CN210214943U - High-efficient multi-functional river course integration processing system - Google Patents

Abstract

An efficient multifunctional river integrated treatment system comprises a floating island component floating on the water surface and a jet flow component arranged on the floating island component. The floating island assembly comprises a floating island assembly and at least one float body arranged at the bottom of the floating island assembly. The jet flow subassembly includes that one sets up jet motor on the chinampa aggregate, one with jet motor is connected and one end stretches into to the ejector under water, one set up under water and with the jet flow inlet tube that the ejector is connected, one sets up on the ejector and keep away from the rotatory transmitter of jet motor's one end, and at least one setting is in on the rotatory transmitter and with the jet flow outlet pipe that the ejector is connected. The utility model discloses well chinampa aggregate has the resiliency, is favorable to adapting to the fluctuation from top to bottom of the surface of water, forms the initiative flow of water on a large scale through the efflux subassembly simultaneously, improves the purification efficiency of water.

Description

High-efficient multi-functional river course integration processing system

Technical Field

The utility model belongs to the technical field of the water purifies, especially a high-efficient multi-functional river course integration processing system.

Background

With the continuous development of society and the continuous progress of science, equipment in various fields is continuously improved and updated, for example, an ecological floating island which is common in life is also optimized and improved to a certain extent. The ecological floating island is a biological control method for purifying water quality by planting higher aquatic plants or terrestrial plants into eutrophic water areas by using floatable materials as substrates or carriers and reducing nitrogen, phosphorus and organic pollutants in the water body through the absorption or adsorption of root systems of the plants, and meanwhile, the eutrophic substances in the water body are moved away from the water body by a method for harvesting the plants, so that the water quality is improved and a good water environment is created.

The ecological chinampa that appears still has certain defect and not enough at present, for example, current ecological chinampa formula structure as an organic whole and current ecological chinampa do not set up the structure that has the cushioning effect. When the ecological floating island is placed in a eutrophic water area of a river channel and is impacted by natural factors such as strong wind and waves for a long time, the ecological floating island is easy to turn over. In addition, when the ecological floating island is applied to a still water environment, the water around the ecological floating island flows poorly, and the purification effect is poor.

SUMMERY OF THE UTILITY MODEL

In view of this, the utility model provides a high-efficient multi-functional river course integration processing system to solve above-mentioned problem.

An efficient multifunctional river channel integrated treatment system comprises a floating island component floating on the water surface of a river channel and a jet flow component arranged on the floating island component. The floating island assembly comprises a floating island assembly and at least one float body arranged at the bottom of the floating island assembly. The jet flow subassembly includes that one sets up jet motor on the chinampa aggregate, one with jet motor is connected and one end stretches into to the ejector under water, one set up under water and with the jet flow inlet tube that the ejector is connected, one with even a section of thick bamboo of ejector and with the ejector is kept away from the one end rotation of jet motor and is connected rotatory transmitter, and at least one setting is in on the rotatory transmitter and with the efflux outlet pipe that the ejector is connected. The jet flow motor is integrally arranged above the water surface under the action of the floating island component. And the jet flow water inlet pipe is positioned above the jet flow water outlet pipe in the direction vertical to the horizontal plane.

Furthermore, the jet flow water outlet pipe is provided with at least one water distribution port arranged along the length direction of the jet flow water outlet pipe, and the water outlet direction of the water distribution port is intersected with the length direction of the jet flow water outlet pipe.

Furthermore, a plurality of water distribution ports are arranged on the jet flow water outlet pipe, and the water distribution ports are respectively and uniformly distributed on two sides of the jet flow water outlet pipe and the upper end of the jet flow water outlet pipe.

Further, a platform balance object is further arranged on the floating island assembly and used for balancing the gravity of the jet flow motor.

Furthermore, an air suction pipe extending to the upper part of the water surface is connected to the ejector.

Furthermore, the rotary emitter comprises a shell sleeved on the ejector, an inner cavity communicated with the ejector and the jet flow water outlet pipe, a bearing arranged between the inner wall of the shell and the outer wall of the ejector, and a group of turbine blades arranged in the inner cavity.

Further, the floating island aggregate comprises at least three floating island substrates distributed circumferentially and at least one floating island plant arranged on the floating island substrates.

Furthermore, a fixing piece which sequentially penetrates through the floating island substrates is arranged between the floating island substrates.

Further, the floating island substrates are cylindrical and gaps are formed between adjacent floating island substrates.

Furthermore, the circumference outside cover of efflux inlet tube is equipped with one and prevents stifled guard shield.

Compared with the prior art, the utility model provides a high-efficient multi-functional river course integration processing system connects into a holistic mode through a plurality of chinampa basement to the messenger improves the cushion nature of chinampa aggregate and in order to be adapted to the fluctuation from top to bottom of the surface of water, forms the initiative flow of water on a large scale through the efflux subassembly simultaneously, improves the purification efficiency of water.

Drawings

Fig. 1 is the utility model provides a high-efficient multi-functional river course integration processing system's schematic structure diagram.

Fig. 2 is a schematic top view of the floating island aggregate of the multifunctional integrated riverway system shown in fig. 1.

Fig. 3 is a partially enlarged schematic view of a part a in the high-efficiency multifunctional river channel integrated treatment system of fig. 1.

Detailed Description

Specific examples of the present invention will be described in further detail below. It should be understood that the description herein of embodiments of the invention is not intended to limit the scope of the invention.

Please refer to fig. 1 to fig. 3, which are schematic structural views of the high-efficiency multifunctional integrated riverway processing system provided by the present invention. The high-efficiency multifunctional river integrated treatment system comprises a floating island component 10 floating on the water surface and a jet flow component 20 arranged on the floating island component 10. It is understood that the present multifunctional integrated treatment system further includes other functional components, such as fixing components, mounting components, power supply components, etc., which are well known in the art, and therefore, will not be described in detail herein.

The floating island assembly 10 includes a floating island assembly 11 and at least one float body 12 disposed at the bottom of the floating island assembly 11. The floating island assembly 11 includes at least three floating island substrates 111 distributed circumferentially, and at least one floating island plant 112 disposed on the floating island substrates 111. The floating island substrate 111 is provided with fillers such as soil for the floating island plants 112 to grow, the floating island plants 112 can be hygrophilic plants such as lysimachia christinae hance and iris, and the floating island plants 112 can improve landscape and increase the adsorption capacity of organic pollutants. A fixing member 113 sequentially penetrating through the floating island substrates 111 is arranged between the floating island substrates 111. The fixing member 113 may be a steel wire connected in series with the floating island substrate 111, or may be a stainless steel frame. The fixing member 113 connects the floating island substrates 111 in series to form a whole to improve the stability of the whole structure. The floating island base 111 is cylindrical, a gap is formed between the adjacent floating island bases 111, and under the condition that waves appear on the water surface, the whole structure of the floating island component 10 has the buffer property of fluctuating up and down along with the water surface, and the floating island component is stable in structure and not easy to turn over. The float body 12 is made of any one of light materials such as rubber, plastic and foam, and is used for supporting the floating force of the floating island substrate 111 on the water surface. The gaps between the floating island bases 111 may also be filled with floating bodies to increase the integrity and floating performance of the floating island assembly 11. It is contemplated that a pile body penetrating through the floating island assembly 10 may be preset in the water for fixing the floating island assembly 10 in order to secure the stability of the floating island assembly 10 in the river.

The jet flow assembly 20 comprises a jet flow motor 21 arranged on the floating island assembly 11, a jet flow device 22 connected with the jet flow motor 21 and having one end extending into the water, a jet flow water inlet pipe 23 arranged under the water and connected with the jet flow device 22, a rotary emitter 24 arranged at one end of the jet flow device 22 far away from the jet flow motor 21, and at least one jet flow water outlet pipe 25 arranged on the rotary emitter 24 and connected with the jet flow device 22. An anti-blocking shield 30 is sleeved on the circumferential outer side of the jet flow water inlet pipe 23. The anti-clogging shield 30 is a screen to prevent clogging of the jet inlet pipe 23. The ejector 22 is composed of a nozzle, a suction chamber and a diffuser pipe, is a multipurpose aeration mode developed by utilizing the negative pressure principle of jet flow, is a known technology, and therefore the internal structure and the connection relation thereof are not explained in detail. In the present embodiment, the ejector 22 is used to convert the water flowing in from the jet water inlet pipe 23 from the normal pressure water flow to the high pressure water flow. The jet motor 21 is a driving motor and is used for providing power for the jet device 22. The rotary emitter 24 includes a housing 241 sleeved on the ejector 22, an inner cavity 242 communicating the ejector 22 and the jet outlet pipe 25, a bearing 243 disposed between an inner wall of the housing 241 and an outer wall of the ejector 22, and a set of turbine blades 244 disposed in the inner cavity. When a high pressure water stream is formed in the jet 22 and enters the inner cavity 242, the turbine blades 244 are pushed, so that the rotating emitter 24 is rotated around the jet 22 as a central axis. The sealed relationship between the rotary emitter 24 and the ejector 22 is well known to those skilled in the art. In this embodiment, there are four jet flow outlet pipes 25 and they are distributed circumferentially, and the rotary emitter 24 drives the jet flow outlet pipe 25 to rotate around the central axis of the diffuser 22, so as to drive the jet flow outlet pipe 25 to rotate. The jet flow water outlet pipe 25 is provided with at least one water distribution port 251 arranged along the length direction of the jet flow water outlet pipe 25. When the jet flow water outlet pipe 25 is provided with a plurality of water distribution ports 251, the plurality of water distribution ports 251 are respectively and uniformly distributed on two sides of the jet flow water outlet pipe 25 and the upper end of the jet flow water outlet pipe 25. It is conceivable that when the water outlets 251 uniformly distributed on both sides of the jet flow water outlet pipe 25 stabilize water outlet, the water body can be formed to flow in the horizontal direction. When the rotating emitter 24 drives the jet flow outlet pipe 25 to rotate around the jet flow device 22 as a central axis, and when the water distribution port 251 uniformly distributed at the upper end of the jet flow outlet pipe 25 stably discharges water, water flows in a cylindrical range taking the length of the jet flow outlet pipe 25 as a radius and towards one end of the jet flow inlet pipe 23 by taking the jet flow device 22 as a central axis, and a reaction force pushing the jet flow assembly 20 downwards is provided, because the floating island assembly 10 and the jet flow assembly 20 are structurally connected with each other, the floating island assembly 10 has a tendency of moving downwards and is more stably attached to the water surface. The water distribution port 251 is not arranged at the bottom of the jet flow water outlet pipe 25, so that the water turbidity of the river channel caused by the flow of water flow at the bottom is avoided. The ejector 22 is connected with an air suction pipe 40 extending above the water surface, and the switch of the air suction pipe 40 can be controlled to be matched with the ejector 22 to form an aeration device according to actual conditions, so that the oxygen content in the water body is increased. In addition, according to actual need, the ejector 22 can be also connected with a medicine adding bottle 50 extending to the upper part of the water surface, and the medicine adding bottle 50 can uniformly dissolve medicines in the water body through the jet assembly 20, so that the water body treatment efficiency is improved. In addition, a platform balancer 60 is further provided on the floating island assembly 11 to balance the gravity of the jet motor 21 and improve the stability of the floating island assembly 11.

The utility model provides a high-efficient multi-functional river course integration processing system connects into a holistic mode through a plurality of chinampa basement 111 to make the cushioning nature that improves chinampa aggregate 11, be applicable to the fluctuation of the surface of water, form the initiative flow of water on a large scale through efflux subassembly 20 simultaneously, improve the purification efficiency of water.

The above description is only for the preferred embodiment of the present invention and should not be construed as limiting the scope of the present invention, and any modification, equivalent replacement or improvement within the spirit of the present invention is encompassed by the claims of the present invention.

Claims (10)

1. The utility model provides a high-efficient multi-functional river course integration processing system which characterized in that: the high-efficiency multifunctional river integrated treatment system comprises a floating island component floating on the water surface of a river, and a jet flow component arranged on the floating island component, wherein the floating island component comprises a floating island aggregate and at least one floater arranged at the bottom of the floating island aggregate, the jet flow component comprises a jet flow motor arranged on the floating island aggregate, a jet device connected with the jet flow motor and with one end extending into the water, a jet flow water inlet pipe arranged under the water and connected with the jet flow device, a rotary emitter connected with the jet flow device connecting cylinder and with one end of the jet flow device far away from the jet flow motor in a rotating way, and at least one jet flow water outlet pipe arranged on the rotary emitter and connected with the jet flow device, the jet flow motor is integrally arranged on the water surface under the action of the floating island component, and the jet flow water inlet pipe is positioned above the jet flow water outlet pipe in the direction vertical to the horizontal plane.

2. The integrated high-efficiency multifunctional river channel treatment system according to claim 1, wherein: the jet flow water outlet pipe is provided with at least one water distribution port arranged along the length direction of the jet flow water outlet pipe, and the water outlet direction of the water distribution port is intersected with the length direction of the jet flow water outlet pipe.

3. The integrated high-efficiency multifunctional river channel treatment system according to claim 2, wherein: and a plurality of water distribution ports are arranged on the jet flow water outlet pipe and are respectively and uniformly distributed on the two sides of the jet flow water outlet pipe and the upper end of the jet flow water outlet pipe.

4. The integrated high-efficiency multifunctional river channel treatment system according to claim 1, wherein: and a platform balance object is further arranged on the floating island assembly and used for balancing the gravity of the jet flow motor.

5. The integrated high-efficiency multifunctional river channel treatment system according to claim 1, wherein: and the ejector is connected with an air suction pipe extending to the upper part of the water surface.

6. The integrated high-efficiency multifunctional river channel treatment system according to claim 1, wherein: the rotary emitter comprises a shell sleeved on the ejector, an inner cavity communicated with the ejector and the jet flow water outlet pipe, a bearing arranged between the inner wall of the shell and the outer wall of the ejector, and a group of turbine blades arranged in the inner cavity.

7. The integrated high-efficiency multifunctional river channel treatment system according to claim 1, wherein: the floating island assembly comprises at least three floating island substrates which are distributed circumferentially and at least one floating island plant which is arranged on the floating island substrates.

8. The integrated high-efficiency multifunctional river channel treatment system according to claim 7, wherein: and a fixing piece which sequentially penetrates through the floating island substrates is arranged between the floating island substrates.

9. The integrated high-efficiency multifunctional river channel treatment system according to claim 7, wherein: the floating island substrates are cylindrical, and gaps are reserved between adjacent floating island substrates.

10. The integrated high-efficiency multifunctional river channel treatment system according to claim 1, wherein: the circumference outside cover of efflux inlet tube is equipped with one and prevents stifled guard shield.

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