401, the first rotating rod 403, the first gear 404 and the stop ring 406, the first rotating rod 403 is rotatably connected to the lower inner wall of the test tube box 401, the first gear 404 and the stop ring 406 are both fixedly connected to the surface of the test tube box 401, the first rotating rod 403 is located at the lower side of the stop ring 406, the gear belt 405 is sleeved on the surfaces of the four first gears 404, the gear belt 405 is engaged with the four first gears 404, the second supporting plate 407 is arranged in the test tube placing mechanism 4, the stop sliding groove 408 is arranged at the surface of the second supporting plate 407, the third mounting hole is arranged as four movable mounting holes, the third mounting hole 409 is connected to the upper end of the sliding rod 410, the fixing rod 410, the sliding shaft 410 is arranged at the upper end of the stop sliding groove 411, the fixing rod 410, the auxiliary sliding groove 410, and the stop sliding groove 410, the fixing rod 410.

In the embodiment of the present invention, the test tube box 401 is for facilitating the rotation of the first rotating rod 403, the slot 402 is for facilitating the insertion of the sealing cover plate 5, the first rotating rod 403 is for facilitating the fixing of the first gear 404, the first gear 404 is for facilitating the cooperation with the gear belt 405, the stop ring 406 is for facilitating the supporting of the second support plate 407, the second support plate 407 is for facilitating the drilling of the stop sliding slot 408 and the third mounting hole 409, the stop sliding slot 408 is for facilitating the sliding of the auxiliary sliding rod 412, the third mounting hole 409 is for the movable penetration of the first rotating rod 403, the fixing rod 410 is for facilitating the rotation of the test tube stop collar 411, the test tube stop collar 411 is for facilitating the placement of the test tube, the auxiliary sliding rod 412 is for facilitating the cooperation with the stop sliding slot 408, the second gear 414 is for facilitating the fixing of the second servo motor 413, and the second servo motor 413 is for facilitating the rotation of driving the first gear 404.

Specifically, referring to fig. 10, the sealing cover plate 5 includes a holding groove 501 and a fourth mounting hole 502, the holding groove 501 and the fourth mounting hole 502 are opened at the upper end of the sealing cover plate 5, and the holding groove 501 is located at the front side of the fourth mounting hole 502.

In the embodiment of the present invention, the sealing cover 5 includes a holding groove 501 and a fourth mounting hole 502, the holding groove 501 and the fourth mounting hole 502 are opened at the upper end of the sealing cover 5, the holding groove 501 is located at the front side of the fourth mounting hole 502, the holding groove 501 is convenient for holding by hand, and the fourth mounting hole 502 is convenient for the detection instrument 2 to detect the test tube in the test tube box 401.

Specifically, referring to fig. 11, the chain transmission mechanism 6 includes four second rotating rods 601, four third gears 602, four chains 603, a third servo motor 604 and a fourth gear 605, the second rotating rods 601 and the third gears 602 are rotatably connected to the lower end of the first supporting plate 106, the third gear 602 is fixedly connected to the surface of the second rotating rod 601, the chains 603 are sleeved on the surfaces of the four third gears 602, the four third gears 602 are in transmission connection with each other through the chains 603, the third servo motor 604 is fixedly connected to the upper end of the first supporting plate 106, the output end of the third servo motor 604 movably penetrates through the second mounting hole 108, the fourth gear 605 is fixedly connected to the output end of the third servo motor 604, and the fourth gear 605 is engaged with the second rotating rod 601.

In the embodiment of the present invention, the second rotating rod 601 is for fixing the third gear 602, the third gear 602 is for cooperating with the chain 603, the third servo motor 604 is for driving the fourth gear 605 to rotate, and the fourth gear 605 is for driving the third gear 602 to rotate.

Specifically, referring to fig. 12, the lifting mechanism 7 includes a lifting screw 701, a lifting nut 702, square rods 703 and a third support plate 704, the lifting screw 701 and the lifting nut 702 are all four, the lifting screw 701 is rotatably connected to the upper end of the first support plate 106, the second rotating rod 601 movably penetrates through the lower end of the first support plate 106, the upper end of the second rotating rod 601 is fixedly connected to the lower end of the lifting screw 701, the lifting nut 702 is in threaded connection with the surface of the lifting screw 701, the number of the square rods 703 is two, each square rod 703 is fixedly connected between two lifting nuts 702, the third support plate 704 is fixedly connected between two square rods 703, the detector 2 is fixedly connected to the upper end of the third support plate 704, and a 5G communication module is disposed in the detector 2.

In an embodiment of the present invention, the lifting screw 701 is for facilitating the threaded connection of the lifting nut 702, the lifting nut 702 is for facilitating the surface of the lifting screw 701, the square rod 703 is for facilitating the fixation of the third support plate 704, the third support plate 704 is for facilitating the fixation of the detector 2, the 5G communication module (not shown in the figure) is for facilitating the transmission of 5G signals, and there are block link nodes, so configured, the detection system may perform corresponding signal transmission based on a 5G network and in a block link node environment, and it needs to be described that: it is common knowledge of those skilled in the art and does not belong to the technical problem to be solved by the present invention, so that the detailed description of the internal construction thereof will not be provided.

Specifically, referring to fig. 13, the closing mechanism 8 includes a closing cover plate 801, a circular rod 802, a pulley 803, an electric telescopic rod 804, a connecting rod 805 and an observation glass 806, the number of the closing cover plate 801, the circular rod 802, the pulley 803, the connecting rod 805 and the observation glass 806 are two, the closing cover plate 801 is slidably connected in the first sliding hole 102, the circular rod 802 is fixedly connected to the rear end of the closing cover plate 801, the pulley 803 is fixedly connected to the surface of the circular rod 802, the electric telescopic rod 804 is fixedly connected to the upper end of the mounting plate 105, the connecting rod 805 is movably hinged to the circular rod 802 and the connecting rod 805, and the observation glass 806 is fixedly connected in the closing cover plate 801.

In the embodiment of the present invention, the cover plate 801 is closed to facilitate closing the housing 1, the round bar 802 is used to facilitate fixing the pulley 803, the pulley 803 is used to facilitate reducing friction force when the cover plate 801 moves, the electric telescopic rod 804 is used to facilitate driving the connecting rod 805 to move up and down, the connecting rod 805 is used to facilitate driving the round bar 802 to move, and the observation glass 806 is used to facilitate observing the inside situation.

Specifically, referring to fig. 14, the supporting mechanism 9 includes four supporting legs 901 and two cross bars 902, the four supporting legs 901 are respectively and fixedly connected to four corners of the lower end of the housing 1, the two cross bars 902 are provided, and each cross bar 902 is fixedly connected between the two supporting legs 901.

In the embodiment of the present invention, the supporting legs 901 are for supporting the housing 1, and the cross bar 902 is for further improving stability.

The use method of the tumor cell radiosensitivity detection system based on 5G and the block chain comprises the following steps:

s1, detecting tumor cells in a test tube:

s11, moving the test tube box in front and outside: starting the first servo motor 304 to reversely rotate, reversely rotating the first servo motor 304 to reversely rotate the driving belt pulley 305, reversely rotating the driving belt pulley 305 to drive the movable screw 301 to reversely rotate through the mutual matching of the connecting belt 307 and the driven belt pulley 306, reversely rotating the movable screw 301 to enable the movable nut 302 to move forwards on the surface of the movable screw 301, moving the movable nut 302 to drive the test tube box 401 to move forwards through the fixed block 303, closing the first servo motor 304 when the movable nut 302 is in contact with the front inner wall of the shell 1, and completing the movement of the test tube box;

s12, placing a test tube to be detected: holding the sealing cover plate 5 by hand, taking the sealing cover plate 5 out of the slot 402, then sequentially placing the test tubes into the test tube stop collar 411, holding the sealing cover plate 5 by hand after placing the test tubes, and inserting the sealing cover plate 5 into the slot 402;

s13, moving the test tube box inwards: the test tube box can be moved into the shell 1 by the reverse operation according to the step S11;

s14, detecting test tubes one by one: the second gear 414 is started to rotate, the second servo motor 413 is driven to rotate positively by the positive rotation of the second gear 414, the first gear 404 is driven to rotate reversely by the positive rotation of the second servo motor 413, the gear belt 405 rotates reversely by the reverse rotation of the first gear 404, the test tube stop collar 411 moves intuitively and slowly by the reverse rotation of the gear belt 405, the test tubes are detected one by one through the detector 2, and the detection result is penetrated through the observation glass 806;

s2, overhauling the detector:

s21, opening and closing the mechanism: starting the electric telescopic rod 804 to extend, wherein the two connecting rods 805 are moved upwards by the extension of the electric telescopic rod 804, the two round rods 802 are moved towards the far side by the upward movement of the two connecting rods 805, the closed cover plate 801 is driven by the movement of the round rods 802 to move towards the far end of the two closed cover plates 801, the electric telescopic rod 804 is closed when the two pulleys 803 are in contact with the left inner wall and the right inner wall of the second sliding hole 103, and the pulleys 803 are used for reducing the friction force generated when the closed cover plate 801 moves;

s22, an ascending detector: the third servo motor 604 is started to rotate reversely, the fourth gear 605 rotates reversely by the reverse rotation of the third servo motor 604, the third gear 602 is driven to rotate positively by the reverse rotation of the fourth gear 605, the second rotating rod 601 rotates positively by the forward rotation of the third gear 602, the chain 603 rotates positively by the forward rotation of the third gear 602, the four third gears 602 rotate positively by the forward rotation of the chain 603, the lifting screw 701 rotates positively by the forward rotation of the second rotating rod 601, the lifting nut 702 moves upwards on the surface of the lifting screw 701 by the forward rotation of the lifting screw 701, the third support plate 704 is driven to move upwards by the movement of the lifting nut 702 through the square rod 703, and the detector 2 moves upwards by the upwards movement of the third support plate 704.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that changes may be made in the embodiments and/or equivalents thereof without departing from the spirit and scope of the invention. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (8)

1. A tumor cell radiosensitivity detection system based on 5G and a block chain is characterized by comprising: a housing (1); the detector (2) is arranged in the shell (1), and the detector (2) is used for detecting tumor cells; the containing mechanism (3), the containing mechanism (3) is arranged in the shell (1), and the containing mechanism (3) is positioned at the lower side of the detector (2); the test tube placing mechanism (4) is arranged in the shell (1), and the test tube placing mechanism (4) is connected with the storage mechanism (3); the sealing cover plate (5), the sealing cover plate (5) is arranged in the test tube placing mechanism (4), and the sealing cover plate (5) is used for sealing the test tube placing mechanism (4); the chain transmission mechanism (6) is arranged in the shell (1), and the chain transmission mechanism (6) is positioned at the lower side of the detector (2); the lifting mechanism (7) is arranged in the shell (1) and is positioned on the upper side of the accommodating mechanism (3), and the lifting mechanism (7) is used for lifting the detector (2); the closing mechanism (8), the closing mechanism (8) is arranged outside the shell (1), and the closing mechanism (8) is used for closing the shell (1); the supporting mechanism (9), the supporting mechanism (9) is arranged at the lower side of the shell (1), and the supporting mechanism (9) is used for supporting the shell (1); the test tube placing mechanism (4) comprises a test tube box (401), an inserting groove (402), a first rotating rod (403), a first gear (404), a gear belt (405), a limiting ring (406), a second supporting plate (407), a limiting sliding groove (408), a third mounting hole (409), a fixing rod (410), a test tube limiting sleeve (411), an auxiliary sliding rod (412), a second servo motor (413) and a second gear (414), wherein the test tube box (401) is fixedly connected between the two fixing blocks (303), the inserting groove (402) is formed in the upper end of the test tube box (401), the first rotating rod (403), the first gear (404) and the limiting ring (406) are fixedly connected to the lower inner wall of the test tube box (401), the first gear (404) and the limiting ring (406) are both fixedly connected to the surface of the test tube box (401), the first rotating rod (403) is located on the lower side of the limiting ring (406), the gear belt (405) is sleeved on the surfaces of the four first gears (404), the second gear (407) is meshed with the surface of the second supporting plate (408), and the second limiting sliding groove (408) is arranged in the supporting plate (408), third mounting hole (409) set up to four, the upper end in second backup pad (407) is seted up in third mounting hole (409), third mounting hole (409) is run through in first bull stick (403) activity, dead lever (410), test tube stop collar (411) and supplementary slide bar (412) all set up to a plurality ofly, dead lever (410) fixed connection is in the upper end of toothed belt (405), test tube stop collar (411) rotate to be connected in the surface of dead lever (410), supplementary slide bar (412) rotate to be connected in the surface of test tube stop collar (411), supplementary slide bar (412) sliding connection is in spacing spout (408).

2. The 5G and blockchain based tumor cell radiosensitivity detection system according to claim 1, wherein: shell (1) includes first square hole (101), first slide opening (102), second slide opening (103), first mounting hole (104), mounting panel (105), first backup pad (106), second square hole (107) and second mounting hole (108), the front end of shell (1) is seted up in first square hole (101), both ends about shell (1) are seted up in first slide opening (102), the rear end of shell (1) is seted up in second slide opening (103), first mounting hole (104) sets up to two, every the rear end of shell (1) is all seted up in first mounting hole (104), mounting panel (105) fixed connection is in the rear end of shell (1), inner wall about first backup pad (106) fixed connection is in shell (1), the upside of first backup pad (106) is all seted up in second square hole (107) and second mounting hole (108).

3. The 5G and blockchain based tumor cell radiosensitivity detection system according to claim 2, wherein: the accommodating mechanism (3) comprises a movable screw (301), a movable nut (302), two fixed blocks (303), two first servo motors (304), a driving belt pulley (305), two driven belt pulleys (306), two connecting belts (307) and a fixed plate (308), wherein the movable screw (301) is arranged into two, the movable screw (301) is connected to the front inner wall of the shell (1) in a rotating manner, the movable screw (301) penetrates through the first mounting hole (104), the movable nut (302) is arranged into two, the movable nut (302) is connected to the surface of the movable screw (301) in a threaded manner, the fixed blocks (303) are arranged into two, the two fixed blocks (303) are respectively and fixedly connected to the opposite ends of the two movable nuts (302), the fixed plate (308) is fixedly connected to the lower end of the shell (1), the first servo motor (304) is fixedly connected to the rear end of the fixed plate (308), the driving belt pulley (305), the driven belt pulleys (306) and the connecting belts (307) are arranged into two, the two driving belt pulleys (305) are respectively and fixedly connected to the surface of the first servo motor (304), the two driven belt pulleys (306) and the driven belt pulleys (306) are connected to the surface of the driven belt pulley (306), and the driving pulley (305) and the driven pulley (306) are in transmission connection through a connecting belt (307).

4. The 5G and blockchain based tumor cell radiosensitivity detection system according to claim 3, wherein: the sealing cover plate (5) comprises a holding groove (501) and a fourth mounting hole (502), the holding groove (501) and the fourth mounting hole (502) are arranged at the upper end of the sealing cover plate (5), and the holding groove (501) is located on the front side of the fourth mounting hole (502).

5. The 5G and blockchain based tumor cell radiosensitivity detection system according to claim 4, wherein: the chain transmission mechanism (6) comprises a second rotating rod (601), a third gear (602), a chain (603), a third servo motor (604) and a fourth gear (605), the number of the second rotating rod (601) and the number of the third gear (602) are four, the second rotating rod (601) is rotatably connected to the lower end of the first supporting plate (106), the third gear (602) is fixedly connected to the surface of the second rotating rod (601), the chain (603) is sleeved on the surfaces of the four third gears (602), the four third gears (602) are in transmission connection through the chain (603), the third servo motor (604) is fixedly connected to the upper end of the first supporting plate (106), the output end of the third servo motor (604) movably penetrates through the second mounting hole (108), the fourth gear (605) is fixedly connected to the output end of the third servo motor (604), and the fourth gear (605) is meshed with the second rotating rod (601).

6. The 5G and blockchain based tumor cell radiosensitivity detection system according to claim 5, wherein: elevating system (7) are including lifting screw (701), lifting nut (702), square pole (703) and third backup pad (704), lifting screw (701) and lifting nut (702) all set up to four, lifting screw (701) rotate to be connected in the upper end of first backup pad (106), the lower extreme of first backup pad (106) is run through in second bull stick (601) activity, and the upper end fixed connection of second bull stick (601) is in the lower extreme of lifting screw (701), lifting nut (702) threaded connection is in the surface of lifting screw (701), square pole (703) set up to two, every equal fixed connection of square pole (703) is between two lifting nut (702), third backup pad (704) fixed connection is between two square poles (703), detector (2) fixed connection is in the upper end of third backup pad (704), be provided with 5G communication module in detector (2).

7. The 5G and blockchain based tumor cell radiosensitivity detection system according to claim 6, wherein: the closing mechanism (8) comprises a closing cover plate (801), a round rod (802), a pulley (803), an electric telescopic rod (804), a connecting rod (805) and observation glass (806), the closing cover plate (801), the round rod (802), the pulley (803), the connecting rod (805) and the observation glass (806) are arranged in two, the closing cover plate (801) is connected in a first sliding hole (102) in a sliding mode, the round rod (802) is fixedly connected to the rear end of the closing cover plate (801), the pulley (803) is fixedly connected to the surface of the round rod (802), the electric telescopic rod (804) is fixedly connected to the upper end of the mounting plate (105), the connecting rod (805) is movably hinged to the round rod (802) and the connecting rod (805) through hinge shafts, and the observation glass (806) is fixedly connected to the closing cover plate (801).

8. The 5G and blockchain based tumor cell radiosensitivity detection system according to claim 7, wherein: the supporting mechanism (9) comprises supporting legs (901) and cross rods (902), the number of the supporting legs (901) is four, the four supporting legs (901) are respectively and fixedly connected to four corners of the lower end of the shell (1), the number of the cross rods (902) is two, and each cross rod (902) is fixedly connected between the two supporting legs (901).

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