CN107182632B

CN107182632B - Drip irrigation pipe buried agricultural greenhouse system and greenhouse planting method

Info

Publication number: CN107182632B
Application number: CN201710396312.2A
Authority: CN
Inventors: 纪晶; 胡彩旗; 李胜多; 刘玉高
Original assignee: Qingdao Agricultural University
Current assignee: Qingdao Agricultural University
Priority date: 2017-01-17
Filing date: 2017-05-31
Publication date: 2020-05-08
Anticipated expiration: 2037-05-31
Also published as: CN107182621A; CN107231974B; CN107182632A; CN107182620A; CN108307878A; CN108307878B; CN208863238U; CN108157028B; CN107750708A; CN108157028A; CN107182620B; CN107182621B; CN107231974A

Abstract

The invention discloses a drip irrigation pipe buried agricultural greenhouse system and a greenhouse planting method. Agricultural greenhouse system includes the big-arch shelter and sets up the drip irrigation pipe in the big-arch shelter, drip irrigation the pipe and include water pipe and a plurality of cylinder water dropper, the middle part of the interior pipe wall of cylinder water dropper is formed with the heliciform recess, the tip of the interior pipe wall of cylinder water dropper is formed with annular groove, be provided with the silica gel section of thick bamboo in the annular groove, a plurality of perforating holes have been seted up on the silica gel section of thick bamboo, form the steady voltage cavity of effluenting between the outer tube wall of silica gel section of thick bamboo and the annular groove, set up the wash port that effluents the cavity intercommunication with the steady voltage on the outer wall of cylinder water dropper, the cylinder water dropper cover is in the outside of water pipe, form spiral buffering passageway between the outer tube wall of heliciform recess and water pipe, form the pressure. The use reliability of the agricultural greenhouse system is improved.

Description

Drip irrigation pipe buried agricultural greenhouse system and greenhouse planting method

Technical Field

The invention relates to the technical field of irrigation of agricultural greenhouse systems, in particular to a drip irrigation pipe buried agricultural greenhouse system and a greenhouse planting method.

Background

At present, the planting technology of the agricultural greenhouse system is widely popularized, and the agricultural greenhouse system is matched with the drip irrigation technology to become the trend of the development of green and environment-friendly agriculture at present. The drip irrigation pipe is generally laid on the ground surface of the greenhouse and generally comprises a water pipe and a water dropper, wherein the water dropper is arranged on the inner pipe wall of the water pipe, a turbulent flow channel is formed between the water dropper and the water pipe, and water in the water pipe is discharged from a water outlet of the water pipe through the turbulent flow channel. However, in the actual use process, because the drip irrigation pipe contacts the ground, silt easily enters the water outlet, and the turbulent flow channel of the dripper is small in size, has more roundabouts, corners and dead corners, is easy to block by the silt entering from the water outlet, so that the dripper fails, crops at the corresponding position cannot obtain sufficient water supply to influence the growth, and the use reliability of the drip irrigation pipe is low. The invention aims to solve the technical problem of how to design a drip irrigation pipe with high use reliability to improve the use reliability of an agricultural greenhouse.

Disclosure of Invention

The technical problem to be solved by the invention is as follows: the drip irrigation pipe buried agricultural greenhouse system and the greenhouse planting method are provided, so that the use reliability of the drip irrigation pipe buried agricultural greenhouse system is improved, and products with excellent quality are obtained.

The technical scheme provided by the invention is as follows: a drip irrigation pipe buried agricultural greenhouse system comprises a greenhouse built on the ground and drip irrigation pipes arranged in the greenhouse, wherein a plurality of vacuum glass plates are arranged at the top of the greenhouse, water collecting grooves are formed in the bottoms of the vacuum glass plates, water tanks are further arranged at the bottoms of the greenhouse, the water collecting grooves are connected with the water tanks, the water tanks are connected with the drip irrigation pipes, and the drip irrigation pipes are buried under the ground; the drip irrigation pipe comprises a water pipe and a plurality of cylindrical drippers, a plurality of water outlets are formed in the water pipe, a spiral groove is formed in the middle of the inner pipe wall of each cylindrical dripper, an annular groove is formed in the end part of the inner pipe wall of each cylindrical dripper, a silica gel cylinder is arranged in the annular groove, a plurality of through holes are formed in the silica gel cylinder, a pressure-stabilizing outflow cavity is formed between the outer cylinder wall of the silica gel cylinder and the annular groove, a drain hole communicated with the pressure-stabilizing outflow cavity is formed in the outer wall of each cylindrical dripper, each cylindrical dripper is sleeved outside the water pipe, a spiral buffer channel is formed between the spiral groove and the outer pipe wall of the water pipe, a pressure adjusting cavity is formed between the inner cylinder wall of the silica gel cylinder and the outer pipe wall of the water pipe, and the pressure adjusting cavity is communicated with the spiral; the greenhouse is characterized in that a water retaining wall is arranged at the lower edge of the greenhouse, the lower end of the water retaining wall is buried under the ground, and the water retaining wall is located above the drip irrigation pipe.

Furthermore, an anti-blocking assembly is arranged in the drain hole and comprises an umbrella-shaped flexible sealing cover and a connecting rod, the connecting rod is inserted into the drain hole, one end of the connecting rod is connected with the umbrella-shaped flexible sealing cover, and the other end of the connecting rod is connected with the silica gel cylinder; the umbrella-shaped flexible sealing cover is positioned outside the cylindrical dripper and is used for covering the drain hole.

Furthermore, an elastic membrane capable of being opened and closed is arranged in the through hole.

Furthermore, the elastic diaphragm and the silica gel cylinder are of an integral structure.

Furthermore, the buried agricultural greenhouse system with the drip irrigation pipe also comprises a controller and a water supply pump, the water tank is connected with the drip irrigation pipe through the water supply pump, and the upper part and the lower part of the drip irrigation pipe are correspondingly provided with an upper humidity sensor and a lower humidity sensor; the upper humidity sensor, the lower humidity sensor and the water supply pump are respectively connected with the controller; the upper humidity sensor and the lower humidity sensor are both buried under the ground.

The drip irrigation pipe is connected with the air pump and the water pump through mixing valves respectively, and the air pump and the mixing valves are connected with the controller respectively.

Further, the inside temperature sensor that is provided with of big-arch shelter with the controller is connected, the big-arch shelter is provided with the vent of switch.

The invention also provides a greenhouse planting method, which adopts the drip irrigation pipe buried agricultural greenhouse system; the method comprises the following steps: an initial planting mode and a conventional cultivation mode;

the initial planting mode specifically comprises the following steps: the greenhouse is built on the ground, water retaining enclosing walls are arranged around the greenhouse, the drip irrigation pipes are buried by digging grooves in the greenhouse, crops are planted in the grooves, root systems of the crops are distributed around the drip irrigation pipes, and under the action of the water retaining enclosing walls, an upper soil layer of soil in the greenhouse, which is located on the ground surface, is in a dry and water-deficient state;

the conventional cultivation mode specifically comprises the following steps: in the water supply process, if the humidity value detected by the lower humidity sensor is lower than the set value, the water pump is controlled to input the water in the water tank into the drip irrigation pipe, and when the humidity value of the upper humidity sensor is higher than the set value, the water supply of the water pump needs to be stopped.

Further, the regular incubation pattern further comprises: when the humidity value detected by the lower humidity sensor is lower than a set value, air is introduced into the drip irrigation pipe to loosen the soil, and then water is supplied to the drip irrigation pipe through the water pump.

Compared with the prior art, the invention has the advantages and positive effects that: according to the buried agricultural greenhouse system with the drip irrigation pipe and the greenhouse planting method, the cylindrical dripper is sleeved outside the water pipe, the spiral buffer channel is formed between the spiral groove in the cylindrical dripper and the outer pipe wall of the water pipe and replaces a turbulent flow channel to realize water flow deceleration and buffering, and the spiral buffer channel is of a spiral structure without roundabout, corner and dead angle, so that the deposition and accumulation of large particles at the roundabout, corner and dead angle can be effectively avoided, the blockage is avoided in the flow principle, and the use reliability can be effectively improved; simultaneously, because set up the silicone cylinder in the cylinder water dropper, the silicone cylinder can form the steady voltage with the terminal surface cavity and the water pipe periphery of cylinder water dropper and flow out cavity and pressure regulation cavity, the silicone cylinder will change the appearance according to the water pressure difference, thereby adjust the volume that the steady voltage flowed out cavity and pressure regulation cavity and change, steady voltage flowed out the cavity and diminishes and pressure regulation cavity grow when water pressure increases, otherwise, then steady voltage flowed out the cavity grow and pressure regulation cavity diminishes, can ensure like this that the water yield keeps steady, actual effect pressure compensation automatically regulated, optimize and drip irrigation the effect.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly introduced below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

FIG. 1 is a perspective view of the buried agricultural greenhouse system with drip irrigation pipes according to the present invention;

FIG. 2 is a schematic structural view of the buried agricultural greenhouse system with drip irrigation pipes according to the present invention;

FIG. 3 is a partial cross-sectional view of a drip irrigation pipe in the buried agricultural greenhouse system of the drip irrigation pipe of the present invention;

FIG. 4 is a cross-sectional view of a cylindrical dripper in the buried agricultural greenhouse system with drip irrigation pipes according to the present invention;

FIG. 5 is a schematic structural view of an anti-blocking component in the buried agricultural greenhouse system with drip irrigation pipes according to the present invention;

fig. 6 is a cross-sectional view of a silica gel cylinder in the buried agricultural greenhouse system with drip irrigation pipes of the present invention.

Detailed Description

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

As shown in fig. 1-6, the buried agricultural greenhouse system with drip irrigation pipes in the embodiment includes a greenhouse 1, a storage battery (not shown), and a controller (not shown), wherein a plurality of vacuum glass plates 12 are disposed on the top of the greenhouse 1, the plurality of vacuum glass plates 12 form a light-transmitting surface of the greenhouse 1, photovoltaic power generation films 10 are disposed on a part of the vacuum glass plates 12, and every two adjacent photovoltaic power generation films 10 are arranged in a staggered manner; the greenhouse 1 is internally provided with a drip irrigation pipe 2 buried under the ground, a plurality of water outlets 20 are arranged on a water pipe of the drip irrigation pipe 2, a spiral groove 211 is formed on the inner pipe wall of a cylindrical dripper 21, an annular groove (not marked) is formed at the end part of the inner pipe wall of the cylindrical dripper 21, a silica gel cylinder 23 is arranged in the annular groove, a plurality of through holes 231 are arranged on the silica gel cylinder 23, a pressure-stabilizing outflow cavity 210 is formed between the outer pipe wall of the silica gel cylinder 23 and the annular groove, a water drain hole 212 communicated with the pressure-stabilizing outflow cavity 210 is arranged on the outer wall of the cylindrical dripper 21, the cylindrical dripper 21 is sleeved outside the water pipe of the drip irrigation pipe 2, a spiral buffer channel 200 is formed between the spiral groove 211 and the outer pipe wall of the water pipe of the drip irrigation pipe 2, and a pressure adjusting cavity 201 is formed between the inner pipe wall of the silica gel cylinder 23 and, the pressure adjusting cavity 201 is communicated with the spiral buffering channel 200; a water collecting tank 13 is arranged at the bottom of the vacuum glass plate 12, a water tank 3 is also arranged at the bottom of the greenhouse 1, the water collecting tank 13 is connected with the water tank 3, the water tank 3 is connected with the drip irrigation pipe 2 through a water supply pump (not shown), and the water pump is connected with the controller; the side wall of the greenhouse 1 is provided with a vacuum insulation board (not shown), the lower edge of the greenhouse is provided with a water retaining wall 4, the lower end part of the water retaining wall 4 is buried under the ground, the water retaining wall 4 is positioned above the drip irrigation pipe 2, the upper edge of each vacuum glass plate 12 is provided with a spray pipe (not shown), and the spray pipes are connected with the water tank 3 through a cleaning pump (not shown).

Specifically, the cylindrical dripper adopted by the drip irrigation pipe 2 in the buried agricultural greenhouse system of the drip irrigation pipe of the embodiment is externally embedded outside the water pipe of the drip irrigation pipe 2, the cylindrical dripper 21 can be externally embedded outside the water pipe of the drip irrigation pipe 2 by adopting a hot-melt welding mode, the spiral groove 211 in the cylindrical dripper 21 and the outer wall of the water pipe of the drip irrigation pipe 2 form a spiral buffer channel 200, the spiral buffer channel 200 replaces a turbulent channel formed by drippers in the prior art, the spiral buffer channel 200 is distributed on the periphery of the drip irrigation pipe 2, the length of the spiral buffer channel 200 can be effectively increased, the water flow capacity can be effectively increased, the water pressure can be reduced, the effect of the turbulent channel is realized through the spiral buffer channel 200, the water flow stroke of the spiral buffer channel 200 is increased, the energy consumption is large, and the spiral groove 211 can be much larger than the size of the traditional internally embedded cylindrical dripper (the traditional size: 0., the size of the cylindrical dripper 21 of the present invention: 2-6 mm, and simultaneously, the drain hole 212 can also be provided with a large hole), more importantly, the spiral buffer channel 200 has no roundabout, corner and dead angle in the stroke, thereby avoiding the deposition and accumulation of large particles at the roundabout, corner and dead angle, and avoiding the blockage in the flowing principle. And water is input into the pressure regulating cavity 201 from the spiral buffer channel 200 and enters the pressure-stabilizing outflow cavity 210 through the through hole 231 and is output through the water discharge hole 212 to realize drip irrigation. Preferably, still be provided with the elastic diaphragm 232 of switch in the perforating hole 231, the silica gel section of thick bamboo 23 is outside protruding deformation under the water pressure effect, elastic diaphragm 232 on the silica gel section of thick bamboo 23 is backed up to water pressure simultaneously, elastic diaphragm 232 can be according to water pressure variation in size and automatically regulated opening angle, when pressure adjustment cavity 201 water pressure hour, elastic diaphragm 232 opening degree is little or do not open, thereby guarantee that the steady voltage is flowed cavity 210 rivers and do not flow back, ensure that there is enough water to continue to flow from wash port 212, can realize automatically regulated water pressure, the steady voltage is flowed. When the silicone tube 23 is provided with the through hole 231, the elastic membrane 232 can be formed directly by cutting off the excess material. In addition, in order to improve the anti-blocking performance, an anti-blocking assembly 22 is further arranged in the drain hole 212, the anti-blocking assembly 22 comprises an umbrella-shaped flexible cover 221 and a connecting rod 222, the connecting rod 222 is inserted in the drain hole 212, one end of the connecting rod 222 is connected with the umbrella-shaped flexible cover 221, and the other end of the connecting rod 222 is connected with the silica gel cylinder 23; the umbrella-shaped flexible cover 221 is positioned outside the cylindrical dropper 21 and is used for covering the water discharge hole 212. When the cylindrical dropper 21 is not in operation, the silicone tube 23 is reset and drives the connecting rod 222 to move inwards, so that the umbrella-shaped flexible cover 221 just covers the drain hole 212 to prevent foreign objects from blocking the flow channel. Under the mutual cooperation of the silica gel tube 23 and the anti-blocking component 22, the drip irrigation pipe 2 has the following functions: 1. pressure regulation: after the water in the spiral buffer channel 200 flows into the pressure adjusting cavity 201 and is fully stored, the silicone cylinder 23 protrudes and deforms outwards under the action of water pressure and drives the anti-blocking component 22 to move outwards, meanwhile, the water pressure pushes the elastic membrane 232 open, the water flows into the pressure-stabilizing outflow cavity 210, and after the pressure-stabilizing outflow cavity 210 is fully stored, the water flows out of the pipe through the water discharge hole 212 to perform drip irrigation; in addition, when the pressure of the pressure adjusting cavity 201 is small, the opening degree of the elastic diaphragm 232 is small or not opened, so that the water flow in the outflow cavity is ensured not to flow back (enough fluid is available), the liquid outlet is ensured to continuously flow out, the automatic adjustment of the water pressure can be realized, and the outflow is stabilized. 2. Pressure supplement: when the water pressure is increased, the flow speed of water flow is high, the flow rate is large, the silica gel cylinder 23 protrudes outwards to the circumference to be deformed and increased, the drain hole 212 is shielded, and the outflow speed of the drain hole 212 is reduced; when the water pressure is low, the flow rate is low, the silica gel cylinder 23 slightly protrudes out of the cylindrical surface shape, the shielding degree of the water outlet hole 212 is low, and the outflow speed of the water outlet is high; thereby ensuring that the drippers have consistent flow under different pressures.

The photovoltaic power generation film 10 is arranged on the light transmission surface of the greenhouse 1, the photovoltaic power generation film 10 is arranged in a staggered mode, the illumination direction of the sun in the daytime is changed from time to time, the photovoltaic power generation film 10 arranged in the staggered mode can ensure that crops in different position areas in the greenhouse 1 can obtain enough illumination, preferably, the photovoltaic power generation film 10 adopts an amorphous film solar cell, the amorphous film solar cell has a light transmission effect, external red light and blue light can be transmitted into the greenhouse 1, illumination required by plant growth is met, and the photovoltaic power generation film 10 is directly arranged on the light transmission surface of the greenhouse 1, the area of the photovoltaic power generation film 10 can be effectively increased, and the generated energy is improved. The electric energy generated by the photovoltaic power generation film 10 is stored in the storage battery, and the controller controls the relevant electric appliance parts to supply power for operation. Wherein, the lateral wall of big-arch shelter 1 adopts vacuum insulation board to keep warm, vacuum insulation board has good thermal insulation performance, and vacuum glass board 12 is adopted at the top of big-arch shelter 1, vacuum glass board 12 can ensure that 1 top of big-arch shelter has good thermal insulation performance, thereby realize night in winter, need not the user and hide the heat preservation curtain on big-arch shelter 1, in addition, adopt the light-permeable face that polylith vacuum glass board 12 concatenation formed big-arch shelter 1, vacuum glass board 12's life is longer, can avoid adopting the transparent film to need often change and the trouble that brings. And bury drip irrigation pipe 2 in the below ground in big-arch shelter 1, and still be provided with water catch bowl 13 on the photic surface of big-arch shelter 1 and collect the rainwater and save in water tank 3, when needs are irrigated, controller control water pump circular telegram, during the water pump carries drip irrigation pipe 2 with the water in the water tank 3, directly irrigates the crops root system in the soil. In the in-service use process discovery, because drip irrigation pipe 2 supplies water at the degree of depth position of subaerial crops 100 root system 101, the water from drip irrigation pipe 2 output flows downwards under the action of gravity, and crops 100's root system 101 is to waterborne, moisture is many in the deep soil, can attract crops 100's root system 101 can be deeper prick the root to the underground, make crops 100 can grow with more flourishing state, obtain the good quality agricultural product, the water of also having avoided drip irrigation pipe 2 output simultaneously is evaporated in a large number, the water consumption has been reduced. And for the ground surface in the greenhouse 1, as no water is supplied, the soil layer on the ground surface is in a dry state for a long time, so that weeds growing on the ground surface cannot survive, and the labor intensity of farmers for weeding is reduced. In order to improve the light transmittance of the vacuum glass plates 12, a shower pipe is arranged at the upper edge of each vacuum glass plate 12, the shower pipe is connected with the water tank 3 through a cleaning pump (not shown), in the actual use process, the light transmittance of the vacuum glass plates 12 is reduced due to dust and other factors, at the moment, high-pressure water is injected into the shower pipe through the cleaning pump, the surfaces of the vacuum glass plates 12 are cleaned through nozzles of the shower pipe, the water circulating from the vacuum glass plates 12 flows back to the water collecting tank 13 and flows into the water tank 3 again through the water collecting tank 13 for recycling, and a filter screen is arranged at the inlet of the water collecting tank 13 or the water tank 3 as required to filter impurities entering the water tank 3. Preferably, the photovoltaic ecological greenhouse system of the embodiment further includes an air pump (not shown), the drip irrigation pipe 2 is connected to the air pump and the water pump through a mixing valve, the air pump and the mixing valve are connected to the controller, specifically, in the actual use process, in order to increase the oxygen content at the position of the root system 101 of the crop 100, the water pump and the air pump can be connected to the drip irrigation pipe 2 through the mixing valve, and when the drip irrigation pipe 2 supplies water, a proper amount of air generated by the air pump can be delivered to the soil at the lower layer, so as to be more beneficial to the luxuriant growth of the root system 101 of the crop 100; of course, the air may be introduced first as needed to transport water, and the present invention is not limited thereto.

In order to ensure that the surface soil layer in the greenhouse 1 is always in a dry state and avoid external rain and other factors from causing external water to flow into the greenhouse 1, the lower edge of the greenhouse 1 is provided with a water-retaining wall 4, the lower end part of the water-retaining wall 4 is buried below the ground, and the water-retaining wall 4 is positioned above the drip irrigation pipe 2. Specifically, the water retaining wall 4 encloses soil at a certain depth below the ground surface inside the greenhouse 1 to be isolated from the outside, under the action of the water retaining wall 4, rainwater outside the greenhouse 1 can be prevented from permeating into a surface soil layer in the greenhouse 1 from the ground surface, so that the ground surface inside the greenhouse 1 is ensured to be in a dry and dry state, in the growth process of crops in the greenhouse 1, water is directly supplied to root systems 101 of the crops 100 from the ground surface by using the drip irrigation pipe 2 to ensure that the ground surface is in the dry state, weeds on the ground surface are difficult to germinate or survive due to water shortage, meanwhile, the humidity in the inner space of the greenhouse 1 is kept at a lower level by the dry ground surface, thereby bacteria and insects are difficult to grow and propagate on the crops 100, the use amount of pesticides can be greatly reduced, meanwhile, a weed killer can be completely eradicated, and a large amount of labor force is not required to artificially weed, the purpose of green and environment-friendly planting is achieved; meanwhile, the dry ground surface can facilitate the farmer to dig and ventilate, and the quality of agricultural products can be greatly improved. The depth of the water retaining wall 4 buried in the soil in the embodiment is determined according to the growth depth of the local weed species root system, so as to ensure that the depth of the dry soil layer on the ground surface does not meet the requirement of the growth of the weeds, and the burying depth of the drip irrigation pipe 2 depends on the growth depth of the root system 101 of the crops 100, and the growth depth of the root system 101 of the crops 100 is larger than the growth depth of the root system of the weeds, so that the drip irrigation pipe 2 only supplies water to the crops 100, and the soil layer with the specific depth on the ground surface is always ensured to be kept in a dry state, and the height dimension of the water retaining wall 4 and the burying depth dimension of the drip irrigation pipe.

Further, in order to realize automatic irrigation and planting and more accurately control the water supply amount of the drip irrigation pipe 2, an upper humidity sensor 51 and a lower humidity sensor 52 are correspondingly arranged on the upper part and the lower part of the drip irrigation pipe 2, and the upper humidity sensor 51 and the lower humidity sensor 52 are respectively connected with the controller; the upper humidity sensor 51 and the lower humidity sensor 52 are buried under the ground. Specifically, in the crop planting process, the drip irrigation pipe 2, the lower humidity sensor 52 and the root system 101 of the crop 100 are buried in the soil in the greenhouse 1 through the trench, the upper humidity sensor 51 is buried in the soil on the upper layer in the burying process, in the actual irrigation process, the lower humidity sensor 52 detects the surrounding humidity value to judge whether the drip irrigation pipe 2 needs to supply water for irrigation, in the irrigation process, if the humidity detected by the upper humidity sensor 51 is larger than a set value, the continuous irrigation of the drip irrigation pipe 2 is stopped, so that the ground surface is ensured to be in a dry state, and the root system 101 of the crop 100 can obtain the optimal water supply amount. Preferably, a water level detector (not shown) connected with the controller is arranged in the water tank 3, and when the water level detector detects that the water in the water tank 3 reaches the maximum water storage capacity in rainy seasons with large rainfall, the water pump is started to convey redundant rainwater to other containers for temporary storage, so that the water supply requirement of uneven rainfall distribution in different seasons is met.

In addition, 1 inside of big-arch shelter be provided with the temperature sensor (not shown) that the controller is connected, big-arch shelter 1 is provided with the vent 14 of switch, and is concrete, can the temperature in real-time supervision big-arch shelter 1 through temperature sensor, when the high temperature in big-arch shelter 1, will influence crops fast growing, then has controller control big-arch shelter 1 to open the vent. When the temperature in the greenhouse 1 is too low, the crops can be influenced to grow rapidly, and the controller controls the greenhouse 1 to close the ventilation opening and keep warm in due time. Preferably, photosynthesis time for effectual extension crops, solar protection devices (not shown) of switch still are provided with in 1 top in big-arch shelter, solar protection devices will cooperate light sensor (not shown), in the highest period of noon sunshine intensity, because illumination intensity can lead to crops to stop photosynthesis on the contrary because the illumination intensity is too strong, be greater than the setting value after the light intensity that light sensor detected, controller control solar protection devices opens and covers big-arch shelter 1, reduce the light intensity in big-arch shelter 1, thereby make crops in the big-arch shelter 1 continue to carry out photosynthesis, it is richer to reach the nutrition of crops, better quality. The sun-shading device can be a sun-shading net, a sun-shading film or a sun-shading board and other sun-shading equipment.

the initial planting mode specifically comprises the following steps: the greenhouse is built on the ground and the water retaining enclosing wall is arranged around the greenhouse, the ditch is dug inside the greenhouse to bury the drip irrigation pipe and plant crops, moreover, root systems of the crops are distributed around the drip irrigation pipe, and the upper soil layer of the soil in the greenhouse on the ground surface is in a dry water shortage state under the action of the water retaining enclosing wall. Specifically, the greenhouse is constructed in the process of forming a water retaining wall at the bottom of the greenhouse, and after the greenhouse is constructed, a groove is dug in the greenhouse to lay a drip irrigation pipe humidity sensor and plant crops.

The conventional cultivation mode specifically comprises the following steps: in the water supply process, if the humidity value detected by the lower humidity sensor is lower than the set value, the water pump is controlled to input the water in the water tank into the drip irrigation pipe, and when the humidity value of the upper humidity sensor is higher than the set value, the water supply of the water pump needs to be stopped. After crops are planted in the greenhouse, conventional water supply cultivation can be performed, and the specific water supply amount can be adjusted according to requirements of different types of crops, so that more accurate water supply for the crops can be realized. Preferably, for crops, keeping good air permeability of soil is an important factor for flourishing growth, therefore, in the process of supplying water, when the humidity value detected by the current humidity sensor is lower than a set value, the soil around the root systems of the crops is in a relatively dry state, at the moment, air can be introduced into the drip irrigation pipe for loosening the soil, then, water is supplied to the drip irrigation pipe through the water pump, the underground soil is ventilated, soil hardening is reduced, water retention, fertilizer retention, ventilation and root development promotion are facilitated, a comfortable growth environment is provided for the crops, effects which cannot be achieved in conventional agricultural planting can be achieved, and the root systems of the crops are developed, so that the fruits growing the crops are better.

Claims

1. A drip irrigation pipe buried agricultural greenhouse system comprises a greenhouse built on the ground and drip irrigation pipes arranged in the greenhouse, and is characterized in that a plurality of vacuum glass plates are arranged at the top of the greenhouse, a water collecting tank is arranged at the bottom of each vacuum glass plate, a water tank is further arranged at the bottom of the greenhouse, the water collecting tank is connected with the water tank, the water tank is connected with the drip irrigation pipes, and the drip irrigation pipes are buried under the ground; the drip irrigation pipe comprises a water pipe and a plurality of cylindrical drippers, a plurality of water outlets are arranged on the water pipe, a spiral groove is formed in the middle of the inner pipe wall of the cylindrical dripper, an annular groove is formed at the end part of the inner pipe wall of the cylindrical dripper, a silica gel cylinder is arranged in the annular groove, a plurality of through holes are arranged on the silica gel cylinder, a pressure-stabilizing outflow cavity is formed between the outer cylinder wall of the silica gel cylinder and the annular groove, an elastic diaphragm which can be opened and closed is arranged in the through hole, a drain hole communicated with the pressure-stabilizing outflow cavity is arranged on the outer wall of the cylindrical dripper, the cylindrical dripper is sleeved outside the water pipe, a spiral buffer channel is formed between the spiral groove and the outer pipe wall of the water pipe, a pressure adjusting cavity is formed between the inner wall of the silica gel barrel and the outer wall of the water pipe and is communicated with the spiral buffer channel; the lower edge of the greenhouse is provided with a water-retaining wall, the lower end part of the water-retaining wall is buried under the ground, and the water-retaining wall is positioned above the drip irrigation pipe; an anti-blocking assembly is further arranged in the drain hole and comprises an umbrella-shaped flexible sealing cover and a connecting rod, the connecting rod is inserted into the drain hole, one end of the connecting rod is connected with the umbrella-shaped flexible sealing cover, and the other end of the connecting rod is connected with the silica gel cylinder; the umbrella-shaped flexible sealing cover is positioned outside the cylindrical dripper and is used for covering the drain hole.

2. The buried agricultural greenhouse system with drip irrigation pipes of claim 1, wherein the elastic membrane and the silicone tube are of an integral structure.

3. The buried agricultural greenhouse system with drip irrigation pipes of claim 1, further comprising a controller and a water supply pump, wherein the water tank is connected with the drip irrigation pipes through the water supply pump, and the upper and lower parts of the drip irrigation pipes are correspondingly provided with an upper humidity sensor and a lower humidity sensor; the upper humidity sensor, the lower humidity sensor and the water supply pump are respectively connected with the controller; the upper humidity sensor and the lower humidity sensor are both buried under the ground.

4. The buried agricultural greenhouse system with drip irrigation pipes as claimed in claim 3, further comprising an air pump, wherein the drip irrigation pipes are respectively connected with the air pump and the water pump through mixing valves, and the air pump and the mixing valves are respectively connected with the controller.

5. The buried agricultural greenhouse system with drip irrigation pipes as claimed in claim 3, wherein the greenhouse is internally provided with a temperature sensor connected with the controller and is provided with an openable and closable vent.

6. A greenhouse planting method, which is characterized in that the drip irrigation pipe buried agricultural greenhouse system as claimed in any one of claims 1 to 5 is adopted; the method comprises the following steps: an initial planting mode and a conventional cultivation mode;

7. The greenhouse planting method of claim 6, wherein the normal cultivation mode further comprises: when the humidity value detected by the lower humidity sensor is lower than a set value, air is introduced into the drip irrigation pipe to loosen the soil, and then water is supplied to the drip irrigation pipe through the water pump.