CN218939122U - Simulator for water quantity transfer between areas - Google Patents

Abstract

The utility model discloses an inter-floor water quantity transfer simulator which comprises a supporting base, a supporting mechanism, a water plant simulation plate, a lake simulation plate, a town simulation plate, a water treatment simulation plate and a sky simulation plate, wherein the supporting mechanism is arranged on the supporting base; the support mechanism is provided with four, four support mechanism fixed welding in support base top surface four corners, the water works simulate the plate the lake simulate the plate, the town simulate the plate with the water treatment simulate the plate be spiral echelonment take over welding in an organic wholely, the water works simulate the plate the lake simulate the plate the town simulate the plate with water treatment simulate the plate fixed mounting in four between the support mechanism. When the utility model is used, the land topography difference conversion and amplification can be displayed in regions, the method is more visual and obvious, the understanding is convenient, and meanwhile, the step-shaped height difference is utilized to naturally form the liquid circulation process, the natural circulation process is more fitted, and the simulation effect is better.

Description

Simulator for water quantity transfer between areas

Technical Field

The utility model relates to the technical field of water quantity transfer simulators, in particular to an inter-area water quantity transfer simulator.

Background

The water circulation means that water in different places on the earth changes state to another place on the earth by absorbing the energy of the sun. For example, ground water is evaporated by the sun into water vapor in the air. While the state of water in the earth includes solid, liquid and gaseous states. While most of the water in the earth is present in the atmosphere, ground bottom, lakes, rivers and oceans. Water may be exposed to some physical action, such as: evaporation, precipitation, penetration, surface flow, ground flow, etc., from place to place. However, in the existing water circulation process between areas, which adds much manpower and water transfer to natural circulation, a water transfer simulator is generally required to show the circulation process in order to study and teach the water transfer.

However, the existing water quantity device simulators in the regions are generally displayed in a two-dimensional space mode, so that imagination is difficult for people with weak space imagination, a complete water circulation display cannot be completed, only a part of the water quantity device simulators can be displayed, and research and learning effects are poor.

Disclosure of Invention

The utility model aims to provide an inter-area water quantity transfer simulator, which solves the problems in the technical background, realizes three-dimensional demonstration of inter-area water quantity transfer, and demonstrates the water circulation process in a three-dimensional amplifying mode, so that the water circulation simulator is more visual and convenient to understand.

In order to achieve the above purpose, the present utility model provides the following technical solutions: a water quantity transfer simulator between floors comprises a supporting base, a supporting mechanism, a water plant simulation plate, a lake simulation plate, a town simulation plate, a water treatment simulation plate and a sky simulation plate;

the four supporting mechanisms are fixedly welded at four corners of the top surface of the supporting base, the water plant simulation plate, the lake simulation plate, the town simulation plate and the water treatment simulation plate are spirally and stepwise welded in a whole, the water plant simulation plate, the lake simulation plate, the town simulation plate and the water treatment simulation plate are fixedly arranged between the four supporting mechanisms, the sky simulation plate is fixedly welded at the top ends of the four supporting mechanisms, and underground pipelines are arranged between two adjacent water plant simulation plates, lake simulation plate, town simulation plate and water treatment simulation plate;

the supporting base and the four supporting mechanisms are used for providing support, the sky simulation plate is used for simulating rainfall in rainy days, the water plant simulation plate is used for simulating water plant water quantity transfer, the lake simulation plate is used for simulating lake water quantity transfer, the town simulation plate is used for simulating town water quantity transfer, and the water treatment simulation plate is used for simulating sewage treatment water quantity transfer.

Further, the water plant simulation plate comprises a first supporting plate, a water tank is arranged in the first supporting plate, a water plant is fixedly installed on the top surface of the first supporting plate, and trees are fixedly welded on the periphery of the water plant on the top surface of the first supporting plate.

Furthermore, the town simulating plate comprises a second supporting plate, a city river is arranged in the center of the top surface of the second supporting plate, and buildings are fixedly welded on the left side and the right side of the city river on the top surface of the second supporting plate.

Further, the water treatment simulation plate comprises a third supporting plate, a sewage storage tank is arranged in the center of the top surface of the third supporting plate, and a water treatment mechanism is arranged on the top surface of the third supporting plate in a protruding mode on one side of the sewage storage tank.

Further, a water pump is arranged in the first supporting plate, and a water inlet port of the water pump is communicated with the interior of the sewage storage tank through the underground pipeline.

Further, the sky simulation plate comprises a top plate, a cloud groove is formed in the center of the top surface of the top plate, an electromagnetic valve is arranged in the center of the bottom surface of the Yun Xingcao, yun Xingcao is fixedly welded to a uniform flow plate under the electromagnetic valve, and water outlet micropores are uniformly formed in the bottom surface of the top plate and the bottom surface of the uniform flow plate.

Further, the supporting mechanism comprises a supporting column, a circulating water pump is embedded in the supporting column, four water inlet ports of the circulating water pump are respectively communicated with the inner parts of the first supporting plate, the lake simulation plate, the second supporting plate and the third supporting plate, and four water outlet ports of the circulating water pump are communicated with the inner parts of the cloud grooves.

Compared with the prior art, the utility model has the beneficial effects that:

the utility model can display the land form difference conversion and amplification of the area by arranging the water plant simulation plate, the lake simulation plate, the town simulation plate and the water treatment simulation plate in a rotating step type, is more visual and obvious, is convenient to understand, is more suitable for the natural circulation process by utilizing the step-shaped height difference in the natural circulation process of forming liquid, and has better simulation effect.

Through being provided with supporting mechanism and sky simulation plate and cooperate, the water yield transfer process under the overcast and rainy weather of simulation that can be simple can guarantee the invariable of water yield simultaneously for the hydrologic cycle process is more accurate, and the referenceability is higher.

Drawings

FIG. 1 is a schematic perspective view of an embodiment of the present utility model;

FIG. 2 is a schematic view of the internal structure of the embodiment of FIG. 1;

FIG. 3 is a schematic side cross-sectional view of the embodiment of FIG. 1;

FIG. 4 is a schematic top view of the embodiment of FIG. 1;

fig. 5 is a schematic view of the bottom surface structure of the sky simulation board in the embodiment of fig. 1.

Reference numerals: 1. a support base; 2. a support mechanism; 201. a support column; 202. a circulating water pump; 3. a water plant simulation plate; 301. a first support plate; 302. a water works; 303. a tree; 4. a lake simulation plate; 5. town simulating plate blocks; 501. a second support plate; 502. urban river; 503. building is provided with a plurality of stories; 6. a water treatment simulation plate; 601. a third support plate; 602. a water treatment mechanism; 603. a sewage storage tank; 7. a sky simulation plate; 701. a top plate; 702. yun Xingcao; 703. an electromagnetic valve; 704. a water outlet micropore; 705. a flow homogenizing plate; 8. an underground pipe.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1-5, an inter-floor water transfer simulator includes a support base 1, a support mechanism 2, a water plant simulation board 3, a lake simulation board 4, a town simulation board 5, a water treatment simulation board 6, and a sky simulation board 7;

the four supporting mechanisms 2 are fixedly welded to four corners of the top surface of the supporting base 1, the water plant simulation plate 3, the lake simulation plate 4, the town simulation plate 5 and the water treatment simulation plate 6 are spirally and stepwise welded into a whole, the water plant simulation plate 3, the lake simulation plate 4, the town simulation plate 5 and the water treatment simulation plate 6 are fixedly arranged between the four supporting mechanisms 2, the sky simulation plate 7 is fixedly welded to the top ends of the four supporting mechanisms 2, and underground pipelines 8 are arranged between two adjacent water plant simulation plate 3, lake simulation plate 4, town simulation plate 5 and water treatment simulation plate 6;

the supporting base 1 and the four supporting mechanisms 2 are used for providing support, the sky simulation plate 7 is used for simulating rainfall in rainy days, the water plant simulation plate 3 is used for simulating water plant water quantity transfer, the lake simulation plate 4 is used for simulating lake water quantity transfer, the town simulation plate 5 is used for simulating town water quantity transfer, and the water treatment simulation plate 6 is used for simulating sewage treatment water quantity transfer.

In order to simulate water quantity transfer of a water plant, the water plant simulation plate 3 comprises a first support plate 301, a water tank is arranged in the first support plate 301, a water plant 302 is fixedly arranged on the top surface of the first support plate 301, and trees 303 are fixedly welded on the periphery of the water plant 302 on the top surface of the first support plate 301.

In order to simulate the water transfer of towns, the town simulating plate 5 comprises a second supporting plate 501, an urban river channel 502 is arranged in the center of the top surface of the second supporting plate 501, and buildings 503 are fixedly welded on the left side and the right side of the urban river channel 502 on the top surface of the second supporting plate 501.

In order to simulate the water transfer of water treatment, the water treatment simulation plate 6 comprises a third support plate 601, a sewage storage tank 603 is arranged in the center of the top surface of the third support plate 601, and a water treatment mechanism 602 protrudes from the top surface of the third support plate 601 on one side of the sewage storage tank 603.

In order to form a complete water circulation, a water pump is arranged inside the first supporting plate 301, and a water inlet port of the water pump is communicated with the inside of the sewage storage tank 603 through the underground pipeline 8.

In order to simulate the sky rainfall pattern, the sky simulation plate 7 comprises a top plate 701, a cloud groove 702 is formed in the center of the top surface of the top plate 701, an electromagnetic valve 703 is arranged in the center of the bottom surface of the Yun Xingcao 702, yun Xingcao is fixedly welded to a uniform flow plate 705 below the electromagnetic valve 703, and water outlet micropores 704 are uniformly formed in the bottom surface of the top plate 701 and the bottom surface of the uniform flow plate 705.

In order to provide rainfall, the supporting mechanism 2 includes a supporting column 201, a circulating water pump 202 is embedded in the supporting column 201, water inlet ports of the four circulating water pumps 202 are respectively communicated with the interiors of the first supporting plate 301, the lake simulation plate 4, the second supporting plate 501 and the third supporting plate 601, and water outlet ports of the four circulating water pumps 202 are communicated with the interiors of the cloud-shaped grooves 702.

In summary, when the inter-area water quantity transfer simulator provided by the utility model works, the device is firstly communicated with a power supply, then enough water is added into the lake simulation plate 4 and the sewage storage tank 603, meanwhile, the water in the sewage storage tank 603 is pumped by the water pump in the first supporting plate 301 to be supplied to the water plant 302, the water flows from the water plant 302 to the lake simulation plate 4 according to the height of the terrain, then flows from the lake simulation plate 4 to the city river 502, and finally enters the sewage storage tank 603 from the city river 502 to form liquid circulation;

secondly, water in the water works simulation plate 3, the lake simulation plate 4, the town simulation plate 5 and the water treatment simulation plate 6 can be pumped through the circulating water pump 202 and supplied to the cloud groove 702, meanwhile, the electromagnetic valve 703 is opened, water flows downwards to the surface of the uniform flow plate 705 through the electromagnetic valve 703 and is uniformly diffused, and then flows out from the inside of the water outlet micropores 704 on the bottom surface of the top plate 701 to form a rainfall phenomenon, meanwhile, the whole water quantity is kept in a constant state, and the water quantity transferring and circulating process can be accurately demonstrated.

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

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

Claims (7)

1. An inter-site water transfer simulator, comprising: the device comprises a supporting base (1), a supporting mechanism (2), a water plant simulation plate (3), a lake simulation plate (4), a town simulation plate (5), a water treatment simulation plate (6) and a sky simulation plate (7);

the water treatment simulation device comprises a supporting base (1), a water plant simulation plate (3), a lake simulation plate (4), a town simulation plate (5) and a water treatment simulation plate (6) are fixedly welded to four corners of the top surface of the supporting base (1), the water plant simulation plate (3), the lake simulation plate (4), the town simulation plate (5) and the water treatment simulation plate (6) are spirally and stepwise welded in a whole, the water plant simulation plate (3), the lake simulation plate (4), the town simulation plate (5) and the water treatment simulation plate (6) are fixedly installed between the four supporting mechanisms (2), the sky simulation plate (7) is fixedly welded to the four tops of the supporting mechanisms (2), and underground pipelines (8) are arranged between two adjacent water plant simulation plates (3), lake simulation plates (4), town simulation plates (5) and water treatment simulation plates (6).

The supporting base (1) and the four supporting mechanisms (2) are used for providing support, the sky simulation plate (7) is used for simulating rainfall in rainy days, the water plant simulation plate (3) is used for simulating water flow transfer of a water plant, the lake simulation plate (4) is used for simulating water flow transfer of a lake, the town simulation plate (5) is used for simulating water flow transfer of a town, and the water treatment simulation plate (6) is used for simulating water flow transfer of sewage treatment.

2. The inter-site water quantity transfer simulator according to claim 1, wherein the water plant simulation plate (3) comprises a first support plate (301), a water tank is arranged inside the first support plate (301), a water plant (302) is fixedly arranged on the top surface of the first support plate (301), and trees (303) are fixedly welded on the periphery of the water plant (302) on the top surface of the first support plate (301).

3. The inter-site water quantity transfer simulator according to claim 2, wherein the town simulation board (5) comprises a second supporting board (501), an urban river channel (502) is arranged in the center of the top surface of the second supporting board (501), and buildings (503) are fixedly welded on the left side and the right side of the urban river channel (502) on the top surface of the second supporting board (501).

4. A water transfer simulator between areas according to claim 3, characterized in that the water treatment simulation plate (6) comprises a third support plate (601), a sewage storage tank (603) is arranged in the center of the top surface of the third support plate (601), and a water treatment mechanism (602) protrudes from the top surface of the third support plate (601) at one side of the sewage storage tank (603).

5. The inter-site water transfer simulator according to claim 4, wherein a water pump is provided inside the first support plate (301), and the water inlet port of the water pump is communicated with the inside of the sewage storage tank (603) through the underground pipe (8).

6. The inter-site water quantity transfer simulator of claim 5, wherein the sky simulation plate (7) comprises a top plate (701), a cloud groove (702) is formed in the center of the top surface of the top plate (701), an electromagnetic valve (703) is arranged in the center of the bottom surface of the Yun Xingcao (702), yun Xingcao (702) is fixedly welded to a uniform flow plate (705) under the electromagnetic valve (703), and water outlet micropores (704) are uniformly formed in the bottom surface of the top plate (701) and the bottom surface of the uniform flow plate (705).

7. The inter-site water transfer simulator according to claim 6, wherein the supporting mechanism (2) comprises a supporting column (201), a circulating water pump (202) is embedded in the supporting column (201), water inlet ports of the four circulating water pumps (202) are respectively communicated with the interiors of the first supporting plate (301), the lake simulation plate (4), the second supporting plate (501) and the third supporting plate (601), and water outlet ports of the four circulating water pumps (202) are communicated with the interiors of the Yun Xingcao (702).

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