CN217336842U - Automatic aerial fog cultivation planting system - Google Patents

Abstract

The utility model discloses an automatic aeroponic cultivation planting system, which comprises a frame consisting of a chassis and a seedbed; at least two planting towers arranged on the surface of the chassis; a nutrient solution tank arranged below the seedbed; the aerial fog spraying device is arranged on the chassis and connected to the nutrient solution tank, and at least carries out automatic aerial fog spraying on the interior of the two planting towers; wherein install the timer among the aerial fog injection apparatus, the aerial fog injection apparatus who is located planting tower carries out the accuracy to the plant of specific position department and sprays. The utility model discloses a be provided with the timer in automatic aerial fog cultivation planting system, can realize the automatic start and close the operation of nutrient solution pump, effectively solved the high power consumption that the nutrient solution pump does not stop the function and leads to, the increase of operation cost and the problem of final nutrient solution pump destruction. Connect through the nutrient solution pump and extend the branch pipe, carry out the nutrient solution to the plant in at least two sets of planting towers and spray accurately.

Description

Automatic aerial fog cultivation planting system

Technical Field

The utility model belongs to the technical field of the farming technique and specifically relates to an automatic aerial fog cultivation system of planting is related to.

Background

As more and more people move to cities to find better employment opportunities, the dramatic increase in urban population also means a dramatic increase in food demand. Today, more than half of the world's population resides in cities. By the united nations 'estimate, the urban population will account for 65% of the world's total population by the year 2050. This will present a great challenge to the food supply in cities.

Urban agriculture, growing more food in smaller areas, can address some of the pressure facing rural areas. However, because the economic benefits that agriculture can bring are not great, many young people are reluctant to use farming as an occupational work, resulting in the average age of farmers becoming larger and larger. But if we want to have food, we have to get farmers a higher income, make agriculture a running industry, and make farmers an attractive occupation to attract more knowledgeable young people to do agriculture. There is a need to increase agricultural productivity and scale up production and economic efficiency in specialized production.

Traditional agriculture requires the use of a large amount of water and land resources, but these resources are limited. Aeroponic cultivation is one of the most efficient planting techniques in modern agriculture. The roots of the vegetables planted by the technology are suspended in the air, and meanwhile, the nutrient solution is sprayed to the roots of the vegetables in a mist form through the spray nozzle, so that the roots of the vegetables absorb the nutrient solution most effectively and fully, the vegetables grow fast and greatly, and the aerial fog cultivation is rapidly popularized. Therefore, the present application proposes the development of soilless culture technology to solve the problem of limited water and land resources.

Although there are some soilless cultivation systems, such as an independent automatic aeroponic cultivation box with patent number 2020232504277.

For example, patent No. ZL200920074242X discloses a spray type three-dimensional cultivation system for trapezoidal three-dimensional planting bodies, and discloses a technology such as steel frame, one-piece, fixing and installation by welding, bolts, nuts and other processes. Because parts are produced manually in a factory, the precision is difficult to achieve in hundreds, and the parts are corrected and reworked due to inaccurate machining size during field assembly, so that the characteristics of time and labor waste, installation, higher construction cost than equipment cost, incapability of realizing aerial root at low cost and low … cost are realized, the popularization of agricultural industrial technology is facilitated, and farmers are easy to transform into blue-collar workers.

And so many parts are installed manually, and the interface of every part is difficult to accomplish all to seal, leads to when spraying nutrient solution, and the nutrient solution leaks and causes the waste of operation one-tenth, and when the nutrient solution leaks, meets the sunshine, can impel the planting body to grow green alga, destroys the planting body, harms vegetables simultaneously. Because the vegetation district need be connected to other independent nutrient solution pond through the pipeline, carry the vegetation district through high-pressure pump pumping water, just need calculate the demand that guarantees that the nutrient solution volume can satisfy whole vegetation district to the high-pressure pump flow, pressure etc. earlier, plant vegetables. The further the plant growing area is from the independent nutrient solution pool, the higher the price of the high-pressure pump. And the whole installation is complex, time-consuming and expensive.

The residual nutrient solution needs to be recycled to the nutrient solution pool through a pipeline. Because of the long distance, the nutrient solution may be infected, requiring the installation of a sterilization device. In order to slow down the flow rate of the returned nutrient solution and ensure that the returned nutrient solution can be sterilized by the sterilizing device, a buffer groove and a buffer wall are needed, and the manufacturing cost and the installation time are increased. In order to reduce the waste of nutrient solution, an inclined backflow groove (namely, a backflow groove dug on the ground) is arranged on the bottom surface of the three-dimensional planting body to allow the nutrient solution to flow back to a remote nutrient pool. The planting technology is only suitable for soil farms which are lack of cultivated land and are not suitable for urban agriculture, particularly soilless planting, popularized in more and more cities in the world due to the requirement of dramatic increase of population.

Because of the high total cost including the field construction and the long construction time, the method is not suitable for urban agricultural plants with high yield and high efficiency which are popularized all over the world. The hole of the implant is 90-degree straight through. All plants, including the vegetables, grow upwards according to the natural law in the whole growth process. When the vegetable seedlings are planted on the planting bodies on the two inclined side surfaces, the vegetable seedlings can not grow upwards according to a natural rule by directly passing through the holes at 90 degrees, and the growth of the vegetable seedlings is finally influenced.

The existing spray type three-dimensional cultivation system patent technology of related trapezoidal three-dimensional planting bodies completely depends on manually placing a culture medium with vegetable seedlings into each planting hole on a hole plate. During picking, each vegetable is pulled out from each planting hole and placed into the vegetable basket completely by manpower, after the vegetable basket is full, the vegetable basket is required to be conveyed to a vegetable collection place along a narrow passage between each row of three-dimensional planting bodies one by one to deliver the vegetable in the basket to a collection person, and then the vegetable is returned to the original final picking position through the narrow passage, so that labor and time are consumed, and low production efficiency and economic benefit are caused. The larger the farm, the more workers are required. The problem that farmers age all over the world at present, and the work is outdoor work, the problem that needed labor force is difficult to solve, especially young labor force is attracted, the practical application of the prior patent technology is greatly limited, the popularization of the agricultural industrialized technology cannot be facilitated, and the farmers are transformed into blue-collar workers.

SUMMERY OF THE UTILITY MODEL

The utility model provides a technical problem be that prior art's cultivation system field installation is complicated, and construction cost is high, need to engage a lot of workman in vegetable planting and the work of reaping.

For solving the technical problem, the utility model discloses technical scheme provides an automatic aerial fog cultivation system of planting, wherein, include:

a frame composed of a chassis and a seedbed;

at least two planting towers mounted on the surface of the chassis;

a nutrient solution tank installed below the seedbed;

the aerial fog spraying device is arranged on the chassis and connected to the nutrient solution tank, and at least carries out automatic aerial fog spraying on the interior of the two planting towers; wherein

The aerosol injection device is internally provided with a timer, and the aerosol injection device positioned in the planting tower can accurately spray plants at specific positions;

the automatic seeding equipment consists of a sponge piece storage box, a sponge piece conveying belt, a seeded sponge output belt, a seeding limiting cylinder, a vacuum device capable of moving left and right and lifting, a seed tank vibration device, a liftable perforated panel and a cabinet;

the seedling transplanter consists of a manipulator transverse moving module, a manipulator longitudinal module and a spacing manipulator;

the placing system comprises a full-automatic placing/collecting mechanism and a machine-assisted placing device;

the automatic vegetable root cutting equipment consists of a cutting table, a pore plate mounting opening, an automatic pore plate fixing clamp, an air cylinder, a cutting knife, a vegetable root collecting box, a limit switch and a compressor;

the automatic vegetable packaging mechanism consists of a vegetable conveying belt, a packaging unit and an output machine.

Optionally, plant the tower including orifice plate, back orifice plate, a pair of curb plate and the roof that is trapezoidal tower column structure equipment, the orifice plate with back orifice plate relative slope and be close to the setting, it is a pair of the curb plate is connected respectively the orifice plate with the left and right sides of back orifice plate, the roof lid is located the orifice plate back orifice plate and a pair of the top and the four sides of curb plate respectively with the orifice plate back orifice plate and a pair of the topside of curb plate is connected, the orifice plate back orifice plate with the surface of roof is provided with the planting hole that a plurality of matrixes were arranged, just all be provided with the culture medium in planting the hole, plant the hole with the inside cavity UNICOM of planting the tower, the planting hole is cylinder hole structure and sets up with the axially perpendicular horizontal plane, the culture medium level set up in planting the hole.

Optionally, the aerosol spray device comprises:

a nutrient solution pump fixed on the chassis;

the water inlet pipe is connected with an inlet of the nutrient solution pump;

the delivery pipe is connected with the outlet of the nutrient solution pump;

an extension branch pipe connected with the delivery pipe and passing through any side plate of the planting tower, and

the atomizing spray head is arranged on the extension branch pipe;

nutrient solution is sprayed on the plants planted in the planting holes in an aerosol manner through the water inlet pipe, the nutrient solution pump, the conveying pipe, the extension branch pipe and the atomizing spray head, wherein

The inlet tube with install the stop valve between the nutrient solution pump, the conveyer pipe with extend and install filter and strong magnetism treater between the branch pipe, the filter is close to the nutrient solution pump.

Optionally, a liquid level display for displaying the liquid level of the nutrient solution is installed on the side wall of the nutrient solution tank, a liquid level ball float valve is installed in the nutrient solution tank, the liquid level ball float valve is connected to an external nutrient solution supply tank through a pipeline, the nutrient solution supply tank is connected to a nutrient solution blending tank through a pipeline, and the nutrient solution pump is connected with the liquid level ball float valve in a communication manner or electrically connected with a background controller.

Optionally, the sowed sponge output belt and the sponge piece conveying belt are mounted at the top of the cabinet, the sowed sponge output belt and the sponge piece conveying belt are mounted on the outer walls of the sowed sponge output belt and the sponge piece conveying belt, the sponge piece storage box is mounted at the top of the sponge piece conveying belt, two racks are fixedly connected to the top of the cabinet, driving cylinders are mounted on the outer walls of the two racks, the total number of the driving cylinders is four, the two driving cylinders control the vacuum device to move and lift, the other two driving cylinders control the opening panel to lift, the outer wall of the opening panel is communicated with and provided with a conical nozzle, the vacuum device is provided with a needle type suction nozzle, and a seed groove vibration device are mounted above the sowed sponge output belt.

Optionally, install sponge transfer chain and orifice plate transfer chain on the seedling transplanter, and set up the sensor in the transport terminal position of sponge transfer chain and orifice plate transfer chain, divide apart from the manipulator and install five tong, divide apart from the manipulator still to install servo motor lead screw structure.

Optionally, the full-automatic mechanism of putting/receiving comprises compound automated guided vehicle, arm clamp, transports the frame, orifice plate and roof for put and collect orifice plate and roof, compound automated guided vehicle still includes the vision ware from the area, transport and install the traction lever on the frame, orifice plate and roof all run through and are equipped with the hook hole, the outer wall of orifice plate and roof all is seted up flutedly, the arm is installed on compound automated guided vehicle, be connected with the arm clamp on the arm.

Optionally, the machine-assisted placing device comprises an internal combustion engine or an electric drive vehicle, a controller, a guardrail and a shelf, wherein the controller, the guardrail and the shelf are all mounted on the internal combustion engine or the electric drive vehicle.

Optionally, an orifice plate mounting opening is formed in the top of the cutting table, a fixing clamp is mounted on one side of the top of the cutting table, an air cylinder is mounted on the right side of the top of the cutting table, the output end of the air cylinder is fixedly connected with the orifice plate mounting opening, the cutting knife is mounted in the middle of the cutting table, the limit switch is mounted at the left end of the fixing clamp, and the compressor is mounted on a cross frame below the cutting table.

Optionally, the packing unit is fixedly connected to the upper side of the vegetable conveying belt, the packing unit includes a driving motor, a driving roller, a packing roll film, a feeding conveyor and a former, and the output machine is installed at the right end of the vegetable conveying belt and used in cooperation with an outlet of the packing unit.

The utility model discloses technical scheme's beneficial effect is:

1. the utility model discloses a be provided with the timer in automatic aerial fog cultivation planting system, can realize the automatic start and close the operation of nutrient solution pump, effectively solved the high power consumption that the nutrient solution pump does not stop the function and leads to, the increase of operation cost and the problem of final nutrient solution pump destruction. Connect through the nutrient solution pump and extend the branch pipe, carry out the nutrient solution to the plant in at least two sets of planting towers and spray accurately. Meanwhile, the method can be used for quickly and accurately building agricultural factories with lower construction cost, is suitable for high-efficiency and high-capacity urban farms which are popularized in more and more cities, and solves the problem that the safety of an urban food chain is not guaranteed.

2. The utility model discloses a cultivation planting system can replace and need a lot of workman in the open air now, from the sponge piece that tears down and to have the vegetable seedling of sponge piece one to need according to the position of planting hole on orifice plate and the roof incessantly repeated bending or carrying come to the artifical hole of plugging in orifice plate and roof of sponge piece that the countless has the vegetable seedling, practice thrift the work that consumes manpower and time very much greatly, effectively solve present agricultural generally in the face of very difficult finding young workman and engage in the problem of agricultural. The automatic guiding vehicle with the automatic robot hand is used for hanging the hole plate with the vegetable seedling sponge block on the hook of the planting tower from the conveying frame and taking down the hole plate (top plate) with vegetables from the automatic guiding vehicle with the automatic robot hand when the vegetables are collected, and the hole plate (top plate) is put on the hole plate (top plate) to be conveyed to the automatic vegetable root cutting equipment to cut off the vegetable roots, so that the problem that the existing agriculture generally faces to the situation that young workers are very difficult to find to engage in the agriculture is solved, the productivity and the income are greatly improved, and the problem that the safety of an urban food chain is not guaranteed is solved.

Drawings

Fig. 1 is a schematic structural view of an automatic aerial fog cultivation planting system in an embodiment of the present invention;

FIG. 2 is a perspective view of an automatic aerial fog cultivation system with an aerial fog spraying device removed according to an embodiment of the present invention;

FIG. 3 is a perspective view of an automatic sowing apparatus in an embodiment of the present invention;

fig. 4 is a perspective view of a seedling transplanter in an embodiment of the present invention;

FIG. 5 is a perspective view of the seedling transplanter in an embodiment of the present invention;

FIG. 6 is a side view of the fully automatic placing/retrieving mechanism according to the embodiment of the present invention;

fig. 7 is a partial structural plan view of the fully automatic placing/collecting mechanism in the embodiment of the present invention;

fig. 8 is a perspective view of a partial structure of the fully automatic placing/collecting mechanism in the embodiment of the present invention;

fig. 9 is a perspective view of the structure of the internal combustion engine or the electric drive vehicle according to the embodiment of the present invention;

fig. 10 is a perspective view of the cylinder of the automatic vegetable root cutting device in the embodiment of the present invention in an initial state;

fig. 11 is a perspective view of the automatic vegetable root cutting device according to the embodiment of the present invention in an extended state of the cylinder;

fig. 12 is a perspective view of the automatic vegetable packaging mechanism according to the embodiment of the present invention.

The specific implementation mode is as follows:

the present invention will be further described with reference to the accompanying drawings and specific embodiments, but the present invention is not limited thereto.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise" and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and to simplify the description, but do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore should not be construed as limiting the present invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless specifically limited otherwise.

In the present invention, unless otherwise explicitly specified or limited, the terms "mounted," "connected," "secured," and the like are to be construed broadly, e.g., as being fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood according to specific situations by those skilled in the art.

In the present disclosure, unless expressly stated or limited otherwise, the first feature "on" or "under" the second feature may comprise direct contact between the first and second features, or may comprise contact between the first and second features not directly. Also, the first feature being "on," "above" and "over" the second feature includes the first feature being directly on and obliquely above the second feature, or merely indicating that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature includes the first feature being directly above and obliquely above the second feature, or simply meaning that the first feature is at a lesser level than the second feature.

Referring to fig. 1-12, an embodiment of an automated aerial fog planting system is shown, which includes a frame consisting of a chassis 2 and a seedbed 13; at least two planting towers 1 arranged on the surface of the chassis 2; a nutrient solution tank 9 arranged below the chassis 2; the aerial fog spraying device is arranged on the chassis 2 and connected to the nutrient solution tank 9, and at least carries out automatic aerial fog spraying on the interior of the two planting towers 1; wherein install in the aerial fog injection apparatus and be connected with background controller communication (accessible arbitrary communication connected mode, such as the most common connected modes such as RS35, RS232, RS422, are prior art, and it does not describe here) timer 22, the aerial fog injection apparatus who is located planting tower 1 carries out the accuracy to the plant of specific position department and sprays.

In this embodiment, the planting tower 1 includes a pore plate 3 assembled in a trapezoidal tower-shaped structure, a pair of side plates 12, and a top plate 19, the pore plate 3 is relatively inclined and disposed close to each other, the pair of side plates 12 are respectively connected to two sides of the pore plate 3 located on the front side and the rear side, and the top plate 19 covers the top of the pair of side plates 12 of the pore plate 3 and four sides of the top plate are respectively connected to the top edges of the pore plate 3 and the pair of side plates 12.

In this embodiment, the surface of orifice plate 3, roof 19 is provided with planting hole 4 that a plurality of matrixes were arranged, and all is provided with culture medium 5 in planting hole 4, plants hole 4 and plants the inside cavity UNICOM of tower 1.

In this embodiment, the planting holes 4 are cylindrical hole structures and are arranged axially and vertically in the horizontal plane, and the culture medium 5 is horizontally arranged in the planting holes 4.

In this embodiment, the aerosol spray device comprises a nutrient solution pump 10 fixed to the chassis 2; an inlet pipe 26 connected to an inlet of the nutrient solution pump 10; a delivery pipe 8 connected to the outlet of the nutrient solution pump 10; an extension branch pipe 6 connected with the delivery pipe 8 and penetrating through a side plate 12 of any planting tower 1, and an atomizing nozzle 7 mounted on the extension branch pipe 6; nutrient solution is sprayed in an aerosol form on the plants planted in the planting holes 4 through the water inlet pipe 26, the nutrient solution pump 10, the conveying pipe 8, the extension branch pipe 6 and the atomizing spray head 7.

In this embodiment, a shut-off valve 14 is installed between the inlet line 26 and the nutrient solution pump 10.

In this embodiment, a filter 20 and a strong magnetic processor 21 are installed between the delivery pipe 8 and the extension branch pipe 6, and the filter 20 is close to the nutrient solution pump 10.

In this embodiment, a liquid level display 15 for displaying the liquid level of the nutrient solution is installed on the side wall of the nutrient solution tank 9, a liquid level ball float valve 11 is installed in the nutrient solution tank 9, the liquid level ball float valve 11 is connected to an external nutrient solution supply tank 24 through a pipeline 23, and the nutrient solution supply tank 24 is connected to a nutrient solution blending tank 25 through a pipeline; the nutrient solution supply tank 24 and the nutrient solution blending tank 25 are disposed in a vertical direction so that the nutrient solution flows downward toward the nutrient solution tank 9 by gravity.

In this embodiment, the nutrient solution pump 10 and the liquid level float valve 11 are both in communication connection or electrically connected to the background controller, and the nutrient solution supply tank 24 and the nutrient solution blending tank 25 are also in communication connection with the background controller.

In the embodiment, the automatic seeding device comprises a sponge piece storage box, a sponge piece conveying belt, a sowed sponge output belt, a seeding limiting cylinder, a vacuum device capable of moving left and right and lifting, a seed groove vibration device, a liftable perforated panel and a cabinet, wherein the sowed sponge output belt 33 and the sponge piece conveying belt 32 are both arranged at the top of the cabinet 30, small cylinders 34 are arranged on the outer walls of the sowed sponge output belt 33 and the sponge piece conveying belt 32, the sponge piece storage box 31 is arranged at the top of the sponge piece conveying belt 32, the top of the cabinet 30 is fixedly connected with two racks, driving cylinders are arranged on the outer walls of the two racks, the total number of the driving cylinders is four, the two driving cylinders control the vacuum device 35 to move and lift, the other two driving cylinders control the perforated panel 38 to lift, and a conical nozzle is arranged on the outer wall of the perforated panel 38, the vacuum device 35 is provided with a needle type suction nozzle, and a seed groove 36 and a seed groove vibrating device 37 are arranged above the output belt 33 of the sowed sponge.

During the specific use, after sponge piece 39 was placed to sponge piece storage box 31, sponge piece conveyer belt 32 automatic operation, sponge piece conveyer belt 32 rotated the automatic shutdown in a week back. The sponge sheet conveying belt 32 starts to run, and the lowermost sponge sheet 39 in the sponge sheet storing box 31 is conveyed below the perforated panel 38 which is provided so as to be able to rise and fall. When the sponge sheet 39 is in this position, the small air cylinders 34 are provided on both sides to restrict the position of the sponge sheet 39. After the detection device detects that the sponge sheet exists, the sponge sheet conveying belt 32 automatically stops. Then the screw mandrel module drives the vacuum device 35 to move to the position above the seed groove 36, and then the vacuum device descends, meanwhile, the seed groove vibration device 37 starts to vibrate, so that the needle type suction nozzle arranged on the vacuum device 35 can easily suck the vibrated seeds, and then the vacuum device 35 sucking the seeds automatically returns to the position right above the perforated panel 38. The liftable panel 38 is then lowered over the sponge sheet 39 which has just stopped on the belt 32, and all the tapered nozzles of the panel 38 are aligned with the holes of all the previously cut round pieces of sponge sheet, thereby enlarging the diameter of all the holes. At this point the vacuum unit 35 just above the aperture plate 38 begins to descend and all the needle nozzles of the vacuum unit 35 will be aligned with all the tapered holes in the aperture plate 38. At this point the vacuum 35 stops sucking and the seed falls naturally from all its needle nozzles into the hole of the previously cut round piece of sponge 39, which has been enlarged. After the seeds fall into all the holes preset in the sponge sheet, the vacuum device 35 is automatically lifted back to the original position, and then the perforated panel 38 is also automatically lifted back to the original position. The small air cylinders 34 on the two sides are opened for limiting, the sowed sponge output belt 33 starts to output the sponge pieces 39 with sowed seeds from the sowing position. After the sponge pieces 39 with the seeds sowed are output from the sowing position, the machine continues to circulate, the sponge piece 39 at the bottom in the sponge piece storage box 31 is sent to the position below the preset liftable perforated panel 38, the small cylinders 34 at the two sides are opened again for limiting, and the steps are repeated.

In this embodiment, by the seedling transplanter that manipulator sideslip module, the vertical module of manipulator and minute apart from manipulator are constituteed, install sponge transfer chain and orifice plate transfer chain on the seedling transplanter 40, and set up the sensor in the transport terminal position of sponge transfer chain and orifice plate transfer chain, five tong 44 are installed to minute apart from manipulator 43, and servo motor lead screw structure 45 is still installed to minute apart from manipulator 43.

In particular, the young-seedling-planted sponge blocks 46 are pre-cut into 9 x 9 rows of sponge blocks 46 from 250 mm x 250 mm sponge pieces by equipment, and conveyed from the sponge conveying lines in regular rows, and the top plate 19 or the pore plate 3 is conveyed through the pore plate conveying lines as required. When the entire sponge block 46 and the top plate 19 (or the well plate 3) are conveyed to the specified position of the loading position by the conveyor line, the sensor senses that the position is in place, and the conveyor line is temporarily stopped. After the sensor transmits a signal to the programmable controller, the programmable controller controls the longitudinal manipulator module 42, the transverse manipulator module 41 and the spacing manipulator 43 to move to the specified position of the sponge block, the spacing manipulator 43 is provided with 5 clamping hands 44 with the same spacing as the single position of the sponge block, the clamping hands 44 are sleeved into the sponge block 46 at the specified position through a servo motor screw rod structure 45 on the spacing manipulator, the sponge block 46 is clamped (the diameter of the sponge block is 21 mm, the aperture of the top plate 19 and the aperture plate 3 is 20 mm, the sponge block needs to be clamped and deformed to the diameter of 20 mm), and then the clamped sponge block 46 is loaded into the planting hole at the specified position. Because the distance between the positions of the top plate 19 and the pore plate 3 for loading the sponge blocks is different, the distance-dividing manipulator 43 adjusts the clamping distance of the sponge blocks 46 through the distance between the top plate 19 and the pore plate 3 by a servo motor screw rod structure 45, and the distance-dividing manipulator follows the change of the distance between the loading positions of the top plate 19 and the pore plate 3.

In this embodiment, the placement system includes a fully-automatic placement/collection mechanism and a machine-assisted placement device;

specifically, full-automatic putting/collecting mechanism comprises compound automated guided vehicle, arm clamp, transports frame, orifice plate and roof for put and collect orifice plate and roof, compound automated guided vehicle 60 still includes the vision ware from taking, transport and install traction lever 71 on the frame 63, orifice plate 3 and roof 19 all run through and are equipped with hook hole 64, recess 65 has all been seted up to the outer wall of orifice plate 3 and roof 19, arm 61 is installed on compound automated guided vehicle 60, be connected with arm clamp 62 on the arm 61, compound automated guided vehicle can be the AGV dolly in the mechanism is put/collected in full-automatic, wholly adopts full-automatic intelligent operation, only need the procedure of manual control settlement, can accomplish 24 incessant works in whole day, be fit for extensive planting user.

Specifically, the compound automatic guiding vehicle 60 is connected to a traction rod 71 of an idle conveying frame 63 through a traction connecting rod according to a self-contained vision device and a set program, and then is driven to the related planting tower 1, the mechanical arm 61 is clamped to grooves 65 of hole plates 3 at two oblique feet of each planting tower 1 full of vegetables through mechanical arm clamps 62 on the arm, the hole plates 3 positioned at the front and the back are placed on the idle conveying frame 63 one by one from bottom to top until the conveying frame is filled, then the hole plates 3 positioned at the front and the back of the full vegetables loaded on the conveying frame are transferred to a vegetable root cutting area for unloading, and then the idle conveying frame 63 is pulled to return to the original position for continuing vegetable harvesting work. According to the steps, the hole plates 3 which are positioned at the front and the back and are full of vegetables are collected and transported.

Further, according to the inputted program, the composite automatic guided vehicle 60 is opened to the planting tower 1 through the draw bar 71 connected to the empty carrying frame 63 through the draw connection bar according to the vision device and the set program, the robot arm is clamped to the groove 65 of the top plate 19 of the full vegetable through the clamp 62 on the arm, the top plate 19 of the full vegetable is picked up one by one, placed on the empty carrying frame 63 to the carrying frame 63 to be filled, transferred to the root cutting area to be unloaded, and then the empty carrying frame 63 is pulled to return to the original position to continue the vegetable picking up work. The top plate 19 full of vegetables is collected and transported according to this step, and the movable supporting arm 70 is provided on the transporting frame 63, and the distance between them can be adjusted to the most suitable distance by the movable supporting arm 70.

In this embodiment, the machine auxiliary placing device is composed of an internal combustion engine or electric drive vehicle 72, a controller 73, a guardrail 74 and a shelf 75, the controller 73, the guardrail 74 and the shelf 75 are all installed on the internal combustion engine or electric drive vehicle 72, the machine auxiliary placing device is a manual semi-automatic device, and the semi-automatic device replaces automatic equipment such as the composite automatic guided vehicle 60 and a mechanical arm with manual work, so that the overall manufacturing cost is low, and the machine auxiliary placing device is suitable for small-scale planting users.

Further, the operator moves the internal combustion engine or the electric drive vehicle 72 to the position where the well plate 3 or the top plate 19 is to be placed by the controller 73, takes out the well plate 3 or the top plate 19 with seedlings from the shelf 75 by grasping the handle 76 mounted on the plate, and hooks the two hook holes 64 of the well plate 3 or the top plate 19 to the hooks on the support rods of the planting tower 1. According to the steps, all the pore plates 3 or the top plates 19 in the goods shelves 75 of the internal combustion engine or the electric drive vehicle 72 are placed on the planting tower 1. Then the operator drives the internal combustion engine or the electric drive vehicle 72 back to the seedling raising area through the controller 73 to load other hole plates 3 or top plates 19 with seedlings on the shelf 75 until the shelf is full, and then drives the internal combustion engine or the electric drive vehicle back to the position of the last hole plate 3 or top plate 19 to finish the placement of the hole plates 3 or the top plates 19 according to the same steps.

In this embodiment, by the cutting bed, the orifice plate installing port, automatic orifice plate fixation clamp, the cylinder, the cutting knife, the vegetable root collecting box, the vegetable root automatic cutting equipment that limit switch and compressor are constituteed, the top of cutting bed 80 is equipped with orifice plate installing port 82, fixation clamp 83 is installed to one side at cutting bed 80 top, fixation clamp 83 is the braking anchor clamps of industry conventional use, this braking anchor clamps are equipped with the solenoid valve, cylinder 84 is installed on the right side at cutting bed 80 top, cylinder 84's output and orifice plate installing port 82 fixed connection, cutting knife 85 is installed in the middle part of cutting bed 80, limit switch 87 is two, two limit switch 87 are installed respectively in the left end portion of fixation clamp 83 and the right-hand member portion of orifice plate installing port 82, compressor 81 cutting bed is installed on the crossbearer below 80, the solenoid valve, limit switch 87 and cylinder 84 electric connection.

Before use, the arms of the air cylinder 84 are retracted. When the hole plate 3 (or the top plate 19) full of vegetables is manually placed in the hole plate mounting opening 82, the limit switch 87 is contacted, the electromagnetic valve connected with the circuit is started, the fixing clamp 83 automatically fixes the hole plate 3 (or the top plate 19), meanwhile, the air cylinder 84 automatically stretches, the hole plate 3 (or the top plate 19) full of vegetables is pushed towards the direction of the cutting knife 85 until the limit switch 87 at the other end is contacted, the electromagnetic valve connected with the circuit is closed to cut off an air source, the cylinder arm of the air cylinder 84 stops working, and meanwhile, the fixing clamp 83 is automatically opened. When the hole plate 3 (or the top plate 19) is pushed forwards through the automatic stretching of the air cylinder 84, the vegetable roots are cut off by the cutting knife 85 when the hole plate 3 (or the top plate 19) passes through the cutting knife 85. The cut vegetable roots fall into the vegetable root collection box 86 for convenient disposal. The compressor 81 provides compressed air for the control system. When the perforated plate 3 (or the top plate 19) which has been cut into root is manually removed, the limit switch 87 is opened, the electromagnetic valve connected with the circuit opens the air source, so that the cylinder arm of the air cylinder 84 retracts to return to the initial state.

In this embodiment, by the vegetables automatic packaging mechanism that vegetables conveyer belt, packing unit and export machine are constituteed, the top fixedly connected with packing unit 91 of vegetables conveyer belt 90, packing unit 91 includes driving motor, drive roller, packing roll up membrane, feeding conveyer and former, and export machine 92 is installed in the right-hand member portion of vegetables conveyer belt 90, and uses in the export cooperation of packing unit 91.

During specific use, vegetables which are cut into roots are manually placed on the vegetable conveying belt 90 of the packaging machine, and the vegetable conveying belt 90 conveys the vegetables to the packaging unit 91. In the packaging unit 91, the driving roller is driven to rotate by the driving motor, then the packaging film is packaged and formed by the packaging film, the packaged vegetables are sent into the forming device by the feeding conveyor to be longitudinally sealed and transversely sealed and cut, and then the vegetables are output by the discharging output machine 92.

The features and functions of the present invention will be further understood from the following description.

The embodiment shows an automatic aeroponic cultivation planting system, which comprises a nutrient solution tank 9; the planting tower 1 consists of a pore plate 3 and a top plate 19 which are formed by at least two groups of independent and same plates and is used for planting green plants; isolating the nutrient solution tank 9 from the chassis 2 of the planting tower 1 and the seedbed 13 supporting the same; and an aerosol injection device which is arranged between the two planting towers 1 and is used for adding nutrient solution to the green plants.

The planting tower 1 comprises a pore plate 3, a side plate 12 and a top plate 19, wherein the pore plate 3, the side plate 12 and the top plate are connected in a surrounding mode; the pore plate 3 and the top plate 19 are respectively provided with a plurality of planting holes 4.

The culture medium 5 is arranged in the planting hole 4, and the axis of the planting hole 4 is in a horizontal and vertical state. The pore plate 3, the top plate 19 and the side plate 12 are fixed through a connecting rod, and the side plate 12 is provided with two water inlet holes 121 in a penetrating mode. The automatic aerosol injection device comprises a nutrient solution pump 10 arranged on a chassis 2, an outlet of the nutrient solution pump 10 is connected with a delivery pipe 8, the delivery pipe 8 is connected with a filter 20 and a strong magnetic processor 21, the delivery pipe 8 penetrates through water inlet holes 121 of side plates 12 on the left side and the right side, the delivery pipe 8 is positioned on a surface extension branch pipe 6 in a planting tower 1, and an atomization nozzle 7 is arranged on the extension branch pipe 6. A liquid level display 15 is installed on the side wall of the nutrient solution tank 9, a liquid level ball float valve 11 is installed in the nutrient solution tank 9, and a drain plug 17 is installed below the nutrient solution tank 9.

The planting body of the planting tower 1 consists of a pore plate 3 and a top plate 19. The pore plate 3 is provided with planting holes 4 which are arranged at intervals, the vertical distance of the planting holes 4 is larger than the horizontal distance of the planting holes, the top plate 19 is provided with planting holes 4 which are arranged at intervals, the vertical distance of the planting holes 4 is the same as the horizontal distance of the planting holes, and the planting holes 4 are provided for placing seedling growth culture media 5 which are strong in water absorption and have standard sizes, such as sponges, and the seedlings can absorb nutrient solution to grow.

At least two rows of extension branch pipes 6 for conveying nutrient solution are arranged in a closed space formed by the top plate 19, the pore plate 3, the side plate 12 and the bottom plate 2, atomizing nozzles 7 with the distance of preferably at least 250 mm are arranged on the extension branch pipes 6, and mist nutrient solution is provided for seedlings planted in the planting holes 4.

Chassis 2 installs and runs through it and is connected to the nutrient solution pump 10 of the nutrient solution in the nutrient solution case 9 through inlet tube 26, and nutrient solution pump 10's exit linkage is to conveyer pipe 8, installs filter 20 and strong magnetism treater 21 on the conveyer pipe 8, passes the inlet opening 121 of the curb plate 12 on left and right sides, connects the surface extension branch pipe 6 that conveyer pipe 8 is located planting tower 1, extends and installs atomizer 7 on the branch pipe 6.

Connected to at least two rows of extension legs 6 with atomizer nozzles 7 arranged at a distance of at least 250 mm from each other in the closed space formed by the top plate 19, the perforated plate 3, the side plate 12 and the inside of the bottom plate 2. A liquid level ball float valve 11 is arranged in the nutrient solution tank 9.

The nutrient solution pump 10 draws nutrient solution from the nutrient solution tank 9 through a water inlet pipe 26 that passes through the bottom plate. A stop valve 14 is installed at the water inlet pipe 26, and when the liquid level float valve 11 is out of order and the nutrient solution cannot be automatically supplied from the nutrient solution supply tank, the stop valve 14 can be manually opened to directly supply the nutrient solution from the nutrient solution supply tank 24 through the pipeline 23. A drain plug 17 is provided below each nutrient solution tank 9 for draining the nutrient solution in the nutrient solution tank 9 when necessary.

The tower type design of the automatic aerial fog cultivation planting system is scientific and reasonable; as long as a walkway of at least 0.6 m is reserved between each row of equipment, the surfaces of the automatic aerial fog cultivation planting systems at two ends, on which vegetables are not planted, of each row are arranged in the east-west direction, and each row of planting bodies can be exposed to the irradiation of sunlight all day.

The liquid level float valve 11 in the nutrient solution tank of the automatic aerial fog cultivation planting system of the embodiment is connected to a nutrient solution supply tank 24 through a pipeline 23 to form a nutrient solution supply system. When the liquid level of the nutrient solution is reduced to a set low liquid level, the liquid level ball float valve 11 is automatically opened, the nutrient solution automatically flows to the related nutrient solution box 9 from the nutrient solution supply tank 24 through gravity flow until the liquid level rises to the set liquid level, the liquid level ball float valve is closed, and the input of the nutrient solution is stopped. The nutrient solution in the nutrient solution supply tank 24 is input from a blending tank 25 with the function of automatically blending the fertilizer proportion through a pipeline. The design truly realizes the function of automatically supplying the nutrient solution of the automatic aerial fog cultivation planting system.

All the components of the system of the embodiment are module standard parts produced by moulds and accurately connected into the system. In addition, because the components are produced by moulds, the price is low, the field installation time and the installation cost are simultaneously reduced to the minimum degree, and the popularization of agricultural industrialized technology can be really realized.

All components are module standard parts produced by a mould, so that all seams can be sealed, and the situation that the planting body grows green algae and damages the planting body and vegetables when the planting body wastes waste caused by the leakage of nutrient solution and encounters sunlight is avoided.

The automatic aerial fog cultivation planting system of this embodiment's structure comprises planting tower, curb plate and chassis. Each system is provided with a preset nutrient solution box, a nutrient solution pump is arranged at the top of the nutrient solution box, an outlet of the pump is connected to a conveying pipe, a filter and a strong magnetic processor are connected, the conveying pipe penetrates through side plates on the left side and the right side, surface extension branch pipes in the planting tower are connected to the conveying pipe, and spray heads are installed on the branch pipes.

The delivery pipe passes through the side plate and is connected to at least two rows of nutrient solution branch pipes with aerosol nozzles with the distance of at least 250 mm in the closed space formed by the side plate and the base plate of the planting tower. Because the system is composed of standard modules, several standard specifications can be preset, pipeline hydraulic calculation is carried out, and parts such as pumps, pipelines, spray heads and the like of all parts of the irrigation system are standardized. The system is spliced according to the relevant preset specifications of the area pairing of the relevant farm, and the problems that the flow, the pressure and the like of each high-pressure pump are firstly calculated to ensure that the nutrient solution amount can meet the requirement of the whole plant growth area and the whole installation is complex, time-consuming and high in cost due to the fact that the original nutrient solution pump is far away from a nutrient solution pool are effectively solved.

The system of this embodiment, the direct gravity of remaining nutrient solution that spouts the vegetable root from the shower nozzle down flows back to the nutrient solution case, has solved because the nutrient solution pond is kept away from the plant species and is led to the backflow pipeline because the distance is long and need install the problem that sterilizing equipment and buffering ditch groove and buffer wall's demand brought.

The automatic aerial fog cultivation planting system of this embodiment's design lets the direct gravity of surplus nutrient solution that spouts the vegetable root from the shower nozzle down flow back to the nutrient solution case of self, need not to dig the backward flow groove on ground and lets surplus nutrient solution flow back to the nutrient solution pond, is applicable to the farmland that has the ground, and ground planting such as reinforced concrete or pitch is favorable to promoting urban agriculture to solve the problem that global face lacks arable land and urban population sharply increases.

The system of the embodiment can be connected through pipelines to form a large or small system according to specific requirements, is operated automatically, and is suitable for large-scale agricultural factories and small farmers in cities.

The holes of the implant in the automatic aeroponic cultivation planting system of the embodiment are opened according to the most suitable angle after calculation according to the specific inclination of the implant. The holes which are opened after calculation are right upward, accord with the natural growth rule of the vegetables, and are beneficial to the growth of the vegetables.

To sum up, the utility model discloses a be provided with the timer in automatic aerial fog cultivation planting system, can realize the automatic start and close the operation of nutrient solution pump, effectively solved the nutrient solution pump and incessantly function and the high power consumption that leads to, the increase of operation cost and the problem of final nutrient solution pump destruction. Connect through the nutrient solution pump and extend the branch pipe, carry out the nutrient solution to the plant in at least two sets of planting towers and spray accurately. Meanwhile, the method can be used for quickly and accurately building agricultural factories with lower construction cost, is suitable for high-efficiency and high-energy urban farms popularized in more and more cities, and solves the problem that the safety of an urban food chain is not guaranteed.

The above is only a preferred embodiment of the present invention, and not intended to limit the scope of the invention, and it should be appreciated by those skilled in the art that equivalent substitutions and obvious changes made from the description and drawings should be included within the scope of the present invention.

Claims (10)

1. An automated aerial fog planting system, comprising:

a frame composed of a chassis and a seedbed;

at least two planting towers mounted on the surface of the chassis;

a nutrient solution tank installed below the seedbed;

the aerial fog spraying device is arranged on the chassis and connected to the nutrient solution tank, and at least carries out automatic aerial fog spraying on the interior of the two planting towers; wherein

The aerial fog spraying device is internally provided with a timer, and the aerial fog spraying device positioned in the planting tower accurately sprays plants at specific positions;

the automatic seeding equipment consists of a sponge piece storage box, a sponge piece conveying belt, a seeded sponge output belt, a seeding limiting cylinder, a vacuum device capable of moving left and right and lifting, a seed tank vibration device, a liftable perforated panel and a cabinet;

the seedling transplanter consists of a manipulator transverse moving module, a manipulator longitudinal module and a spacing manipulator;

the placing system comprises a full-automatic placing/collecting mechanism and a machine-assisted placing device;

the automatic vegetable root cutting equipment consists of a cutting table, a pore plate mounting opening, an automatic pore plate fixing clamp, an air cylinder, a cutting knife, a vegetable root collecting box, a limit switch and a compressor;

the automatic vegetable packaging mechanism consists of a vegetable conveying belt, a packaging unit and an output machine.

2. The automated aerial fog cultivation planting system of claim 1, wherein the planting tower comprises a hole plate, a rear hole plate, a pair of side plates, and a top plate assembled in a trapezoidal tower-like structure, the pore plate and the rear pore plate are relatively inclined and are arranged close to each other, the pair of side plates are respectively connected with the left side and the right side of the pore plate and the rear pore plate, the top plate covers the top parts of the pore plate, the rear pore plate and the pair of side plates, four edges of the top plate are respectively connected with the top edges of the pore plate, the rear pore plate and the pair of side plates, a plurality of planting holes arranged in a matrix form are arranged on the surfaces of the pore plate, the rear pore plate and the top plate, and the planting holes are all provided with culture mediums, the planting holes are communicated with the inner cavity of the planting tower, the planting holes are in cylindrical hole structures and are axially and vertically arranged in a horizontal plane, and the culture mediums are horizontally arranged in the planting holes.

3. The automated aerial fog planting system of claim 2, wherein the aerial fog spray device comprises:

a nutrient solution pump fixed on the chassis;

the water inlet pipe is connected with an inlet of the nutrient solution pump;

the delivery pipe is connected with the outlet of the nutrient solution pump;

an extension branch pipe connected with the delivery pipe and passing through any side plate of the planting tower, and

the atomizing spray head is arranged on the extension branch pipe;

nutrient solution is sprayed on the plants planted in the planting holes in an aerosol manner through the water inlet pipe, the nutrient solution pump, the conveying pipe, the extension branch pipe and the atomizing spray head, wherein

The inlet tube with install the stop valve between the nutrient solution pump, the conveyer pipe with extend and install filter and strong magnetism treater between the branch pipe, the filter is close to the nutrient solution pump.

4. The automatic aeroponic cultivation planting system according to claim 1, wherein a liquid level display for displaying the liquid level of the nutrient solution is installed on the side wall of the nutrient solution tank, a liquid level ball float valve is installed in the nutrient solution tank, the liquid level ball float valve is connected to an external nutrient solution supply tank through a pipeline, the nutrient solution supply tank is connected to a nutrient solution preparation tank through a pipeline, and the nutrient solution pump and the liquid level ball float valve are in communication connection or electric connection with a background controller.

5. The automatic aerial fog cultivation planting system of claim 1, wherein the sowed sponge output belt and the sponge sheet conveying belt are both mounted at the top of a cabinet, the outer walls of the sowed sponge output belt and the sponge sheet conveying belt are provided with sowing limiting cylinders, the top of the sponge sheet conveying belt is provided with a sponge sheet storage box, the top of the cabinet is fixedly connected with two frames, the outer walls of the two frames are provided with driving cylinders, the total number of the driving cylinders is four, the two driving cylinders control a vacuum device to move and lift, the other two driving cylinders control an opening panel to lift, the outer wall of the opening panel is communicated with a conical nozzle, the vacuum device is provided with a needle type suction nozzle, and a seed groove vibration device are mounted above the sowed sponge output belt.

6. The automatic aeroponic cultivation planting system according to claim 1, wherein a sponge conveying line and a pore plate conveying line are installed on the seedling transplanter, sensors are arranged at the conveying end positions of the sponge conveying line and the pore plate conveying line, the spacing manipulator is provided with five clamping hands, and the spacing manipulator is further provided with a servo motor screw rod structure.

7. The automated aerial fog cultivation planting system of claim 1, wherein the fully-automatic placing/collecting mechanism comprises a composite automated guided vehicle, a mechanical arm clamp, a conveying frame, a pore plate and a top plate, and is used for placing and collecting the pore plate and the top plate.

8. The automated aerial fog cultivation planting system of claim 1, wherein the machine-assisted placement device is comprised of an internal combustion engine or an electric drive vehicle, a controller, a guardrail, and a shelf, the controller, the guardrail, and the shelf all mounted on the internal combustion engine or the electric drive vehicle.

9. The automatic aeroponic cultivation planting system according to claim 1, wherein a hole plate mounting opening is formed in the top of the cutting table, a fixing clamp is mounted on one side of the top of the cutting table, an air cylinder is mounted on the right side of the top of the cutting table, the output end of the air cylinder is fixedly connected with the hole plate mounting opening, the cutting knife is mounted in the middle of the cutting table, the limit switch is mounted at the left end of the fixing clamp, and the compressor is mounted on a cross frame below the cutting table.

10. The automatic aerial fog cultivation planting system of claim 1, wherein a packing unit is fixedly connected above the vegetable conveyer belt, the packing unit comprises a driving motor, a driving roller, a packing roll film, a feeding conveyer and a former, and the output machine is mounted at the right end of the vegetable conveyer belt and is used in cooperation with an outlet of the packing unit.

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