CN113447304A - Distributed underground tunnel fertilizer collection device - Google Patents

Abstract

The invention discloses a distributed underground tunnel fertilizer collecting device, which comprises a collecting shaft and is characterized in that: the front end of the collecting shaft is provided with an induction component, the left side and the right side of the surface of the collecting shaft are provided with shunting components, the upper part of the surface of the collecting shaft is provided with a mixing component, the induction component is connected with the shunting components through a pipeline, the shunting components are connected with the mixing component through a pipeline, the induction component comprises an upper valve port, a lower valve port, a left valve port and a right valve port, one sides of the upper valve port, the lower valve port, the left valve port and the right valve port, which are positioned in the collecting shaft, are respectively provided with an upper valve ball, a lower valve ball, a left valve ball and a right valve ball, the tail ends of the left valve ball and the right valve ball are respectively provided with a magnet, the surfaces of the left valve ball and the right valve ball are respectively provided with a clamping groove, and the shunting components comprise a left shunting shell and a right shunting shell.

Description

Distributed underground tunnel fertilizer collection device

Technical Field

The invention relates to the technical field of soilless culture, in particular to a distributed underground tunnel fertilizer collecting device.

Background

Soilless culture lets the root system of plant direct and water contact, reaches the planting method that need not earth, and this kind of planting method can practice thrift the planting cost, can also reduce the reliance to the soil simultaneously, and the fertilizer in the current soilless culture device is mostly artifical the interpolation, and the staff of difference also can be different to the mastery degree of fertilizer like this, can lead to the growth human error of plant great, consequently, it is very necessary to design a distributed underground tunnel fertilizer collection device that the practicality is strong and can the ratio of automatically regulated fertilizer.

Disclosure of Invention

The invention aims to provide a distributed underground tunnel fertilizer collecting device to solve the problems in the background technology.

In order to solve the technical problems, the invention provides the following technical scheme: the utility model provides a distributed underground tunnel fertilizer collection device, includes collects axle, its characterized in that: the front end of collecting the axle installs response subassembly, collect the axle the surperficial left and right sides and install the reposition of redundant personnel subassembly, the top of the surface of collecting the axle installs mixes the subassembly, response subassembly and reposition of redundant personnel subassembly pipe connection, reposition of redundant personnel subassembly and mixed subassembly pipe connection.

According to the technical scheme, the sensing assembly comprises an upper valve port, a lower valve port, a left valve port and a right valve port, wherein an upper valve ball, a lower valve ball, a left valve ball and a right valve ball are respectively arranged on one side of the upper valve port, the lower valve port, the left valve port and the right valve port, which are located inside the collecting shaft, the tail ends of the left valve ball and the right valve ball are respectively provided with a magnet, and the surfaces of the left valve ball and the right valve ball are respectively provided with a clamping groove.

According to the technical scheme, the flow distribution assembly comprises a left flow distribution shell and a right flow distribution shell, a left flow distribution chamber is arranged inside the left flow distribution shell, the upper end and the lower end of the left side of the left flow distribution chamber are respectively connected with a lower valve port and a left valve port through pipelines, the right side of the left flow distribution chamber is connected with a left control mechanism through a pipeline, a right flow distribution chamber is arranged inside the right flow distribution shell, the upper side and the lower side of the right flow distribution chamber are respectively connected with an upper valve port and a right valve port through pipelines, and the left side of the right flow distribution chamber is connected with a right control mechanism through a pipeline.

According to the technical scheme, left side control mechanism is including three left control valves of group, three groups left side control valve is series connection, three groups the end and the collection central siphon way of left side control valve are connected, the inside fixed mounting of left side reposition of redundant personnel room has baffle one, the inside slidable mounting of left side reposition of redundant personnel room has valve plate one, right side control mechanism is including three right control valves of group, three groups right side control valve is series connection, three groups the end and the collection central siphon way of right side control valve are connected, the inside fixed mounting of right side reposition of redundant personnel room has baffle two, the inside slidable mounting of right side reposition of redundant personnel room has valve plate two.

According to the technical scheme, three groups the inside of left side control valve all is provided with counter weight valve ball one, elastic valve bag one has been cup jointed on the surface of counter weight valve ball one, both ends all are connected with left parallel connection pipe about the right side of left side reposition of redundant personnel room, left side parallel connection pipe respectively with three group elastic valve bag pipe connection, the inside of right side control valve all is provided with counter weight valve ball two, elastic valve bag two all is cup jointed on the surface of counter weight valve ball two, both ends all are connected with right parallel connection pipe about the left side of right side reposition of redundant personnel room, right side parallel connection pipe respectively with three group elastic valve bag two pipe connections.

According to the technical scheme, the mixing assembly is including mixing the shell, mixing the inside of shell and being provided with guide valve and mixing valve, the guide valve respectively with first left control valve of a set, first right control valve pipe connection of a set, there are left counter weight bag and right counter weight bag in the below both sides of guide valve pipe connection respectively, the bottom of left counter weight bag and right counter weight bag is provided with left spring bag and right spring bag respectively, be provided with flexible pipeline between guide valve and left counter weight bag, the right counter weight bag, the upper surface fixed connection of left counter weight bag and left spring bag, the upper surface fixed connection of right counter weight bag and right spring bag.

According to the technical scheme, the lower end of the mixing valve is respectively connected with the left spring bag and the right spring bag through pipelines, the left side and the right side of the mixing valve are respectively connected with the second group of left control valves and the second group of right control valves through pipelines, and the left spring bag and the right spring bag are respectively connected with the third group of left control valves and the third group of right control valves through pipelines.

According to the technical scheme, ethanol is filled in the upper portion of the right side of the left shunting chamber and the upper portion of the left side of the right shunting chamber, and mercury is filled in the lower portion of the right side of the left shunting chamber and the lower portion of the left side of the right shunting chamber.

According to the technical scheme, the density of the upper valve ball is smaller than that of the lower valve ball.

According to the technical scheme, the pipeline above the left control mechanism is connected with a fertilizer inlet, and the pipeline above the right control mechanism is connected with a clear water inlet.

Compared with the prior art, the invention has the following beneficial effects: according to the invention, the sensing component is arranged, the fertilizer and water are fused to form the nutrient solution, the sensing component can judge the fertilizer concentration according to the density of the nutrient solution, then the shunting component can guide the fertilizer and water to different positions according to the fertilizer concentration sensed by the sensing component, and finally the mixed fertilizer is supplied into the collecting shaft by the mixing component.

Drawings

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

FIG. 1 is a schematic overall elevational view of the present invention;

FIG. 2 is a schematic view of the integral piping connection of the present invention;

in the figure: 1. a collection shaft; 2. a mixing housing; 3. a left shunt housing; 4. a right shunt housing; 5. an upper valve port; 6. a lower valve port; 7. a left valve port; 8. a right valve port; 9. a valve ball is arranged; 10. a valve ball is arranged; 11. a left valve ball; 12. a right valve ball; 13. a pilot valve; 14. a mixing valve; 15. a left weight cell; 16. a right weight cell; 17. A left spring pocket; 18. a right spring pocket; 19. a left diversion chamber; 20. a right diversion chamber; 21. a first clapboard; 22. A second clapboard; 23. a first valve plate; 24. a left control valve; 25. a right control valve; 26. a left parallel pipe; 27. a right parallel pipe; 28. and a second valve plate.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be 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.

Referring to fig. 1-2, the present invention provides the following technical solutions: the utility model provides a distributed underground tunnel fertilizer collection device, includes collection axle 1, its characterized in that: the front end of collecting axle 1 installs response subassembly, and the reposition of redundant personnel subassembly is installed to the surface left and right sides of collecting axle 1, and the mixed subassembly is installed to the surface top of collecting axle 1, and response subassembly and reposition of redundant personnel subassembly pipe connection, reposition of redundant personnel subassembly and mixed subassembly pipe connection. Can form the nutrient solution after fertilizer and water fuse, its fertilizer concentration can be judged according to the density of nutrient solution to the response subassembly, and the reposition of redundant personnel subassembly can be according to the fertilizer concentration that the response subassembly sensed afterwards, with fertilizer and water leading-in different positions, and finally inside the fertilizer that will mix by the mixed subassembly supplies the collection axle again.

The sensing assembly comprises an upper valve port 5, a lower valve port 6, a left valve port 7 and a right valve port 8, wherein one side of the upper valve port 5, the lower valve port 6, the left valve port 7 and the right valve port 8, which is positioned inside the collecting shaft 1, is provided with an upper valve ball 9, a lower valve ball 10, a left valve ball 11 and a right valve ball 12 respectively, the tail ends of the left valve ball 11 and the right valve ball 12 are provided with magnets, and the surfaces of the left valve ball 11 and the right valve ball 12 are provided with clamping grooves. The collecting shaft is positioned at the bottom of the waterless cultivation device, the culture solution in the waterless cultivation device can flow through the collecting shaft and then be recycled, the culture solution can pass through the sensing assembly, when the concentration of the fertilizer in the culture solution is normal, the upper valve ball can float upwards under normal buoyancy, so that the upper valve port is blocked, the lower valve ball can keep a sinking state due to insufficient normal buoyancy, so that the lower valve port is blocked, at the moment, the left valve ball and the right valve ball can be mutually adsorbed together under the action of the magnet at the tail ends of the left valve ball and the right valve ball, so that the left valve port and the right valve port are opened, the culture solution can flow out from the left valve port and the right valve port for subsequent requirements, when the concentration of the fertilizer in the culture solution is low, the overall density of the culture solution can be reduced, at the moment, the buoyancy borne by the upper valve ball can be reduced, so that the upper valve port is opened, and the upper valve ball can be clamped in the clamping groove between the left valve ball and the right valve ball after sinking, the sinking depth of the upper valve ball will be continuously increased along with the continuous reduction of the fertilizer concentration content, at the same time, the upper valve ball will push the left and right valve balls to both sides from the clamping groove, so that the left and right valve ports can be blocked together when the fertilizer concentration is too low, when the fertilizer concentration in the culture solution is higher, the whole density of the culture solution will be increased, the buoyancy of the culture solution to the lower valve ball will also be increased, thereby the lower valve ball is caused to float upwards, the lower valve port is opened, the lower valve ball can be clamped in the clamping groove between the left valve ball and the right valve ball after floating upwards, along with the continuous increase of the fertilizer concentration in the culture solution, the buoyancy borne by the lower valve ball will also be continuously increased, and finally the left and right valve balls are pushed away to block the left and right valve ports, until the fertilizer concentration content in the culture solution is normal, the initial state can be restored, so as to and fro, the movement direction and the movement amplitude of each valve ball can be passed, and automatically judging the concentration content of the fertilizer in the culture solution.

The reposition of redundant personnel subassembly is including left reposition of redundant personnel shell 3 and right reposition of redundant personnel shell 4, the inside of left reposition of redundant personnel shell 3 is provided with left reposition of redundant personnel room 19, both ends respectively with lower valve port 6 about the left side of left side reposition of redundant personnel room 19, 7 pipe connections of left valve port, the right side pipe connection of left side reposition of redundant personnel room 19 has left control mechanism, the inside of right side reposition of redundant personnel shell 4 is provided with right reposition of redundant personnel room 20, both sides respectively with last valve port 5 about the right side of right side reposition of redundant personnel room 20, 8 pipe connections of right valve port, the left side pipe connection of right side reposition of redundant personnel room 20 has right control mechanism. When the concentration of the culture solution is normal, the left valve port and the right valve port are opened, the culture solution flows into the left lower part of the left shunting chamber and the right lower part of the right separation chamber through the left valve port and the right valve port, then the left shunting chamber can control the left control mechanism to input the fertilizer solution into the collecting pipe, the right shunting chamber can control the right control mechanism to input the clear water into the collecting pipe, therefore, when the concentration of the fertilizer in the culture solution is normal, the fertilizer solution and the clear water with normal proportion are continuously supplied to the collecting shaft, when the concentration of the fertilizer in the culture solution is high, the lower valve port is opened at the moment, the culture solution enters the left upper part of the left shunting chamber, the left shunting chamber can cut off the supply of the fertilizer solution of the left control mechanism, and the right shunting chamber can continuously supply the clear water, thus, the culture solution can be diluted by the clear water, the concentration of the fertilizer is reduced until the concentration of the culture solution is normal, when fertilizer concentration in the culture solution is lower, the last valve port will be opened this moment, the culture solution can get into the right side top of right side reposition of redundant personnel chamber, with this right side reposition of redundant personnel room will control right control mechanism and cut off the confession of clear water, this kind just can let left control mechanism for collecting the inside fertilizer solution that lasts of axle, the fertilizer concentration of increase culture solution, normal until the concentration, with this reciprocating, each reposition of redundant personnel subassembly can be according to the fertilizer concentration of the automatic allotment culture solution of the motion of the valve ball in the response subassembly, need not again by artifical allotment, can also reduce artificial error when improving work efficiency.

Left control mechanism is including three left control valve 24 of group, three left control valve 24 of group are series connection, three left control valve 24 of group's end and collection axle 1 pipe connection, the inside fixed mounting of left side branch flow chamber 19 has a baffle 21, the inside slidable mounting of left side branch flow chamber 19 has a valve plate 23, right control mechanism is including three right control valve 25 of group, three right control valve 25 of group are series connection, the end and the collection axle 1 pipe connection of three right control valve 25 of group, the inside fixed mounting of right side branch flow chamber 20 has baffle two 22, the inside slidable mounting of right side branch flow chamber 20 has valve plate two 28. When the concentration in the culture solution is normal, the culture solution can respectively enter the left side lower part of the left shunting chamber and the right side lower part of the right shunting chamber from the left valve port and the right valve port, at the moment, the culture solution can push the valve plate I and the valve plate upwards, the valve plate I and the valve plate II can push the ethanol on the other sides of the partition plate I and the partition plate II into each control valve, each control valve can be conducted, so that the fertilizer solution can flow through the left control valve and then enter the collecting shaft, the clean water with the same proportion flows through the right control valve and then enters the collecting shaft, when the concentration in the culture solution is high, the culture solution can enter the left side upper part of the left shunting cavity through the lower valve port, the culture solution can push the valve plate I downwards, the valve plate can push the mercury on the other side of the partition plate I and the left control valve for a moment, so that the channels of each left control valve are cut off, and meanwhile, the right control valve still continuously supplies the clean water, so can dilute the culture solution when the concentration is higher, the same reason, when fertilizer concentration is lower in the culture solution, right control valve passageway will be cut off, and left control valve will continue to supply fertilizer solution to this fertilizer concentration that can increase the culture solution.

Three left control valve 24's of group inside all is provided with counter weight valve ball one, elastic valve bag one has been cup jointed on the surface of counter weight valve ball one, both ends all are connected with left parallelly connected pipe 26 about the right side of left side flow distribution chamber 19, left side parallelly connected pipe 26 respectively with three elastic valve bag pipe connections of group, right control valve 25's inside all is provided with counter weight valve ball two, elastic valve bag two all is cup jointed on the surface of counter weight valve ball two, both ends all are connected with right parallelly connected pipe 27 about the left side of right side flow distribution chamber 20, right parallelly connected pipe 27 respectively with three elastic valve bag two pipe connections of group. After the culture solution enters the upper left side of the left shunt chamber through the lower valve port, the culture solution pushes the valve plate to move downwards, the valve plate pushes mercury on the right side of the valve plate to be discharged, in the process, when the floating amplitude of the lower valve ball is smaller, liquid entering the left shunt chamber is smaller, so that the distance of the valve plate moving downwards is smaller, extruded mercury is smaller, the mercury enters the left parallel pipe after being extruded, at the moment, the mercury is positioned below the left parallel pipe because the density of the mercury is larger than that of ethanol, the extruded mercury enters the first elastic valve bag of the third group of left control valves, so that the mass of the first counterweight valve ball in the third group of left control valves is increased, the first counterweight valve ball sinks to block the third group of left control valves, and the fertilizer supply of the left control valves can be cut off temporarily, meanwhile, as the squeezed mercury is less, ethanol still exists in the first elastic valve bag of the second and first groups of left control valves, and as the density of the ethanol is lower, the first counterweight valve ball of the first and second groups of left control valves floats up in the left control valves, so that the first and second groups of left control valves are conducted, the fertilizer solution entering from the fertilizer solution inlet flows out from the right sides of the first, second and third groups of left control valves, and after the culture solution entering the left branch flow chamber from the lower valve port becomes more, the squeezed mercury also becomes more, so that the mercury content in the left parallel pipes is increased, and the mercury also enters the first elastic valve bag of the second group of left control valves, so that the fertilizer solution flowing from the second group of left control valves to the third group of left control valves is cut off, and the fertilizer solution only flows out from the right sides of the first and second groups of left control valves, the concentration of the culture solution continues to be high, the culture solution flowing into the left shunting chamber also continues to increase, so that the fertilizer solution can only flow out from the right side of the first group of left control valves, and similarly, when the concentration of the fertilizer in the culture solution is low, the culture solution can enter the right shunting valve from the upper valve port, and the clear water is controlled to flow out from different right control valves according to the concentration, and in conclusion, the specific flow directions of the fertilizer solution and the clear water can be controlled according to the change of the concentration of the fertilizer in the culture solution.

Mixing unit is including mixing casing 2, mixing casing 2's inside is provided with guide valve 13 and mixing valve 14, guide valve 13 respectively with first group left control valve 24, first group right control valve 25 pipe connection, the below both sides of guide valve 13 pipe connection respectively have left counter weight bag 15 and right counter weight bag 16, the bottom of left counter weight bag 15 and right counter weight bag 16 is provided with left spring bag 17 and right spring bag 18 respectively, guide valve 13 and left counter weight bag 15, be provided with flexible pipeline between the right counter weight bag 16, left counter weight bag 15 is connected with the upper surface fixed of left spring bag 17, the upper surface fixed connection of right counter weight bag 16 and right spring bag 18. The fertilizer solution flowing out of the first group of left control valves flows through the guide valve and then enters the right counterweight bag, the clear water flowing out of the first group of right control valves flows through the guide valve and then enters the left counterweight bag, the density of the culture solution does not enable the upper valve ball to sink and the lower valve ball to float, so the fertilizer solution and the clear water cannot enter the guide valve simultaneously, when the fertilizer solution enters the guide valve, the concentration of the culture solution is higher, then the fertilizer solution enters the right counterweight ball, the right counterweight ball becomes heavy after the fertilizer solution is collected, the right spring bag is extruded, the clear water in the right spring bag is extruded, the supply amount of the clear water can be increased, the dilution efficiency is higher, and similarly, when the clear water enters the guide valve, the concentration of the culture solution is lower, the fertilizer solution needs to be supplemented, can extrude left spring bag after the clear water gets into left counter weight bag to extrude its inside fertilizer solution, with the attack volume of increase fertilizer solution, improve and supply efficiency.

The lower end of the mixing valve 14 is respectively connected with a left spring bag 17 and a right spring bag 18 through pipelines, the left side and the right side of the mixing valve 14 are respectively connected with a second group of left control valves 24 and a second group of right control valves 25 through pipelines, and the left spring bag 17 and the right spring bag 18 are respectively connected with a third group of left control valves 24 and a third group of right control valves 25 through pipelines. Liquid output from the second group of control valves enters the mixing valve, liquid output from the third group of control valves enters the left spring bag and the right spring bag respectively, when the amount of culture solution entering the left diversion chamber is large, fertilizer solution can only enter the mixing valve from the right side of the first group of left control valves, when the amount of the culture solution entering is reduced, the dilution effect on the culture solution is shown, the culture solution density is reduced, the culture solution entering the left diversion chamber is also reduced, the fertilizer solution can enter the mixing valve through the second group of left control valves, the mixing valve can simultaneously inject the fertilizer solution into the left spring bag and the right spring bag, so that a small amount of fertilizer solution can be supplemented into the right spring bag to prevent over dilution, and then the fertilizer solution can be supplemented into the left spring bag for subsequent use, after the concentration of the culture solution is gradually recovered, the culture solution that gets into left side flow distribution chamber will also continue to reduce, all left control valves homoenergetic discharge fertilizer medicament this moment, can get into left spring bag from the left control valve of third group exhaust fertilizer solution, left spring bag can expand afterwards, can upwards promote left counter weight bag after the left spring bag inflation, highly being higher than the back of guide valve in left counter weight bag, its inside clear water can flow backwards to the right side of guide valve, can pour the clear water in the left counter weight bag like this, in order to make things convenient for follow-up circulation to use, and the same reason, when the fertilizer concentration of culture solution is lower, right side flow distribution chamber and right control valve also can be according to the leading-in corresponding position of actual fertilizer concentration with the clear water, with this improvement replenishment efficiency.

The upper right side of the left diversion chamber 19 and the upper left side of the right diversion chamber 20 are filled with ethanol, and the lower right side of the left diversion chamber 19 and the lower left side of the right diversion chamber 20 are filled with mercury. The mercury and the ethanol are incompatible liquids, so the mercury is always below in the left and right parallel pipes, the ethanol is above, along with the change of the content of the mercury and the ethanol in the parallel pipes, the mercury enters the elastic valve bags which are consistent with the horizontal plane of the mercury and the ethanol, the corresponding elastic valve bags are made to sink in the control valves, the ethanol enters the other elastic valve bags, and simultaneously, the density of the ethanol is smaller than that of the water, so the mercury and the ethanol are always kept above the control valves when fluid passes through each control valve, and the fluid cannot be blocked.

The density of the upper ball 9 is less than the density of the lower ball 10. The upper valve ball can sink after the concentration of the fertilizer in the culture solution is reduced, and the lower valve ball can float after the concentration of the fertilizer in the culture solution is increased, so that the change of the concentration of the fertilizer in the culture solution can be judged through the movement of the upper valve ball and the lower valve ball.

The upper pipeline of the left control mechanism is connected with a fertilizer inlet, and the upper part of the right control mechanism is connected with a clear water inlet. The left mechanism can continuously supply fertilizer solution for the collecting shaft, the right control mechanism can continuously supply clear water for the collecting shaft, the supplied fertilizer and the clear water can be just fused into normal culture solution, and the input proportion can be automatically adjusted according to the specific fertilizer concentration of the existing culture solution.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, those skilled in the art will understand that various changes, modifications and substitutions can be made without departing from the spirit and scope of the present invention. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention shall fall within the protection scope of the present invention.

Claims (10)

1. The utility model provides a distributed underground tunnel fertilizer collection device, includes collection axle (1), its characterized in that: the front end of collecting axle (1) installs response subassembly, the reposition of redundant personnel subassembly is installed to the surface left and right sides of collecting axle (1), the mixed subassembly is installed to the surface top of collecting axle (1), response subassembly and reposition of redundant personnel subassembly pipe connection, reposition of redundant personnel subassembly and mixed subassembly pipe connection.

2. The distributed underground tunnel fertilizer collection device of claim 1, wherein: the induction component comprises an upper valve port (5), a lower valve port (6), a left valve port (7) and a right valve port (8), wherein an upper valve ball (9), a lower valve ball (10), a left valve ball (11) and a right valve ball (12) are respectively arranged on one side of the upper valve port (5), the lower valve port (6), the left valve port (7) and the right valve port (8) which are positioned inside the collecting shaft (1), magnets are respectively arranged at the tail ends of the left valve ball (11) and the right valve ball (12), and clamping grooves are respectively formed in the surfaces of the left valve ball (11) and the right valve ball (12).

3. The distributed underground tunnel fertilizer collection device of claim 2, wherein: the flow dividing assembly comprises a left flow dividing shell (3) and a right flow dividing shell (4), a left flow dividing chamber (19) is arranged inside the left flow dividing shell (3), the upper end and the lower end of the left side of the left flow dividing chamber (19) are respectively connected with a lower valve port (6) and a left valve port (7) through pipelines, the right side of the left flow dividing chamber (19) is connected with a left control mechanism through a pipeline, a right flow dividing chamber (20) is arranged inside the right flow dividing shell (4), the upper side and the lower side of the right flow dividing chamber (20) are respectively connected with an upper valve port (5) and a right valve port (8) through pipelines, and the left side of the right flow dividing chamber (20) is connected with a right control mechanism through a pipeline.

4. The distributed underground tunnel fertilizer collection device of claim 3, wherein: left side control mechanism is including three left control valve of group (24), three groups left side control valve (24) are series connection, three groups the end and the collection axle (1) pipe connection of left side control valve (24), the inside fixed mounting of left side flow distribution room (19) has baffle (21), the inside slidable mounting of left side flow distribution room (19) has valve plate (23), right side control mechanism is including three right control valve of group (25), three groups right side control valve (25) are series connection, three groups the end and the collection axle (1) pipe connection of right side control valve (25), the inside fixed mounting of right side flow distribution room (20) has baffle two (22), the inside slidable mounting of right side flow distribution room (20) has valve plate two (28).

5. The distributed underground tunnel fertilizer collection device of claim 4, wherein: three the inside of left side control valve (24) all is provided with counter weight valve ball one, elastic valve bag one has been cup jointed on the surface of counter weight valve ball one, both ends all are connected with left parallelly connected pipe (26) about the right side of left side reposition of redundant personnel room (19), left side parallelly connected pipe (26) respectively with three elastic valve bag pipe connections of group, the inside of right side control valve (25) all is provided with counterweight valve ball two, elastic valve bag two all is cup jointed on the surface of counterweight valve ball two, both ends all are connected with right parallelly connected pipe (27) about the left side of right side reposition of redundant personnel room (20), right side parallelly connected pipe (27) respectively with three elastic valve bag two pipe connections of group.

6. The distributed underground tunnel fertilizer collection device of claim 5, wherein: the hybrid module is including mixing shell (2), the inside of mixing shell (2) is provided with guide valve (13) and mixing valve (14), guide valve (13) respectively with first left control valve (24), the first right control valve (25) pipe connection of group, the below both sides of guide valve (13) pipe connection respectively have left counter weight bag (15) and right counter weight bag (16), the bottom of left side counter weight bag (15) and right counter weight bag (16) is provided with left spring bag (17) and right spring bag (18) respectively, be provided with flexible pipeline between guide valve (13) and left counter weight bag (15), right counter weight bag (16), the last fixed surface of left side counter weight bag (15) and left spring bag (17) is connected, the upper surface fixed surface of right counter weight bag (16) and right spring bag (18) is connected.

7. The distributed underground tunnel fertilizer collection device of claim 6, wherein: the lower extreme of mixing valve (14) respectively with left spring bag (17), right spring bag (18) pipe connection, the left and right sides of mixing valve (14) respectively with the left control valve of second group (24), right control valve of second group (25) pipe connection, left side spring bag (17), right spring bag (18) respectively with the left control valve of third group (24), right control valve of third group (25) pipe connection.

8. The distributed underground tunnel fertilizer collection device of claim 7, wherein: the upper right side of the left shunting chamber (19) and the upper left side of the right shunting chamber (20) are filled with ethanol, and the lower right side of the left shunting chamber (19) and the lower left side of the right shunting chamber (20) are filled with mercury.

9. The distributed underground tunnel fertilizer collection device of claim 8, wherein: the density of the upper valve ball (9) is less than that of the lower valve ball (10).

10. The distributed underground tunnel fertilizer collection device of claim 9, wherein: the top pipe connection of left side control mechanism has the fertilizer entry, the top of right side control mechanism is connected with the clear water entry.

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