TWM563740U - Organic biological fertilizer automatic control system - Google Patents

Abstract

This creation refers to an organic biological fertilizer automatic control system, which has: a receiving component and an automatic control component. The accommodating member is surrounded by a fertilizer container, a hydrogen-rich water device, an ultra-micro bubble aeration device, and a farming chamber. And the tillage room is an excellent basis for the fact that the organic bio-fertilizer is provided for the components.

Description

Organic biological fertilizer automatic control system

This creation is related to an automatic control system for organic biological fertilizers, in which the high oxygen-containing air is injected into the water to form ultra-fine bubble water, and the ultra-fine bubble water is integrated into the technical field of organic biological fertilizer.

First press, due to the increasing accumulation of various types of pollution in the global land, the demand for soilless cultivation is increasing, and soilless cultivation is compared with land cultivation. Soilless soiling, soil-borne diseases and continuous cropping obstacles The problem, and soilless cultivation in the site selection, as long as it can set up a closed place to provide planting, and does not need to consider the implementation of the arable land, no arable land planting seasonal restrictions and fallow hurdles, and can produce more than the same land area It is more improved, and at the same time, it is more stable and improves the quality of crops.

In addition, the nutrients required for soilless cultivation of crops are mainly based on liquefied fertilizers. In addition, at least the following technologies must be used in the use of liquefied fertilizers:

First, the consumption control of oxygen content.

Second, the use and control of oxygen time.

3. Disinfection and sterilization of liquefied fertilizers.

It can be seen that the oxygen content, oxygen time and disinfection and sterilization control are the core of soilless culture technology, and it is also the key to the safety of crops, the improvement of production efficiency, and the success or failure of planting. However, so far, its key technologies for controlling oxygen content, oxygen time and disinfection and sterilization are still not effectively mastered, so that soilless cultivation can not get rid of the following problems during production and operation:

One is that the content of oxygen in the liquefied fertilizer is difficult to increase.

The second is: it is easy to breed algae that consume too much oxygen.

The third is: easy to spread mold, disease and viral.

The problems of one to three are just the root cause of growth retardation and infection and decay, and soilless cultivation is a closed field, so that if there are molds, diseases and viral viruses, it will spread rapidly in a very short time. And can't stop it.

In view of the above, it is known that there is a problem that the soilless culture has difficulty in increasing the oxygen content of the liquefied fertilizer, the algae which is easy to breed and consume a large amount of oxygen, and the mold, the disease and the spread of the filter virus which are liable to cause infection and rot of the plant crop, Therefore, the creators of this case are oriented towards the development of liquefied fertilizers: the increase of oxygen content, the elimination of algae breeding, and the elimination of mold and disease and viral viruses, and through the creators of this case, think about it and use it. Microbubbles are best for disinfection, sterilization, and increased oxygen content.

The organic biological fertilizer automatic control system of the present invention comprises: a receiving component and an automatic control component. The receiving component is internally provided with a chamber, and the receiving component is connected with a conducting chamber: a liquid fertilizer nozzle, a hydrogen ultra-micro bubble water nozzle, an oxygen ultra-micro bubble water nozzle, and an output nozzle. The liquid fertilizer pipe is connected with a first pump, and the first pump is connected with a fertilizer container, and the fertilizer container stores an organic biological fertilizer which is transported into the chamber through the first pump. The hydrogen ultra-micro bubble water pipe is connected with a hydrogen-rich water device, the hydrogen-rich water device is provided with: a second pump, a second pump side is connected with a first external water source, and the second pump is connected by the first external water source. The pumping water is output to a first gas mixing joint, the first gas mixing joint is connected with a hydrogen gas container, and then the first gas mixing joint is connected with a first magnetic wave oscillating member, and the first magnetic wave oscillating member is connected with a hydrogen ultra-fine bubble water pressure vessel. The hydrogen ultra-micro bubble water pressure vessel is connected with a hydrogen ultra-micro bubble water nozzle. The oxygen ultra-bubble water connection pipe is connected with an ultra-micro bubble aeration device, the ultra-micro bubble aeration device is provided with a third pump, the third pump side is connected with a second external water source, and the third pump is connected with a second external water source. The external water source pumping water is output to a second gas mixing joint, the second gas mixing joint is connected with an aerator, and then the second gas mixing joint is connected with a second magnetic wave oscillating member, and the second magnetic wave oscillating member is coupled with an oxygen ultrafine bubble water. The pressure vessel, the oxygen ultra-micro bubble water pressure vessel is connected to the aerobic ultra-micro bubble water nozzle. The output connecting pipe is connected with a tilling chamber, and the working chamber has an indoor connecting pipe connecting the output connecting pipe, and the indoor connecting pipe is connected with a tilling tank; and the automatic control component setting operation includes: a first pump, Hydrogen-rich water device and ultra-micro bubble aeration device.

The second pump of the present invention is provided with a first water connection pipe connecting the first gas mixing joint, the first gas mixing joint is provided with a first venturi hole, and the first venturi hole is recessed to the right side of the first venturi hole. a first inlet pressure chamber of the tapered diameter, the first inlet tube is connected to the first water pipe on the left side, and the first pressure narrow hole on the right side of the first pressure inlet chamber has a small pressure pressurized water, the first addition a first spoiler chamber having a tapered tapered diameter is disposed on the right side of the narrowing hole, a hydrogen water conduit is disposed on the right side of the first spoiler chamber, the first magnetic wave oscillating member is coupled to the hydrogen water conduit, and then the first mixing A first air inlet hole penetrating into the first venturi hole is added above the gas joint, and the first air inlet hole is provided with a hydrogen inlet pipe connected to the hydrogen container.

The third pump of the present invention is provided with a second water connection pipe connecting the second gas mixture joint, the second gas mixture joint is provided with a second venturi hole, and the second venturi hole is recessed to the right side with a tapered cone a second inlet chamber having a tapered shape, a second inlet pipe connected to the left side of the second inlet chamber, and a second pressurized narrow hole having a small diameter pressurized water on the right side of the second inlet chamber, the second addition a second spoiler chamber with a tapered tapered diameter is arranged on the right side of the narrowing hole, an oxygen water conduit is added on the right side of the second spoiler chamber, a second magnetic wave oscillating member is connected to the oxygen water conduit, and then a second air-mixing joint is connected. The upper side is provided with a second air inlet hole extending through the second venturi hole, and the second air inlet hole is provided with an oxygen inlet pipe connected to the aerator.

At least one first indoor pump connected to the output is connected to the interior of the creation, and the first indoor pump is connected to at least one indoor nozzle. Then, at least one second indoor pump connected to the output nozzle is disposed in the tilling chamber, and the second indoor pump is connected to at least one indoor spray nozzle, and the indoor spray nozzle is connected to at least one spray head.

The interior of the creation has at least: a temperature sensing element, an oxygen content sensing element and a pH sensor element; and the automatic control element is connected to the temperature sensing element, the oxygen content sensing element and the pH sensor. In addition, there is at least one sedimentation recovery tank in the tilling chamber, and a recovery pump is arranged above the sedimentation recovery tank, the recovery pump is provided with a suction pipe extending downward into the sedimentation recovery tank, and the recovery pump is provided with a recovery guide tube of the conduction chamber. . However, the organic biological fertilizer automatic control system is provided with at least one chiller connected to the control element, and the chiller is provided with a condensing tube placed in the chamber and the sedimentation recovery tank.

A‧‧‧Organic Biological Fertilizer

B‧‧‧Water

B1‧‧‧ Hydrogen ultra-fine bubble water

B2‧‧‧Oxygen ultra-fine bubble water

C‧‧‧ Hydrogen

C1‧‧‧ Hydrogen ultra-micro bubbles

D‧‧‧High oxygenated air

D1‧‧‧Oxygen ultra-fine bubbles

E‧‧‧ plants

E1‧‧‧ root

E2‧‧‧Foliage

1‧‧‧Organic Biological Fertilizer Automatic Control System

2‧‧‧ housing components

21‧‧ ‧ room

211‧‧‧First pump

212‧‧‧Temperature sensing element

213‧‧‧Oxygen content sensing element

214‧‧‧pH-sensing element

22‧‧‧With liquid fertilizer takeover

23‧‧‧ Hydrogen ultra-micro bubble water take-over

24‧‧‧Oxygen ultra-micro bubble water take-over

25‧‧‧ Output takeover

26‧‧‧ fertilizer container

3‧‧‧Automatic control components

4‧‧‧ Hydrogen-rich water installation

41‧‧‧Second pump

411‧‧‧First water pipe

42‧‧‧First external water source

43‧‧‧First aeration connector

431‧‧‧First Venturi Tube Hole

432‧‧‧First pressure hole chamber

433‧‧‧First pressurized narrow hole

434‧‧‧First spoiler chamber

435‧‧‧ Hydrogen water conduit

436‧‧‧First air vent

437‧‧‧ Hydrogen into the trachea

44‧‧‧ Hydrogen container

45‧‧‧First magnetic oscillation component

451‧‧‧The first high-frequency oscillator

46‧‧‧ Hydrogen ultra-micro bubble water pressure vessel

5‧‧‧Supermicrobubble aerator

51‧‧‧ third pump

511‧‧‧Second water pipe

52‧‧‧Second external water source

53‧‧‧Second air mixing joint

531‧‧‧Second venturi hole

532‧‧‧Second pressure chamber

533‧‧‧Second pressurized narrow hole

534‧‧‧Second spoiler

535‧‧‧Oxygen water conduit

536‧‧‧Second air inlet

537‧‧‧Oxygen into the trachea

54‧‧‧Aerator

55‧‧‧Second magnetic oscillation component

551‧‧‧Second high-frequency oscillator

56‧‧‧Oxygen ultra-fine bubble water pressure vessel

6‧‧‧ farming room

61‧‧‧ Indoor takeover

62‧‧‧ farming trough

63‧‧‧First indoor pump

64‧‧‧Second indoor pump

65‧‧‧Indoor spray takeover

66‧‧‧ spray head

67‧‧‧Precipitation recovery tank

68‧‧‧Recycled pump

681‧‧‧ suction tube

682‧‧‧Recycling guide tube

7‧‧‧ice water machine

71‧‧‧Condensation tube

Figure 1 is a schematic diagram of the automatic control system for organic biological fertilizers.

Figure 2 is a schematic diagram of the hydrogen-rich water device of the creation.

Figure 3 is a schematic diagram of the ultra-microbubble aerator of the creation.

The fourth picture is a schematic diagram of the farming room and the ice water machine of the creation.

In order to make your reviewer have a better understanding of this creation, Zize will explain it in the following examples.

The present invention provides an automatic control system for organic fertilizers, at least comprising: a receiving member 2 and an automatic control member 3; the receiving member 2 is internally provided with at least one chamber 21, and the periphery of the receiving member 2 is at least connected There is a liquid fertilizer nozzle 22, a hydrogen ultra-micro bubble water nozzle 23, an oxygen ultra-fine bubble water nozzle 24, and an output nozzle 25 for guiding the chamber 21; and the liquid fertilizer nozzle 21 is connected with a first pump 211. The first pump 211 is coupled to a fertilizer container 26. The fertilizer container 26 stores an organic bio-fertilizer A that is transported into the chamber 21 through the first pump 211. The hydrogen ultra-micro-bubble water pipe 22 is connected to a hydrogen-rich water device 4, the hydrogen-rich water device 4 is provided with a second pump 41, and the second pump 41 is connected to a first external water source 42 on the side thereof, and the first The second pump 41 is pumped from the first external water source 42 to a first gas mixture joint 43. A hydrogen gas container 44 is connected to the first gas mixture port 43, and the hydrogen gas C is output from the hydrogen gas container 44 to the first gas mixture port. 43 is mixed into the water B, and then the first agitating joint 43 is connected to a first magnetic oscillation element 45, and the electromagnetic wave generated by the first high-frequency oscillation element 45 firstly mixed with the first high-frequency oscillator 451 is mixed into the water. The hydrogen C in B is oscillated into a hydrogen ultra-micro bubble C1 by a magnetic wave, and uniformly integrated into the water B according to the hydrogen ultra-fine bubble C1 to become a hydrogen ultra-fine bubble water B1, and the first magnetic oscillation element 45 is coupled to temporarily store the hydrogen-hydrogen super a hydrogen ultra-bubble water pressure vessel 46 of microbubble water B1, the hydrogen ultrafine bubble water pressure vessel 46 is connected to the hydrogen ultramicro The bubble water nozzle 23 is passed through the hydrogen ultrafine bubble water pressure vessel 46 to introduce the hydrogen ultrafine bubble water B1 into the chamber 21 to be mixed with the organic bio-fertilizer A. The oxygen ultra-bubble water nozzle 24 is connected to an ultra-microbubble aeration device 5, the ultra-microbubble aerator 5 is provided with a third pump 51, and a second external water source 52 is connected to the third pump 51 side. The third pump 51 is pumped from the second external water source 52 to a second air mix connector 53. An aerator 54 is connected to the second air mix connector 53. The aerator 54 outputs a booster 54. The high oxygen-containing air D enters the second air-mixing joint 53 and is mixed into the water B. Then, the second air-mixing joint 53 is connected to a second magnetic-wave oscillating member 55, and the second magnetic-wave oscillating member 55 can be The electromagnetic wave generated by the second high-cycle oscillator 551 oscillates the high-oxygen air D mixed in the water B into an oxygen ultra-fine bubble D1, and the oxygen ultra-micro-bubble D1 uniformly integrates into the water B to become an oxygen-super-bubble water. B2, and the second magnetic oscillation element 55 is coupled to an oxygen ultra-bubble water pressure vessel 56 for temporarily storing the oxygen ultra-bubble water B2, and the oxygen ultra-bubble water pressure vessel 56 is connected to the oxygen ultra-bubble water nozzle 24 And the oxygen ultra-fine bubble water pressure vessel 56 is passed through the oxygen ultra-fine bubble water nozzle 2 4 The oxygen ultra-bubble water B2 is introduced into the chamber 21 and mixed into the organic bio-fertilizer A. The output nozzle 25 is at least connected to the tilling chamber 6. The indoor container 61 has at least one indoor connecting pipe 61 connected to the output connecting pipe 25. The indoor connecting pipe 61 is connected to at least one working tank for accommodating the organic biological fertilizer A. 62. The tillage tank 62 is planted with plant E above the liquid organic bio-fertilizer A. The automatic control element 3 can be configured to operate at least: the first pump 211, the hydrogen-rich water device 4 and the ultra-micro bubble aeration device 5 for performing the operation of the hydrogen ultra-fine bubble water B1 and oxygen ultra-micro The bubble water B2 is produced, and then the hydrogen ultra-bubble water B1 and the oxygen ultra-bubble water B2 are input into the chamber 21 and uniformly mixed with the organic bio-fertilizer A (for example, as shown in Fig. 1; One pump 211 can be a peristaltic motor).

The hydrogen ultrafine bubble C1 contained in the hydrogen ultrafine bubble water B1 is uniformly mixed with the organic bio-fertilizer A in the chamber 21, and the organic bio-fertilizer A mainly utilizes the hydrogen ultra-micro bubble C1. The hydrogen gas C is released due to the collapse of the surface tension and produces an instantaneous fine explosion to remove bacteria, viral viruses, various heavy metals and chemical pollutants. Then, the hydrogen ultra-fine bubble water B1 does not consume the hydrogen ultra-fine bubble C1 in the chamber 21, so the hydrogen ultra-fine bubble C1 is accompanied by the organic biological fertilizer A and the oxygen ultra-fine bubble water B2. In the tank 62, the instantaneous micro-explosion sterilization and the algae removal are performed on the tilling tank 62 by the remaining hydrogen ultra-fine bubble C1, thereby completely preventing the algae from breeding in the tilling tank 62, and the organic The bio-fertilizer A can also be activated and decomposed by the oxygen contained in the oxygen ultra-microbubble D1 to facilitate the absorption of the plant E. Moreover, the oxygen contained in the oxygen ultra-microbubble D1 can be used to provide the plant E to grow and breathe. Need (eg as shown in Figure 1).

The second pump 41 of the present invention is further provided with a first water connection pipe 411 connecting the first gas mixture joint 43 , and the first gas mixture joint 43 is provided with a first venturi hole 431 , the first Wenshi A first inlet pressure chamber 432 having a tapered tapered shape is disposed on the left side of the tube hole 431. The first inlet pressure chamber 432 is coupled to the first water connection tube 411. The first pressure inlet chamber 432 is connected to the left side. The right side further has a small diameter narrowing hole 433 for pressurizing the water, and a first spoiler hole 434 having a tapered and expanded diameter is added to the right side of the first pressing narrow hole 433. The first spoiler hole A hydrogen water conduit 435 is coupled to the right side of the chamber 434. The hydrogen water conduit 435 is coupled to the first magnetic wave oscillating member 45, and then the first first gas mixing joint 43 is provided with a first portion extending through the first venturi hole 431. The air inlet hole 436 is provided with a hydrogen inlet pipe 437 connected to the hydrogen container 44. That is, the first aeration joint 43 is mainly pressurized in the first pressurized narrow hole 433, the accelerated water B flows into the first spoiler chamber 434, and the hydrogen inflow pipe 437 is introduced into the first spoiler chamber 434. Mixing in water B, and forcing hydrogen C to appear as microbubbles in water B, causing microbubbled hydrogen C to flow along with water B to first magnetic wave oscillating element 45, according to which first magnetic wave oscillating element 45 will microbubble The hydrogen C is oscillated into a hydrogen ultra-fine bubble C1 having a diameter of less than 1 mm, and then uniformly mixed into the water B by the hydrogen ultra-fine bubble C1 to become a hydrogen ultra-fine bubble water B1 (as shown in Fig. 2).

The third pump 51 of the present invention is further provided with a second water connection pipe 511 connecting the second gas mixture joint 53 , and the second gas mixture joint 53 is provided with a second venturi hole 531 , the second Wenshi A second inlet chamber 532 having a tapered tapered shape is disposed on the left side of the tube hole 531, and the second inlet tube 511 is coupled to the left side of the second inlet chamber 532. The second inlet chamber 532 is connected to the left side. The second side has a small diameter narrowing hole 533 for pressurizing the water, and the second pressurized narrow hole A second spoiler chamber 534 having a tapered tapered diameter is added to the right side of the 533. An oxygen water conduit 535 is added to the right side of the second spoiler chamber 534. The oxygen water conduit 535 is coupled to the second magnetic wave oscillating member 55, and then A second air inlet 536 extending through the second venturi hole 531 is added to the second air inlet joint 53. The second air inlet 536 is provided with an oxygen inlet pipe 537 connected to the aerator 54. The second air-mixing joint 53 is mainly pressurized in the second pressurized narrow hole 533, accelerates the water B into the second spoiler chamber 534, and the oxygen-injecting air pipe 537 introduces the high oxygen-containing air D in the second spoiler. The cell 534 is mixed in the water B, and the high oxygen-containing air D is forced to be micro-bubble in the water B, so that the micro-bubble-containing high-oxygen air D flows along the water B to the second magnetic wave oscillating element 55, according to The second magnetic wave oscillating element 55 oscillates the microbubble high oxygen-containing air D into an oxygen ultra-micro bubble D1 having a diameter of less than 1 mm, and then uniformly integrates the oxygen ultra-micro bubble D1 into the water B to become an oxygen ultra-fine bubble water B2 ( Such as: Figure 3).

At least another first indoor pump 63 that connects the output nozzle 25 is disposed in the tilling chamber 6 of the present invention. The first indoor pump 63 is connected to at least one of the indoor nozzles 61, and is then connected by the indoor connector 61. The organic bio-fertilizer A cultivation tank 62 is used to provide the root E1 of the plant E to absorb the organic bio-fertilizer A. In addition, at least another second indoor pump 64 that connects the output nozzle 25 is disposed in the tilling chamber 6. The second indoor pump 64 is coupled to at least one indoor spray nozzle 65. The indoor spray nozzle 65 is at least rotated. A spray head 66 is attached, and the spray head 66 is located above the plant E, so that the organic bio-fertilizer A can be sprayed on the leaf surface E2 of the plant E as another way for the plant E to absorb the organic bio-fertilizer A (for example, Fig. 4) Show).

The organic biological fertilizer automatic control system 1 of the present invention is provided with at least one chiller 7 connected to the control element 2, and the chiller 7 is provided with a condensing tube 71 placed in the chamber 21 for adjusting the chamber 21 The organic bio-fertilizer A is maintained at a temperature range in which the plant E is most suitable for absorbing nutrients, and the control of the hydrogen ultra-fine bubble C1 and the oxygen ultra-micro-bubble D1 in the organic bio-fertilizer A can have a temperature suitable for maintaining stability. Then, at least a temperature sensing element 212, an oxygen content sensing element 213 and a pH sensor element 214 are added to the chamber 21; and the automatic control element 2 is connected to the temperature sensing element 212 and the oxygen content. The sensing element 213 and the pH sensor element 214. And the automatic control component 2 matches the temperature sensing component 212 with the set value, the oxygen a data sensing operation monitored by the amount sensing element 213 and the pH sensor 214: the first pump 211 provides extraction of the organic bio-fertilizer A, output of the hydrogen ultra-microbubble water B1 of the hydrogen-rich water device 4, and The oxygen microbubble water B2 of the ultramicrobubble aerator 5 is provided (as shown in Fig. 4).

The organic bio-fertilizer A of the present invention is reduced to a general water B after use, and at least one sedimentation recovery tank 67 containing the reduced water is stored in the cultivation chamber 6, and a recovery pump is added above the sedimentation recovery tank 67. In the pump 68, the recovery pump 68 is provided with a suction pipe 681 extending downward into the sedimentation recovery tank 67, and the recovery pump 68 is provided with a recovery nozzle 682 that conducts the chamber 21, but the recovery pump 68 The water B is pumped from the suction pipe 681 and sent back to the chamber 21 for recycling. In addition, the precipitation recovery tank 67 is provided with an additional condensing pipe 71 connected to a chiller 7 provided outside the cultivation chamber 6, whereby the chiller 7 adjusts the sediment by the condensing pipe 71. The temperature of the water B recovered in the recovery tank 67 is similar to the condition in the chamber 21, so that the organic bio-fertilizer A can be kept in the low temperature state in the chamber 21 to avoid biogas production by the bio-fertilizer A, and to ensure hydrogen superheating. The stability of the microbubbles C1 and the oxygen ultrafine bubbles D1 allows the hydrogen ultramicrobubbles C1 and the oxygen ultrafine bubbles D1 to be fully used in the living environment of the plant E (for example, as shown in Fig. 4).

According to the above description, this creation system uses the organic biological fertilizer automatic control system 1 to mix the hydrogen ultra-fine bubble C1 and the oxygen ultra-micro bubble D1 with the organic biological fertilizer A, and the organic biological fertilizer A provides the basic survival for the plant E. And the basic requirement of respiratory and photosynthesis is provided by plant ultra-microbubble D1 for plant E, and then the micro-emission of hydrogen ultra-fine bubble C1 is followed by micro-explosion: bacteria, filter virus, various heavy metals and chemical pollutants. The organic bio-fertilizer A, the tillage tank 62, the root E1 of the plant E and the leaf surface E2 can maintain the primary superior characteristics in the best clean conditions.

The chiller 7 is provided with a condensing pipe 71 in the chamber 21 and the sedimentation recovery tank 67 for adjusting the organic bio-fertilizer A and water B in the chamber 21 to be kept in the plant E and the hydrogen ultra-microbubbles. Another excellent feature of the temperature range in which C1 and oxygen ultra-microbubble D1 are most suitable for use, it is known that this creation does have new patent requirements that meet the novelty, advancement and industrial applicability.

The technical content and technical features of the present invention have been disclosed above, but those skilled in the art may still make various substitutions and modifications based on the disclosure of the present invention without departing from the spirit of the present invention. Therefore, the scope of the present invention is not limited to the embodiments disclosed, but includes various alternatives and modifications without departing from the invention, and is covered by the scope of the novel application.

Claims (9)

An organic biological fertilizer automatic control system includes at least: a receiving component and an automatic control component; the receiving component has at least one chamber inside, and at least a periphery of the receiving component is connected to the chamber: a liquid fertilizer nozzle a hydrogen super-micro bubble water nozzle, an oxygen ultra-micro bubble water nozzle, and an output nozzle; and the liquid fertilizer nozzle is connected with a first pump, the first pump is connected with a fertilizer container, and the fertilizer container is stored therein The organic bio-fertilizer fed into the chamber through the first pump; and the hydrogen ultra-micro-bubble water connection is connected to a hydrogen-rich water device, the hydrogen-rich water device is provided with a second pump, and the second pump is a first external water source is connected to the side, and the second pump is pumped by the first external water source to a first gas mixing joint, a hydrogen gas tank is connected to the first gas mixing joint, and then the first gas mixing joint is connected Connected to a first magnetic wave oscillating member, the first magnetic wave oscillating member is coupled to a hydrogen ultra-fine bubble water pressure vessel, and the hydrogen ultra-fine bubble water pressure vessel is connected to the hydrogen ultra-fine gas a water inlet pipe; the oxygen ultra-bubble water pipe is connected to an ultra-micro bubble aeration device, the ultra-micro bubble aeration device is provided with a third pump, and the third pump side is connected with a second external water source, and the The third pump draws the water from the second external water source to a second gas mixing joint, and an aerator is connected to the second gas mixing joint, and then the second gas mixing joint is connected with a second magnetic wave oscillating member. The second magnetic wave oscillating member is coupled to an oxygen ultra-bubble water pressure vessel, the oxygen ultra-bubble water pressure vessel is connected to the oxygen ultra-bubble water nozzle; and the output nozzle is at least connected to a tilling chamber, the tilling capacity At least one indoor connecting pipe connecting the output connecting pipe is disposed in the indoor, the indoor connecting pipe is connected to at least one tilling tank; and the automatic control element is configured to operate at least: the first pump, the hydrogen-rich water device and the ultra-micro bubble aeration Device. The organic biological fertilizer automatic control system according to claim 1, wherein the second pump is further provided with a first water connection pipe connecting the first gas mixing joint, the first gas mixing joint A first venturi hole is added, and a first inlet hole chamber with a tapered tapered shape is recessed to the left of the first venturi hole, and the first inlet port is connected to the first connection a water pipe, the first pressure inlet hole has a small diameter to press the first pressurized narrow hole of the water, and the first pressure narrow hole has a first spoiler chamber with a tapered tapered diameter on the right side. A hydrogen water conduit is coupled to the right side of the first spoiler chamber, the hydrogen water conduit is coupled to the first magnetic wave oscillating member, and then a first portion of the first gas mixing joint is inserted through the first venturi hole. An air inlet hole is provided, and the first air inlet hole is provided with a hydrogen inlet pipe connected to the hydrogen container. The organic biological fertilizer automatic control system according to claim 1, wherein the third pump is further provided with a second water connection pipe connecting the second gas mixing joint, and the second gas mixing joint is provided with a second venturi pipe. a second inlet hole chamber having a tapered tapered shape, and a second inlet pipe connected to the left side of the second inlet hole chamber, the second inlet pressure The second side of the hole chamber has a second diameter narrowing hole for pressurizing the water, and a second spoiler chamber with a tapered tapered diameter is added to the right side of the second pressurized narrow hole. The second spoiler chamber is provided. An oxygen water conduit is connected to the right side, the oxygen water conduit is connected to the second magnetic wave oscillating member, and then a second air inlet hole penetrating into the second venturi hole is added above the second gas mixing joint, the second inlet The air hole is provided with an oxygen inlet pipe connected to the aerator. The organic biological fertilizer automatic control system according to claim 1, wherein at least another first indoor pump connected to the output nozzle is disposed in the tilling chamber, and the first indoor pump is coupled to at least one of the indoor nozzles. The organic biological fertilizer automatic control system according to claim 1, wherein at least another second indoor pump connected to the output nozzle is disposed in the tilling chamber, and the second indoor pump is coupled to at least one indoor spray nozzle. The indoor spray nozzle is connected to at least one spray head. The organic biological fertilizer automatic control system according to claim 1, wherein at least one temperature sensing element, an oxygen content sensing element and a pH sensor element are added to the chamber; and the automatic control element is set to connect the temperature. Inductive element, the oxygen a content sensing element and the pH sensor. The organic biological fertilizer automatic control system according to claim 1, wherein the organic biological fertilizer automatic control system is provided with at least one chiller connected to the automatic control element, and the chiller is provided with a condensing tube placed in the chamber. . The organic biological fertilizer automatic control system according to claim 1, wherein at least one precipitation recovery tank is added to the cultivation chamber, and a recovery pump is added above the precipitation recovery tank, and the recovery pump is provided with a downward extension into the sediment. The suction pipe of the recovery tank is provided, and the recovery pump is provided with a recovery guide pipe that conducts the chamber. The organic biological fertilizer automatic control system according to claim 8, wherein the sedimentation recovery tank is provided with an additional condensing pipe connected to a chiller added outside the tilling chamber.