CN217895260U - River channel treatment diving shock wave overflowing system based on Internet of things - Google Patents

Abstract

The utility model relates to a river channel treatment diving shock wave overflow system based on the Internet of things, which comprises an equipment room, a pneumatic pump, a pulser, an oxygen pipe, a biological fluid pipe and a main gas pipe; a gas distribution pipe and a water suction pipe are led out of the main gas pipe; a hydrolysis hydrogen production station is arranged on the water suction pipe; a guide pipe is led out of the gas distribution pipe, a flying wing fatigue-resistant steel pile head is arranged on the side of the guide pipe, the flying wing fatigue-resistant steel pile head is connected with the gas distribution pipe through a fatigue-resistant clutch pile, a plurality of guide rings are sleeved on the fatigue-resistant clutch pile, and a locking control rod is connected between the guide pipes; the draft tube is connected with the gas distribution tube through the electromagnetic valve; the main gas pipe is connected with the pneumatic pump through a pulser to form a closed circuit, and the pulser is connected to the hydrolysis hydrogen production station through an oxygen pipe. The air generates microcrystal bubbles under the mechanical action, the continuous microcrystal bubbles can impact, stir and gradually flow the water body, the scattering and mixing of the bubbles into the water body are accelerated, the characteristic of a diffuse fluid is realized, and the biodegradation process of pollutants in the water body and bottom mud is accelerated.

Description

River channel treatment diving shock wave overflowing system based on Internet of things

Technical Field

The utility model belongs to the technical field of the environmental protection equipment technique and specifically relates to a river course is administered dive and is shaken ripples and overflow system based on thing networking.

Background

The river channel is not only an important water transportation channel, but also plays an important role in flood control and waterlogging prevention, and is the basis for protecting the healthy operation of an ecological system.

The following methods are commonly used for river regulation:

the physical method comprises the following steps:

the physical method mainly comprises dredging and digging bottom mud, mechanically removing algae, guiding water and flushing silt, adjusting water and the like. But physical methods are usually temporary and permanent.

The chemical method comprises the following steps:

chemical methods such as coagulating sedimentation, adding chemical agents to kill algae, adding iron salts to promote phosphorus precipitation, adding lime to denitrify and the like are easy to cause secondary pollution.

Ecological-biological method: comprises a river aeration reoxygenation method, a biomembrane method, a bioremediation method, a land treatment method and an aquatic plant purification method.

The river aeration method is to artificially oxygenate river in an anoxic or anaerobic state to enhance the self-purification capacity of the river, but because the water quality of the water body is dynamic, the oxygen charging amount of normal aeration is almost a fixed value, and the dissolved oxygen is insufficient.

The biofilm technology is to utilize microorganisms on a biofilm to absorb and assimilate organic matters in sewage as nutrients, thereby purifying the sewage. The drawback of biofilm technology is that microbial biomass is difficult to control and anaerobic conditions are easily created.

The bioremediation technology is to degrade toxic and harmful pollutants in water or soil into CO on site by using microorganisms and other organisms ₂ And water or converted into non-toxic and harmless substances, and the method has obvious effects on eliminating black and odorous water and increasing dissolved oxygen in the water, but has long repairing time.

The land treatment technology utilizes the adsorption, filtration and purification functions and self-regulation and control functions of soil and plant systems to achieve the purification purpose; the percolation systems of land treatment technology are prone to clogging.

The aquatic plant purifying method is one sewage purifying method with the natural purifying function of aquatic plant utilized fully. For example, duckweed, reed in a wetland, or the like is used to perform purification treatment in a certain water area. However, the discharge of domestic sewage causes problems such as odor, pests, and landscape effects.

SUMMERY OF THE UTILITY MODEL

The applicant provides a river channel treatment diving shock wave overflow system based on the internet of things, which is reasonable in structure and aims at overcoming the defects in the prior art, and power is provided by converging currents of a solar photovoltaic generator and a magnetic suspension breeze generator on a coupler; the content of the generated oxygen is obviously improved, so that the biodegradation process is accelerated, and COD, ammonia nitrogen and total phosphorus are effectively removed.

The utility model discloses the technical scheme who adopts as follows:

a river channel treatment diving shock wave overflow system based on the Internet of things comprises an equipment room and a pneumatic pump positioned in the equipment room, wherein an opening of the pneumatic pump is provided with a pulser, and an oxygen pipe, a biological fluid pipe and a main gas pipe are led out of the pulser;

a gas distribution pipe and a water suction pipe are led out of the main gas pipe; a hydrolysis hydrogen production station is arranged on the water suction pipe; a guide pipe is led out of the gas distribution pipe, a flying wing fatigue-resistant steel pile head is arranged on the side of the guide pipe,

the flying wing fatigue-resistant steel pile head is connected with the gas distribution pipe through a fatigue-resistant clutch pile column, a plurality of guide rings are sleeved on the fatigue-resistant clutch pile column, and a locking operating rod is connected between the guide pipes; the head of the flying-wing fatigue-resistant steel pile is spirally provided with flying-wing blades,

the guide pipe is provided with a balance hole, and the guide pipe is sleeved with a microcrystalline tension pipe; the draft tube is connected with the gas distribution tube through the electromagnetic valve;

the main gas pipe is connected with the pneumatic pump through a pulser to form a closed circuit, and the pulser is connected to the hydrolysis hydrogen production station through an oxygen pipe.

As a further improvement of the technical scheme:

each guide ring is provided with an opening and closing lock catch, and a clutch nut is arranged on the locking operating rod; the locking operating lever controls the locking and the separation of the opening and closing lock catch and the clutch nut.

The aperture of the balance hole is gradually increased along the airflow direction.

And a plurality of tension micropores are arranged on the microcrystal tension tube corresponding to the balance holes.

The middle top of the equipment room is provided with a solar photovoltaic panel, a coupler and a magnetic suspension breeze generator.

The oxygen content in the total gas pipe should be more than 30%.

A water intake is arranged at the bank of the river where the overflowing system is located, and river water in an overflowing state permeates into the water intake; the water inlet end of the water suction pipe is placed in the water inlet to suck water.

The magnetic suspension breeze generator is connected to the coupler, and the coupler is connected with the air pump, the hydrolysis hydrogen generation station and the wireless network bridge.

The biological fluid pipe is led out from the pulser and bound with the gas distribution pipe.

The beneficial effects of the utility model are as follows:

the utility model has the advantages of compact structure, it is reasonable, high durability and convenient operation, overflow through dive oscillatory wave system makes the air produce the micrite bubble under mechanical action, and under oscillatory wave interference, increase bubble specific surface energy, separation micrite bubble gathers into big bubble fast and breaks, the micrite bubble that lasts can take place to the water and assault, the stirring, the class, it mixes to the water to accelerate the bubble scattering, it is long to exist in the water, the process that inside gas released the aquatic is slower, be the overflow fluid characteristic, can dual air feed, improve aquatic dissolved oxygen content, can strengthen aquatic aerobic microorganism, plankton and aquatic animal's biological activity, it is to the biodegradation process of pollutant in water and the bed mud with higher speed, to COD, ammonia nitrogen and total phosphorus have better removal effect, and simultaneously, system energy-concerving and environment-protective, has mobility, fatigue-resistant steel separation and reunion stake can screw out under the reaction force, move to required part along with the equipment room, reach the effect of "just of living, can save the investment.

Drawings

Fig. 1 is the utility model discloses a river course plane layout schematic diagram.

Fig. 2 is a schematic view of the fatigue-resistant clutch pile of the present invention.

Fig. 3 is a schematic view of the submerged overflow structure of the present invention.

Fig. 4 is a schematic diagram of the structure of the equipment room system of the present invention.

Wherein: 01. a flying wing fatigue-resistant steel pile head; 012. a clutch joint; 02. fatigue-resistant clutch piles; 03. a guide ring; 031. a locking lever; 032. opening and closing the lock catch; 033. a clutch nut; 034. a flying wing blade; 04. a flow guide pipe; 041. a balance hole; 042. a microcrystalline tension tube; 05. An electromagnetic valve; 06. a gas distributing pipe; 07. a main gas pipe; 08. a pulser; 09. a pneumatic pump; 10. A coupler; 11. a magnetic suspension breeze generator; 12. an equipment room; 13. a solar photovoltaic panel; 14. a wireless network bridge; 15. a hydrolysis hydrogen production station; 16. a suction pipe; 17. an oxygen tube; 18. a biological fluid tube.

Detailed Description

The following describes embodiments of the present invention with reference to the drawings.

As shown in fig. 1 to 4, the system for treating the submerged oscillatory wave overflowing in the river channel based on the internet of things of the present embodiment includes an equipment room 12 and a pneumatic pump 09 located in the equipment room 12, wherein a pulser 08 is installed at a mouth of the pneumatic pump 09, and an oxygen pipe 17, a biological fluid pipe 18 and a main gas pipe 07 are led out of the pulser 08;

a gas distributing pipe 06 and a water suction pipe 16 are led out of the main gas pipe 07; the water suction pipe 16 is provided with a hydrolysis hydrogen production station 15; a draft tube 04 is led out of the gas distribution tube 06, a flying wing fatigue-resistant steel pile head 01 is arranged at the side of the draft tube 04,

the flying wing fatigue-resistant steel pile head 01 is connected with the gas distribution pipe 06 through a fatigue-resistant clutch pile 02, a plurality of guide rings 03 are sleeved on the fatigue-resistant clutch pile 02, and a locking control lever 031 is connected between the guide pipes; the flying wing fatigue-resistant steel pile head 01 is spirally provided with a flying wing blade 034,

the draft tube 04 is provided with a balance hole 041, and the draft tube 04 is externally sleeved with a microcrystal tension tube 042; the draft tube 04 is connected with the gas distribution tube 06 through the electromagnetic valve 05;

the main gas pipe 07 is connected with a pneumatic pump 09 through a pulser 08 to form a closed circuit, and the pulser 08 is connected to the hydrolysis hydrogen production station 15 through an oxygen pipe 17.

Each guide ring 03 is provided with an opening and closing lock 032, and a clutch nut 033 is arranged on a locking operating rod 031; the locking lever 031 controls the locking and releasing of the locking and releasing lock 032 and the clutch nut 033.

The aperture of the balance hole 041 gradually increases along the airflow direction in the draft tube 04.

The microcrystal tension tube 042 is provided with a plurality of tension micropores corresponding to the balance holes 041.

The top of the equipment room 12 is provided with a solar photovoltaic panel 13, a coupler 10 and a magnetic suspension breeze generator 11.

The oxygen content in the total gas pipe 07 should be more than 30%.

A water intake is arranged at the bank of the river where the overflowing system is located, and river water in an overflowing state permeates into the water intake; the water inlet end of the water suction pipe 16 is placed in the water inlet to suck water.

The magnetic suspension breeze generator 11 is connected to the coupler 10, and the coupler 10 is connected with an air pump, a hydrolysis hydrogen production station 15 and a wireless network bridge 14.

The biological fluid pipe 18 is led out from the pulser 08 and is bound with the gas distribution pipe 06.

The specific structure and working process of the embodiment are as follows:

as shown in fig. 4, a solar photovoltaic panel 13 is laid on the roof of the equipment room 12, a wireless network bridge 14 is also arranged on the roof, and intermittent current generated by the solar photovoltaic panel 13 and the magnetic levitation breeze generator 11 is converged to the coupler 10 and amplified into a continuous constant-current air supply and pressure pump 09, a hydrolysis hydrogen production station 15 and the wireless network bridge 14 through the coupler 10.

The solar photovoltaic panel 13 can be directly converged with the current of the magnetic suspension breeze generator 11 in the coupler 10 without the system components such as a conventional controller, an inverter, a storage battery and the like, the coupler 10 amplifies the intermittent current coupling of the solar photovoltaic panel 13 and the magnetic suspension breeze generator 11 into a continuous constant current, the coupler supplies a gas pressure pump 09 to work with a hydrolysis hydrogen generation station 15 and a wireless network bridge 14, and the residual electricity can be also used for grid connection or as power energy for pumping the river water treated by the system to irrigate farmlands.

The solar photovoltaic panel 13 in the embodiment adopts a commercially available monocrystalline silicon photovoltaic panel, the blades of the magnetic suspension breeze generator 11 in the embodiment are in a building block type, and the magnetic suspension breeze generator 11 and the coupler 10 are purchased from Jiangsu Co., ltd. According to the detection data of the product quality supervision and inspection center of Jiangsu power saving machine, the 1024h continuous power supply coupling coefficient of the coupler is 1069.2 times

As shown in fig. 1 and 2, the flying wing fatigue-resistant steel pile head 01 is provided with a flying wing blade 034, is connected with a fatigue-resistant clutch pile 02 through a clutch joint 012, is screwed into a riverbed through a mechanical mode by using a positioning template, can remove the fatigue-resistant clutch pile 02 through counter-rotation, and leaves the flying wing fatigue-resistant steel pile head 01 in the riverbed soil.

As shown in fig. 2, the guide ring 03 is sleeved on the fatigue-resistant clutch pile 02, the opening and closing lock 032 and the clutch nut 033 matched with the guide ring 03 are controlled to be locked and separated by the locking control rod 031, the guide pipe 04 is submerged into the water bottom by using the guide ring 03, and is locked on the flying wing fatigue-resistant steel pile head 01 by the separated clutch nut 033, and the locking control rod 031 and the opening and closing lock 032 can be separated by reversely rotating. The utility model discloses in only stay wing fatigue-resistant steel pile head 01 in the riverbed soil, not receive the interference of pasture and water, can not influence the ship operation yet.

The utility model provides a pulser 08 goes up throttle's piston stroke motion and to the air current air pressure size production invariable rule change in total trachea 07 to the quality of water change of surveying according to the sensor, biological fluid pipe 18 of dynamic switching carries biological promoter simultaneously, strengthens improving quality of water.

When the pneumatic control valve is used, the pneumatic pump 09 is started, and the electromagnetic valve 05 balances the air pressure of each branch; the microcrystal tension tube 042 generates micron-sized microcrystal bubbles, the size change of the microcrystal bubbles with the diameter of 1-100 microns is obtained by double control of the electromagnetic valve 05, and under the interference of oscillation waves of the flow guide tube 04, the dynamic viscosity coefficient of water is improved, the specific surface energy of the bubbles is increased, the microcrystal bubbles are prevented from being rapidly aggregated into large bubbles to be broken, the dynamic viscosity coefficient of the water is improved, the specific surface energy of the bubbles is increased, and the aggregation of the microcrystal bubbles is prevented; the continuous microcrystalline bubbles can impact, stir and gradually flow the water body, so that the scattering and mixing of the bubbles into the water body are accelerated, the existence time in the water is long, and the process of releasing the internal gas into the water is slow, so that the water flow is in a diffuse fluid characteristic, the content of dissolved oxygen in the water is improved, the biological activity of aerobic microorganisms, plankton and aquatic animals in the water can be enhanced, and the biodegradation process of the aerobic microorganisms, plankton and aquatic animals in the water body and pollutants in bottom mud is accelerated;

a water intake is arranged around the river bank provided with the overflowing system, the river water in the overflowing state permeates into the water intake, the water inlet end of the water suction pipe 16 is arranged in the water intake, the water outlet end of the water suction pipe is connected with the hydrolysis hydrogen production station 15, after the water is taken by the hydrolysis hydrogen production station 15, the electric energy provided by the coupler 10 is utilized to electrolyze the water to generate hydrogen and oxygen, and the hydrogen is output; oxygen is delivered to the pulser 08 through oxygen line 17. Oxygen is conveyed to the pulser 08 through the oxygen pipe 17 and is loaded into the gas of the main gas pipe 07, the oxygen content in the gas can be increased from 20.95% to 34.95%, so that the dissolved oxygen of river water is naturally and greatly increased, the biological activity of aerobic microorganisms, plankton and aquatic animals in the water can be enhanced, the biodegradation process of pollutants in water and bottom sediment is accelerated, and the oxygen removing device has a good removing effect on COD, ammonia nitrogen and total phosphorus.

The water intake in the embodiment is surrounded by glass pumice, which is a product of Jiangsu Jingruit environmental-friendly new material company Limited.

The equipment room 12 of the embodiment adopts an assembled steel structure, and the material is made of a fatigue-resistant steel material with the steel pile.

In the above process, the guide pipe 04 is submerged under the water by the guide ring 03, and is locked on the flying wing fatigue-resistant steel pile head by the separated clutch nut 033, and the locking lever 031 and the opening and closing lock 032 are separated by counter-rotation. The coupler 10 couples and amplifies the intermittent current of the solar photovoltaic panel 13 and the magnetic suspension breeze generator 11 into a continuous constant current, and the continuous constant current is supplied to the air pressure pump 09, the hydrolysis hydrogen production station 15 and the wireless network bridge 14 to work. In this embodiment, all the controllers and sensors, including information generated by the electromagnetic valve 05, are uploaded to the river regulation control center through the wireless network bridge 14, and are subjected to control instructions.

The above description is for the purpose of explanation and not limitation of the invention, and reference is made to the claims for what are intended to be covered by the present invention.

Claims (8)

1. The utility model provides a river course administers dive and vibrates ripples and overflow system based on thing networking which characterized in that: the device comprises an equipment room (12) and a pneumatic pump (09) positioned in the equipment room (12), wherein a pulser (08) is installed at the opening part of the pneumatic pump (09), and an aerobic pipe (17), a biological fluid pipe (18) and a main air pipe (07) are led out of the pulser (08); a gas distribution pipe (06) and a water suction pipe (16) are led out from the main gas pipe (07); a hydrolysis hydrogen production station (15) is arranged on the water suction pipe (16); a guide pipe (04) is led out of the gas distribution pipe (06), a flying wing fatigue-resistant steel pile head (01) is arranged on the side of the guide pipe (04),

the flying wing fatigue-resistant steel pile head (01) is connected with the gas distribution pipe (06) through a fatigue-resistant clutch pile column (02), a plurality of guide rings (03) are sleeved on the fatigue-resistant clutch pile column (02), and a locking control rod (031) is connected between the guide pipes; the flying wing fatigue-resistant steel pile head (01) is spirally provided with a flying wing blade (034),

the draft tube (04) is provided with a balance hole (041), and the draft tube (04) is sleeved with a microcrystalline tension tube (042); the draft tube (04) is connected with the gas distribution tube (06) through the electromagnetic valve (05); the aperture of the balance holes (041) is gradually increased along the airflow direction;

the main gas pipe (07) is connected with a pneumatic pump (09) through a pulser (08) to form a closed circuit, and the pulser (08) is connected to the hydrolysis hydrogen production station (15) through an oxygen pipe (17).

2. The internet-of-things-based river regulation submersible shock wave overflow system of claim 1, wherein: each guide ring (03) is provided with an opening and closing lock catch (032), and a clutch nut (033) is arranged on the locking operating lever (031); the locking and unlocking operating lever (031) controls the locking and the unlocking of the opening and closing lock catch (032) and the clutch nut (033).

3. The internet-of-things-based river regulation submersible shock wave overflow system of claim 1, wherein: a plurality of tension micropores are arranged on the microcrystal tension tube (042) corresponding to the balance holes (041).

4. The internet-of-things-based river regulation submersible shock wave overflow system of claim 1, wherein: the top of the equipment room (12) is provided with a solar photovoltaic panel (13), a coupler (10) and a magnetic suspension breeze generator (11).

5. The internet-of-things-based river regulation diving oscillatory wave flow-spreading system as claimed in claim 1, wherein: the oxygen content in the total gas pipe (07) should be more than 30%.

6. The internet-of-things-based river regulation submersible shock wave overflow system of claim 1, wherein: a water intake is arranged at the bank of the river where the overflowing system is located, and river water in an overflowing state permeates into the water intake; the water inlet end of the water suction pipe (16) is placed in the water inlet to suck water.

7. The internet-of-things-based river regulation diving oscillatory wave flow-spreading system as claimed in claim 1, wherein: the magnetic suspension breeze generator (11) is connected to the coupler (10), and the coupler (10) is connected with the air pump, the hydrolysis hydrogen production station (15) and the wireless network bridge (14).

8. The internet-of-things-based river regulation submersible shock wave overflow system of claim 1, wherein: the biological fluid pipe (18) is led out from the pulser (08) and is bound with the gas distribution pipe (06).

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