CN212164321U - Transparent root system cultivation container photographing system - Google Patents

Abstract

The invention relates to a transparent root system cultivation container photographing system which comprises an imaging area, wherein the imaging area comprises an imaging platform, a rotary photographing device, an outer pipe photographing camera and a clamping moving assembly; the rotary photographing device: imaging the root system of the inner wall of the transparent root system cultivation container to be observed on the imaging platform; the camera for photographing the outer tube: imaging the root system of the outer wall of the transparent root system cultivation container to be observed on the imaging platform; clamping and moving assembly: the imaging platform is used for transporting the transparent root system cultivation container to be observed to the imaging platform from the sample injection area, and transporting the imaged transparent root system cultivation container to the sample injection area from the imaging platform. According to the invention, the rotary photographing device and the outer tube photographing camera are arranged in the imaging area, so that the inner wall and the outer wall of each transparent root system cultivation container can be automatically imaged simultaneously, and the crop root system image can be obtained through omnibearing, multi-angle and automatic real-time monitoring.

Description

Transparent root system cultivation container photographing system

Technical Field

The invention relates to a photographing system for dynamic growth of a root system, in particular to a photographing system for a transparent root system cultivation container.

Background

The research of gene-environment-phenotype interaction mechanism needs to be assisted by modern information technology taking big data as core. With the improvement of sequencing technology efficiency and the reduction of cost, crop genome data is continuously increased and improved; however, the current phenotype information acquisition technology lags behind, so that huge genomics data cannot be matched with the phenotype information acquisition technology, and the breeding process is seriously hindered. The construction of automatic equipment with lossless, efficient and systematic collection of phenotype group information becomes a hotspot problem to be solved urgently in agriculture, plant physiology, genetic breeding and the like.

In recent years, many academic institutions and enterprises have been devoted to the development of phenotypic assay platforms. At present, the overground phenotype measuring technology is mature, and most of the overground phenotype measuring technology is based on a conveyor belt running mode of a 'Plant-to-Sensor' and is combined with 360-degree imaging of a digital camera to collect phenotype information of crops. The observation and measurement of the root system is difficult due to the opacity of the root system growth medium and the complexity of the root system structure. Researchers try to measure the root system in the soil by methods such as X-ray computed tomography or Magnetic Resonance Imaging (MRI), but the methods can only obtain limited root system phenotype information due to low resolution, and have the defects of small cultivation container, low flux, long time consumption, immovable equipment, high price and the like. The method for measuring the root system is a popular method for measuring the root system at present by adopting a low-cost imaging sensor to obtain the root system image. The GROWSCREEN-Rhizo developed by the research center of ulixi, germany, can image the root system in the narrow root box, but the method can only obtain the phenotype information of a part of fragmented root system, and when crops with larger root systems, such as a fibrous root system crop, corn, and the like are cultivated, the narrow root box limits the growth space of the root system, so that the overlapping of the root system in an imaging window is serious, and the obtained root system image loses more root system phenotype information.

In summary, the existing root phenotype measuring platform can only obtain smaller plant root phenotype information, and the problems of low flux, high equipment cost, low space utilization rate and the like generally exist. In addition, the existing phenotype measuring platform cannot acquire the root system image of the fibrous root system crop with high quality. The flux expansion of the transportation mode based on the conveyor belt is easy to realize, but the cost of the matched equipment is high, and particularly for the ultra-large crop phenotype platform, the cost of the whole configuration conveying system is extremely high. The modular photographing system can effectively reduce the configuration number of the automatic transmission system and greatly reduce the construction cost. Therefore, based on a modular design concept, the method takes omnibearing and multi-angle acquisition of the phenotype information of the underground crops as a starting point, and develops a set of high-throughput and automatic crop phenotype imaging platform, so that the requirements of large-scale phenotype data acquisition and scientific research on crop breeding are met.

Disclosure of Invention

In view of the above problems, the present invention provides a transparent root system cultivation container photographing system, which can meet the requirements of high-throughput crop cultivation and root system imaging, and realize high-throughput, omnibearing, multi-angle, automatic and real-time monitoring and acquisition of crop root systems.

The specific technical scheme of the invention is as follows:

a transparent root system cultivation container photographing system comprises an imaging area, wherein the imaging area comprises an imaging platform, a rotary photographing device, an outer tube photographing camera and a clamping moving assembly;

the rotary photographing device: imaging the root system of the inner wall of the transparent root system cultivation container to be observed on the imaging platform;

the camera for photographing the outer tube: imaging the root system of the outer wall of the transparent root system cultivation container to be observed on the imaging platform;

clamping and moving assembly: the imaging platform is used for transporting the transparent root system cultivation container to be observed to the imaging platform from the sample injection area, and transporting the imaged transparent root system cultivation container to the sample injection area from the imaging platform.

Preferably, the transparent root system cultivation container comprises a cultivation base, a cultivation container body, a shading cover and a shading cover;

the cultivation container body comprises a transparent inner cylinder, a transparent outer cylinder and a transparent top cover, the transparent outer cylinder is opened up and down, the transparent inner cylinder and the transparent outer cylinder are mutually nested and fixed on a cultivation base, the transparent top cover is arranged at the top of the transparent inner cylinder, a root system annular cultivation space is formed between the transparent inner cylinder and the transparent outer cylinder, a shading cover is arranged above the root system annular cultivation space, a central hole communicated with an inner cavity of the transparent inner cylinder is formed in the cultivation base, and a water receiving box is arranged below the cultivation base;

the lens hood is established between shield cover and cultivation base, and the lens hood is including dismantling left lens hood and the right lens hood of connection, and left lens hood and right lens hood form hollow rectangle structure, and cultivation container body establishes in this cavity.

Preferably, a lens hood dismounting mechanism is arranged beside the imaging platform and comprises a support and a vacuum chuck clamp, and the vacuum chuck clamp is connected to the support in a sliding mode so that the vacuum chuck clamp is far away from or close to the imaging platform in the horizontal direction;

the vacuum chuck clamp comprises a mounting seat, a left clamp and a right clamp, the left clamp and the right clamp are symmetrically arranged on the mounting seat and form a horizontal moving pair with the mounting seat, and a driving mechanism for driving the left clamp and the right clamp to synchronously move in opposite directions or move in a back direction is installed on the mounting seat.

Preferably, the lens hood dismounting mechanism comprises a support and a vacuum chuck clamp, the support comprises an opening and closing support and a linear motor module arranged above the opening and closing support, and the linear motor module is provided with a linear guide rail and a sliding seat connected with the linear guide rail;

the vacuum chuck clamp comprises a mounting seat, a positive and negative tooth clamping module, a left clamp and a right clamp, the mounting seat is connected with a sliding seat on the linear guide rail, and a motor on the linear motor module drives the mounting seat to slide along the linear guide rail so as to enable the mounting seat to be far away from or close to the imaging platform in the horizontal direction; the left clamp and the right clamp respectively comprise shading installation arms, sucker installation plates and vacuum suckers arranged at the upper ends and the lower ends of the sucker installation plates, the vacuum suckers are connected with a vacuum generator in a matched mode, one ends of the shading installation arms are connected with the sucker installation plates, the other ends of the shading installation arms are connected with the positive and negative tooth clamping modules in a sliding mode, positive and negative rotating motors are arranged on the positive and negative tooth clamping modules, and the two shading installation arms and the two sucker installation plates connected with the shading installation arms are driven to synchronously move in opposite directions or move in the opposite directions through the positive.

Preferably, the next door of imaging platform is equipped with tears water box structure open, tear water box structure open and include the water box tray, the one end sliding connection of water box tray is on the guide rail, and the other end of water box tray is equipped with the recess that is used for placing the water receiving box, and the water box tray slides along the guide rail under actuating mechanism's drive and is used for putting into the below of cultivation base or takes out from the below of cultivation base with the water receiving box in the recess.

Preferably, the clamping moving assembly slides between the sample injection area and the imaging platform and between the imaging platform and the sample outlet area through a slide rail;

the clamping and moving assembly comprises a fixed mounting plate, a moving seat and two supporting claws, the moving seat is connected to the slide rails between the sample inlet area and the imaging platform and between the imaging platform and the sample outlet area in a sliding manner, and one side of the fixed mounting plate is mounted on the moving seat and can slide up and down along the moving seat; the two supporting claws are symmetrically arranged on the other side of the fixed mounting plate and form a horizontal moving pair with the fixed mounting plate, and a driving mechanism for driving the two supporting claws to synchronously move in opposite directions or move back to back is arranged on the fixed mounting plate.

Preferably, the outer tube camera of shooing includes camera and camera mounting bracket of shooing, and the camera setting of shooing still is equipped with camera guiding mechanism of shooing between camera and the camera mounting bracket on the camera mounting bracket of shooing.

Preferably, transparent root system cultivation container system of shooing still includes the outer tube light filling lamp of shooing, the outer tube light filling lamp of shooing includes lamp strip, installation pole, horizontal installation board, the lamp strip is established on the installation pole, and installation pole sliding connection makes it keep away from or be close to imaging platform on the horizontal direction on horizontal installation board.

Preferably, the rotary photographing device comprises a rotary workbench arranged on the surface of the imaging platform, the upper part of the rotary workbench is sequentially provided with a positioning cushion high ring and a cultivation container positioning seat, the bottom end of the inner wall imaging stand column sequentially penetrates through holes in the centers of the cultivation container positioning seat, the positioning cushion high ring and the rotary workbench, the through holes are fixed on the lifting module mounting plate and can slide up and down along the lifting module mounting plate, and the upper part of the inner wall imaging stand column is provided with a contact type image sensor.

Preferably, the cultivation container positioning seat comprises a base, a water receiving box used for containing the lower portion of the cultivation base is arranged at a central through hole of the base, a containing cavity with a groove end is formed in the water box tray, one end of the water box tray with the groove extends into the bottom of the containing cavity from one side of the central through hole of the base, and a positioning block is arranged above the base.

By adopting the technical scheme, the invention has the following advantages: 1. according to the invention, the transparent root system cultivation container is rotated among the sample introduction area, the imaging platform and the sample discharge area in the imaging process through the clamping and moving assembly, so that high-throughput and automatic real-time monitoring and acquisition of the transparent root system cultivation container are realized. 2. According to the invention, the rotary photographing device and the outer tube photographing camera are arranged in the imaging area, so that the inner wall and the outer wall of each transparent root system cultivation container can be automatically imaged simultaneously, and the crop root system image can be obtained through omnibearing, multi-angle and automatic real-time monitoring. 3. According to the invention, the inner wall and the outer wall of the transparent root system cultivation container are imaged for 360 degrees to collect the phenotype information of the crops by combining the rotary photographing device with the outer tube photographing camera, all the root systems in the imaging range can be imaged, the imaging speed is high, and the imaging is more accurate.

Drawings

FIG. 1 is a schematic structural view of a transparent root system cultivation container photographing system according to the present invention;

FIG. 2 is a schematic structural view of the transparent root system cultivation container according to the present invention;

FIG. 3 is a front view of FIG. 2;

FIG. 4 is a cross-sectional view taken along line A-A of FIG. 3;

FIG. 5 is a schematic structural view of a lens hood mounting and dismounting mechanism of the present invention;

FIG. 6 is a schematic structural view of a rotary table and a water-splitting box structure according to the present invention;

fig. 7 is a schematic structural view of the gripping and moving assembly of the present invention;

FIG. 8 is a schematic structural diagram of an outer tube photographing camera and an outer tube photographing light supplement lamp according to the present invention;

FIG. 9 is a schematic structural diagram of an inner wall imaging column according to the present invention.

Detailed Description

The preferred embodiments of the present invention will be described in detail below with reference to the accompanying drawings so that the objects, features and advantages of the invention can be more clearly understood. It should be understood that the embodiments shown in the drawings are not intended to limit the scope of the present invention, but are merely intended to illustrate the spirit of the technical solution of the present invention. The invention is not mentioned in part as prior art.

Referring to fig. 1, the transparent root system cultivation container photographing system provided by the invention comprises an imaging area 3, wherein the imaging area comprises an imaging platform 14, a rotary photographing device, an outer tube photographing camera 6 and a clamping moving assembly 7; the rotary photographing device: imaging the root system of the inner wall of the transparent root system cultivation container 8 to be observed on the imaging platform 14; outer tube camera 6: imaging the root system of the outer wall of the transparent root system cultivation container 8 to be observed on the imaging platform 14; the clamping and moving assembly 7: the imaging platform is used for transporting the transparent root system cultivation container 8 to be observed to the imaging platform 3 from the sample injection area, and transporting the imaged transparent root system cultivation container 8 to the sample injection area from the imaging platform 14. And four corners of the bottom of the imaging area 3 can be provided with traveling wheels 1, so that the imaging area is convenient to move.

Further, referring to fig. 2 to 4, the transparent root system cultivation container 8 includes a cultivation base 8-5, a cultivation container body, a light-shielding cover 8-2 and a light-shielding cover; the cultivation container body comprises a transparent inner cylinder 8-9, a transparent outer cylinder 8-8 and a transparent top cover 8-7, the transparent outer cylinder 8-8 is opened up and down, the transparent inner cylinder 8-9 and the transparent outer cylinder 8-8 are mutually nested and fixed on a cultivation base 8-5, the transparent top cover 8-7 is arranged at the top of the transparent inner cylinder 8-9, a root system annular cultivation space is formed between the transparent inner cylinder 8-9 and the transparent outer cylinder 8-8, a shading cover 8-2 is arranged above the root system annular cultivation space, and a central hole (not shown in the figure) communicated with an inner cavity of the transparent inner cylinder 8-9 is further formed in the cultivation base 8-5. When the annular cultivation space is used, soil is filled in the annular cultivation space of the root system, the annular cultivation space is sowed in the depth of 3-4 cm of the soil, and the root system of the crop grows in the soil. A water receiving box 8-6 is arranged below the cultivation base 8-5; the light shield is arranged between the light shield cover 8-2 and the cultivation base 8-5 and comprises a left light shield 8-3 and a right light shield 8-1 which are detachably connected, the left light shield 8-3 and the right light shield 8-1 form a hollow rectangular structure, and the cultivation container body is arranged in the cavity. The preferred snap-fit structure is: when the left light shield 8-3 and the right light shield 8-1 are pulled outwards and forcefully, the left light shield 8-3 and the right light shield 8-1 can be separated, and when the left light shield 8-3 and the right light shield 8-1 are leaned together and squeezed forcefully, the left light shield 8-3 and the right light shield 8-1 can be clamped. When the plant root system in the cultivation container body needs to be imaged, only the left light shield or the right light shield needs to be disassembled, and the left light shield 8-3 and the right light shield 8-1 are clamped together after imaging is finished. The left light shield 8-3 and the right light shield 8-1 can be provided with a pin sleeve 8-4, and two light shields are arranged on each light shield and are respectively arranged at two sides of the light shield.

Preferably, the transparent inner cylinder is a transparent cylinder with the wall thickness of 2mm and the height of 600mm, the transparent outer cylinder is a transparent cylinder made of PC (polycarbonate), the wall thickness of 2mm and the height of 700mm, and the transparent top cover is a transparent conical cover with the wall thickness of 2mm and the height of 50 mm.

Preferably, the cultivation base is provided with a through hole (not shown) communicated with the annular cultivation space of the root system, so that the excessive moisture at the bottoms of the transparent outer cylinder 8-8 and the transparent inner cylinder 8-9 can be conveniently seeped out, and the bottom of the cultivation container body is prevented from being stagnant. A water receiving box 8-6 is arranged below the cultivation base 8-5, and the excessive water seeped from the bottom of the transparent outer cylinder 8-8 and the transparent inner cylinder 8-9 flows out and then enters the water receiving box 8-6, so that the ground is not polluted.

Preferably, in order to facilitate the placement and the removal of the water receiving box 8-6 from the lower part of the cultivation base 8-5, the bottom of the cultivation base 8-5 is connected with a first T-shaped clamping opening 8-11 and a second T-shaped clamping opening 8-10, the opening end of the first T-shaped clamping opening 8-11 faces the opening end of the second T-shaped clamping opening 8-10 to form a clamping cavity, and the water receiving box 8-6 is placed in the clamping cavity.

Preferably, the upper transverse plates of the first T-shaped clamping opening 8-11 and the second T-shaped clamping opening 8-10 are connected with the cultivation base 8-5, the front end and the rear end of the lower transverse plate of the first T-shaped clamping opening 8-11 and the second T-shaped clamping opening 8-10 are respectively provided with an inverted cone, and a placement space is formed between 4 inverted cones; the water receiving box 8-6 is a cylinder body with a cylindrical structure, the upper end of the cylinder body is provided with an opening, the opening end of the cylinder body is provided with an extension part 8-12 extending outwards along the circumferential direction of the cylinder body, and the extension part 8-12 is placed in the placing space; when the water receiving box is placed, the extending part 8-12 of the water receiving box 8-6 is inserted into a clamping cavity formed by the first T-shaped clamping opening 8-11 and the second T-shaped clamping opening 8-10 from a position slightly higher than the top of the inverted cone, and when the clamping cavity is positioned at the middle position of the water receiving box, the water receiving box 8-6 is put down to enable the extending part 8-12 to be placed in the placing space; because the front and back ends of the lower transverse plate of the first T-shaped clamping opening 8-11 and the second T-shaped clamping opening 8-10 are provided with the inverted cones, the extension part 8-12 of the water receiving box is placed in the placing space to prevent the water receiving box from moving and sliding off.

When the root systems of the inner wall and the outer wall of the transparent root system cultivation container need to be imaged, a light shield outside the cultivation container body and a water receiving box below the cultivation base need to be removed so as to image the root systems of the inner wall and the outer wall of the transparent root system cultivation container; therefore, the transparent root system cultivation container photographing system further comprises a light shield assembling and disassembling mechanism and a water disassembling box structure.

Further, referring to fig. 5, a light shield disassembling and assembling mechanism 9 is arranged beside the imaging platform 14 and used for disassembling the light shield outside the cultivation container body so as to image the root system of the outer wall of the transparent root system cultivation container to be observed. The lens hood dismounting mechanism comprises a support and a vacuum chuck clamp, wherein the vacuum chuck clamp is connected to the support in a sliding mode so that the vacuum chuck clamp is far away from or close to the imaging platform 14 in the horizontal direction; the vacuum chuck clamp comprises a mounting seat 9-10, a left clamp and a right clamp, the left clamp and the right clamp are symmetrically arranged on the mounting seat 9-10 and form a horizontal moving pair with the mounting seat 9-10, and a driving mechanism for driving the left clamp and the right clamp to synchronously move in opposite directions or move in a back direction is arranged on the mounting seat 9-10.

Further, the light shield assembling and disassembling mechanism 9 comprises a support and a vacuum chuck clamp, the support comprises an opening and closing support 9-1 and a linear motor module arranged above the opening and closing support 9-1, the linear motor module is the conventional linear motor module, and the linear motor module is provided with linear guide rails 9-12 and sliding seats 9-13 connected with the linear guide rails 9-12. The vacuum chuck clamp comprises a mounting seat 9-10, a positive and negative tooth clamping module 9-2, a left clamp and a right clamp, wherein the mounting seat 9-10 is connected with a sliding seat 9-13 on a linear guide rail 9-12, and a motor 9-11 on the linear motor module drives the mounting seat 9-10 to slide along the linear guide rail 9-12, so that the mounting seat 9-10 is far away from or close to an imaging platform 14 in the horizontal direction. The positive and negative tooth clamping module 9-2 is commercially available, the left clamp and the right clamp respectively comprise a shading mounting arm 9-3, a sucker mounting plate 9-4, vacuum suckers 9-6 arranged at the upper end and the lower end of the sucker mounting plate 9-4, the vacuum suckers 9-6 are matched and connected with a vacuum generator (not shown in the figure), one end of the shading mounting arm 9-3 is connected with the sucker mounting plate 9-4, the other end of the shading mounting arm is connected with the positive and negative tooth clamping module 9-2 in a sliding manner, a positive and negative rotating motor 9-14 is arranged on the positive and negative tooth clamping module 9-2, and the two shading mounting arms 9-3 and the two sucker mounting plates 9-4 connected with the positive and negative tooth clamping module are driven to synchronously move in opposite directions or move in. Preferably, the upper end and the lower end of the sucker mounting plate 9-4 can be provided with hanging pins 9-5 matched with the hanging pin sleeves 8-4 on the light shield, so that the positioning effect can be achieved, and in addition, after the left light shield and the right light shield are firmly sucked and disassembled by the vacuum sucker, the hanging pins 9-5 matched with the hanging pin sleeves 8-4 can share the weight of the left light shield and the right light shield, so that the service life of the vacuum sucker is prolonged.

Furthermore, a slide rail (not shown in the figure) is arranged in the vertical direction on the mounting seat 9-10, the positive and negative tooth clamping module 9-2 is connected to the slide rail through a slide block 9-9, and a motor 9-8 on the mounting seat 9-10 drives the positive and negative tooth clamping module 9-2 to slide in the vertical direction of the mounting seat 9-10, so that the adjustment of the sucker mounting plate 9-4 in the vertical direction is realized.

When the device works, the positive and negative rotating motor 9-14 is controlled to drive the two shading mounting arms 9-3 connected with the positive and negative tooth clamping module 9-2 to drive the two sucker mounting plates 9-4 to synchronously move back and forth until the distance between the two sucker mounting plates 9-4 is larger than the width of the transparent root system cultivation container 8; controlling a motor 9-11 on the linear motor module to drive the mounting seat 9-10 to slide along the linear guide rail 9-12 in the direction close to the imaging platform 14, and simultaneously controlling a motor 9-8 on the mounting seat 9-10 to drive the positive and negative tooth clamping module 9-2 to slide along a vertical slide rail on the mounting seat 9-10 until the hanging pins 9-5 on the two sucker mounting plates 9-4 are over against hanging pin sleeves 8-4 on a left light shield and a right light shield of a transparent root system cultivation container 8 on the imaging platform 14; controlling a forward and reverse rotating motor 9-14 to drive two shading mounting arms 9-3 connected with a forward and reverse tooth clamping module 9-2 to drive two sucker mounting plates 9-4 to synchronously move in opposite directions so as to tightly abut a vacuum sucker 9-6 against a left shading cover 8-3 and a right shading cover 8-1, and simultaneously inserting a hanging pin 9-5 on the sucker mounting plate 9-4 into a hanging pin sleeve 8-4, wherein a vacuum generator works to suck, so that negative pressure is generated in the vacuum sucker 9-6, and the left shading cover 8-3 and the right shading cover 8-1 are firmly sucked; after the vacuum suction cup 9-6 firmly sucks the left light shield 8-3 and the right light shield 8-1, the forward and reverse rotating motor 9-14 drives the two light shield mounting arms 9-3 connected with the forward and reverse tooth clamping module 9-2 to drive the two suction cup mounting plates 9-4 to synchronously move back and forth so as to disassemble the left light shield and the right light shield, and then the motor 9-11 on the linear motor module is controlled to drive the mounting seat 9-10 to slide along the linear guide rail 9-12 so as to drive the left light shield 8-3 and the right light shield 8-1 to be far away from the imaging platform 14, so that the transparent root system cultivation container 8 on the imaging platform 14 can be imaged. After the transparent root system cultivation container 8 on the imaging platform 14 is imaged, controlling a motor 9-11 on a linear motor module to drive a mounting seat 9-10 to slide along a linear guide rail 9-12 to drive a left light shield 8-3 and a right light shield 8-1 to slide to the imaging platform 14, controlling a motor 9-8 on the mounting seat 9-10 to drive a positive and negative tooth clamping module 9-2 to slide along a vertical slide rail on the mounting seat until the left light shield 8-3 and the right light shield 8-1 on the two sucker mounting plates 9-4 are positioned between a light shield 8-2 and a cultivation base 8-5 of the transparent root system cultivation container 8 on the imaging platform 14, the clamping position on the left light shield 8-3 is right opposite to the clamping position on the right light shield 8-1, and controlling the positive and negative rotation motor 9-14 to drive two light shield mounting arms 9-3 belts connected with the positive and negative tooth clamping module 9-2 Moving the two sucker mounting plates 9-4 to synchronously move in opposite directions to clamp the left light shield 8-3 and the right light shield 8-1 on the vacuum sucker 9-6, and after the left light shield and the right light shield are clamped, the vacuum generator works to inflate the vacuum sucker 9-6, so that the vacuum sucker 9-6 is changed into positive pressure and is separated from the left light shield and the right light shield; the forward and reverse rotating motor 9-14 is controlled to drive the forward and reverse tooth clamping module 9-2 to drive the two sucker mounting plates 9-4 to synchronously move back and forth to be far away from the left light shield 8-3 and the right light shield 8-1, and meanwhile, the motor 9-11 on the linear motor module is controlled to drive the mounting seat 9-10 to slide along the linear guide rail 9-12 to be far away from the imaging platform 14.

Further, referring to fig. 6, a water box detaching structure 5 is further disposed beside the imaging platform 14 and used for taking out or putting in a water receiving box below the cultivation base, the water box detaching structure includes a water box tray 5-6, one end of the water box tray 5-6 is slidably connected to the guide rail 5-2, a groove 5-7 for placing the water receiving box is disposed at the other end of the water box tray 5-6, and the water box tray 5-6 is driven by the driving mechanism 5-4 to slide along the guide rail 5-2 and used for putting the water receiving box in the groove 5-7 below the cultivation base or taking out the water receiving box from the lower side of the cultivation base. If the height of the water box tray is lower than that of the imaging platform, a water box dismounting heightening plate 5-5 can be arranged between the water box tray 5-6 and the guide rail 5-2; the top of the water box dismounting heightening plate 5-5 is connected with one end of the water box tray 5-6, and the bottom of the water box dismounting heightening plate is connected with the guide rail 5-2 in a sliding manner. The driving mechanism 5-4 can adopt an air cylinder, and one side of the guide rail 5-2 is provided with a proximity switch 5-3 for sensing the sliding distance of the water box tray 5-6.

Further, referring to fig. 7, the gripping and moving assembly 7 slides between the sample injection area and the imaging platform 14 and between the imaging platform 14 and the sample outlet area through the slide rail. The sample inlet area and the sample outlet area can be in the same place or different places. Taking the sample inlet area and the sample outlet area in the same place as an example, the transparent root system cultivation container to be observed in the sample inlet area is sent to the imaging platform 14 for imaging, and the imaged transparent root system cultivation container is sent back to the original place; the sampling area is provided with a positioning tool 11 for placing the transparent root system cultivation container 8. Two parallel slide rails 12 are arranged between the sample injection area and the imaging platform 14, the two parallel slide rails 12 are respectively arranged at two sides of the imaging platform 14, the slide rails 14 extend to the whole imaging area 3, and the imaging area 3 is provided with a driving device 2 for driving the clamping moving assembly 7 to slide along the slide rails 12. Preferably, the light shield assembling and disassembling mechanism 9 and the outer tube photographing camera 6 are arranged on the outer sides of the two parallel sliding rails 12 and located on two sides of the imaging platform 14, the water disassembling box structure 5 is arranged in the two parallel sliding rails 12, and the guide rail 5-2 on the water disassembling box structure 5 is parallel to the sliding rails 12. The clamping and moving assembly comprises a fixed mounting plate 7-2, a moving seat 7-6 and two supporting claws 7-12, the moving seat 7-6 is connected to two parallel sliding rails 12 in a sliding manner, and one side of the fixed mounting plate 7-2 is mounted on the moving seat 7-6 and can slide up and down along the moving seat 7-6; the two supporting claws 7-12 are symmetrically arranged on the other side of the fixed mounting plate 7-2 and form a horizontal moving pair with the fixed mounting plate 7-2, and a driving mechanism for driving the two supporting claws 7-12 to synchronously move in opposite directions or move in a back direction is arranged on the fixed mounting plate 7-2.

Further, referring to fig. 7, the clamping and moving assembly 7 comprises a fixed mounting plate 7-2, a moving seat 7-6 and two supporting claws 7-12, wherein one side of the moving seat 7-6 is connected with two parallel vertical slide rails 7-5, one side of the fixed mounting plate 7-2 is respectively connected with the two parallel vertical slide rails 7-5 through sliders 7-13, the moving seat 7-6 is further provided with a driving mechanism 7-4 for driving the fixed mounting plate 7-2 to slide in the vertical direction of the moving seat along the two parallel vertical slide rails 7-5, and the driving mechanism is preferably an air cylinder. The other side of the fixed mounting plate 7-2 is connected with two parallel horizontal sliding rails 7-3 and a bidirectional cylinder 7-1, the upper end and the lower end of the two supporting claw mounting plates 7-8 are respectively connected with the two horizontal sliding rails 7-3 through sliding blocks 7-7, the two supporting claws 7-12 are symmetrically arranged on the two supporting claw mounting plates 7-8, and the bidirectional cylinder 7-1 drives the sliding blocks 7-7 to drive the two supporting claws 7-12 to synchronously move in the opposite direction or move in the opposite direction, so that the transparent root system cultivation container 8 is clamped and put down. When the clamping is carried out, in order to enable the transparent root system cultivation container to be more stable and not easy to shake, the middle part of each supporting claw is provided with a support bar 7-10, the front end and the rear end of each supporting claw are respectively provided with a baffle 7-11, the distance between the two baffles 7-11 at the front end and the rear end is matched with the distance between the two ends of the cultivation base of the transparent root system cultivation container, and the four baffles just form an accommodating space capable of accommodating the cultivation base when the clamping is carried. The inner side and the outer side of each horizontal sliding rail 7-3 are symmetrically provided with a limiting block 7-9 for limiting the sliding distance of the sliding block 7-7.

Further, referring to fig. 8, the outer tube photographing camera 6 comprises a photographing camera 6-9 and a camera mounting bracket, the photographing camera 6-9 is arranged on the camera mounting bracket, and a photographing camera adjusting mechanism is further arranged between the photographing camera and the camera mounting bracket, so that the angle of the photographing camera can be adjusted conveniently when photographing.

Further, referring to fig. 8, the outer tube photographing camera 6 includes a camera mounting bracket including a camera mounting rod 6-5, a photographing fixing bracket 6-1, an optical axis and an adjusting connecting block, the photographing fixing bracket 6-1 is disposed near the imaging area imaging platform 14, one end of the first optical axis 6-2 is connected to the photographing fixing bracket 6-1, the other end thereof is connected to one end of the second optical axis 6-4 through a first adjusting connecting block 6-3, the other end of the second optical axis 6-4 is connected to the camera mounting rod 6-5 through a second adjusting connecting block 6-6, the photographing camera 6-9 is disposed on the camera mounting rod 6-5, the photographing camera 6-9 can be adjusted in different directions by disposing the first adjusting connecting block 6-3 and the second adjusting connecting block 6-6, to meet the requirements of photographing. A camera protective cover 6-7 can be further designed on the photographing camera 6-9 to protect the camera, and in addition, in order to increase the stability of the camera mounting frame, a connecting plate 6-8 can be adopted to connect the upper end of the second optical axis 6-4 with the mounting frame 4-1 on the outer tube photographing light supplement lamp.

Further, referring to fig. 8, the photographing system for the transparent root system cultivation container further comprises an outer tube photographing light supplement lamp 4, so that light supplement is performed when the outer tube photographing camera 6 works, the outer tube photographing light supplement lamp 4 is arranged near the outer tube photographing camera 6, the outer tube photographing light supplement lamp comprises a light bar 4-5, an installation rod 4-8 and a horizontal installation plate 4-2, the light bar 4-5 is arranged on the installation rod 4-8, and the installation rod 4-8 is connected to the horizontal installation plate 4-2 in a sliding mode to enable the horizontal installation plate to be far away from or close to the imaging platform 14 in the horizontal direction; make outer tube light filling lamp 4 that shoots can carry out the light filling according to actual need.

Further, referring to fig. 8, the light supplement lamp 4 for outer tube photographing comprises a light bar 4-5, a light bar support 4-6, a mounting rod 4-8, a lamp holder connecting plate 4-4, a horizontal mounting plate 4-2 and a mounting frame 4-1, wherein the horizontal mounting plate 4-2 is connected with the mounting frame 4-1, two light bars 4-5 are arranged on the light bar support 4-6, the upper end and the lower end of the light bar support 4-6 are connected with the vertical mounting rod 4-8 through the lamp holder connecting plate 4-4, the mounting rod 4-8 is arranged on a sliding block 4-3 in a penetrating manner, the sliding block 4-3 is connected with the horizontal mounting plate 4-2, the horizontal mounting plate 4-2 is also provided with a driving mechanism 4-7 for driving the sliding block 4-3 to slide, and the driving mechanism 4-7 is preferably an air cylinder; the cylinder drives the mounting rod 4-8 to slide in the horizontal direction along the horizontal mounting plate 4-2, when the light supplement light is weaker than the required light, the cylinder drives the light bar 4-5 on the mounting rod 4-8 to slide in the direction close to the imaging platform 14, and when the light supplement light is stronger than the required light, the cylinder drives the light bar 4-5 on the mounting rod 4-8 to slide in the direction far from the imaging platform 14; and adjusting the light bars 4-5 on the mounting rods 4-8 in the horizontal direction according to the actual light supplement requirement.

Further, referring to fig. 6 and 9, the rotary photographing device comprises a rotary workbench 10 arranged on the surface of an imaging platform 14, wherein a positioning seat cushion high ring 10-2 and a cultivation container positioning seat 10-3 are sequentially arranged on the upper portion of the rotary workbench 10, the bottom end of an inner wall imaging upright column 13 sequentially penetrates through holes in the centers of the cultivation container positioning seat 10-3, the positioning seat cushion high ring 10-2 and the rotary workbench 10 to be fixed on a lifting module mounting plate 13-6 and can slide up and down along the lifting module mounting plate 13-6, and a contact type image sensor 13-8 is arranged on the upper portion of the inner wall imaging upright column 13.

Further, referring to fig. 6 and 9, the rotary photographing device comprises a rotary table 10 disposed on the surface of the imaging platform, the rotary table preferably adopts a slewing bearing 10-1, the slewing bearing 10-1 is driven by a servo motor 10-4 to rotate, and a photoelectric sensor 10-5 is disposed beside the slewing bearing 10-1; the upper part of the slewing bearing 10-4 is sequentially provided with a positioning seat cushion high ring 10-2 and a cultivation container positioning seat 10-3; the bottom end of the inner wall imaging upright column 13 sequentially penetrates through holes in the centers of the cultivation container positioning seat 10-3, the positioning seat cushion high ring 10-2 and the slewing bearing 10-4 to be fixed on the lifting module mounting plate 13-6 and can slide up and down along the lifting module mounting plate 13-6, and the lifting module mounting plate 13-6 is arranged below the imaging platform 14. When the cultivation container is used, the transparent root system cultivation container 8 is placed on the cultivation container positioning seat 10-3, the inner wall imaging upright column 13 slides upwards along the lifting module mounting plate 13-6, the upper part of the inner wall imaging upright column vertically extends into an inner cavity of an inner cylinder of the cultivation container, the servo motor 10-4 drives the slewing bearing 10-1 to rotate, so that the positioning seat cushion high ring 10-2 and the cultivation container on the cultivation container positioning seat 10-3 are driven to rotate together, and the Contact type Image sensor 13-8 images the root system of the inner wall of the cultivation container; after imaging, the inner wall imaging upright column 13 slides downwards along the lifting module mounting plate 13-6 and retreats from the inner cavity of the inner cylinder of the cultivation container.

Further, the lifting module mounting plate 13-6 is provided with a sliding rail 13-5 along the vertical direction, one end of the inner wall imaging column is provided with a mounting plate 13-4, the mounting plate 13-4 is connected with the sliding rail 13-5 on the lifting module mounting plate 13-6 through a sliding seat 13-1, and the lifting module mounting plate 13-6 is also provided with a motor 13-2 for driving the inner wall imaging column 13 to slide up and down along the lifting module mounting plate 13-6.

Furthermore, in order to enable the inner wall imaging upright post to slide up and down more stably, a reinforcing rib 13-3 is arranged on the mounting plate 13-4.

Further, in order to facilitate the installation of the CIS, CIS connecting blocks 13-9 are arranged on the inner wall imaging upright post.

Further, in order to stabilize the distance between the CIS and the transparent inner cylinder side wall of the cultivation container during rotation, a rotating guide wheel assembly 13-7 is installed on the upper part of the inner wall imaging upright column 13, and the rotating guide wheel assembly 13-7 is preferably a Fowler wheel assembly.

Further, referring to fig. 6, the positioning seat 10-3 for the cultivation container comprises a base, a water receiving box 8-6 for receiving the lower portion of the cultivation base 8-5 is arranged at a central through hole 10-7 of the base, a receiving cavity 10-8 with a groove end is arranged on the water box tray 5-6, one end of the water box tray 5-6 with the groove 5-7 extends into the bottom of the receiving cavity 10-8 from one side of the central through hole 10-7 of the base, the groove 5-7 on the water box tray 5-6 is located at the center of the receiving cavity 10-8, and a positioning block 10-10 is arranged above the base.

Furthermore, a containing cavity at the position of the central through hole 10-7 of the base is used for containing a first T-shaped clamping opening 8-11 and a second T-shaped clamping opening 8-10 which are arranged below the cultivation base 8-5, a water receiving box 8-6 and one end of the water box tray 5-6 with a groove 5-7, one end of the water box tray 5-6 with the groove 5-7 extends into the bottom of the containing cavity 10-8 from one side of the central through hole 10-7 of the base, and the other side of the central through hole 10-7 of the base is provided with a limiting groove 10-6 for limiting the extending position of the water box tray 5-6. When the first T-shaped clamping opening 8-11, the second T-shaped clamping opening 8-10 and the water receiving box 8-6 are placed in the accommodating cavity, the first T-shaped clamping opening 8-11 and the second T-shaped clamping opening 8-10 are positioned on two sides of the water box tray 5-6 along the base extending direction; when one end of the water box tray 5-6, which is provided with the groove 5-7, extends into the bottom of the accommodating cavity 10-8 from one side of the central through hole 10-7 of the base, the water box tray 5-6 slightly jacks up the water receiving box 8-6 which is positioned in the groove 5-7 and below the cultivation base, so that the water receiving box 8-6 can be conveniently taken out from the lower part of the cultivation base. Four positioning blocks 10-10 for placing the cultivation base are arranged above the base, positioning pins 10-9 are arranged on two positioning blocks on the diagonal, and positioning grooves (not shown in the figure) matched with the transparent root system cultivation container are arranged on the transparent root system cultivation container; when the transparent root system cultivation container is placed at the cultivation container positioning seat, the position of the transparent root system cultivation container is positioned.

The using process of the invention is as follows:

the cylinder on the control water box structure 5 drives the water box tray 5-6 to slide towards the imaging platform 14, and one end of the water box tray 5-6, which is provided with the groove 5-7, extends into the bottom of the accommodating cavity 10-8 from one side of the central through hole 10-7 of the base until the end part of the water box tray is positioned in the limiting groove 10-6.

Controlling a driving device 2 on an imaging area 3 to drive a clamping moving assembly 7 to integrally slide to the position right in front of a transparent root system cultivation container to be observed in an sampling area, controlling a cylinder on a moving seat 7-6 to drive a fixed mounting plate 7-2 to slide downwards along the moving seat 7-6 until two supporting claws 7-12 on the fixed mounting plate 7-2 are lowered to the position below a cultivation base 8-5 of the transparent root system cultivation container 8, and then driving the clamping moving assembly 7 to integrally move towards the direction of the transparent root system cultivation container 8 until the two supporting claws 7-12 are positioned right below the cultivation base 8-5; then the fixed mounting plate 7-2 is controlled to move upwards along the moving seat 7-6, the two supporting claws 7-12 move upwards along the fixed mounting plate 7-2 and support the transparent root system cultivation container 8, and meanwhile the two supporting claws 7-12 are driven by the two-way air cylinder 7-1 on the fixed mounting plate 7-2 to drive the sliding block 7-7 to drive the two supporting claws 7-12 to synchronously move oppositely to clamp the cultivation base 8-5. Then, the driving clamping moving assembly 7 integrally drives the transparent root system cultivation container 8 to move towards the imaging platform 14, the fixing mounting plate 7-2 is combined to slide up and down along the moving seat 7-6, so that the transparent root system cultivation container 8 is positioned right above the four positioning blocks 10-10 on the cultivation container positioning seat 10-3, the fixing mounting plate 7-2 is controlled to slide down along the moving seat 7-6, meanwhile, the two supporting claws 7-12 are driven by the two-way air cylinders 7-1 on the fixing mounting plate 7-2 to synchronously move backwards to put down the cultivation base 8-5, so that the transparent root system cultivation container 8 is placed on the four positioning blocks 10-10, and the driving device 2 on the imaging area 3 is controlled to drive the clamping moving assembly 7 to integrally slide away from the transparent root system cultivation container 8.

The air cylinder on the water removal box structure 5 is controlled to drive the water box tray 5-6 to slide towards the direction far away from the imaging platform 14, the water box tray 5-6 drives the water receiving box 8-6 with the groove 5-7 to slide out of the accommodating cavity 10-8 of the central through hole 10-7 of the base, and the water receiving box 8-6 is taken out from the lower part of the cultivation base 8-5.

A forward and reverse rotation motor 9-14 on the control light shield disassembling and assembling mechanism 9 drives two light shield mounting arms 9-3 connected with the forward and reverse tooth clamping module 9-2 to drive two sucker mounting plates 9-4 to synchronously move backwards until the distance between the two sucker mounting plates 9-4 is larger than the width of the transparent root system cultivation container 8; a motor 9-11 on the linear motor module drives a mounting seat 9-10 to slide to an imaging platform 14, and a motor 9-8 on the mounting seat 9-10 drives a positive and negative tooth clamping module 9-2 to slide up and down along the mounting seat 9-10 until hanging pins 9-5 on two sucker mounting plates 9-4 are over against hanging pin sleeves 8-4 on a left light shield 8-3 and a right light shield 8-1 of a transparent root system cultivation container 8 on the imaging platform; controlling a forward and reverse rotating motor 9-14 to drive two shading mounting arms 9-3 connected with a forward and reverse tooth clamping module 9-2 to drive two sucker mounting plates 9-4 to synchronously move in opposite directions so as to tightly abut a vacuum sucker 9-6 against a left shading cover 8-3 and a right shading cover 8-1, and then a vacuum generator works to suck to generate negative pressure in the vacuum sucker 9-6 so as to firmly absorb the left shading cover 8-3 and the right shading cover 8-1; after the vacuum suction cup 9-6 firmly sucks the left light shield 8-3 and the right light shield 8-1, the forward and reverse rotating motor 9-14 is controlled to drive the two light shield mounting arms 9-3 connected with the forward and reverse tooth clamping module 9-2 to drive the two suction cup mounting plates 9-4 to synchronously move back and forth so as to disassemble the left light shield 8-3 and the right light shield 8-1, and then the motor 9-11 on the linear motor module is controlled to drive the mounting seat 9-10 to slide along the linear guide rail so as to drive the left light shield 8-3 and the right light shield 8-1 to move away from the imaging platform 14, so that the transparent root system cultivation container 8 on the imaging platform 14 can be imaged.

Controlling a motor 13-2 on a lifting module mounting plate 13-6 to drive an inner wall imaging upright post 13 to slide upwards along the lifting module mounting plate 13-6, enabling the upper part of the inner wall imaging upright post 13 to sequentially pass through a through hole in the centers of a slewing bearing 10-1, a positioning seat cushion high ring 10-2 and a cultivation container positioning seat 10-3 and vertically extend into an inner cavity of an inner cylinder of a cultivation container, driving the slewing bearing 10-1 to rotate by a servo motor 10-4 so as to drive the positioning seat cushion high ring 10-2 and the cultivation container on the cultivation container positioning seat 10-3 to rotate together, and simultaneously imaging the roots of the inner wall and the outer wall of the transparent root system cultivation container by a CIS and an outer tube camera in the rotating process. The light filling lamp can also shoot through the outer tube to fill light in the imaging process.

After imaging is finished, the inner wall imaging upright column is controlled to slide downwards along the lifting module mounting plate 13-6 and exit from the inner cavity of the inner cylinder of the cultivation container, the cultivation container positioning seat 10-3, the positioning seat cushion high ring 10-2 and a through hole in the center of the slewing bearing 10-1 in sequence.

A motor 9-11 on the control linear motor module drives a mounting seat 9-10 to slide along a linear guide rail 9-12 to drive a left light shield 8-3 and a right light shield 8-1 to slide towards an imaging platform 14, a motor 9-8 on the control mounting seat 9-10 drives a positive and negative tooth clamping module 9-2 to slide up and down along the mounting seat 9-10 until a left light shield 8-3 and a right light shield 8-1 on two sucker mounting plates 9-4 are right opposite to a position between a light shield 8-2 and a cultivation base 8-5 of a transparent root system cultivation container 8 on the imaging platform 14, a clamping position on the left light shield 8-3 is right opposite to a clamping position on the right light shield 8-1, and two shading mounting arms 9-3 on the positive and negative rotation motor drive 9-14 and the positive and negative tooth clamping module 9-2 are controlled to drive two suckers 9-4 to synchronously move in opposite directions to enter into the imaging platform The left light shield 8-3 and the right light shield 8-1 on the vacuum sucker 9-6 are embedded between the light shield cover 8-2 and the cultivation base 8-5 and clamped, and after the left light shield 8-3 and the right light shield 8-1 are clamped, the vacuum generator is controlled to inflate the vacuum sucker, so that the vacuum sucker 9-6 is changed into positive pressure and is separated from the left light shield 8-3 and the right light shield 8-1; the two shading mounting arms 9-3 which control the forward and reverse rotating motor drive 9-14 to be connected with the forward and reverse tooth clamping module 9-2 drive the two sucker mounting plates 9-4 to synchronously move back and forth to be further away from the left shading cover 8-3 and the right shading cover 8-1, and meanwhile, the motor 9-11 on the linear motor module drives the mounting seat 9-10 to slide along the linear guide rail 9-12 to be far away from the imaging platform 14.

The air cylinder on the water removal box structure 5 is controlled to drive the water box tray 5-6 to slide towards the imaging platform 14, the water box tray 5-6 drives the water receiving box 8-6 in the groove 5-7 to extend into the bottom of the accommodating cavity 10-8 from one side of the central through hole 10-7 of the base, and the water receiving box 8-6 is placed below the cultivation base 8-5.

Controlling a driving device 2 on an imaging area 3 to drive a clamping moving assembly 7 to integrally slide to the position right in front of a transparent root system cultivation container 8 on an imaging platform 14, controlling an air cylinder on a moving seat 7-6 to drive a fixed mounting plate 7-2 to slide downwards along the moving seat 7-6 until two supporting claws 7-12 on the fixed mounting plate 7-2 are lowered to the position below a cultivation base 8-5 of the transparent root system cultivation container 8, and then driving the clamping moving assembly 7 to integrally move towards the direction of the transparent root system cultivation container 8 until the two supporting claws 7-12 are positioned right below the cultivation base 8-5; then the fixed mounting plate 7-2 is controlled to move upwards along the moving seat 7-6, the two supporting claws 7-12 move upwards along the fixed mounting plate 7-2 and support the transparent root system cultivation container 8, and meanwhile the two supporting claws 7-12 are driven by the two-way air cylinder 7-1 on the fixed mounting plate 7-2 to drive the sliding block 7-7 to drive the two supporting claws 7-12 to synchronously move oppositely to clamp the cultivation base 8-5.

Then, the clamping and moving assembly 7 is driven to integrally drive the transparent root system cultivation container 8 to move towards the sample injection area, the fixed mounting plate 7-2 is combined to slide up and down along the moving seat 7-6, so that the transparent root system cultivation container 8 is positioned right above the sample injection area positioning tool 11, the fixed mounting plate 7-2 is controlled to slide down along the moving seat 7-6, meanwhile, the bidirectional cylinder 7-1 on the fixed mounting plate 7-2 drives the slide block 7-7 to drive the two supporting claws 7-12 to synchronously move backwards and put down the cultivation base 8-5, so that the imaged transparent root system cultivation container 8 is placed on the positioning tool 11, the driving device 2 on the imaging area 3 is controlled to drive the clamping and moving assembly 7 to integrally slide away from the transparent root system cultivation container 8, and the imaged transparent root system cultivation container on the positioning tool 11 is output to other areas, and placing the next transparent root system cultivation container to be imaged on the positioning tool 11 of the sampling area. And repeating the steps.

The present invention has been described with reference to the above embodiments, and the structure, arrangement, and connection of the respective members may be changed. On the basis of the technical scheme of the invention, the improvement or equivalent transformation of the individual components according to the principle of the invention is not excluded from the protection scope of the invention.

Claims (10)

1. A transparent root system cultivation container photographing system is characterized by comprising an imaging area, wherein the imaging area comprises an imaging platform, a rotary photographing device, an outer tube photographing camera and a clamping moving assembly;

the rotary photographing device: imaging the root system of the inner wall of the transparent root system cultivation container to be observed on the imaging platform;

the camera for photographing the outer tube: imaging the root system of the outer wall of the transparent root system cultivation container to be observed on the imaging platform;

clamping and moving assembly: the imaging platform is used for transporting the transparent root system cultivation container to be observed to the imaging platform from the sample injection area, and transporting the imaged transparent root system cultivation container to the sample injection area from the imaging platform.

2. The transparent root system cultivation container photographing system of claim 1, wherein the transparent root system cultivation container comprises a cultivation base, a cultivation container body, a shading cover and a shading cover;

the cultivation container body comprises a transparent inner cylinder, a transparent outer cylinder and a transparent top cover, the transparent outer cylinder is opened up and down, the transparent inner cylinder and the transparent outer cylinder are mutually nested and fixed on a cultivation base, the transparent top cover is arranged at the top of the transparent inner cylinder, a root system annular cultivation space is formed between the transparent inner cylinder and the transparent outer cylinder, a shading cover is arranged above the root system annular cultivation space, a central hole communicated with an inner cavity of the transparent inner cylinder is formed in the cultivation base, and a water receiving box is arranged below the cultivation base;

the lens hood is established between shield cover and cultivation base, and the lens hood is including dismantling left lens hood and the right lens hood of connection, and left lens hood and right lens hood form hollow rectangle structure, and cultivation container body establishes in this cavity.

3. The transparent root system cultivation container photographing system of claim 2, wherein a hood removal mechanism is provided beside the imaging platform, the hood removal mechanism comprising a bracket and a vacuum chuck clamp slidably connected to the bracket to move the vacuum chuck clamp horizontally away from or close to the imaging platform;

the vacuum chuck clamp comprises a mounting seat, a left clamp and a right clamp, the left clamp and the right clamp are symmetrically arranged on the mounting seat and form a horizontal moving pair with the mounting seat, and a driving mechanism for driving the left clamp and the right clamp to synchronously move in opposite directions or move in a back direction is installed on the mounting seat.

4. The transparent root system cultivation container photographing system of claim 3, wherein the light shield assembling and disassembling mechanism comprises a bracket and a vacuum chuck clamp, the bracket comprises an opening and closing bracket, a linear motor module is arranged above the opening and closing bracket, and a linear guide rail and a sliding seat connected with the linear guide rail are arranged on the linear motor module;

the vacuum chuck clamp comprises a mounting seat, a positive and negative tooth clamping module, a left clamp and a right clamp, the mounting seat is connected with a sliding seat on the linear guide rail, and a motor on the linear motor module drives the mounting seat to slide along the linear guide rail so as to enable the mounting seat to be far away from or close to the imaging platform in the horizontal direction; the left clamp and the right clamp respectively comprise shading installation arms and sucker installation plates, vacuum suckers are arranged at the upper ends and the lower ends of the sucker installation plates and are connected with a vacuum generator in a matched mode, one ends of the shading installation arms are connected with the sucker installation plates, the other ends of the shading installation arms are connected with the positive and negative tooth clamping modules in a sliding mode, positive and negative rotating motors are arranged on the positive and negative tooth clamping modules, and the two shading installation arms and the two sucker installation plates connected with the shading installation arms are driven to synchronously move in opposite directions or move in the opposite directions through the positive and negative rotation.

5. The transparent root system cultivation container photographing system of claim 2, wherein a water box detaching structure is arranged beside the imaging platform, the water box detaching structure comprises a water box tray, one end of the water box tray is slidably connected to the guide rail, a groove for placing a water receiving box is formed in the other end of the water box tray, and the water box tray is driven by the driving mechanism to slide along the guide rail and is used for placing the water receiving box in the groove below the cultivation base or taking the water receiving box out of the groove below the cultivation base.

6. The transparent root system cultivation container photographing system according to any one of claims 1 to 5, wherein the clamping moving assembly slides between the sample introduction area and the imaging platform and between the imaging platform and the sample discharge area through a slide rail;

the clamping and moving assembly comprises a fixed mounting plate, a moving seat and two supporting claws, the moving seat is connected to the slide rails between the sample inlet area and the imaging platform and between the imaging platform and the sample outlet area in a sliding manner, and one side of the fixed mounting plate is mounted on the moving seat and can slide up and down along the moving seat; the two supporting claws are symmetrically arranged on the other side of the fixed mounting plate and form a horizontal moving pair with the fixed mounting plate, and a driving mechanism for driving the two supporting claws to synchronously move in opposite directions or move back to back is arranged on the fixed mounting plate.

7. The transparent root system cultivation container photographing system according to any one of claims 1 to 5, wherein the outer tube photographing camera comprises a photographing camera and a camera mounting bracket, the photographing camera is arranged on the camera mounting bracket, and a photographing camera adjusting mechanism is further arranged between the photographing camera and the camera mounting bracket.

8. The transparent root system cultivation container photographing system of any one of claims 1 to 5, further comprising an outer tube photographing light supplement lamp, wherein the outer tube photographing light supplement lamp comprises a light bar, a mounting rod and a horizontal mounting plate, the light bar is arranged on the mounting rod, and the mounting rod is slidably connected to the horizontal mounting plate to enable the horizontal mounting plate to be far away from or close to the imaging platform in the horizontal direction.

9. The transparent root system cultivation container photographing system of claim 1 or 2, wherein the rotary photographing device comprises an inner wall imaging column and a rotary worktable arranged on the surface of the imaging platform, the upper part of the rotary worktable is sequentially provided with a positioning cushion high ring and a cultivation container positioning seat, the bottom end of the inner wall imaging column sequentially passes through holes in the centers of the cultivation container positioning seat, the positioning cushion high ring and the rotary worktable and is fixed on the lifting module mounting plate and can slide up and down along the lifting module mounting plate, and the upper part of the inner wall imaging column is provided with a contact type image sensor.

10. The transparent root system cultivation container photographing system of claim 9, wherein the cultivation container positioning seat comprises a base, a water receiving box for receiving the lower portion of the cultivation base is arranged at a central through hole of the base, a receiving cavity with a groove end is arranged on the water receiving box tray, the end with the groove of the water receiving box tray extends into the bottom of the receiving cavity from one side of the central through hole of the base, and a positioning block is arranged above the base.

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