CN116656480B

CN116656480B - Medical science inspection microorganism cultivates equipment

Info

Publication number: CN116656480B
Application number: CN202310601951.3A
Authority: CN
Inventors: 徐泽; 李婷; 韩毅; 曹文婷
Original assignee: Wuxi Center for Disease Control and Prevention
Current assignee: Wuxi Center for Disease Control and Prevention
Priority date: 2023-05-25
Filing date: 2023-05-25
Publication date: 2024-03-15
Anticipated expiration: 2043-05-25
Also published as: CN116656480A

Abstract

The invention relates to the technical field of microorganism culture, in particular to medical inspection microorganism culture equipment. The utility model provides a medical science inspection microorganism cultivates equipment, includes the bottom plate, and the top fixedly connected with of bottom plate cultivates the frame, cultivates the bilateral symmetry of frame and has seted up two and run through the groove, and the inner peripheral wall that runs through the groove is provided with spacing axle, and the periphery wall fixedly connected with connecting rod of spacing axle, the beneficial effect of the invention is: this medical science inspection microorganism cultivates equipment can be after the connecting rod rotates along with the lift of elevating platform, change the crooked radian of luminescent light board place height and luminescent light board to make the light that luminescent light board sent can assemble a certain position department on the elevating platform all the time, thereby can cultivate the microorganism continuously at the equipment and make microorganism's weight and volume change after, guarantee that the microorganism can feel abundant light and temperature, guarantee that the light condition and the temperature that the microorganism received are in invariable state simultaneously.

Description

Medical science inspection microorganism cultivates equipment

Technical Field

The invention relates to the technical field of microorganism culture, in particular to medical inspection microorganism culture equipment.

Background

Microorganism culture detection, inoculating a sample into one or more culture flasks or culture tubes for finding and identifying bacteria or other culturable microorganisms, detecting microorganisms in the blood of a patient is of clinical significance for diagnosis, treatment and prognosis of infectious diseases, and medical examination often requires examination and observation through culturing microorganisms or corresponding bacteria, so that development of procedures such as immune clinical treatment and medical care is carried out, and therefore effective culture of various bacterial microorganisms in clinical laboratory is important. The biological incubator widely applied in various fields at present is mostly in a box body with a heat insulation function, and the constant temperature in the box body is kept through repeated and alternative work of a refrigerating device and a heating device so as to meet the temperature required by various experiments and the optimal environment required by the generation and growth of the cultivated objects.

During the cultivation of the microorganism, the volume of the microorganism itself changes, and the light conditions to which the microorganism is subjected at this time change.

The existing medical test microorganism culture equipment is difficult to correspondingly adjust the light irradiated by the equipment along with the change of the volume of microorganisms, so that the microorganisms are easy to influence the effective culture of the equipment on the microorganisms because of different light conditions received by the microorganisms in the growth process.

Disclosure of Invention

Aiming at the technical problems in the prior art, the invention provides medical test microorganism culture equipment which solves the problem that the traditional medical test microorganism culture equipment is difficult to correspondingly adjust the light irradiated by microorganisms along with the change of the microorganism volume.

The technical scheme for solving the technical problems is as follows: the utility model provides a medical science inspection microorganism cultivates equipment, the on-line screen storage device comprises a base plate, the top fixedly connected with cultivation frame of bottom plate, two through grooves have been seted up to the bilateral symmetry of cultivateing the frame, the inner peripheral wall of through groove is provided with spacing axle, the periphery wall fixedly connected with connecting rod of spacing axle, one of them end fixedly connected with luminescent light board of connecting rod, be provided with a plurality of lamp strips in the luminescent light board, be provided with a plurality of lamp pearls in a plurality of lamp strips, the articulated telescopic sleeve that is connected with of other one end of connecting rod, the screw thread groove has been seted up in the telescopic sleeve, the inner peripheral wall threaded connection of screw thread groove has the lead screw, the tip of lead screw is provided with electric motor, electric motor's output shaft tip and lead screw fixed connection.

The beneficial effects of the invention are as follows:

1) The monitoring device for freeze thawing and sedimentation has better effect, the invention is improved on the basis of the prior art, and the height of the luminous lamp panel and the bending radian of the luminous lamp panel can be changed after the connecting rod rotates along with the lifting of the lifting platform, so that the light rays emitted by the luminous lamp panel can be always converged at a certain position on the lifting platform, and the microorganism can be ensured to feel sufficient light rays and temperature after the weight and the volume of the microorganism are changed due to continuous cultivation of the microorganism by the equipment.

2) Meanwhile, the light condition and the temperature of the microorganism are ensured to be in a constant state.

On the basis of the technical scheme, the invention can be improved as follows.

Further, cultivate the internal perisporium symmetry of frame and be provided with four dead levers, the equal cover of peripheral wall of four dead levers is connected with the lantern ring, and the periphery wall fixedly connected with elevating platform of lantern ring, the bottom of elevating platform are provided with the elastic component, one side fixedly connected with connecting block of electric motor, connecting block and elevating platform fixed connection.

The lifting platform has the beneficial effects that the lifting platform can be moved along the fixed rod in the moving process while the fixed rod limits the lifting platform, and then under the action of the elastic piece, the lifting platform can have upward bouncing acting force after the microbial volume and the weight at the top of the lifting platform are reduced, so that the lifting platform and the luminous lamp panel can interact.

Further, servo motor is fixedly connected with in the middle of the top of elevating platform, servo motor's output shaft end fixedly connected with carousel, the top fixedly connected with cultivation household utensils of carousel, the inner peripheral wall symmetry of cultivation household utensils is provided with two ventilation fans, two wind grooves have been seted up to the symmetry in the cultivation household utensils, two wind grooves respectively with two ventilation fan UNICOM, the equal fixedly connected with ventilation pipe of inner peripheral wall of two wind grooves, the tip of ventilation pipe is provided with flexible hose, flexible hose's tip is provided with the joint, the one end of joint is provided with gas configuration subassembly.

The air duct is connected with the air configuring assembly through the ventilating pipe, the ventilating fan can convey air configured by the air configuring assembly into the culture vessel for microorganisms after operation, and the air is sucked by the other ventilating fan and is reconfigured by the air configuring assembly so as to ensure normal use of the air and circulate in the culture vessel.

Further, the inner peripheral wall of cultivateing the frame is provided with the sensor, and one side of sensor is provided with microprocessor, and a distance sensing piece is respectively embedded to the both sides of luminescent light board, and two distance sensing pieces and sensor looks adaptation.

The beneficial effect of adopting above-mentioned further scheme is, can be according to the distance information of two distance sensing spare respectively with the sensor, obtain the angle that the luminescent light board leaned on after carrying out the analysis by microprocessor, and two electric motor then can control the height that luminescent light board both sides are located respectively, and then can make the sensor sense behind microorganism locate position and the size, carry out corresponding pivoted effect through microprocessor control two electric motor and go on changing the inclination of luminescent light board, so that it can shine light on microorganism accurately.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present invention;

FIG. 2 is a schematic view of the front cross-sectional structure of the present invention;

FIG. 3 is a schematic view of a partial top view cross-section of the present invention;

FIG. 4 is a schematic diagram showing a cross-sectional structure of a front surface of a culture vessel according to the present invention;

FIG. 5 is an enlarged schematic view of FIG. 2A;

FIG. 6 is a schematic top sectional view of a culture vessel according to the present invention;

fig. 7 is a schematic flow chart of a system for controlling the inclination angle of a light-emitting lamp panel according to the present invention.

In the drawings, the list of components represented by the various numbers is as follows:

1. a bottom plate; 2. culturing the outer frame; 201. a through groove; 202. a limiting shaft; 203. a connecting rod; 204. a light emitting lamp panel; 2041. a light bar; 2042. a lamp bead; 2043. a distance sensor; 205. a telescoping sleeve; 2051. a thread groove; 2052. a screw rod; 2053. an electric motor; 206. a connecting block; 3. a fixed rod; 301. a collar; 302. a lifting table; 303. an elastic member; 304. a servo motor; 305. a turntable; 4. a culture vessel; 401. a ventilation fan; 402. a wind groove; 403. a ventilation pipe; 404. a gas configuration assembly; 405. a flexible hose; 406. a ventilation joint; 5. a sensor; 6. and a microprocessor.

Detailed Description

The principles and features of the present invention are described below with reference to the drawings, the examples are illustrated for the purpose of illustrating the invention and are not to be construed as limiting the scope of the invention.

Microorganism culture testing, inoculating a sample into one or more flasks or tubes to discover, identify bacteria or other culturable microorganisms, and detecting microorganisms in the blood of a patient is of clinical importance for diagnosis, treatment and prognosis of infectious diseases, a medical test microorganism culture apparatus has been proposed by the inventors to solve the above-mentioned problems.

The present invention provides the following preferred embodiments

As shown in fig. 1-6, a medical examination microorganism culture device comprises a bottom plate 1, a culture outer frame 2 is fixedly connected to the top of the bottom plate 1, two through grooves 201 are symmetrically arranged on two sides of the culture outer frame 2, a limiting shaft 202 is arranged on the inner peripheral wall of the through groove 201, a connecting rod 203 is fixedly connected to the outer peripheral wall of the limiting shaft 202, a light-emitting lamp plate 204 is fixedly connected to one end of the connecting rod 203, a plurality of lamp strips 2041 are arranged in the light-emitting lamp plate 204, a plurality of lamp beads 2042 are arranged in the plurality of lamp strips 2041, a telescopic sleeve 205 is hinged to the other end of the connecting rod 203, a threaded groove 2051 is formed in the telescopic sleeve 205, a screw rod 2052 is connected to the inner peripheral wall of the threaded groove 2051 in a threaded manner, an electric motor 2053 is arranged at the end part of the screw rod 2052, the output shaft end part of the electric motor 2053 is fixedly connected with the screw rod 2052, the through groove 201 is arranged on two sides of the culture outer frame 2, and a limiting shaft 202 is arranged on the inner peripheral wall of the through groove 201, and then the limiting shaft 202 is connected with the connecting rod 203, so that the connecting rod 203 can rotate by taking the limiting shaft 202 as the center of a circle, then one end of the connecting rod 203 is mutually fixed with the light-emitting lamp panel 204, the other end of the connecting rod 203 is hinged with the telescopic sleeve 205, the telescopic sleeve 205 is connected with the connecting block 206 through the screw rod 2052 and the electric motor 2053, and the connecting block 206 is fixed on the lifting platform 302, thus the connecting rod 203 can be indirectly driven to rotate after the height of the lifting platform 302 changes, the height of the light-emitting lamp panel 204 can be changed, meanwhile, as the distance between the limiting shaft 202 and the end part of the connecting rod 203 (namely the connecting part of the connecting rod 203 and the light-emitting lamp panel 204) is unchanged, and the end part distance between the two groups of connecting rods 203 can rotate along with the rotation of the connecting rod 203 after the inclination angle of the connecting rod 203 changes, in addition, the light bar 2041 having a bar shape is disposed in the light-emitting light panel 204, and the material of the light-emitting light panel 204 is soft, so that both sides of the light-emitting light panel 204 are fixed with the two connecting rods 203 respectively, after the end intervals of the two connecting rods 203 change, the light-emitting light panel 204 can bend, and the bending amplitude changes with the change of the end intervals of the two connecting rods 203, i.e. when the lifting platform 302 descends, the connecting part of the connecting rods 203 and the light-emitting light panel 204 moves upwards after rotating, and the end intervals of the two connecting rods 203 expand, so that the bending amplitude of the light-emitting light panel 204 at this time becomes larger, i.e. the arc radius formed after bending becomes larger, thereby the point where the light sources emitted by the light-emitting light panel 204 in the arc state converge is downwards deflected, and corresponds to the downward phase shift of the lifting platform 302, and similarly, when the lifting platform 302 ascends, the radius of the light-emitting lamp panel 204 can be indirectly reduced, the point where the light beams of the light-emitting lamp panel 204 are converged is close to the light-emitting lamp panel 204, and the distance between the lifting platform 302 and the light-emitting lamp panel 204 is reduced at this time, so that after the connecting rod 203 correspondingly rotates along with the lifting platform 302, the light-emitting lamp panel 204 is correspondingly bent, the bending amplitude corresponds to the lifting amplitude of the lifting platform 302, and then based on the bending amplitude, the light generated by the lamp beads 2042 arranged in the light-emitting lamp panel 204 is always converged on the microorganism for illumination or heating, and can change along with the growth of the microorganism, namely the weight change of the microorganism, after the change of the lifting platform 302, the light or the temperature received by the microorganism is ensured to be in a stable state, thereby improving the cultivation effect of the microorganism by the device, and on the basis of the telescopic sleeve 205, after the threaded groove 2051 formed in the telescopic sleeve 205 is connected with the screw rod 2052, the screw rod 2052 is fixed with the end part of the output shaft of the electric motor 2053, so that the electric motor 2053 can drive the screw rod 2052 to rotate after running, then under the action of the threaded connection relation between the screw rod 2052 and the telescopic sleeve 205, the distance between the telescopic sleeve 205 and the connecting block 206 is changed, so that a user can correspondingly adjust the rotation amplitude of the connecting rod 203 and the lifting amplitude of the lifting platform 302 according to the rotation amplitude and the volume variation amplitude of the microorganisms, the rotation amplitude of the connecting rod 203 and the lifting amplitude of the lifting platform 302 can be adjusted according to the weight variation amplitude and the volume variation amplitude of the microorganisms, and therefore, by the light-emitting lamp panel 204 can be changed after the connecting rod 203 rotates along with the lifting of the lifting platform 302, the height of the light-emitting lamp panel 204 and the bending radian of the light-emitting lamp panel 204 can be always converged at a certain position on the lifting platform 302, and the light emitted by the light-emitting lamp panel 204 can be continuously cultured by the device, so that the weight and the volume of the microorganisms can be ensured to be changed, and the temperature of the microorganisms can be prevented from being influenced or the light can be fully influenced by the light.

In this embodiment, as shown in fig. 1, 2 and 5, in order to further improve the self-adaptive effect of the medical test microorganism culture apparatus, four fixing rods 3 are symmetrically disposed on the inner peripheral wall of the culture outer frame 2, the outer peripheral walls of the four fixing rods 3 are all sleeved with a collar 301, the outer peripheral wall of the collar 301 is fixedly connected with a lifting platform 302, the bottom of the lifting platform 302 is provided with an elastic member 303, one side of the electric motor 2053 is fixedly connected with a connecting block 206, the connecting block 206 is fixedly connected with the lifting platform 302, the four fixing rods 3 are respectively disposed at four corners in the culture outer frame 2, then the collar 301 is disposed on the outer peripheral wall of the fixing rod 3, the collar 301 is fixed with the lifting platform 302, and after the lifting platform 302 is connected with the fixing rods 3 through the collar 301, the lifting platform 302 can be limited, and the lifting platform 302 can move along the fixing rods 3, then the bottom of the lifting platform 302 is provided with an elastic member 303, so that the lifting platform 302 can have upward bouncing force after the microorganism volume and weight at the top of the lifting platform 302 are reduced, and the lifting platform 204 can interact with the light-emitting plate 204.

In this embodiment, as shown in fig. 1, 2, 4 and 6, in order to further enhance the auxiliary effect of the device on the cultivation of the medical test microorganism, a servo motor 304 is fixedly connected in the middle of the top of the lifting platform 302, the end of the output shaft of the servo motor 304 is fixedly connected with a turntable 305, a cultivation vessel 4 is fixedly connected at the top of the turntable 305, two ventilation fans 401 are symmetrically arranged on the inner peripheral wall of the cultivation vessel 4, two ventilation slots 402 are symmetrically arranged in the cultivation vessel 4, the two ventilation slots 402 are respectively communicated with the two ventilation fans 401, ventilation pipes 403 are fixedly connected on the inner peripheral wall of the two ventilation slots 402, a telescopic hose 405 is arranged at the end of the ventilation pipe 403, a connector 406 is arranged at the end of the telescopic hose 405, a gas configuration component 404 is arranged at one end of the connector 406, the gas configuration component 404 is communicated with the two ventilation fans 401 through the two ventilation pipes 403 and the two ventilation slots 402, the servo motor 304 is fixed on the lifting table 302 and then fixed with the culture vessel 4 by the turntable 305, thus the culture vessel 4 can be rotated to ninety degrees after the servo motor 304 is operated, and can be reversed and restored to the original position after the rotation is completed, namely microorganisms in the culture vessel 4 can be adjusted between the transverse direction and the longitudinal direction by the servo motor, then two ventilation fans 401 are arranged on the inner peripheral wall of the culture vessel 4, the directions of the gases flowing through the two ventilation fans 401 after the operation are the same, then the air grooves 402 are respectively arranged at the opposite positions of the two ventilation fans 401, the air grooves 402 are connected with the gas configuration assembly 404 by the ventilation pipe 403, the telescopic hose 405 and the connector 406, so that the ventilation fans 401 can convey the gases configured by the gas configuration assembly 404 into the culture vessel 4 for use by the microorganisms after the operation, then is inhaled by another ventilation fan 401 and is reconfigured by the gas configuration component 404 so as to ensure that gas can circulate in the culture vessel 4 while being used normally, and meanwhile, in the process of rotating the culture vessel 4, as the telescopic hose 405 is in an arc shape and the radian is larger than the rotating amplitude of the culture vessel 4, the rotating amplitude of the culture vessel 4 can be buffered through the telescopic hose 405 so as to assist the culture vessel 4 to rotate, and after the culture vessel 4 has a rotating function, the irradiation angle of the luminescent lamp panel 204 can be adjusted by the auxiliary microprocessor 6 of the culture vessel 4, so that the microorganism can conveniently adjust the growth direction of the microorganism to be longitudinal in a mode of driving the culture vessel 4 to rotate when the luminescent lamp panel 204 cannot be completely irradiated on the microorganism due to overlarge size of the microorganism in transverse growth.

In this embodiment, as shown in fig. 1, fig. 2 and fig. 7, in order to further improve the auxiliary effect of the device on the cultivation of the medical test microorganism, the inner peripheral wall of the cultivation outer frame 2 is provided with a sensor 5, one side of the sensor 5 is provided with a microprocessor 6, two sides of the light-emitting lamp plate 204 are respectively embedded with a distance sensor 2043, two distance sensors 2043 are adapted to the sensor 5, the sensor 5 is disposed on the inner peripheral wall of the cultivation outer frame 2 and is directly above the light-emitting lamp plate 204, and then is connected with the microprocessor 6 in a linear relationship, meanwhile, after the microprocessor 6 is in signal connection with the sensor 5, the two distance sensors 2043 can be respectively connected with the sensor 5 according to distance information of the two distance sensors 2043, after the microprocessor 6 analyzes, the inclined angle of the light-emitting lamp plate 204 is obtained, the two electric motors 2053 can respectively control the heights of the two sides of the light-emitting lamp plate 204, and then the sensor 5 can accurately sense the inclined angle of the light-emitting lamp plate 204 by controlling the two electric motors 2053 after the position of the sensor 6 and the two telescopic sleeves 205, and the corresponding inclination angle of the light-emitting lamp plate can be changed by the micro-irradiation of the light.

The specific working process of the invention is as follows:

(1) Placing microorganisms in the culture vessel 4 by a user

First, microorganisms are placed in the culture vessel 4 by a user, and then the gas culture assembly 404 and the ventilation fan 401 are controlled to operate so that the culture vessel 4 can supply the microorganisms with a desired gas;

(2) Controlling the light-emitting lamp panel 204 to emit light and enabling the light to be concentrated on microorganisms

Then, the user controls the light-emitting lamp panel 204 to emit light, and the emitted light is converged at the position where the microorganism is located, so that the microorganism can grow under the corresponding light and temperature conditions.

(3) Height of the elevating platform 302 is changed by gravity of the microorganism itself

After the microorganism grows to change its gravity and volume, the height of the lifting platform 302 can be changed correspondingly, and the connecting rod 203 is driven to rotate by the connecting block 206.

(4) The connecting rod 203 drives the light-emitting lamp panel 204 to correspondingly change

Finally, after the connecting rods 203 rotate, the connecting rods 203 and the light-emitting lamp panels 204 are driven to lift and change the bending amplitude of the light-emitting lamp panels 204 by the height change of the connecting parts of the connecting rods 203 and the light-emitting lamp panels 204 and the distance between the end parts of the two connecting rods 203, so that the light rays emitted by the light-emitting lamp panels 204 after bending can be converged at the positions of microorganisms.

To sum up: the invention has the advantages that the structure is improved on the basis of the prior art, the medical test microorganism culture equipment has better effect, the through groove 201 is arranged at two sides of the culture outer frame 2, the limiting shaft 202 is arranged at the inner peripheral wall of the through groove 201, then the limiting shaft 202 is connected with the connecting rod 203, so that the connecting rod 203 can rotate by taking the limiting shaft 202 as the center of a circle, then one end of the connecting rod 203 is mutually fixed with the luminous lamp plate 204, the other end of the connecting rod 203 is hinged with the telescopic sleeve 205, the telescopic sleeve 205 is connected with the connecting block 206 through the screw rod 2052 and the electric motor 2053, the connecting block 206 is fixed on the lifting table 302, thus the connecting rod 203 can be indirectly driven to rotate after the height of the lifting table 302 is changed, and the height of the luminous lamp plate 204 is changed, meanwhile, as the distance between the limiting shaft 202 and the end parts of the connecting rods 203 (i.e. the connection parts of the connecting rods 203 and the light-emitting lamp plates 204) is unchanged, and the pitch of the end parts of the connecting rods 203 can rotate along with the rotation of the connecting rods 203 after the change of the inclination angle of the connecting rods 203, and the light-emitting lamp plates 204 are internally provided with the strip-shaped lamp bars 2041, the self material of the light-emitting lamp plates 204 is softer, so that the two sides of the light-emitting lamp plates 204 are respectively fixed with the two connecting rods 203, after the pitch of the end parts of the two connecting rods 203 is changed, the light-emitting lamp plates 204 can be bent, and the bending amplitude changes along with the change of the pitch of the end parts of the two connecting rods 203, namely, when the lifting table 302 is lowered, the connection parts of the connecting rods 203 and the light-emitting lamp plates 204 are moved upwards, and the pitch of the end parts of the two connecting rods 203 is enlarged, the bending amplitude of the light-emitting lamp plates 204 is enlarged, namely the bending radius formed after bending is enlarged, accordingly, the point where the light source emitted by the light-emitting lamp panel 204 in the arc state converges can be shifted downward and corresponds to the downward phase shift of the elevating platform 302, and in the same way, when the elevating platform 302 ascends, the radius of the light-emitting lamp panel 204 can be indirectly reduced, the point where the light beam of the light-emitting lamp panel 204 converges is close to the light-emitting lamp panel 204, and the distance between the elevating platform 302 and the light-emitting lamp panel 204 is reduced at the same time, so that after the connecting rod 203 correspondingly rotates along with the elevating platform 302, the light-emitting lamp panel 204 is correspondingly bent, the bending amplitude corresponds to the elevating amplitude of the elevating platform 302, and then, based on the bending amplitude, the light generated by the lamp beads 2042 arranged in the light-emitting lamp panel 204 always converges on the microorganism for illumination or heating, and can change along with the growth of the microorganism, namely the weight change of the microorganism after the change of the elevating platform 302, the light or temperature of the microorganism is ensured to be in a stable state, so that the cultivation effect of the device on the microorganism can be improved, on the basis of the telescopic sleeve 205, after the threaded groove 2051 formed in the telescopic sleeve 205 is connected with the screw rod 2052, the screw rod 2052 is fixed with the end part of the output shaft of the electric motor 2053, so that the electric motor 2053 can drive the screw rod 2052 to rotate after running, then under the action of the threaded connection relation between the screw rod 2052 and the telescopic sleeve 205, the distance between the telescopic sleeve 205 and the connecting block 206 is changed, so that a user can correspondingly adjust the rotation amplitude of the connecting rod 203 and the lifting amplitude of the lifting platform 302 according to the weight change amplitude and the volume change amplitude of the microorganism, so that the rotation amplitude of the connecting rod 203 and the lifting amplitude proportion of the lifting platform 302 can be adjusted according to the weight change amplitude and the volume change amplitude of the microorganism, after the connecting rod 203 rotates along with the lifting of the lifting platform 302, the height of the light-emitting lamp panel 204 and the bending radian of the light-emitting lamp panel 204 can be changed, so that the light emitted by the light-emitting lamp panel 204 can be always converged at a certain position on the lifting platform 302, and the microorganism can be ensured to feel sufficient light and temperature after the weight and the volume of the microorganism are changed due to continuous cultivation of the microorganism by the equipment, so that the growth of the microorganism is prevented from being influenced after the light or the temperature is changed.

When the structure is used, four fixing rods 3 are respectively arranged at four corners in the culture shell 2, then a lantern ring 301 is arranged at the peripheral wall of the fixing rod 3, the lantern ring 301 is fixed with a lifting platform 302, the lifting platform 302 is connected with the fixing rod 3 through the lantern ring 301, the lifting platform 302 can be limited, the lifting platform 302 moves along the fixing rod 3 in the moving process, and then an elastic piece 303 is arranged at the bottom of the lifting platform 302, so that the lifting platform 302 can have upward bouncing acting force after the microbial volume and weight at the top of the lifting platform are reduced, and the lifting platform 302 and the luminous lamp panel 204 can interact;

when the structure is used, the culture vessel 4 is fixed at the top of the lifting platform 302, two ventilation fans 401 are arranged on the inner peripheral wall of the culture vessel 4, the directions of the two ventilation fans 401 can enable gas to circulate after operation are the same, then air grooves 402 are respectively arranged at the opposite positions of the two ventilation fans 401, the air grooves 402 are connected with a gas configuration assembly 404 through ventilation pipes 403, so that the ventilation fans 401 can convey gas configured by the gas configuration assembly 404 into the culture vessel 4 for microorganism use after operation, and then the other ventilation fans 401 can suck and reconfigure the gas configuration assembly 404 to ensure normal use of the gas and simultaneously circulate in the culture vessel 4.

When the structure is used, the sensor 5 is arranged on the inner peripheral wall of the culture shell 2 and is positioned right above the light-emitting lamp panel 204, then the sensor 5 is connected with the microprocessor 6 in a linear relation, meanwhile, the microprocessor 6 is electrically connected with the two electric motors 2053 in the two telescopic sleeves 205, and as the two distance sensing pieces 2043 are in signal connection with the sensor 5, the inclined angle of the light-emitting lamp panel 204 can be obtained according to the distance information of the two distance sensing pieces 2043 and the sensor 5 after the two distance sensing pieces 2043 are analyzed by the microprocessor 6, the two electric motors 2053 can respectively control the heights of the two sides of the light-emitting lamp panel 204, and then the inclination angle of the light-emitting lamp panel 204 can be changed by controlling the corresponding rotating action of the two electric motors 2053 through the microprocessor 6 after the position and the body shape of the microorganism are sensed, so that the light can be accurately irradiated on the microorganism.

The invention is improved on the basis of the prior art, and the height of the light-emitting lamp panel and the bending radian of the light-emitting lamp panel can be changed after the connecting rod rotates along with the lifting of the lifting table, so that the light rays emitted by the light-emitting lamp panel can be always converged at a certain position on the lifting table, and the microorganism can be ensured to feel sufficient light rays and temperature after the weight and the volume of the microorganism are changed due to continuous cultivation of the microorganism by the equipment.

The foregoing description of the preferred embodiments of the invention is not intended to limit the invention to the precise form disclosed, and any such modifications, equivalents, and alternatives falling within the spirit and scope of the invention are intended to be included within the scope of the invention.

Claims

1. The utility model provides a medical science inspection microorganism cultivates equipment, its characterized in that includes bottom plate (1), the top fixedly connected with of bottom plate (1) cultivates frame (2), two run through groove (201) have been seted up to the bilateral symmetry of cultivateing frame (2), the inner peripheral wall of run through groove (201) is provided with spacing axle (202), the periphery wall fixedly connected with connecting rod (203) of spacing axle (202), one of them end fixedly connected with luminescent light plate (204) of connecting rod (203); a plurality of lamp strips (2041) are arranged in the light-emitting lamp plate (204), and a plurality of lamp beads (2042) are arranged in the lamp strips (2041); the other end of the connecting rod (203) is hinged with a telescopic sleeve (205), a thread groove (2051) is formed in the telescopic sleeve (205), a screw rod (2052) is connected with the inner peripheral wall of the thread groove (2051) in a threaded mode, an electric motor (2053) is arranged at the end portion of the screw rod (2052), and the end portion of an output shaft of the electric motor (2053) is fixedly connected with the screw rod (2052); four fixing rods (3) are symmetrically arranged on the inner peripheral wall of the culture outer frame (2), lantern rings (301) are sleeved on the outer peripheral walls of the four fixing rods (3), lifting platforms (302) are fixedly connected to the outer peripheral walls of the lantern rings (301), and elastic pieces (303) are arranged at the bottoms of the lifting platforms (302); one side of the electric motor (2053) is fixedly connected with a connecting block (206), and the connecting block (206) is fixedly connected with the lifting table (302).

2. The medical examination microorganism culture equipment according to claim 1, wherein a servo motor (304) is fixedly connected in the middle of the top of the lifting table (302), a rotary table (305) is fixedly connected to the end part of an output shaft of the servo motor (304), a culture vessel (4) is fixedly connected to the top of the rotary table (305), and two ventilation fans (401) are symmetrically arranged on the inner peripheral wall of the culture vessel (4).

3. The medical test microorganism culture equipment according to claim 2, wherein two air grooves (402) are symmetrically formed in the culture vessel (4), the two air grooves (402) are respectively communicated with the two ventilation fans (401), and ventilation pipes (403) are fixedly connected to the inner peripheral walls of the two air grooves (402); the end of ventilation pipe (403) is provided with flexible hose (405), the end of flexible hose (405) is provided with joint (406), the one end of joint (406) is provided with gas configuration subassembly (404).

4. A medical test microorganism culture apparatus according to claim 1, wherein the inner peripheral wall of the culture casing (2) is provided with a sensor (5), and one side of the sensor (5) is provided with a microprocessor (6).

5. The medical test microorganism culture apparatus according to claim 4, wherein a distance sensor (2043) is embedded in each of both sides of the light-emitting lamp panel (204), and the two distance sensors (2043) are adapted to the sensor (5).