阅读说明：本技术 无能耗、水动能装置及蓄能方法 (Energy consumption-free water kinetic energy device and energy storage method ) 是由 徐礼红 渠中权 王建美 冯丽美 渠中胜 冯丽京 于 2021-09-11 设计创作，主要内容包括：本发明属于水动能、储能技术领域,具体为无能耗、水动能装置及蓄能方法,包括：水能机构、取水机构、温控机构和分用机构,所述水能机构包括置于大坝下游引入水源的进水头、对所述进水头引入水源进行输送的进水管、用于对输送水源进行过滤的过滤器、对输送水源进行储存的蓄水箱组、安装于所述蓄水箱组用于能量转换的转换组件、用于排出水源至大坝上游的出水管、设置于所述蓄水箱组顶部的排气阀。本发明中,通过水能机构,可以将河流大坝下游中的水流引入,在蓄水箱组内制造形成负压状态,利用势能将水排出至大坝上游,实现无能耗输送,水流经转换组件将水动能转换为电能,利用转换组件的设置使得水流可以充分带动涡筒转动,实现电能的储备。(The invention belongs to the technical field of water kinetic energy and energy storage, and particularly relates to a device and an energy storage method for water kinetic energy and water kinetic energy without energy consumption, which comprises the following steps: hydroenergy mechanism, water intaking mechanism, temperature control mechanism and branch use the mechanism, hydroenergy mechanism is including arranging the dam low reaches in and introducing the head of intaking at the water source, right it introduces the water source and carries out the inlet tube of carrying, is used for carrying the water source and carry out filterable filter, carry the water storage tank group that the water source stored, install in water storage tank group is used for energy conversion's conversion components, is used for the outlet pipe of discharge water source to the dam upper reaches, set up in the discharge valve at water storage tank group top. According to the invention, water flow in the downstream of a river dam can be introduced through the water energy mechanism, a negative pressure state is formed in the water storage tank set, water is discharged to the upstream of the dam by utilizing potential energy, energy-consumption-free conveying is realized, water flow converts hydrodynamic energy into electric energy through the conversion assembly, and the arrangement of the conversion assembly enables the water flow to fully drive the vortex cylinder to rotate, so that the electric energy is stored.)

1. There is not energy consumption, water kinetic energy device, its characterized in that includes:

the water energy mechanism (100) comprises a water inlet head (110) which is arranged at the downstream of a dam and used for introducing a water source, a water inlet pipe (120) which is used for conveying the water source introduced by the water inlet head (110), a filter (130) which is used for filtering the conveyed water source, a water storage tank group (140) which is used for storing the conveyed water source, a conversion component (150) which is arranged on the water storage tank group (140) and used for converting energy, a water outlet pipe (160) which is used for discharging the water source to the upstream of the dam, an exhaust valve (170) which is arranged at the top of the water storage tank group (140), a pressure sensor (180) which is arranged on the water storage tank group (140) and used for detecting the pressure and a water level detector (190) which is used for detecting the water level in the water storage tank group (140);

the water taking mechanism (200), the water taking mechanism (200) is connected to the water outlet pipe (160) and is used for daily water use in the area;

the temperature control mechanisms (300) are connected to the water outlet pipe (160) and used for regulating and controlling the temperature of each system;

a distribution mechanism (400) comprising an oxygen supply assembly (410) connected to said outlet pipe (160) and for a fishery system, a refrigeration assembly (420) for a water system and an agricultural assembly (430) for an agricultural system.

2. The non-energy consuming, water powered device as recited in claim 1, wherein the conversion assembly (150) comprises a plurality of scrolls (151) disposed at a bottom of the tank assembly (140), a drive shaft (152) connected to the scrolls (151) for driving the generation of electricity, a generator set (153) connected to another end of the drive shaft (152) for generating electricity, and a deflector (154) mounted within the tank assembly (140) for limiting water flow.

3. The non-energy-consuming, water-powered device as recited in claim 1, wherein the water intake mechanism (200) comprises a water intake pipe (210) connected to the water outlet pipe (160) for taking water, a purifier (220) connected to the other end of the water intake pipe (210) for purifying the water source, a reservoir (230) piped to the purifier (220) for storing the purified water source, and a bypass line (240) connected to the reservoir (230) for using the water source.

4. The non-energy consuming, water powered device according to claim 1, characterized in that the temperature control means (300) comprises a branch line (310) for draining and a cooling zone (320) and a heating zone (330) for distribution of the branch line (310).

5. The non-energy consuming, water powered device as recited in claim 1, wherein the oxygen supply assembly (410) comprises a first water usage pipe (411) connected to the water outlet pipe (160), a first impeller (412) connected to the first water usage pipe (411), and an oxygenator (413) connected to the other end of the first impeller (412) for oxygenating.

6. The non-energy consuming, water powered device as recited in claim 1, wherein the cooling module (420) comprises a second water using pipe (421) connected to the water outlet pipe (160), a second impeller (422) connected to the second water using pipe (421), and a compressor fan (423) connected to the other end of the second impeller (422) for cooling intake air.

7. The non-energy consuming, water powered device as recited in claim 1, characterised in that the agricultural assembly (430) includes a water pipe three (431) connected to the water outlet pipe (160) for directing water and a field area (432) connected to the water pipe three (431) for field crops.

8. The non-energy consuming, water powered device as recited in claim 1, characterised in that the outlet pipe (160) is fitted with temperature detectors at the front and rear ends of the temperature control means (300).

9. The non-energy consuming, water powered device as recited in claim 1, characterised in that the conduits for the hydro-energy means (100), the water intake means (200), the temperature control means (300) and the distribution means (400) are provided with valves.

10. The method of storing energy in a non-energy consuming, water powered device as defined in any one of claims 1 to 9, comprising:

s1: placing the water inlet head (110) into a downstream area of a river dam, and placing the tail end of the water outlet pipe (160) into an upstream area of the river dam;

s2: opening the exhaust valve (170), opening a valve on the water outlet pipe (160), opening a water inlet valve on the water storage tank group (140), injecting water into the sealed container through a water injection port at the top end, gradually closing the water inlet valve and the water outlet valve to ensure that the water inlet pipeline and the water outlet pipeline are filled with water, and filling the sealed container through the water injection port;

s3: closing the exhaust valve (170), opening the water outlet valve and the water inlet valve, and opening the valve on the water storage tank (160) to discharge part of water flow in the water storage tank group (140) through the water outlet pipe (160), so that a negative pressure space is formed above the rest water source;

s4: under the action of negative pressure, water is continuously injected into the water storage tank group (140) through the water inlet pipe (120), and the water in the water storage tank group (140) is continuously discharged through the water outlet pipe (160) and is discharged to the upstream of the river dam, so that energy-consumption-free circulation is realized.

Technical Field

The invention relates to the technical field of water kinetic energy and energy storage, in particular to a water kinetic energy device without energy consumption and an energy storage method.

Background

The hydrodynamic energy without energy consumption is that water energy is converted into other energy sources for people to use, and redundant energy sources can be stored, based on the law of energy conservation and conversion, the liquid is converted among various mechanical energy (kinetic energy, pressure potential energy and position potential energy) in the flowing process, meanwhile, a part of mechanical energy is lost by overcoming water flow resistance and is converted into the heat energy of the liquid in an equivalent manner, the mechanical energy loss is called energy loss for short, unsteady flow changes along with space and time, the energy relationship is complex, and the energy conservation and conversion relationship is generally researched only by unsteady flow.

At present, the consumption of clean energy is continuously increased, people pay more attention to the utilization of renewable energy, wherein the utilization rate of the water energy is improved by including the water energy, the water energy is fully utilized to become a main solution, the energy loss of the traditional mode of directly impacting a turbine by water flow is large, and meanwhile, the water utilization system is not convenient to do circulating motion in a state without energy consumption, so that the water utilization system is immature.

Disclosure of Invention

The present invention is directed to solving one of the technical problems of the prior art or the related art.

Therefore, the technical scheme adopted by the invention is as follows:

a non-energy-consuming, water powered device comprising: the water energy mechanism comprises a water inlet head, a water inlet pipe, a filter, a water storage tank set, a conversion assembly, an exhaust pipe, an exhaust valve, a pressure sensor and a water level detector, wherein the water inlet head is arranged at the downstream of a dam and used for introducing a water source, the water inlet pipe is used for conveying the water source introduced by the water inlet head, the filter is used for filtering the conveyed water source, the water storage tank set is used for storing the conveyed water source, the conversion assembly is arranged on the water storage tank set and used for converting energy, the exhaust pipe is used for exhausting the water source to the upstream of the dam, the exhaust valve is arranged at the top of the water storage tank set, the pressure sensor is arranged on the water storage tank set and used for detecting the pressure, and the water level detector is used for detecting the water level in the water storage tank set; the water taking mechanism is connected with the water outlet pipe and is used for daily water use in the area; the temperature control mechanisms are connected to the water outlet pipe and used for regulating and controlling the temperature of each system; the branch is used the mechanism including connect in the outlet pipe just is used for fishery system's oxygen suppliment subassembly, is used for the refrigeration subassembly of waters system and is used for agricultural system's agricultural subassembly.

Through adopting above-mentioned technical scheme, can introduce the rivers in the river upper reaches, discharge after the conversion subassembly converts the hydrodynamic energy into the electric energy, utilize setting up of scroll to make rivers can fully drive the scroll and rotate, energy loss is less, has improved the conversion rate of energy greatly.

The conversion assembly comprises a plurality of scroll barrels arranged at the bottom of the water storage tank set, a transmission shaft connected with the scroll barrels for transmission power generation, a generator set connected with the other end of the transmission shaft for generating electric energy, and a guide plate arranged in the water storage tank set and used for limiting water flow.

Through adopting above-mentioned technical scheme, can make rivers through conversion subassembly with hydrodynamic energy conversion for the electric energy, utilize setting up of scroll section of thick bamboo to make rivers can fully drive the scroll section of thick bamboo and rotate, realize the deposit of electric energy, it is comparatively reasonable.

The present invention in a preferred example may be further configured to: the water taking mechanism comprises a water taking pipe connected with the water outlet pipe and used for taking water, a purifier connected with the other end of the water taking pipe and used for purifying a water source, a water storage tank connected with the purifier and used for storing a purified water source, and a shunting pipeline connected with the water storage tank and used for using the water source.

By adopting the technical scheme, the novel multifunctional electric heating cooker can be used by surrounding people in daily life, and meets daily requirements.

The present invention in a preferred example may be further configured to: the temperature control mechanism comprises branch pipelines for drainage, and a cooling area and a heating area which are used for the branch pipelines to distribute.

Through adopting above-mentioned technical scheme, can control the temperature to cooling district and heating district region, arrange branch pipeline in the scope of cooling district and heating district, the cooling district is equipment heating environment and building heating environment etc. and the heating district is with heat utilization place and building place etc. and carry away the heat in the cooling district through the water source that flows through in the branch pipeline, and carry the heat to the heating district environment later, and then improve the temperature in the heating district environment, utilize this scheme to carry out the transfer of energy.

The present invention in a preferred example may be further configured to: the oxygen supply assembly comprises a water using pipe I connected with the water outlet pipe, an impeller I connected to the water using pipe I and an oxygen inflator connected to the other end of the impeller I and used for inflating oxygen.

By adopting the technical scheme, the aquaculture pond can be used for supplying and culturing in the fishery aquaculture pond area, and energy is saved.

The present invention in a preferred example may be further configured to: the refrigerating assembly comprises a water pipe II connected with the water outlet pipe, an impeller II connected onto the water pipe II and a compressor fan connected to the other end of the impeller II and used for refrigerating air inlet.

By adopting the technical scheme, various users can carry out compressor refrigeration operation.

The present invention in a preferred example may be further configured to: the agricultural assembly comprises a water pipe III which is connected to the water outlet pipe and used for water diversion and a farmland area which is connected to the water pipe III and used for farmland crops.

By adopting the technical scheme, the planting in the farmland can be facilitated, and the water conservancy control is facilitated.

The present invention in a preferred example may be further configured to: and the water outlet pipe is provided with a temperature detector positioned at the front end and the rear end of the temperature control mechanism.

By adopting the technical scheme, the temperature of water flow in the water outlet pipe can be measured, and the water outlet pipe is convenient to use as required.

The present invention in a preferred example may be further configured to: and a plurality of valves are arranged on the pipelines used by the hydroenergy mechanism, the water taking mechanism, the temperature control mechanism and the branch mechanism.

By adopting the technical scheme, the water flow at each part can be conveniently controlled, and the safety is improved

The present invention in a preferred example may be further configured to: the method comprises the following steps:

s1: placing the water inlet head into a downstream area of a river dam, and placing the tail end of the water outlet pipe into an upstream area of the river dam;

s2: opening the exhaust valve, opening a valve on the water outlet pipe, opening a water inlet valve on the water storage tank group, injecting water into the sealed container through a water injection port at the top end, gradually closing the water inlet valve and the water outlet valve to ensure that the water inlet pipeline and the water outlet pipeline are filled with water, and filling the sealed container through the water injection port;

s3: closing the exhaust valve, opening the water outlet valve and the water inlet valve, and opening the valves to discharge part of water flow in the water storage tank group through the water outlet pipe, so as to form a negative pressure space above the rest water source;

s4: and opening a valve on the water inlet pipe, continuously injecting the water source into the water storage tank group through the water inlet pipe under the action of negative pressure, continuously discharging the water source in the water storage tank group into the upstream of the river dam through the water outlet pipe, and realizing energy-consumption-free circulation.

The technical scheme of the invention has the following beneficial technical effects:

1. according to the invention, water flow in the downstream of the river dam can be introduced through the water energy mechanism, a negative pressure state is manufactured in the water storage tank set, water is discharged to the upstream of the dam by utilizing potential energy, energy-consumption-free conveying is realized, water flow converts hydrodynamic energy into electric energy through the conversion assembly, and the arrangement of the conversion assembly enables the water flow to fully drive the vortex cylinder to rotate, so that electric energy storage is realized, and the water energy storage is reasonable.

2. According to the invention, the branch pipelines are arranged in the range of the cooling area and the heating area through the temperature control mechanism, the cooling area is an equipment heating environment, a building heating environment and the like, the heating area is a heat utilization place, a building place and the like, heat in the cooling area is carried away through a water source flowing through the branch pipelines, and then the heat is carried to the heating area environment, so that the temperature in the heating area environment is further improved, the scheme is utilized for transferring energy, and the heat-transfer system is more environment-friendly and reasonable and is convenient to popularize and use.

Drawings

FIG. 1 is a schematic diagram of a hydroenergy mechanism in accordance with one embodiment of the present invention;

FIG. 2 is a schematic view of a temperature control mechanism according to an embodiment of the present invention;

FIG. 3 is a schematic view of a dispensing mechanism according to one embodiment of the present invention;

FIG. 4 is a layout diagram of one embodiment of the present invention;

FIG. 5 is a schematic diagram of a conversion assembly according to an embodiment of the invention.

Reference numerals:

100. a water energy mechanism; 110. a water inlet head; 120. a water inlet pipe; 130. a filter; 140. a water storage tank group; 150. a conversion component; 151. a scroll; 152. a drive shaft; 153. a generator set; 154. a baffle; 160. a water outlet pipe; 170. an exhaust valve; 180. a pressure sensor; 190. a water level detector;

200. a water taking mechanism; 210. a water intake pipe; 220. a purifier; 230. a reservoir; 240. a shunt line;

300. a temperature control mechanism; 310. a branch line; 320. a cooling zone; 330. a heating zone;

400. a dispensing mechanism; 410. an oxygen supply assembly; 411. using a water pipe I; 412. an impeller I; 413. aerating the oxygen; 420. a refrigeration assembly; 421. a water pipe II is used; 422. an impeller II; 423. a compressor fan; 430. an agricultural component; 431. a third water pipe is used; 432. a farmland area.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in further detail with reference to the accompanying drawings in conjunction with the following detailed description. It should be noted that the embodiments of the present invention and features of the embodiments may be combined with each other without conflict.

It is to be understood that this description is made only by way of example and not as a limitation on the scope of the invention.

The non-energy consumption and water kinetic energy device and the energy storage method provided by some embodiments of the invention are described in the following with reference to the attached drawings.

Example (b):

referring to fig. 1-5, the present invention provides a non-energy consumption, water kinetic energy device, comprising: the water energy mechanism 100, the water taking mechanism 200, the temperature control mechanism 300 and the branch use mechanism 400, the water energy mechanism 100 comprises a water inlet head 110 arranged at the downstream of the dam for introducing water source, a water inlet pipe 120 for introducing water source into the water inlet head 110 for conveying, a filter 130 for filtering conveyed water source, a water storage tank group 140 for storing conveyed water source, a conversion component 150 arranged at the water storage tank group 140 for energy conversion, a water outlet pipe 160 for discharging water source to the upstream of the dam, an exhaust valve 170 arranged at the top of the water storage tank group 140, a pressure sensor 180 arranged at the water storage tank group 140 for pressure detection and a water level detector 190 for detecting the water level in the water storage tank group 140, the conversion component 150 is partially buried underground and is stable, the water inlet head 110 is arranged at the region with relatively fast river water flow, and a mesh enclosure for preliminary process is wrapped at the outer side, the potential energy is larger after entering the water inlet pipe 120, the altitude height value of the pipe of the water inlet pipe 120 from the front end to the rear end is gradually reduced to facilitate the flow of water without energy consumption, the filter 130 can be set into a filtering instrument, a filtering chamber and a filtering station structure, and can be set up close to the water storage tank set 140 according to the terrain, so as to be convenient for maintenance, the middle part of the guide plate 154 is provided with a through hole for accommodating the vortex cylinder 151, when the water flows downwards through the through hole, the vortex cylinder 151 is driven to rotate, and then the kinetic energy is transmitted to the generator set 153 through the transmission shaft 152 to generate electricity, the transmission shaft 152 comprises a shaft body and a gear structure, so as to collect the kinetic energy of a plurality of groups of shaft bodies on one shaft body, the vortex cylinders 151 are uniformly distributed in the water storage tank set 140 at equal intervals, and the outer side of the vortex cylinder 151 is provided with chutes for guiding the water, and the water flow can flow down along the chutes arranged obliquely to drive the vortex cylinder 151 to rotate, and scroll 151 is hollow metal construction, and is less to the hindrance of rivers, reduces the loss of energy, and scroll 151 is equipped with the multiunit of continuous connection, and the bore of chute on scroll 151 from top to bottom crescent, through the continuous decline of rivers, the water conservancy diversion chute of increase makes holistic rotational speed promote, carries out the reutilization.

Specifically, conversion assembly 150 is including setting up a plurality of scrolls 151 in water storage tank group 140, connect in the transmission shaft 152 that scroll 151 is used for the transmission electricity generation, connect in the generating set 153 that the transmission shaft 152 other end is used for output electric energy and install in water storage tank group 140 and be used for spacing rivers guide plate 154, scroll 151 can be annular arrangement or matrix arrangement etc. the maximize utilizes the design area, can introduce the rivers in river dam low reaches, discharge after converting assembly 150 converts hydrodynamic energy into the electric energy, utilize setting up of scroll 151 to make rivers can fully drive scroll 151 and rotate, energy loss is less, the conversion rate of energy has been improved greatly, and is more reasonable.

In addition, the water outlet pipe 160 is arranged below the scroll 151, so that water flow is discharged from the water outlet pipe 160 after passing through the scroll 151, the water flow drives the conversion assembly 150 to perform power generation operation conveniently, and the feasibility of the device is improved.

As shown in fig. 1, the water intake mechanism 200 includes a water intake pipe 210 connected to the water outlet pipe 160 for taking water, a purifier 220 connected to the other end of the water intake pipe 210 for purifying a water source, a water reservoir 230 connected to the purifier 220 for storing the purified water source, and a diversion pipeline 240 connected to the water reservoir 230 for using the water source, the water intake mechanism 200 is provided with a plurality of sets connected to the water outlet pipe 160, the water intake pipe 160 is used by different people in a region, for example, some commercial and agricultural users, the purifier 220 and the water reservoir 230 are arranged according to the region, and then water consumption is performed by each user, so as to form a small-scale water system.

As shown in fig. 2, a plurality of temperature control mechanisms 300 are connected to the water outlet pipe 160 for controlling the temperature of each system, the temperature control mechanisms 300 include branch pipes 310 for drainage, and a cooling area 320 and a heating area 330 for the branch pipes 310 to distribute, and the water taking mechanism 200 can be used to take the water flow discharged from the water outlet pipe 160, including enterprises, individuals and users with multiple needs, and connect the water supply system in the area, thereby expanding the application range.

Specifically, the branch pipelines 310 are arranged in the range of the cooling area 320 and the heating area 330, the cooling area 320 is an equipment heating environment, a building heating environment and the like, the heating area 330 is a heat utilization place, a building place and the like, heat in the cooling area 320 is carried away through a water source flowing through the branch pipelines 310, then the heat is carried to the heating area 330, the temperature in the heating area 330 is further improved, energy transfer is carried out by using the scheme, and the system is more environment-friendly and reasonable.

As shown in fig. 3, the distribution mechanism 400 includes an oxygen supply module 410 connected to the water outlet pipe 160 and used for the fisheries system, a refrigeration module 420 used for the water system, and an agricultural module 430 used for the agricultural system, wherein,

the oxygen supply assembly 410 comprises a water pipe I411 connected to the water outlet pipe 160, an impeller I412 connected to the impeller I412 and an oxygen pumping device 413 connected to the other end of the impeller I412 and used for pumping oxygen, the impeller I412 is driven by water flow to rotate to generate air flow, gas is discharged into the oxygen pumping device 413 located in a fishery water area, oxygen beneficial to fish school life is generated, reactive cultivation can be achieved, and therefore reasonability of the device is improved.

The refrigeration component 420 comprises a water pipe II 421 connected to the water outlet pipe 160, a vane wheel II 422 connected to the water pipe II 421 and a compressor fan 423 connected to the other end of the vane wheel II 422 and used for refrigerating air inlet, wherein the vane wheel II 422 is driven by water flow to rotate to generate air flow, and then the compressor fan 423 connected is driven to rotate, so that the compressor works to refrigerate.

Agricultural subassembly 430 is including connecting on outlet pipe 160 and being used for the water diversion using water pipe three 431 and connecting in using water pipe three 431 to be used for the farmland district 432 of field crop, through partial rivers entering using the inside of water pipe three 431, can guide rivers to regions such as field irrigation and planting, and the effect is better.

It should be noted that, a plurality of valves are disposed on the pipelines used by the water energy mechanism 100, the water taking mechanism 200, the temperature control mechanism 300, and the dispensing mechanism 400, and the flow direction of water flow at various positions can be guided through the valves, so as to facilitate control.

Furthermore, the water outlet pipe 160 is provided with a temperature detector positioned at the front end and the rear end of the temperature control mechanism 300, and the temperature of the water in the water outlet pipe 160 at the section of the temperature control mechanism 300 can be detected through the temperature detector, so that the control and the use are convenient.

The working principle and the using process of the invention are as follows: firstly, the water inlet head 110 is placed in the downstream area of the river dam, the tail end of the water outlet pipe 160 is placed in the upstream area of the river dam, the exhaust valve 170 is opened, the valve on the water outlet pipe 160 is opened, the water inlet valve on the water storage tank set 140 is opened, water is injected into the sealed container through the water injection port at the top end, the water inlet valve and the water outlet valve are gradually closed, the water inlet valve and the water outlet valve are ensured to be filled with water, the sealed container is filled through the water injection port, the exhaust valve 170 is closed firstly, then the water outlet valve and the water inlet valve are opened, the valve on the 160 is opened, partial water in the water storage tank set 140 is discharged through the water outlet pipe 160, a negative pressure space is formed above the residual water source, the water source is continuously injected into the water storage tank set 140 through the water inlet pipe 120 under the action of negative pressure, the water in the water storage tank set 140 is continuously discharged through the water outlet 160 and is discharged into the upstream area of the river dam, energy-free circulation is realized, and the water flows into the water inlet pipe 120 through the water inlet head 110, when the water flows through the filter 130, impurities in the water flow are filtered by the filter 130, the purified water flow is continuously stored in the water storage tank set 140, and the water source in the water storage tank set 140 is continuously discharged through the water outlet pipe 160 and discharged to the upstream of the river dam, so that no energy consumption circulation is realized, in the water discharging process, the water source flows downwards along gaps among the scroll cylinders 151 in the guide plate 154 and simultaneously drives the scroll cylinders 151 to rotate, then power is transmitted to the generator set 153 through the transmission shaft 152, so that the generator set 153 generates electric energy, the generated electric energy is used by the water supply mechanism 100, the water taking mechanism 200, the temperature control mechanism 300 and the distribution mechanism 400, redundant electric energy is stored for later use, the water flow is conveyed along the water outlet pipe 160 after being discharged out of the water storage tank set 140, part of the water source 210 is discharged into the purifier 220 to be purified and is stored in the water storage tank 230 after being purified, the water flow enters the areas of the cooling area 320 and the heating area 330 through the branch pipeline 310, the temperature in the areas is regulated and controlled through the transportation environment energy, then the water flow enters the first water using pipe 411 and the second water using pipe 421 through the oxygen supply assembly 410 and the refrigeration assembly 420 respectively, the first impeller 412 and the second impeller 422 are driven to rotate, the oxygen pumping device 413 generates oxygen to be supplied to a fishpond, the compressor fan 423 performs refrigeration operation, the water flow is led out through the third water using pipe 431 and then can be used by the plurality of agricultural assemblies 430, the water flow is discharged into the upstream area of the dam in the river through the water outlet pipe 160, and redundant energy in the process can be stored for standby by individuals.

In the present invention, the term "plurality" means two or more unless explicitly defined otherwise. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items. The terms "mounted," "connected," "fixed," and the like are to be construed broadly, and for example, "connected" may be a fixed connection, a removable connection, or an integral connection; "coupled" may be direct or indirect through an intermediary. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

It will be understood that when an element is referred to as being "mounted to," "secured to" or "disposed on" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "upper," "lower," "left," "right," and the like as used herein are for illustrative purposes only and do not denote a unique embodiment.

In the description herein, the description of the terms "one embodiment," "some embodiments," "specific embodiments," etc., means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the claims and their equivalents.